Measurement Facility Design Specifications 2008-2009 · Measurement Facility Design Specifications Tab ... Condensate removal/storage/handling requirements ... DESIGN SPECIFICATIONS

Measurement FacilityDesign Specifications

2008-2009

METER STATION DESIGN SPECIFICATIONS &

MEASUREMENT PRACTICES

MEASUREMENT FACILITY DESIGN SPECIFICATIONS

Formerly “Meter Station Design Specifications & Measurement Practices”

2008 / 2009

Entire contents Copyright © by Cheyenne Plains Gas Co., Colorado Interstate Gas Co., El Paso Natural Gas Co., Mojave Pipeline Co., Southern Natural Gas Co., Tennessee Gas Pipeline Co., and

Wyoming Interstate Co. as an unpublished work 1994, 1996, 1998, 2000, 2001, 2002, 2003, 2004/2005, 2006/2007, 2008/2009. All rights reserved. Reproduction, adaptation, public display, and distribution of all or any part or this work are strictly prohibited under penalty of law. For permission to

quote small parts of this work, you must send a request with an explanation of the portion to be copied, number of copies, and purpose to:

TGP Engineering Southeast Engineering Western Engineering 1001 Louisiana 569 Brookwood Village 2 N. Nevada Avenue Houston, TX 77002 Birmingham, AL 35209 Colorado Springs, CO 80903

MESUREMENT FACILITY DESIGN SPECIFICATIONS

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TABLE of CONTENTS

Measurement Facility Design Specifications Tab Approved Measurement Operating Equipment Tab Measurement Facility Equipment Specifications Tab Meter Capacity Tables Tab Standard Meter Tube Drawings Tab

“On a best practices basis, Measurement Services sets the system-wide standards by which Engineering designs and constructs measurement facilities and by which Field Operations operates them.”


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TABLE of CONTENTS 1 1. INTRODUCTION 3 2. GENERAL 3 2.1 Applicable Codes and Standards 3 2.2 Initial Data 3 2.3 Meter Station Sizing 4 3. METER STATION SITE 4 3.1 Onshore Locations 4 3.2 Offshore Locations 5 3.3 Structures 5 4. METER STATION PIPING 6 4.1 Major Piping and Valving 6 4.2 Flow Control and Pressure Regulation 7 4.3 Bi-Directional Piping Configuration 9 4.4 Meter Bypass Piping 9 4.5 Loading Lines and Blowdown Valves 9 5. OVERPRESSURE PROTECTION 10 5.1 MAOP Rating Continuity 10 5.2 General 10 5.3 Onshore Overpressure Protection 10 5.4 Offshore Overpressure Protection 10 6. PRIMARY MEASUREMENT DEVICES 10 6.1 Orifice Meters 11 6.2 Turbine Meters and Positive Displacement Meters 11 6.3 Multipath Ultrasonic Meters 13 6.4 Ultrasonic Meter Performance Requirements 14 7. SECONDARY MEASUREMENT DEVICES 16 7.1 Transmitters, General 16 7.2 Differential Pressure 17 7.3 Static Gauge Pressure 17 7.4 Temperature 17 7.5 Integral Transmitters and Transducers 17 8. TERTIARY MEASUREMENT DEVICES 17 8.1 Installation Criteria 17 8.2 Gas Flow Computer Types 18 8.3 Grounding 18 8.4 Isolation and Intrinsically Safe Wiring Practices 18 8.5 Interfacing 19 9. TUBING 19 10. GAS SAMPLERS 19 10.1 Sampler Requirements 19 10.2 Tubing Installation Requirements 20 10.3 Sample Probe Location 20 10.4 Sample Cylinder 20


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11. GAS CHROMATOGRAPHS 20 11.1 Chromatograph Location Requirements 20 11.2 Chromatograph Installation Requirements 20 12. ODORIZATION 21 13. GAS QUALITY REQUIREMENTS and ANALYTICAL INSTRUMENTATION 21 14. OTHER CONSIDERATIONS 22 14.1 Compression 22 14.2 Dehydration 22 14.3 Heating 22 14.4 Separation and Filtration 22 15. COMMUNICATIONS 23 16. CORROSION CONTROL 23 17. STANDARD MATERIAL SPECIFICATIONS 23 18. STANDARD DRAWINGS 23 19. METERING FOR OFFSHORE USE 23 20. MEASUREMENT FACILITY WAIVERS and VARIANCES 23


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1. INTRODUCTION

These specifications present the meter and regulator station (measurement facilities) design requirements for El Paso Pipeline Group. The design specifications shall apply to internal interstate natural gas transmission pipeline company departments and all other parties. Second and third party designs, drawings, and specifications must be reviewed and approved by El Paso. Any deviation for a specific measurement facility design from these specifications must be reviewed and approved by El Paso's Measurement Services management. All waivers so given must be in writing. Consult Measurement Services for differences among the El Paso pipelines (e.g., regarding equipment).

2. GENERAL

2.1. Applicable Codes and Standards

2.1.1 Measurement facilities shall be designed to comply with all applicable local, state, and federal requirements, which shall include but not be limited to American Gas Association (AGA), American Petroleum Institute (API), American Society of Mechanical Engineers (ASME), U.S. Department of Transportation (DOT) Office on Pipeline Safety (OPS), Minerals Management Service (MMS), National Fire Protection Association (NFPA), National Electric Code (NEC), U.S. Environmental Protection Agency (EPA), U.S. Occupational Safety and Health Administration (OSHA), and all other applicable codes.

2.1.2 Measurement facilities shall be designed to comply with all El Paso company standards, which shall include but not be limited to the latest edition of this manual, Manual of Engineering Standards (MES), Construction Specifications for Compressor and Meter Stations, Construction Specifications for Land Pipeline Construction, Coating Specifications Manual, Welding Manual, NDE Manual, Operating and Maintenance Manual (O&M), and Safety & Health Handbook. Any design consideration producing an unsafe condition shall require immediate corrective action prior to being placed in service.

2.2 Initial Data

The following shall be taken into consideration when designing a measurement facility:

Design Parameter Units Expected flow rates (maximum, normal, minimum) MMscfd Expected peak hourly flow rates (maximum, normal, minimum) Mscfh Projected growth Pressure (maximum, normal, minimum) psig Maximum Allowable Operating Pressure (MAOP) of both systems psig Maximum Operating Pressure (MOP) of both systems psig Overpressure protection Expected flowing temperatures (maximum, normal, minimum) ºF Base pressure Tariff Base Temperature 60 ºF Atmospheric pressure Tariff Specific gravity Hydrocarbon dewpoint ºF Water content lbs. / MMscf Maximum carbon dioxide, nitrogen, and oxygen (diluents) mole %


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Maximum hydrogen sulfide grains/100 scf Gas composition and gas quality determination method Maximum delivery pressure (downstream of meter) psig Maximum allowable noise dBA EGM software and hardware specifics per operating company Control method requirements (e.g., flow control with pressure override) Remote monitoring and control requirements Frequency of monitoring required (real-time/daily/weekly/monthly) Location (onshore/offshore/wetland/residential area, etc.) Availability of utilities (electricity, telephone, etc.) Local building or other permitting requirements Liquid removal, measurement, and re-injection requirements Condensate removal/storage/handling requirements Critical need for service (shutdown of service for inspection allowable or not) Filter separator requirement Heating requirement Odorization requirement

2.3 Meter Station Sizing

2.3.1 Measurement facilities shall be designed to accommodate all requested and expected flow rates for the application.

2.3.2 Designs shall include minimum/low flow rates such as domestic, utility, and/or auxiliary fuel uses in an industrial process. Small capacity meters are required for these applications. Staging or ramping of process loads and start rates shall also be considered.

2.3.3 Consideration shall be given when sizing the meter to eliminate operation for prolonged periods of time at either extremely low flow and/or at maximum capacity, which are outside the given design criteria range.

2.3.4 Meter selection and sizing requirements shall be qualified on the basis of

application experience of Measurement Services and shall be consulted accordingly.

3. METER STATION SITE

3.1. Onshore Locations

3.1.1. The measurement facility shall be located near a public road and/or have an all weather access road. The station shall be located as close to the pipeline rights-of-way as practical, and allow sufficient access to the pipeline. Measurement facilities shall not be constructed over the pipeline. Measurement facilities not owned by El Paso shall be located off of the pipeline rights-of-way.

3.1.2. The site area shall be adequately sized for ease of access and operation. Allowances shall be made to allow a full size pickup truck access between the station piping and the fence. A minimum of 10 feet spacing is required. Generally, a 100’ x 100’ plot is recommended to accommodate all equipment. Noise concerns may require larger sites.

3.1.3. A chain link fence having a minimum height of six feet, with locking gates shall surround all above ground piping. A sign identifying the facility by name and operator shall be posted at or near the gate. This sign shall include an


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emergency telephone number. All El Paso facility security standards shall be adhered to.

3.1.4. The station area within the fence shall be kept vegetation free through the use of ground cover. This could be achieved through the use of plastic covered with gravel, shell, etc.

3.1.5. The site shall have adequate drainage to prevent any flooding or standing water.

3.2. Offshore Locations

3.2.1. As required by field operations the measurement facility shall be located on a platform having both a heliport and boat access. The heliport at the measurement platform location shall meet the American Petroleum Institute standards for Planning, Designing and Constructing Heliports for Fixed Offshore Platforms, API-RP-2L, 4th Edition, dated May 1996, as a minimum. The heliport shall be capable of handling a load rating of no less than 6,000 pounds.

3.2.2. The measurement facility shall be at an elevation to clear storm tides.

3.2.3. The piping to and from the measurement facility shall be designed so as to prevent trapping of liquid.

3.3. Structures

3.3.1. Consult Field Operations for the requirement of structures or the appropriate structure compatible with the local operating area. Where climatic conditions or other critical needs of a meter station exist, a walk-in building will be required. TGP requires the installation of meter buildings.

3.3.2. Buildings are defined as a fully enclosed structure (i.e., roof, four full walls, door, and so forth). Shelters are defined as a cover from the weather (i.e., roof with or without partial walls). Canopies are roof only.

3.3.3. The measurement facilities shall be installed inside a building where operationally required. Buildings constructed over primary devices will be sized to include all temperature thermowells. Provisions shall be made to allow for physical removal of the primary device and piping for inspection. As appropriate, all gas venting devices located inside a building must be piped to the outside.

3.3.4. Where meter buildings are required for offshore locations per Field Operations option, all runs shall be housed within a single structure.

3.3.5. Offshore structures for meter buildings shall be fabricated using aluminum panels rated for offshore environment and shall have a metal checkered plate floor.

3.3.6. For meter tube maintenance, building panels shall be designed to be removable.

3.3.7. If a building is required, specifications for metal buildings are included herewith.


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3.3.8. Metering structures not meeting the requirement of AGA XF0277 (NEC 500 – 503 and 510) shall have an electrical classification of NEC Class I, Division 1, Group D. No flammable material shall be used in NEC Class I, Division 1 and 2 structures or interiors. Building manufacture is subject to inspection and approval by Measurement Services.

3.3.9. If required by Section 3.3.1, secondary measurement and control equipment shall be protected under a canopy, wind break, or in a walk-in type building, which can be secured and protected. This structure may be mounted on a skid or installed on a concrete foundation. Sonotube piers are recommended for skid-mounted meter buildings. Due to the possibility of washouts, surface blocks for mounting meter skids are not recommended.

3.3.10. Any customer operated equipment such as heat exchangers, boilers, regulators/control valves must reside separate from the El Paso meter buildings and structures and be located a minimum of 15 ft. away.

3.3.11. The gas quality building shall be a temperature-controlled environment. The entire gas chromatograph system shall be installed in the gas quality building with combustible gas detection. The detector will shut off the sample stream(s) and calibration gas, give an alarm indication to the GFC, and illuminate a warning light outside of the building. The gas quality building shall be located in a non-hazardous (general purpose) area and ventilated per AGA XF0277 (API RP 500, NFPA 497A and 59A).

4. METER STATION PIPING

4.1. Major Piping and Valving

4.1.1. Measurement facility piping between the meter station and tie-in points shall be designed to minimize pressure drop and gas velocity, preferably less than 50 fps. As applicable, the tie-in point shall include tap (side) valve, blowdown, and check valve.

4.1.2. Piping and fittings located between the meter run and El Paso's pipeline must be welded and coated in accordance with El Paso's specifications. Piping shall be buried wherever possible. The use of screwed piping shall be restricted to less than 2” nominal diameter.

4.1.3. All valves, fittings and equipment subject to pressure must comply with all the requirements of the Federal Gas Pipeline Safety Regulations, El Paso Engineering standards, and all other applicable codes such as but not limited to API Specification 5L, API Specification 6D, ANSI B16.5, and ANSI B16.9.

4.1.4. In accordance with DOT 49 CFR Part 192, pipe used for measurement facilities shall be designed with a Class 3 design factor of 0.50 (50% of SMYS). If the measurement facility is situated in a Class 4 location, then the design factor shall be 0.40.

4.1.5. All meter tubes shall have upstream and downstream isolation valves. The isolation valves shall be non-lubricated full opening ball valves with locking provisions. To minimize flow distortion, the upstream piping effects and design


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should be considered. SNG and TGP required the use of inspection tees as shown on the Standard Meter Tube Drawings.

4.1.6. An insulating gasket set shall be installed on both ends of the meter tube(s) or the inlet(s) and outlet(s) of the skid, as applicable. The insulating gasket should be located outside the meter building. In accordance with DOT 49 CFR 192.467(e), if the insulating gasket is installed inside a building, an arc prevention device must be properly installed. All below grade gas piping must be cathodically protected. Consult Corrosion Control for additional details.

4.1.7. Where single or multiple meter tubes are used, tube-switching actuators shall be installed on all of the downstream meter tube isolation valves, as required. Also, see Section 4.2.14. Primary devices shall be sized to ensure that the expected flow range is covered and proper tube switching is performed. Run #1 shall be the smallest meter with sequential numbering as meter size increases.

4.1.8. All multiple meter tube installations will require upstream and downstream headers. Headers shall be sized to keep the maximum gas velocity in the header to 30 fps or less. Headers shall be sized per the following equation and rounded to the nearest nominal pipe size diameter:

Dh = (2(D12 + D2

2 +… Dn

2))0.5

On a given run, the risers, block valves, and meter tubes are assumed to be of the same size and where:

Dh = Internal diameter of header

D1, D2, …Dn = Internal diameter of the individual meter run

n = Number of active meter runs

4.1.9. Where the active meter runs are of different sizes, the “Z” header configuration is recommended. Utilizing the “T” header configuration and feeding the center of the header will reduce pulsation through the meter station and reduce the required header size for complying with the 30 fps maximum gas velocity criteria. Headers shall be equipped with siphon/blowdown valve assemblies or drains for liquid removal. Vertical header arrangements are not permitted. The header design described herein is recommended for multiple control valve runs. Specifications for headers are available upon request.

4.1.10. Sufficient adjustable supports shall be installed under piping to prevent excess stress, strain, and deflection on the piping assembly. The supports shall be designed to facilitate inspection of the pipe where in contact with the supports. Neoprene or other suitable material shall interface between the pipe and support. For in-ground applications, the supports shall be set in concrete (e.g., Sonotube piers or poured forms). For skid-mounted applications, the supports shall be welded to the structural steel.

4.1.11. If a field pressure test of the meter tube is required, nitrogen shall be used as the test medium, if allowed by code. Field pressure tests require the removal of the primary devices.


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4.1.12. As required by Measurement Services’ Gas Quality group, automatic or remotely-operated shut-in valves shall be installed at all receipt points where gas quality is monitored using on-line analytical instrumentation. (see Sections 11 and 13 for additional information.)

4.2. Flow Control and Pressure Regulation

4.2.1. El Paso does not perform pressure regulation for the purpose of providing a constant regulated delivery pressure to the customer. Pressure regulation may be performed for company operational functionality.

4.2.2. Pressure regulation and/or flow control valves shall be installed downstream of the meter run isolation valve and/or header. Piping is required between the metering and regulation and/or flow control valves to minimize acoustic error effects on metering equipment. When ultrasonic noise is anticipated, consult Measurement Services for recommended piping configurations.

4.2.3. In accordance with ISA Standard S75.01, regulators and control valves shall be sized to handle the expected range of flows and the expected range of pressures, at 10% to 90% of valve travel/open. If this condition cannot be met, additional control valves must be added using split range control. (See Equipment Specifications - Control for additional sizing parameters.)

4.2.4. Depending upon application and design requirements, use of fail-open or fail-closed control valves shall be determined on a case-by-case basis.

4.2.5. Flow control shall be considered on a case-by-case basis depending on the application. Generally, flow control is the responsibility of the party performing custody transfer. Exceptions include gas storage facility interconnects.

4.2.6. Noise prediction methods shall be based upon ISA Standard S75.17. If noise levels exceed local, state, or federal requirements, adequate measures shall be undertaken to attenuate such noise to the acceptable level. For above ground piping, the predicted SPL shall not exceed 85 dBA. The use of extra heavy wall pipe is required for regulator/flow control station piping. Downstream pipe velocities on the regulator/control valve run and regulator/control valve outlet velocities must be limited to a maximum of 100 fps.

4.2.7. Upstream and downstream piping shall be the same diameter or larger than all control valves and regulators. Swages shall be installed adjacent to valve. Seven nominal pipe diameters of straight pipe shall be installed downstream of the control valve and preferably the same upstream.

4.2.8. Isolation full-opening ball valves with locking provisions shall be installed upstream and downstream of all regulators and control valve runs.

4.2.9. A bleed valve shall be installed between the regulator/control valve and any isolation valve, upstream or downstream. Bleed valves shall be installed within any section, which may be isolated.

4.2.10. A bypass shall be installed around all regulators and control valves unless two or more are installed in parallel. Taps shall be provided on the bypass for pressure


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sensing and instrument supply/power gas. Locking devices shall be installed on all bypass valves.

4.2.11. The operating temperature range of all equipment shall be considered. Adequate heating facilities shall be installed to prevent regulator freezing or other control problems.

4.2.12. Pressure and flow control systems shall have filtered and dried sources of instrument supply/power gas.

4.2.13. Each pressure control device shall have independent sensing lines.

4.2.14. Where positive shut-off is required, measurement facilities with flow control or pressure regulation shall be fitted with a valve and actuator for zero flow shut-in or zero flow rate setpoint shut-in. Typically this valve with actuator is installed on meter run #1. Provisions shall be made to provide for pressurizing the piping before opening the positive shut-off valve.

4.3. Bi-Directional Piping Configuration

4.3.1. Orifice and Turbine Meters

Single and multiple meter runs with bi-directional manifold piping shall be designed where gas flow is always in the same direction through the tube(s).

4.3.2. Bi-directional ultrasonic meter stations may be configured in either of two different ways.

4.3.2.1. Single and multiple ultrasonic meter runs with bi-directional manifold piping shall be designed where gas always flows in the same direction through the tubes.

4.3.2.2. Single and multiple ultrasonic meter runs shall be designed where gas flow may be reversed within the tube.

4.3.3. Bi-Directional manifold valves shall be equipped with limit-switches for flow direction indication and check valves for the prevention of un-metered gas.

4.4. Meter Bypass Piping

Installation of meter bypass will be evaluated based on operating conditions and maintenance requirements. A meter bypass must have a piping system utilizing double block and bleed valves with locking mechanisms.

4.5 Loading Lines and Blowdown Valves

4.5.1 All ultrasonic meter tubes, turbine meter tubes, rotary meters, and diaphragm meters shall have a loading line installed as a bypass around the upstream isolation valve.

4.5.2 All ultrasonic meter tubes, turbine meter tubes, rotary meters, and diaphragm meters shall have blowdown valves installed on the last downstream tap of the meter run.


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4.5.3 Loading lines shall consist of tubing and fittings commensurate with the specifications in Section 9. A single full opening ball valve shall be used for loading lines and blowdown valves.

4.5.4 Loading lines and blowdown valves shall be sized as follows:

• ¼” for 1” thru 3” meter tubes or meters • ½” for 4” meter tubes • 1” for 6” and larger meter tubes

5 OVERPRESSURE PROTECTION

5.1 MAOP Rating Continuity

All piping shall comply with DOT 49 CFR 192.195. Continuity in ratings and maximum allowable operating pressure (MAOP) in material is required.

5.2 General

5.2.1 All overpressure protection devices that are operated and controlled by a GFC shall also operate and control pneumatically and independently from the GFC.

5.2.2 Overpressure protection will be required for receipt measurement facilities that have higher MAOPs than El Paso’s system. El Paso will not rely on third parties for this provision.

5.2.3 All relief valves shall have an isolation valve with locking mechanism installed immediately upstream of the relief valve. Provisions shall be made for testing the relief valve such as a bleed ring or test spool.

5.2.4 Unique to CIG, all relief valves at measurement facilities shall be equipped with monitoring devices that will send an alarm to Gas Control via the GFC.

5.3 Onshore Overpressure Protection Devices

5.3.1 Overpressure protection devices must be independent of primary pressure regulators and control valves.

5.3.2 The selection of any overpressure protection device(s) will be with the concurrence of the operator of the system to be protected. Relief valves, fail-closed spring return actuated valves, slam valves with manual reset, and modulating valve monitors are approved for overpressure protection.

5.3.3 Monitor sensing lines and supply/power gas will be independent and dedicated to the overpressure protection purpose. Depending upon customer requirements, use of fail-open or fail-closed monitor valves shall be determined on a case-by-case basis.

5.4 Offshore Overpressure Protection Devices

5.4.1 El Paso will rely on the ESD valve on the departing pipeline as OPP to protect the pipeline MAOP against higher pressures.


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5.4.2 The Engineer or Project Manager will also endeavor to obtain from the production facility operator a statement that the facility's safety shutdown system is designed in accordance with appropriate MMS or DOT regulations applicable and will indicate maximum pressure that might be available on El Paso facilities.

6 PRIMARY MEASUREMENT DEVICES

6.1 Orifice Meters

6.1.1 The orifice meter stations must be constructed to conform to standards as specified in Section 18 and “Orifice Meter Tube Inspection Specifications for Fabricators.” For new tubes, the use of orifice meter fittings that have been previously used are unacceptable and prohibited.

6.1.2 Dimensions and specifications for all orifice meter tubes are to comply with drawing TYP-METR-3000, AGA Report No. 3, and API MPMS 14.3.

6.1.3 The orifice meter tube nominal size shall be designed by utilizing the following criteria:

6.1.3.1 For the purpose of sizing, use a transmitter calibrated span value of 250 In.WC for Rosemount transmitters, 300 In.WC for Bristol, Honeywell, and Yokogawa transmitters.

6.1.3.2 The expected peak maximum hourly flow rate at a 0.6 beta ratio with a maximum differential pressure of 90% of the calibrated span at minimum expected static pressure.

6.1.3.3 The expected minimum hourly flow rate at a 0.2 beta ratio with a minimum differential pressure of 10% of the calibrated span at maximum expected static pressure. Differential pressure transmitter spans may be lowered to capture minimum flow situations but the same span must be used for the minimum and maximum flow calculations.

6.1.3.4 The sizing shall be designed to eliminate or at least minimize the need for orifice plate changes and ensure that the expected flow range is covered.

6.1.4 The sharing of custody meter taps or gauge lines is not permissible.

6.1.5 For an orifice fitting installed and rotated 90 degrees, with the opening for the orifice plate holder on the side and the DP tap holes on the top, a ball valve shall be installed on the bottom upstream differential pressure tap for a drain.

6.1.6 If an onshore orifice fitting is oriented upright, a ball valve shall be installed on the drain tap.

6.1.7 All offshore orifice fittings shall be rotated 90 degrees as described in Section 6.1.5.


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6.1.8 All meter tubes shall be installed and supported in the horizontal position. Instrument stands, meter tube leveling supports, tie down lugs, or other items will not be welded to the meter tube. Adjustable leveling supports may be required. (See Section 4.1.10 for additional information.)

6.1.9 At least one spacer plate shall be installed in the meter run assembly.

6.2 Turbine Meters and Positive Displacement Meters

6.2.1 All positive displacement (diaphragm and rotary) and turbine meter stations must be constructed to conform to standards as specified in Section 18.

6.2.2 Turbine meter tube dimensions and specifications are to comply with Section 18, drawing TYP-METR-2000, and AGA Report No. 7. Turbine meters shall be flow calibrated and sized by evaluating:

6.2.2.1 The expected peak maximum hourly flow rate at 90% of the rated capacity of the meter at minimum expected static pressure.

6.2.2.2 The expected minimum hourly flow rate at 10% of the rated capacity of the meter at maximum expected static pressure.

6.2.2.3 Sensus turbine meters, 6” and smaller, shall be flow calibrated at Sensus. Daniel turbine meters shall be flow calibrated at CEESI high pressure flow calibration facility in Nunn, CO.

6.2.2.4 The meters shall be flow calibrated with air at 420 psig. Flow calibration test points shall be 2.5, 5, 10, 25, 50, 70, and 100% of the meter’s maximum rated capacity. The meters shall be calibrated and supplied with certified accuracy test reports.

6.2.3 Rotary meters shall be calibrated and sized by evaluating:


6.2.3.2 The expected minimum hourly flow rate at manufacturer’s minimum stated capacity at 1% accuracy.

6.2.3.3 The meters shall be calibrated and supplied with certified accuracy test reports.

6.2.3.4 The recommended piping configurations for rotary meter sets are shown on drawings TYP-METR-4000 and 4001.

6.2.4 Diaphragm meters shall be designed by evaluating


6.2.4.2 Diaphragm meters shall be calibrated and supplied with certified accuracy test reports.


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6.2.4.3 The recommended piping configuration for diaphragm meter sets is shown on drawing TYP-METR-4002.

6.2.5 Full port proving taps are application dependent for positive displacement and turbine meter installations 4” and smaller. The upstream proving tap may be the inspection tee or a separate assembly. The downstream proving tap shall be located downstream of the meter and upstream of control valves and the restrictor device. Piping pressure losses between the meter and the proving tap shall be minimized. These proving taps shall accommodate either critical flow provers or transfer provers. The prover tap design shall incorporate instrument valves for bleed down of the prover valves.

6.2.6 The meter shall be installed with sufficient support to prevent any undue stress, strain, or deflection on the connecting piping. (See Section 4.1.10 for additional information.)

6.2.7 Static pressure shall be obtained from a pressure tap on the meter body.

6.2.8 A flow-limiting device must be installed downstream of the turbine or positive displacement meter to prevent over ranging.

6.2.9 Automatic oilers are required for meters that have lubrication ports and allow for the installation of such appurtenances.

6.2.10 A mesh strainer or filter shall be installed upstream of any turbine or rotary meter. If required, specifications for basket strainers are included herewith.

6.2.11 When using rotary meters, consideration is to be given to the impact of meter failure which blocks gas flow. A rupture disk or rupture pin installed in the bypass may be used where rotary meter lockup will block flow.

6.3 Multipath Ultrasonic Meters

6.3.1 Specifications not itemized by this document shall, at a minimum, comply with AGA Report No. 9, “Measurement of Gas by Multipath Ultrasonic Meters.” Ultrasonic meter stations must be constructed to conform to standards as specified in Section 18 of this standard.

6.3.2 The ultrasonic meter and nominal tube size shall be designed by utilizing the

following criteria:

6.3.2.1 The expected peak maximum hourly flow rate at a maximum gas velocity of 70 fps and at the minimum expected metering pressure. Caution should be taken to carefully examine the maximum velocity for noise and piping safety (e.g., erosion, thermowell vibrations, etc.) concerns. Caution should be taken to determine the resonant frequencies of thermowells at 70 fps.

6.3.2.2 The expected minimum hourly flow rate at a minimum gas velocity of 10

fps and at the maximum expected metering pressure.

6.3.3 Meter Requirements


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6.3.3.1 The meter shall be suitable for operation as a facility regulated by the DOT 49 CFR Part 192.

6.3.3.2 The meter shall be powered from a nominal 12 VDC or 24 VDC power supply and battery system that is compatible with the EGM type to be used for the installation. The meter shall remain powered for a minimum of 48 hours in the event of purchase power failure at the meter station.

6.3.3.3 As a minimum, the electronics unit of the meter shall be equipped with the following outputs:

• Serial data interface (RS-232/485) • Frequency representing velocity or uncorrected volume • Scaling shall be 0 - 1,000 Hz or 0 - 5,000 Hz • Voltage level to be specified • Alarms • Diagnostics

6.3.3.4 Static pressure shall be obtained from a pressure tap on the meter

body. 6.3.3.5 Three sets of complete documentation, including installation, operation,

maintenance, user manuals, drawings, flow calibration certification, and so forth, shall be provided. Measurement Services, Field Operations, and Project Management shall each receive one of these sets.

6.3.4 Piping Requirements

6.3.4.1 Dimensions and specifications for all ultrasonic meter tubes are to

comply with drawing TYP-METR-1000 and AGA Report No. 9.

6.3.4.2 The ultrasonic meter bore, flanges, and adjacent pipe spool sections (immediately upstream and downstream of the meter) shall all have the same inside diameter to within 0.5% of each other.

6.3.4.3 Changes in internal diameters and protrusions shall not be permitted at the ultrasonic meter inlet. The ultrasonic meter bore, flanges, and adjacent pipe spool sections shall all be carefully aligned to minimize flow disturbances, especially at the upstream flange. The upstream flange internal weld shall be ground smooth. No part of the upstream gasket or flange face edge shall protrude into the pipe internal diameter.

6.3.4.4 Pressure regulation and/or flow control valves shall be installed

downstream of the metering. Piping is required between metering and regulation and/or flow control valves to minimize acoustic error effects on the ultrasonic metering equipment. When ultrasonic noise is anticipated, consult Measurement Services for recommended piping configurations and other considerations for the attenuation of ultrasonic noise, originating from any source.

6.3.4.5 Ultrasonic transducers shall be non-retractable (i.e., cannot be removed

under pressure), except for single run applications without a bypass.


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To facilitate ultrasonic transducer removal, minimum spacing requirements between ultrasonic meter runs and beyond the outside runs shall be adhered to.

6.3.4.6 For bi-directional applications, conventional forward flow shall be

assigned to the predominant direction of flow.

6.4 Ultrasonic Meter Performance Requirements

6.4.1 All ultrasonic meter and tube assemblies shall be flow calibrated in a natural gas

high pressure flow (test) facility, having pressure and temperature standards which are traceable to NIST and which is acceptable to El Paso.

Bi-directional meters (reverse flow tubes) shall be tested in both directions. The ultrasonic meter shall be tested with all of the upstream and downstream piping sections, fittings, and flow conditioners. Bi-directional meters shall also include all thermowells. Flow calibration need not necessarily be included with the purchase of the meter. Consult Measurement Services and coordinate with MCM when flow calibration is a separate line item on the purchase requisition.

6.4.2 El Paso shall approve the use of any test facility prior to flow calibration. Flow

testing up to the maximum capacity of large ultrasonic meters may not be possible because of limitations of the test facility. In such cases, specify a lower flow rate instead of Q(max.) with approval of El Paso. The manufacturer shall state on all applicable documents if a reduced Q(max.) was used during flow calibration tests.

6.4.3 When possible, the meter assembly shall be tested at a temperature and

pressure equal to the average operating temperature and pressure the meter is expected to operate at in the field.

6.4.4 Measurement Services recommends that ultrasonic meters 8” and smaller be

flow calibrated at the MRF, SwRI, San Antonio, TX. Meters 10” and larger shall be tested at the other approved test facilities, which includes CEESI, Ventura, IA and TCC, Winnipeg, Manitoba, Canada. If the ultrasonic meter manufacturer does not require linearization, then 10” may also be calibrated at SwRI.

6.4.5 The range definition shall be 0-100% which shall be equivalent to 0-100 fps

velocity.

6.4.6 The flow points tested shall be, as close as possible, to 2.5, 5, 10, 25, 50, 70, 100% of range.

6.4.7 Each flow point shall be repeated a minimum of six (6) times or be evaluated

against a data gathering criteria of a minimum of 300 seconds of flow data per flow point and assume normal distribution having a standard distribution with 95% confidence.

6.4.8 If the calibration factors need to be adjusted, they shall be changed using a

multi-point or polynomial algorithm applied to the average flow points in the range from 10 to 70 fps. If the variance of all the data means from 10 to 70 fps


16

are within 0.2% of each other, then a simple meter factor may be applied. After the curve fit and/or adjustment factor has been applied to the meter’s software, two (2) flow points (verification points) shall be selected between 10 and 70 fps and the flow test repeated and the results recorded. These two (2) verification points shall be selected by the El Paso representative witnessing the flow test.

6.4.9 A meter test certification report shall be produced by the flow laboratory and

include all data points tested. A log file shall be produced, which is composed of two minutes of flow data for each tested flow rate. The log file and a copy of the certificate shall be sent to Measurement Services and another copy shall be sent with the meter to its shipping destination.

6.4.10 For bi-directional calibrations, a second set of factors must be used for reverse

flow.

6.4.11 The calibrated meter must meet the following acceptance criteria:

Parameter @ 10 – 70 fps % of Measured Value Maximum Permissible Error ± 0.2 Offset ± 0.04 Linearity ± 0.1 Repeatability 0.2 Resolution ± 0.003 fps Zero Flow Reading < 0.04 fps / path

6.4.12 At velocities below 10 fps, the maximum permissible error given in the table

above may be +/- 0.5%. These various parameters shall be stated with uncertainty analysis as presented in ISO 5168.

6.4.13 After the flow calibration has been conducted, the meter low flow cutoff should

be set at 2 fps by the test facility. 6.4.14 To verify the transit time measurement system of the meter, the manufacturer

shall perform a zero flow verification test. The manufacturer shall document and follow a test procedure that complies with AGA Report No. 9.

7 SECONDARY MEASUREMENT DEVICES

7.1 Transmitters, General

7.1.1 This specification applies to transmitters / transducers and shall be in

compliance with API MPMS 21.1.

7.1.2 Each primary measurement device shall have static gauge pressure and temperature transmitters. See list of “Approved Measurement Operating Equipment” for acceptable transmitters.

7.1.3 Electrical conduit must be run in such a manner, which will allow for easy removal of individual transmitters for service repair. Series connection of conduit between transmitters is not allowed. A conduit seal at the point of area classification change is required even if the seals are installed at the transmitters.


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7.1.4 For offshore installations, the use and proper installation of CLX cable is permissible.

7.1.5 Transmitters, which are not directly mounted on the orifice fitting, shall be

installed on a 2” pipe stand, located as close as is practical to the meter run. Transmitters stacked on the pipe stand shall not be installed at a height greater than 5 ft. The orientation of transmitters shall be such that all access covers shall be able to be easily removed without having to rearrange tubing or conduit.

7.1.6 For those applications where the transmitter’s tubing is not already isolated from

cathodic protection then all tubing connected to the transmitters shall be electrically isolated from the piping and be in compliance with DOT 49 CFR Part 192.467(e). Tubing lines shall be adequately supported using appropriate stands or tubing trays. Tubing lines shall be kept to a minimum run length.

7.1.7 As applicable to the transmitter, cases shall be grounded by use of no smaller

than #10 AWG stranded copper wire (green insulated) connected to a ground rod on the meter station ground grid. The transmitters (pressure, differential, and temperature) shall have in-line transient protection. The transmitter wiring shall be twisted shielded pair, with the shields grounded only at the GFC end.

7.1.8 Unless otherwise permitted, routing of tubing underground is prohibited. Where

permitted, buried tubing shall be continuous and without any fittings. Tubing will be sloped back to the source. Where condensate formation is possible, drip pots will be installed below the instrument manifolds.

7.2 Differential Pressure

7.2.1 The maximum standard calibrated span of the differential pressure transmitter shall not exceed 300 inches of water column (In.WC).

7.2.2 Differential pressure transmitters shall be installed either by means of direct mount manifold or gauge lines connected to a 5-valve manifold.

Both differential pressure transmitter gauge lines shall be of equal length and run as parallel as practical. Gauge lines shall enter the 5-valve manifold from the bottom side.

GFCs with integral transmitters shall be remote mount.

7.2.3 Isolation valves shall be provided at the metering taps and shall be full opening ball valves.

7.3 Static Gauge Pressure

7.3.1 The maximum standard calibrated span of the static gauge pressure transmitter shall not exceed 2000 psig. Storage field applications may be the exception.

7.3.2 Pressure transmitters shall be installed with appropriate valving to allow isolation and a valve for testing and venting. A 2-valve manifold is recommended.

7.4 Temperature


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Temperature transmitters shall be installed with appropriate conduit unions to be able to easily remove them from the meter run when testing. Flexible connectors from the conduit to the temperature transmitter or RTD, when installed on the meter run, are required. Permanent installation of test connectors between the transmitter and the RTD is prohibited.

7.5 Integral Transmitters and Transducers

GFCs, which have integral transmitters, shall be isolated from the meter run and sources of cathodic protection current. Installations must be in compliance with all hazardous area classification installation requirements.

8 TERTIARY MEASUREMENT DEVICES

8.1 Installation Criteria

8.1.1 This specification applies to both GFCs and electronic volume correctors and shall be in compliance with API MPMS 21.1.

8.1.2 The installation of Electronic Gas Measurement (EGM) equipment shall conform to El Paso practices, specifications, and drawings and the latest version of the NEC for hazardous area locations and AGA XF0277, "Classification of Gas Utility Areas for Electrical Installations", and/or local construction codes.

8.1.3 EGM shall be installed on all delivery and receipt meters.

8.1.4 Battery back up power shall be supplied to maintain the GFC for a minimum of 48 hours. For offshore installation, solar power shall have 21 days of autonomy.

8.2 Gas Flow Computer (GFC) Types

See list of “Approved Measurement Operating Equipment” for acceptable GFCs.

8.3 Grounding

8.3.1 Grounding shall be in compliance with NEC 250. When installing EGM system, attention shall be paid to electrical isolation from the pipeline and cathodic protection currents. The resistance to earth ground shall be maintained at a maximum of 5 ohms between instrumentation and ground.

8.3.2 The equipment and rack shall be grounded to a dedicated ground rod adjacent to the building, which is connected to the ground grid.

8.3.3 Every location shall have a single common ground grid throughout the site, using insulated wire. Each major section of the facility (e.g., filter separator, meter skid, control valve skid, EGM/GC building) shall have a ground loop and all loops connected. Each loop shall have at least one test well. Ground rods shall be installed no closer together than the actual length of the rods. Ground rods shall be installed no closer to cathodically protected pipe than the actual length of the rods. Solid copper grounding rods are required. Magnesium anodes are recommended as a replacement for rods, but the area operations personnel shall be contacted for their approval before installation. All grounding activities shall be coordinated with El Paso operations personnel.


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8.3.4 The electrical power service entrance shall be grounded at the pole prior to entering the EGM building. The DC/battery voltage is to be grounded on one leg depending on the polarity of the voltage needed to operate the equipment. The surge protection is to be installed on the input AC voltage supply, the DC battery charger, and all communication connections.

8.3.5 Although the meter tube is isolated from the pipeline, the tube is also grounded by attachment of a grounding lug at a flange or by exothermic welding to the flange (e.g., Cadweld). The grounding lead shall be tied directly to a separate earth ground rod or anode. The ground rod shall be tied to the ground grid.

8.3.6 Use of the conduit as an instrument ground path and/or to act as the ground wire is not acceptable.

8.4 Isolation and Intrinsically Safe Wiring Practices

8.4.1 Electronic equipment shall be isolated from the pipeline and be in compliance with DOT 49 CFR Part 192.467(e). No insulating flange gasket sets, insulating tubing unions, or like devices shall be installed inside measurement facility buildings that are classified hazardous area locations (NEC Class I, Division 1 or 2) unless arc suppression devices are properly employed.

8.4.2 Wiring practices for intrinsically safe circuits shall be in strict accordance with NEC Article 504 and ANSI/ISA-RP 12.6.

8.5 Interfacing

All signals to be shared from the GFC shall be isolated by means of a signal isolation device powered by the other party. Optical isolation shall have a minimum 600 volt rating. The design for sharing signals is limited to information purposes only and is not allowed without written approval.

9 TUBING

The following table defines the size of tubing that shall be used for different applications within a meter station:

Application From To Size (min OD.)

Static pressure Sensing tap 2-valve manifold 3/8”, 1/2” Differential pressure Sensing taps 5-valve manifold 1/2” Supply and power gas Gas supply tap Filter dryer 3/8” Tube switching Filter dryer Meter run tube switching valve actuator 3/8” Filter separator Filter dryer Filter separator 3/8” Control Filter dryer M/P converter 3/8” Control M/P converter A/M station 3/8” Control A/M station Control valve positioner or pilot 3/8” Control A/M station Hi/low selector relay 3/8” Control Hi/low selector relay Control valve positioner or pilot 3/8” GC sample line Tap Chromatograph 1/8”, 1/4”


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1. All tubing shall be 0.035” WT, ASTM A-269, 316SS, seamless, fully annealed. 2. Buried tubing shall have PVC jacket, ASTM D-1047 and shall be continuous without any fittings. 3. All fittings shall be commensurate with tubing and suitable therewith. 4. Differential pressure tubing shall not be run underground. 5. See Sections 7.1.6 and 7.1.8. 6. Sample lines for chromatographs shall be insulated heat-traced tubing.

10 GAS SAMPLERS

10.1 Sampler Requirements

A continuous (composite) sampler shall be installed on all meter stations designed to flow 1 MMscfd or more, unless covered by a chromatograph. Sampling proportional-to-flow is required. Gas sampling and samplers shall be in compliance with API MPMS 14.1.

A heated enclosure for the composite sampler shall be installed at meter station locations, where the ambient temperature may be within 5º F of the gas’ hydrocarbon dewpoint. Consult Measurement Services for this application requirement and for the use of a heat pipe.

10.2 Tubing Installation Requirements

Sample lag-time must be kept to a minimum. Tubing shall be kept as short as possible and slope ¼” per foot towards the source. Unless otherwise indicated, tubing size shall be ¼”, seamless, 316SS. Remote mounted continuous samplers (i.e., not probe mounted) shall use a pitot tube type sampling probe with a "speed loop."

10.3 Sample Probe Location

A sample probe shall be inserted in the least turbulent flowing stream section of meter station piping, preferably at the end of a straight run of horizontal pipe. The sample probe shall be inserted from the top of the pipe to the middle third of the pipe diameter and in accordance with drawing STD-METR-0002.

10.4 Sample Cylinder

Each continuous sampler system shall have only a single constant volume sample cylinder.

11 GAS CHROMATOGRAPHS

11.1 Chromatograph Location Requirements

Unless specified by the operating pipeline company’s tariff, gas chromatographs shall be installed on meter stations designed to flow 25 MMscfd or more. Where compliance with gas quality standards, impact on the pipeline system, or other concerns, chromatographs may be installed on meter stations designed to flow less than 25 MMscfd. Delivery stations from El Paso pipeline systems may not require a chromatograph if the gas analysis is zoned to a mainline chromatograph. A chromatograph shall be required on all bi-directional meter stations, or where the


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installation of a receipt meter station will cause a change in the gas analysis zoning of the El Paso system. Generally, chromatographs are not required at offshore locations.

11.2 Chromatograph Installation Requirements

11.2.1 Gas chromatographs shall consist of an approved controller and analyzer and

all required appurtenances. Installation methods shall be in accordance with El Paso standard methodology. Calibration gas cylinders shall be installed with a heating blanket and insulated from the building floor. If the analyzer power circuit is hardwired, then a switch should be included or it should be wired to a dedicated circuit breaker.

11.2.2 Tubing

11.2.2.1 Sample lag-time must be kept to a minimum and should broadly match GC analysis time. The insulated heat-traced line shall be kept as short as possible.

11.2.2.2 From the sample probe to the heater, tubing shall be insulated and slope ¼” per foot back to the source.

11.2.2.3 From the heater to the chromatograph’s stream shut-off box, the tubing shall be insulated, heat-traced, and in compliance with Section 9. The stream shut-off box shall be insulated.

11.2.2.4 For tubing runs ≤ 250 ft., 1/8” tubing shall be used. For tubing runs > 250 ft., 1/4” tubing shall be used. When H2O and H2S analyzers are used in conjunction with the GC, 1/4” tubing shall be used.

11.2.3 Sample system and conditioning

11.2.3.1 Proper sampling system conditioning is required to maintain the gaseous phase. Where the ambient temperature may be within 5º F of the gas hydrocarbon dewpoint, a heater and insulated heat-traced tubing are required.

11.2.3.2 A sample probe shall be inserted in the least turbulent flowing stream section of meter station piping, preferably at the end of a straight run of horizontal pipe. The sample probe shall be inserted from the top of the pipe to the middle third of the pipe diameter and in accordance with drawing STD-METR-0002. Consult Measurement Services regarding the use a regulator probe.

12 ODORIZATION

El Paso does not odorize for its customers.

Where required for receipts into El Paso odorized pipelines, odorization equipment must be incorporated into the design of the measurement facility. For compatibility, odorant blends shall meet El Paso specifications. Consult Measurement Services for additional requirements and considerations.


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13 GAS QUALITY REQUIREMENTS and ANALYTICAL INSTRUMENTATION

13.1 Gas quality specifications shall comply with the individual El Paso operating pipeline company FERC Gas Tariffs.

13.2 Where compliance with gas quality standards, impact on the pipeline system, or other concerns, analytical instrumentation shall be installed on meter stations. Analytical instrumentation for gas quality may include but shall not be limited to CO2, H2S, H2O, and O2. Consult Measurement Services for additional requirements and considerations.

13.3 On-line gas quality analytical instrumentation shall be installed at the following receipt (producers, gathering systems, pipe-to-pipe, etc.) points:

13.3.1 Plants treating gas for CO2 or H2S.

13.3.2 Production formations where CO2 or H2S has been identified.

13.3.3 Sources with H2O dehydration immediately upstream of an El Paso pipeline.

13.3.4 Sources with a potential of delivering O2 or He.

13.4 Automatic or remotely-operated shut-in valves shall be installed at all receipt points where gas quality is monitored using on-line analytical instrumentation, as required by Measurement Services. These valves shall be installed at the inlet to the meter station and be independent of all other valves. Provisions shall be made for a sample probe and blowdown of the upstream piping.

14 OTHER CONSIDERATIONS

14.1 Compression

14.1.1 When compression facilities are installed it may be necessary to install a pulsation dampener between the compressor and the measuring facility. The cost of remediation shall be borne by the party responsible for the source of pulsation. Consult Measurement Services for pulsation testing.

14.1.2 Compressor fuel gas, domestic fuel, etc. shall be located upstream of the measurement facility at El Paso receipt stations and downstream at El Paso delivery stations unless it is specifically addressed in a contract or agreement.

14.2 Dehydration

14.2.1 If a dehydration unit is not located immediately upstream of the meter station and there is a possibility of liquid accumulation, a separator or filter separator must be installed directly upstream of the measurement facility. The dehydration unit must be approved by El Paso prior to the installation.

14.2.2 All instrument and fuel gas supply points will be upstream of the meter station at El Paso receipt stations and downstream at El Paso delivery stations. Calcium chloride (or other chloride containing compounds) cannot be used as a desiccant for removal of entrained water. Triethylene glycol dehydration units are highly recommended. No by-pass is allowed around the dehydration facility.


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14.2.3 Where dehydration occurs upstream of an El Paso pipeline system, El Paso will, at its discretion, require a moisture analyzer to be installed.

14.3 Heating

14.3.1 The heating requirements for the installation of heating equipment is dependent upon the hydrocarbon and water dew points, the pipe, pipe coating, and the appurtenances for that location. Consult Measurement Services for requirements and considerations.

14.3.2 The heating equipment must be located away from the measuring facility a minimum of 15 ft.

14.4 Separation and Filtration

14.4.1 Producers must install a separator or filter separator equipped with liquid level control upstream of the measurement facility to prevent receipt of free liquids. If the dehydration and/or separation is a significant distance from the pipeline and pipeline drip condensation is possible, a separator or filter separator will be installed at the inlet of the measurement facility.

14.4.2 Delivery meter stations may require filter separators. The determination of the requirement for filtration and separation is made as a result of operating experience for the location.

14.4.3 Specifications for filter separators and, if required, liquid storage tanks are included herewith.

15 COMMUNICATIONS

El Paso Communications Department must review communications requirements for each project.

16 CORROSION CONTROL

El Paso Operations Services Department shall be consulted to ensure that proper corrosion control, cathodic protection, and/or AC mitigation is incorporated into the design of the measurement facilities. All below grade gas piping must be cathodically protected.

Provisions shall be made for the installation of an EM (electron microscope) corrosion coupon. The location for such shall not be on the meter tube(s).

Corrosion control may include but not be limited to such items as insulating flange gasket sets, grounding cells, anode beds, rectifiers, CP jumpers, and monolithic isolating pipe joints.

17 STANDARD MATERIAL SPECIFICATIONS

Either the El Paso Engineering Department or El Paso Measurement Services will make approved material specifications available upon request. Most of these specifications are included herewith.

18 STANDARD DRAWINGS


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Approved standard drawings are available upon request from either the El Paso Engineering Department or Measurement Services. Most of these drawings are included herewith.

19 METERING FOR OFFSHORE USE

As required and to be evaluated on a case-by-case basis, offshore metering uses RTJ flanges on the inlet and outlet meter tube ends.

20 MEASUREMENT FACILITY WAIVERS and VARIANCES

To receive waivers from this standard, Measurement Services shall be notified in writing prior to the granting of any exceptions.

Measurement Services shall be notified in writing prior to any piping or equipment modifications at existing measurement facilities. The notice shall include a description of the proposed modifications and include detailed drawings and specifications on all material and equipment. Second and/or third party company construction specifications must be submitted for approval. No work shall begin until written approval is received from El Paso.

*****

MEASUREMENT FACILITY EQUIPMENT SPECIFICATIONS

1

APPROVED MEASUREMENT OPERATING EQUIPMENT

In most cases, only the manufacturer's names are given. For multiple source items, no one manufacturer is recommended over the other(s). However, preferences do exist. Engineering or Measurement Services may be consulted for specific model numbers, specifications, and ordering descriptions for various applications of the equipment. For all matrices in this section CIG includes Wyoming Interstate Co. (WIC) and Cheyenne Plains Gas Pipeline Co. (CPG). Measurement

Equipment Manufacturer TGP SNG EPNG CIG Mojave Orifice Meter Fittings Daniel Senior X X X X X TMCo Sure Shot X X X X X Orifice Plates Daniel X X X X X Kelly X X X X X Red River X X X X X Star Measurement X X X X X Diaphragm Meters American X X Energy Economics X Sensus X X Turbine Meters Daniel (1) X X X X X Sensus (2) X X Rotary Meters Dresser Roots B3-HPC X X X X X Instromet IRM-HP X X Ultrasonic Meters Daniel SeniorSonic X X X X X Instromet Q.Sonic X X X X X Sick Maihak Flowsic X X X X Coriolis (3) Micromotion Flow Conditioners CPA X X X X X Gallagher X X X X X Instrument Manifolds Anderson Greenwood X X X X X Precision General X X Oilers Welker X X (for turbine meters) Y-Z X X X X X

1. Daniel turbine meters: 3” Mini and 4” 2. Sensus turbine meters: 2” T-10-HP, 4” AAT, and 6” AAT 3. Measurement Services approval required


2

Regulation and Control

Equipment Manufacturer TGP SNG EPNG CIG Mojave Regulators Fisher X X X X X Red Q X X Mooney X X X X Control Valves Becker X X X X X Fisher X X X X X Mooney X X Welker X X Valves (≥ 2”) Cameron X X X X X Grove X X X X X Orbit X X WKM X X X Valves (< 2”) Quadrant X Operators / Actuators Becker X X X Bettis X X X X Biffi / Morin X X X X Fisher X X Shafer X X X X Positioners Becker (inc. DNGP) X X X Bettis X X X X Fisher X X X X X Pilots Badger X X (inc. DMVs) Becker X X X Fisher X X X X X Grove X X X Mooney X X X X Controllers Barton X X Bristol X X Fisher X X X X X Selector Relays Dhal X X (pneumatic) Fairchild X X X X X Moore X X X Valves Asco X X X (pilot pneumatic) Skinner X X X Versa X X X X Numatics X X X X X Relief Valves Anderson Greenwood X X X X Axelson X X Crosby X X X Farris X X Flow Safe X X Grove X X Mooney X X X Catalytic Heaters Bruest X X X X X Catco X X X X Strainers, Anderson X Filters, and Kingtool X X X Separators Mueller X X Peco X X X Royal Guard X Safeco X X X X Winston X X Instrument Regulators Fisher X X X X X Fairchild X X X X X Welker X X X X X


3

Gas Quality

Equipment Manufacturer TGP SNG EPNG CIG Mojave Composite Samplers PGI X X X Welker X X X Y-Z X X X X Chromatographs Daniel Danalyzer X X X X X ABB NGC (1) Moisture Analyzers SpectraSensors X X X X X H2S and Total S Del Mar Scientific X X X Analyzers Envent x Galvanic X X X X X Sensidyne X X Texas Analytical X X Sample Probes and A+ Genie X X X X Regulator Probes Welker X X X X X Y-Z X X X X CO2 Analyzers SpectraSensor X X X X O2 Analyzers Teledyne X X X X

1. Measurement Services approval required. Electrical / Electronic

Equipment Manufacturer TGP SNG EPNG CIG Mojave Gas Flow Computers Bristol X X X X Fisher X Thermo Electron X Electronic Correctors Bristol X X Fisher X Mercury Turbo Monitor X X X X X Roots VCC X Thermo Electron X X Transducers (1) Bristol X Fairchild X Transmitters Bristol X X Rosemount X X X X Yokogawa X X RTDs, Thermowells, Bristol X Test Wells PGI X X X X Rosemount X X X X Signal Converters and Action Instruments X X X X Isolators AGM X Entrelec X IMAC Pulsimatic X X X X MTL X X X X X Moore X X X X X P+F X X X X Turck X UPS and Best Ferrups X X X X X Power Supplies La Marche X X X Statpower Truecharge X X X X X XPiQ (2) X

1. Includes M/Ps, A/Ms, and I/Ps 2. Formerly International Power


i

TABLE of CONTENTS

The equipment specifications listed below and subsequently detailed are examples of the most commonly used equipment and are not all inclusive of all equipment used. Meters (primary devices) Tab Instromet Q.Sonic, Daniel SeniorSonic, and Sick Maihak Flowsic Ultrasonic Meter 1 Sensus T-10-HP Turbine Meter 2 Sensus Auto-Adjust II Turbine Meter 3 Daniel Turbine Meter 4 Daniel Senior and TMCo Sure Shot Orifice Meter 5 Instromet IRM and Dresser Roots B3-HPC Rotary Meter 6 Energy Economics HP 3000, Sensus, and American Diaphragm Meter 7 Welker and CPA Sonic Nozzle 8 Welker OIP and YZ Cyclone MLS Automatic Oiler for Turbine Meters 9 Corrpro and Pikotek Insulating Flange Gasket Set 10 Mid-West 120 and Precision 200 Differential Pressure Gauge 11 EGM Tab (secondary devices) Rosemount 3051CG Static Gauge Pressure Transmitter 1 Rosemount 3051S Static Gauge Pressure Transmitter 2 Rosemount 3051CD Differential Pressure Transmitter 3 Rosemount 3051S Differential Pressure Transmitter 4 Rosemount 3144P Temperature Transmitter 5 Bristol 2808 Temperature Transmitter 6 Rosemount 0078 RTD Sensor Assembly with Thermowell 7 Rosemount 0091Test Well / Thermowell 8 PGI ThermoSync RTD Probe Sensor with Thermowell 9 PGI ThermoSync Test Well / Thermowell 10 Tyco AGCO and PGI Instrument Manifolds and Direct Mounts 11 CIG: Emerson Fisher-Rosemount RS Multivariable Transmitter 13 EPNG: Bristol 3808 Multivariable Transmitter 14 Rosemount 3095FB Multivariable Transmitter 15 Rosemount 0068 RTD Sensor Assembly with Thermowell 16 SNG: Yokogawa EJA430A Static Gauge Pressure Transmitter 17 Yokogawa EJA110A Differential Pressure Transmitter 18 Yokogawa YTA310 Temperature Transmitter 19 Rosemount 0078 RTD Sensor Assembly with Thermowell 20 Rosemount 0091 Test Well / Thermowell 21 Texas Electronic Resources Transient Protectors 22


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(tertiary devices, GFC) TGP: GFC Assembly 23 Bristol DPC 3330 EPTB3330 Version Gas Flow Computer 24 Bristol DPC 3330 EPOR3330 Version Gas Flow Computer 25 Bristol TeleFlow / TeleCorrector 3530 Gas Flow Computer / Volume Corrector 26 Thermo Electron AutoMate / AutoPilot Gas Flow Computer / Volume Corrector 27 Southwest Photovoltaic Systems Power / Communications Assembly 28 Bristol RTU 3310 Data Concentrator 29 Action Instruments Transpak T703 Analog Signal Isolator 29 CIG: Fisher ROC 364 Gas Flow Computer 30 Fisher ROC 312 Gas Flow Computer 31 Fisher ROC 407 Gas Flow Computer 32 EPNG: Bristol DPC 3335 4-Run Version Gas Flow Computer 33 Bristol TeleRTU Plus 3530 Gas Flow Computer 34 Standard Radio Communications Package and Power Supply 35 Mojave: Bristol DPC 3330 3-Run Version Gas Flow Computer 36 SNG: Bristol DPC 3330 Gas Flow Computer, carbon steel cabinet 37 Bristol DPC 3330 Gas Flow Computer, stainless steel cabinet 38 Bristol DPC 3330 Gas Flow Computer, no cabinet 39 Bristol DPC 3330 Data Concentrator 40 Control Tab Becker Flow Control Valve or Pressure Regulator 1 Fisher Flow Control Valve or Pressure Regulator 3 Becker Monitor Regulator 4 Wilson Valve Specialties OPP Shut-In Valve 5 Mooney Controls Flowgrid Pressure Regulator or Flow Control Valve 6 Becker / Bettis / Morin Tube Switcher 7 Ancillary Equipment for FCV, PR, MR, and TS 9 Bristol 5453 (624 II) Indicating Pneumatic Pressure Controller 11 Block Valves and Bypass Valves 12 AGCO, Crosby, and Axelson Safety Relief Valve 13 Gas Quality Tab Daniel Danalyzer Chromatograph 1 Ancillary Equipment for Chromatograph 3 PGI, Welker and YZ Composite Sampler 5 Ancillary Equipment for Samplers and Analyzers 6 SpectraSensors Moisture Analyzer 8 Galvanic Applied Sciences and Del Mar Scientific H2S and Total Sulfur Analyzer 9 Teledyne O2 Analyzer 10


iii

Specifications for Engineered Products Tab Filter Separator Liquids Storage Tank, 45 barrel Liquids Storage Tank, 200 gallon Buildings, metal meter Headers (available upon request) Basket Strainer (available upon request) Heater System (available upon request)


1

ULTRASONIC METER

Instromet Q.Sonic, multi-path retractable / fixed transducers 4” Q3046R40 (3-path) Q3046F40 (3-path) 6” Q3066R40 (3-path) Q3066F40 (3-path) 8” Q3086R40 (3-path) Q3086F40 (3-path)

10” Q3106R40 (3-path) Q3106F40 (3-path) 12” Q5126R40 (5-path) Q5126F40 (5-path)

Daniel SeniorSonic, 4-path, extractable transducers 4” 3400-5A00-05173-4.026 6” 3400-5A00-15173-6.065 8” 3400-5A00-25173-7.981

10” 3400-5A00-35173-10.020 12” 3400-5A00-45173-11.938

Sick Maihak Flowsic600, multi-path, extractable transducers 4” DN100 6” DN150 8” DN200 10” DN250 12” DN300 Multi-path ultrasonic meters shall be transmission type tubes with flow conditioner, pipe, flanges, threadolets, spacer plate, gaskets, stud bolts, and nuts in accordance with the following specifications and drawings: TYP-METR-1000 Typical Ultrasonic Meter Tube with Flow Conditioner STD-METR-1001 to 1005 Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1006 to 1010 Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1011 to 1015 Bi-Directional Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1016 to 1020 Bi-Directional Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-0001 Meter Station Header Design Specifications STD-METR-0002 Standard Downstream Taps Detail Some applications may require tees with blind flanges and davits on each end of the ultrasonic meter tube. Ultrasonic meters with the entire tube assembly shall be flow calibrated in accordance with these specifications and Design Specifications Sections 6.3 and 6.4. Accessories (as required):

Telebyte 285 Superverter, RS-485 to RS-232 interface converter


2

TURBINE METER

Sensus T-10-HP Turbo-Meter Turbine meters shall be transmission type tubes with tube bundle straightening vanes, pipe, flanges, threadolets, spacer plate, sonic nozzle flow restrictor, gaskets, stud bolts, and nuts in accordance with the following specifications and drawings: TYP-METR-2000 Typical Turbine Meter Tube with Sonic Nozzle STD-METR-2002 2” Sensus T-10-HP Turbine Meter Tube STD-METR-0001 Meter Station Header Design Specifications STD-METR-0002 Standard Downstream Taps Detail Turbine meters shall be flat face wafer style body, ANSI 600, cast steel meter housing, conduit connections (1/2" - 14 NPT), 100 CF index rate, and shall include the following ancillary devices: 2" Installation kit (threaded rods, nuts, gaskets), part number 006-15-373-80 Vertical direct reading (VDR) index with aluminum box Blade tip sensors or slot sensor pulser on follower magnet assembly Turbine meters, less the tube, shall be flow calibrated in accordance with these specifications and Design Specifications Sections 6.2.2.3 and 6.2.2.4. Accessories (as required):

Intrinsically safe barrier: MTL 5012, isolator, switch / proximity detector interface, single channel MTL DX070, enclosure

Automatic oiler:

Welker OIP-1BKX YZ MLS-4400


3

TURBINE METER

Sensus Auto-Adjust II Turbo-Meter 4” Model AAT-18 or AAT-27 6” Model AAT-35 or AAT-57 Turbine meters shall be transmission type tubes with tube bundle straightening vanes, pipe, flanges, threadolets, spacer plate, sonic nozzle flow restrictor, gaskets, stud bolts, and nuts in accordance with the following specifications and drawings: TYP-METR-2000 Typical Turbine Meter Tube with Sonic Nozzle STD-METR-2004 4” Sensus Auto-Adjust II Turbine Meter Tube STD-METR-2005 6” Sensus Auto-Adjust II Turbine Meter Tube STD-METR-0001 Meter Station Header Design Specifications STD-METR-0002 Standard Downstream Taps Detail Turbine meters shall be ANSI 600 RFFE, cast steel meter housing, conduit connections (1/2" - 14 NPT), 100 CF index rate, and shall include the following ancillary devices: Vertical direct reading (VDR) index with aluminum box Some applications may require tees with blind flanges and davits on each end of the turbine meter tube. Turbine meters, less the tube, shall be flow calibrated in accordance with these specifications and Design Specifications Sections 6.2.2.3 and 6.2.2.4. Accessories (as required):

Intrinsically safe barrier: Turck MK13-22Ex0-T/24VDC, two-channel switching amplifier with IS input (2 ea.) MTL DX070, enclosure

Automatic oiler:

Welker OIP-1BKX YZ MLS-4400


4

TURBINE METER

Daniel 3" Mini Gas Turbine Meter Assembly, Model 3315 4” Gas Turbine Meter Assembly, Model 4-20-1-5 Turbine meters shall be transmission type tubes with tube bundle straightening vanes, pipe, flanges, threadolets, spacer plate, sonic nozzle flow restrictor, gaskets, stud bolts, and nuts in accordance with the following specifications and drawings: TYP-METR-2000 Typical Turbine Meter Tube with Sonic Nozzle STD-METR-2003 3” Daniel Mini Turbine Meter Tube STD-METR-2004 4” Daniel Turbine Meter Tube STD-METR-0001 Meter Station Header Design Specifications STD-METR-0002 Standard Downstream Taps Detail Turbine meters shall be ANSI 600 RFFE, 100 CF index rate, dual coils, and with MRT 97 Flow Rate Indicator/Totalizer (for 3” Mini Turbine Meters only). Some applications may require tees with blind flanges and davits on each end of the turbine meter tube. Turbine meters, less the tube, shall be flow calibrated in accordance with these specifications and Design Specifications Sections 6.2.2.3 and 6.2.2.4. Accessories (as required):

Bristol Babcock 392783-01-0, turbine meter pre-amp.


5

ORIFICE METER

Daniel Senior and TMCo Sure Shot Orifice meters shall be three-piece transmission type tubes with dual chamber WE x RFFE fittings, flow conditioner, pipe, flanges, threadolets, spacer plate, gaskets, stud bolts, and nuts in accordance with the following specifications and drawings: TYP-METR-3000 Typical Orifice Meter Tube with Flow Conditioner STD-METR-3001 to 3007 Orifice Meter Tube with CPA Flow Conditioner STD-METR-3008 to 3014 Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-0001 Meter Station Header Design Specifications STD-METR-0002 Standard Downstream Taps Detail These specifications and drawings apply to both onshore and offshore applications. Most offshore applications require the use of ring type joint (RTJ) flanges on each end of the orifice meter tube. All offshore applications and some onshore applications require that the orifice fitting be rotated 90˚, with the opening for the orifice plate holder on the side and the DP tap holes on the top. Refer to Design Specifications Section 6.1.5 for the drain. Some applications may require tees with blind flanges and davits on each end of the orifice meter tube. Orifice plates shall be per AGA-3 / API 14.3 standards and specifications with line size, bore, and thickness (1/4" for orifice meters 8” and larger, 1/8" for orifice meters 6” and smaller) specified and 304SS. Seal units must accompany plate.


6

POSITIVE DISPLACEMENT METER

ROTARY Instromet Instromet high pressure model IRMS, positive displacement rotary meter, ANSI 600 RFFE, side (top) inlet, internal bypass, complete with index counter, differential pressure gauge and alarm switch (part number 9-200-001), Bi3-ISM-Y high frequency proximity sensor, and Turck MK13-22Ex0-T/24VDC two-channel switching amplifier with IS input circuit.

IRMS1M-600, 1.5” IRMS1.5M-600, 1.5” IRMS2.5M-600, 2” IRMS3.5M-600, 2” IRMS6M-600, 3” IRMS9M-600-3, 3”

Dresser Roots DMD Dresser Measurement, Roots Meter Series B3-HPC, positive displacement rotary meter, ANSI 600 RFFE, side (top) inlet, full capacity internal by-pass with differential pressure gauge and alarm switch

B3-HPC 1M1480, 2” B3-HPC 3M1480, 2” B3-HPC 5M1480, 3” B3-HPC 7M1480, 3” CD, counter with instrument drive ICEX, counter with high frequency transmitter/pulser, single conduit connection

Positive displacement rotary meters shall be two-lobe contra-rotating impeller design, equipped with anti-friction ball bearings, and bearing and timing gears to be splash-oil lubricated. Rotary meters shall be non-temperature compensated, 10 CF proving circle / index rate, and supplied with instrumentation as specified. Rotary meters shall be calibrated and supplied with certified accuracy test reports. Accessories (as required):

Intrinsically safe barrier: Turck MK13-22Ex0-T/24VDC, two-channel switching amplifier with IS input (2 ea.) MTL DX070, enclosure

Rotary meter sets shall be of the meter specified with block and bypass valves, strainer, pipe, flanges, threadolets, spacer plate, sonic nozzle flow restrictor, gaskets, stud bolts, and nuts in accordance with these specifications and drawing TYP-METR-4000 (vertical orientation) and TYP-METR-4001 (horizontal orientation).


7

POSITIVE DISPLACEMENT METER

DIAPHRAGM Energy Economics HP 3000 Case WP = 1500 psig Sensus 1600, 3000, 5000, and 10,000 Case WP = 100 psig American Meter, AL Series Case WP = 100 psig Positive displacement diaphragm meters shall be single joint, non-temperature compensated, with drains, 10 CF proving circle / index rate, and vertical direct reading (VDR) type index. Diaphragm meters shall be calibrated and supplied with certified accuracy test reports. Accessories (as required):

IMAC Systems (International Measurement and Control Systems) Pulsimatic Transmitter, double independent outputs, 100 pulses per revolution of drive shaft, high frequency, ½” NPT conduit connection

Intrinsically safe barrier: • Turck MK13-22Ex0-T/24VDC, two-channel switching amplifier with IS input (2 ea.) • MTL DX070, enclosure

Diaphragm meter sets shall be of the meter specified with block and bypass valves, strainer, pipe, flanges, threadolets, spacer plate, orifice plate flow restrictor, gaskets, stud bolts, and nuts in accordance with these specifications and drawing TYP-METR-4002.


8

SONIC NOZZLE

Welker Engineering - Flow Limiting Nozzle Canada Pipeline Accessories – Critical Flow Venturi Nozzle ANSI 600, 316SS, designed for flange-mounted direct (reverse) insertion into the pipe, throat sized as indicated in table below and SG = 0.600. Sonic nozzles require a pressure drop of approximately 20% across them for the gas to reach sonic velocity and thus limit the flow. The use of flow restricting orifice plates for rotary and diaphragm meters is generally acceptable. Orifice plates require a pressure drop of approximately 50% across them for the gas to reach sonic velocity and thus limit the flow.

Meter Type Q(base) acfh Limit % Pipe ID

Sonic Nozzle Bore

Orifice Plate Bore

Sensus Turbine 2” T-10-HP 10,000 110 1.939” 0.824” 0.965” 4” AAT-18 18,000 110 4.026” 1.106” 1.294” 4” AAT-27 27,000 110 4.026” 1.355” 1.585” 6” AAT-35 35,000 110 6.065” 1.542” 1.804” 6” AAT-57 57,000 110 6.065” 1.968” 2.303” Daniel Turbine 3” 3315 14,200 110 3.068” 0.982” 1.149” 4” 4-20-1-5 18,000 110 4.026” 1.106” 1.294” Instromet Rotary IRMS1M-600 1,000 110 1.939” 0.261” 0.305” IRMS1.5M-600 1,500 110 1.939” 0.319” 0.374” IRMS2.5M-600 2,500 110 1.939” 0.412” 0.482” IRMS3.5M-600 3,500 110 1.939” 0.488” 0.571” IRMS6M-600 6,000 110 3.068” 0.639” 0.747” IRMS9M-600 9,000 110 3.068" 0.782” 0.915” Dresser Roots B3-HPC 1M1480 1,000 110 1.939” 0.261” 0.305” Rotary B3-HPC 3M1480 3,000 110 1.939” 0.452” 0.528” B3-HPC 5M1480 5,000 110 3.068” 0.583” 0.682” B3-HPC 7M1480 7,000 110 3.068" 0.690” 0.807” EEI Diaphragm HP 3000 3,000 100 1.939” 0.431” 0.504”


9

AUTOMATIC OILER for TURBINE METERS

Welker Engineering OIP-1BKX Oil injection pump, without instrument supply regulator: 6Tc timer, 15 sec. to 255 hr. rangeability 6 VDC solenoid-operated 20 – 100 psig operating range 250 cc oil reservoir, 0.25 cc/stroke, internal check valve ¼” NPT connections SS fittings and tubing NEMA 4 enclosure Pipe mount YZ Systems Cyclone MLS-4400 Meter lubrication system, without instrument supply regulator: C44 solenoid-operated injection pump Z-65/6.1H timer/controller 15 – 55 psig actuation pressure 6 oz. oil reservoir ¼” FNPT supply gas inlet connection 1/8” S/ST tubing lubricant discharge connection 316 SS construction with valves and gauges Pipe mount Accessories (as required):

Intrinsically safe barrier: • MTL 7765ac • MTL DX070, enclosure


10

INSULATING FLANGE GASKET SET

Corrpro Companies Flange Insulation Kit Model No: E-N-D-F-P-XXX-0600 E = Gasket Type: Standard Full Face Type E N = Gasket Material: Neoprene Faced Phenolic D = Washer Type: Double Washer F = Sleeve Material: Phenolic P = Washer Material: Standard Phenolic XXX = Pipe Size (inches): 020 = 2” 030 = 3” 040 = 4” 060 = 6” 080 = 8” 100 = 10” 120 = 12” 0600 = Pressure Rating: ANSI Class 600 Pikotek VCS Insulating Kit For use with x” ANSI 600 RF flange (x” ID) Gasket: VCS Gasket (316SS core, G-10 insulating material, Teflon spring-energized seal) Insulating washer: G-10 Insulating sleeve: G-10 Steel washer: ZPS (zinc-plated steel)


11

DIFFERENTIAL PRESSURE GAUGE

Mid-West Instrument Model 120-SA-0x-yO 120 = “Filter Minder” piston-type differential pressure gauge, 0-10 or 0-15 psid S = 316SS body and piston A = 2 ½” round uni-directional dial 0 = Buna N seals x = connections 0 = ¼” FNPT back connections for pipe mount 2 = ¼” FNPT end connections for wall mount y = mounting kit F = pipe mount kit W = wall mount kit O = no electrical configuration Mid-West Instrument Model 120-SA-0x-yJ-A 120 = “Filter Minder” piston-type differential pressure gauge, 0-10 or 0-15 psid S = 316SS body and piston A = 2 ½” round uni-directional dial 0 = Buna N seals x = connections 0 = ¼” FNPT back connections for pipe mount 2 = ¼” FNPT end connections for wall mount y = mounting kit F = pipe mount kit W = wall mount kit J = switch in explosion-proof enclosure and glass window cover A = SPDT switch, 3 watts, 0.25 amps, 125 VAC/VDC (specify trip point) Precision Model 200-DPG-G-S-2.5-4N-1-F-B-(0-10 or 0- 15 psid)-0-0 200-DPG-G = piston type differential pressure gauge S = 316SS body material and wetted parts 2.5 = 2.5” dial 4N = ¼” FNPT connection 1 = in-line porting F = glass window B = Buna N seals 0-0 = no switch, no options Precision Model EX-200-DPG-GS-S-2.5-4N-1-F-B-(0-10 or 0- 15 psid)-6-0 EX = explosion proof 200-DPG-GS = piston type differential pressure gauge + switch S = 316SS body material and wetted parts 2.5 = 2.5” dial 4N = ¼” FNPT connection 1 = in-line porting F = glass window B = Buna N seals 6 = one SPDT switch with terminal strip, 3 VA, 0.25 amps, 28 VAC/VDC (specify trip point) 0 = no options


1

STATIC GAUGE PRESSURE TRANSMITTER

Rosemount Model 3051CG-5-A-2-2-A-1-A-B4-E5-T1 3051CG = Smart gauge pressure transmitter 5 = Pressure range (URL): 0-20 to 0-2,000 psig A = Output: 4-20 mADC with digital signal based on Hart protocol 2 = Materials of construction: Coplanar process flange SST flange SST drain / vent SST flange adapters 2 = Isolating diaphragm: 316L SST A = O-ring: Glass-filled TFE 1 = Fill fluid: Silicone A = Housing material: Polyurethane-covered aluminum 1/2 - 14 NPT conduit entry B4 = Mounting bracket: Coplanar flange bracket for 2 in. pipe, all SST E5 = Hazardous locations certification: Factory Mutual (FM) explosion-proof approval T1 = Integral transient protection V5 ground screw assembly included --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051CG-5-A-2-2-A-1-J-L4-B4-E5-T1 Offshore applications (same as above except for): J = Housing material: SST, 1/2 - 14 NPT conduit entry L4 = Bolts: Austenitic 316 SST --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051CG-5-M-2-2-A-1-A-B4-E5-T1-C2 Low power onshore applications (same as above except for): M = Low power 0.8-3.2 VDC with digital signal based on Hart protocol (delete C2 for 1-5 VDC) --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051CG-5-M-2-2-A-1-J-L4-B4-E5-T1-C2 Low power offshore applications (same as above except for): M = Low power 0.8-3.2 VDC with digital signal based on Hart protocol (delete C2 for 1-5 VDC) J = Housing material: SST, 1/2 - 14 NPT conduit entry L4 = Bolts: Austenitic 316 SST


2


Rosemount Model 3051S-2-C-G-5A-2-E12-A-1A-B4-E5-T1 3051S = scalable pressure transmitter 2 = Performance class: Classic, 0.065% accuracy, 100:1 turndown C = Supermodule type: Coplanar G = Measurement type: Gauge 5A = Pressure range: -14.2 to 2000 psig 2 = Isolating diaphragm: 316L SST E12 = Process connection: ¼ -18 NPT, 316SST coplanar flange, 316SST drain vent A = Output: 4-20 mADC with digital signal based on Hart protocol 1A = Housing style: Aluminum PlantWeb housing, dual compartment 1/2 - 14 NPT conduit entry B4 = Mounting bracket: Coplanar flange bracket, all SST, 2 in. pipe and panel E5 = Hazardous locations certifications: Factory Mutual (FM) explosion-proof T1 = Terminal blocks: Transient terminal block --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051S-2-C-G-5A-2-E12-A-1J-B4-E5-L4-T1 Offshore applications (same as above except for): 1J = Housing material: 316L SST PlantWeb housing, dual compartment

1/2 - 14 NPT conduit entry L4 = Bolts: Austenitic 316 SST


3

DIFFERENTIAL PRESSURE TRANSMITTER

Rosemount Model 3051CD-2-A-2-2-A-1-A-B4-E5-T1 3051CD = Smart differential pressure transmitter 2 = Pressure range (URL): 0-2.5 to 0-250 In.WC A = Output: 4-20 mADC with digital signal based on Hart protocol 2 = Materials of construction: Coplanar process flange SST flange SST drain / vent SST flange adapters 2 = Isolating diaphragm: 316L SST A = O-ring: Glass-filled TFE 1 = Fill fluid: Silicone A = Housing material: Polyurethane-covered aluminum 1/2 - 14 NPT conduit entry B4 = Mounting bracket: Coplanar flange bracket for 2 in. pipe, all SST E5 = Hazardous locations certification: Factory Mutual (FM) explosion-proof approval T1 = Integral transient protection V5 ground screw assembly included --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051CD-2-A-2-2-A-1-J-L4-B4-E5-T1 Offshore applications (same as above except for): J = Housing material: SST, 1/2 - 14 NPT conduit entry L4 = Bolts: Austenitic 316 SST --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051CD-2-M-2-2-A-1-A-B4-E5-T1-C2 Low power onshore applications (same as above except for): M = Low power 0.8-3.2 VDC with digital signal based on Hart protocol (delete C2 for 1-5 VDC) --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051CD-2-M-2-2-A-1-J-L4-B4-E5-T1-C2 Low power offshore applications (same as above except for): M = Low power 0.8-3.2 VDC with digital signal based on Hart protocol (delete C2 for 1-5 VDC) J = Housing material: SST, 1/2 - 14 NPT conduit entry L4 = Bolts: Austenitic 316 SST


4


Rosemount Model 3051S-2-C-D-2A-2-E12-A-1A-B4-E5-T1 3051S = scalable pressure transmitter 2 = Performance class: Classic, 0.065% accuracy, 100:1 turndown C = Supermodule type: Coplanar D = Measurement type: Differential 2A = Pressure range: -250 to 250 In.WC 2 = Isolating diaphragm: 316L SST E12 = Process connection: ¼ -18 NPT, 316SST coplanar flange, 316SST drain vent A = Output: 4-20 mADC with digital signal based on Hart protocol 1A = Housing style: Aluminum PlantWeb housing, dual compartment 1/2 - 14 NPT conduit entry B4 = Mounting bracket: Coplanar flange bracket, all SST, 2 in. pipe and panel E5 = Hazardous locations certifications: Factory Mutual (FM) explosion-proof T1 = Terminal blocks: Transient terminal block --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3051S-2-C-D-2A-2-E12-A-1J-B4-E5-L4-T1 Offshore applications (same as above except for): 1J = Housing material: 316L SST PlantWeb housing, dual compartment

1/2 - 14 NPT conduit entry L4 = Bolts: Austenitic 316 SST


5

TEMPERATURE TRANSMITTER

Rosemount Model 3144P-D1-A-1-E5-B4-T1 (remote mount transmitter from RTD) Model 3144P-D1-A-1-E5-XA-T1 (direct mount transmitter to RTD) 3144P = Smart temperature transmitter D1 = Housing type / conduit entry: Dual-compartment field mount / aluminum 1/2 - 14 NPT A = Output: 4-20 mADC with digital signal based on HART protocol 1 = Measurement type configuration: Single sensor input E5 = Hazardous location certification: Factory Mutual (FM) explosion-proof approval Mounting: B4 = universal mounting bracket for 2 in. pipe, SST bracket and bolts XA = assemble transmitter to sensor assembly, wrench tight

Telflon (PTFE) tape (where appropriate), fully wired T1 = Integral transient protection G1 external ground lug assembly included --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3144P-D5-A-1-E5-B4-T1 Offshore remote mount applications (same as above except for): D5 = Housing type / conduit entry: Dual-compartment field mount / stainless steel 1/2 - 14 NPT --------------------------------------------------------------------------------------------------------------------------------- Rosemount Model 3144P-D5-A-1-E5-XA-T1 Offshore direct mount applications (same as above except for): D5 = Housing type / conduit entry: Dual-compartment field mount / stainless steel 1/2 - 14 NPT


6


Bristol Babcock Model 2808-41A-101-021-Rxx-W00022yy 2808-41A = Low power direct mount onshore/offshore, 1-5 VDC 1 = RTD module 100Ω platinum per IEC 751 Class B 0 = Indication No local indicator 1 = Certification UL/CUL explosion proof 0 = Warning plate None 2 = RTD option Spring loaded 1 = Extension/thermowell With thermowell xx = Insertion length 03 for 2”, 3”, 4” meter tubes 3 ½” length 04 for 6” meter tubes 4 ½” length 05 for 8” meter tubes 5 ½” length 06 for 10, 12” meter tubes 6 ½” length 000 = Extension None 22 = Thermowell Tapered, 3/4 – 14 NPT yy = Insertion length 04 for 2”, 3”, 4” meter tubes 2 ½” length 05 for 6” meter tubes 3 ½” length 06 for 8” meter tubes 4 ½” length 07 for 10, 12” meter tubes 5 ½” length


7

RTD SENSOR ASSEMBLY with THERMOWELL

Rosemount Model 0078-R-21-N-00-A-xxx-yyy-E5-V1 (remote mount transmitter from RTD) Model 0078-N-21-C-30-A-xxx-yyy-E5-XA-V1 (direct mount transmitter to RTD) 0078 = Platinum temperature sensor assembly Sensor lead wire termination: R = aluminum connection head, six terminals, flat cover

N = sensor only with 6” Teflon insulated, #22 AWG leads 21 = Sensor type and temp. range: Single element temperature sensor

-328 to 932 Deg.F Spring-loaded style N = No extension C = Nipple union Extension length: 00 = 0.0" 30 = 3.0” A = Material: Type 316 SST xxx = Lengths: 020 for 3", 4" meter tubes U = 2.0" 030 for 2”, 6" meter tubes U = 3.0" 040 for 8" meter tubes U = 4.0" 050 for 10" meter tubes U = 5.0"

060 for 12" meter tubes U = 6.0" yyy = Thermowell, mounting, and stem: T26 = Thread mount, 3/4 - 14 NPT, tapered stem T34 = Thread mount, 3/4 - 14 NPT, straight stem

(for xxx = 020 only)

E5 = Hazardous locations certification: Factory Mutual (FM) explosion-proof approval V1 = Accuracy enhancement Callendar-Van Dusen constants XA = Mounting Assemble transmitter to sensor assembly, wrench tight,

Telflon (PTFE) tape (where appropriate), fully wired R11 (optional, include as required) Thermowell vent hole


8

TEST WELL / THERMOWELL

Rosemount Model 0091-A-xxx-yyy-T000-P-zzz 0091 = Series 91 thermowell A = 316 SST xxx = Length: 020 for 3", 4" meter tubes U = 2.0" 030 for 2”, 6" meter tubes U = 3.0" 040 for 8" meter tubes U = 4.0" 050 for 10" meter tubes U = 5.0" 060 for 12" meter tubes U = 6.0" yyy = Mounting and stem: T26 = Thread mount, 3/4 - 14 NPT, tapered stem T34 = Thread mount, 3/4 - 14 NPT, straight stem (for xxx = 020 only) T000 = Lagging length T = 0.0” P = Instrument connection thread ½” – 14 NPT zzz = Options R06 = SST plug and chain Blank = none R11 (optional, include as required) Thermowell vent hole


9

RTD PROBE SENSOR with THERMOWELL

PGI ThermoSync Part Number ATA-1000-XX-B-C-R4-V-W1C (remote mount transmitter from RTD) Part Number ATA-1000-XX-C-R4-V-W1C (direct mount transmitter to RTD) ATA 316SS ThermoSync thermowell 316SS close nipple, PVC union and Delrin coupler 1000 = Process connection: ¾” MNPT XX = Pipeline size: L4 for 2”, 3”, 4” meter tubes L8 for 6” and 8” meter tubes L12 for 10” and 12” meter tubes B = Explosion-proof conduit box: ½” FNPT connection C = RTD calibration: Callendar-Van Dusen constants R4 = 4-wire spring-loaded RTD probe V = Vent/bleed hole in thermowell: 1/8” W1C = 316SS identification tag: Callendar-Van Dusen constants


10


PGI ThermoSync Part Number TAN-34CO-XX-PV (test well) Part Number TAN-34CO-XX-V (thermowell) TAN ThermoSync thermowell 34 = Process connection: ¾” MNPT CO = Material: 316L SS XX = Pipeline size: L4 for 2”, 3”, 4” meter tubes L8 for 6” and 8” meter tubes L12 for 10” and 12” meter tubes P = Cap and chain: (separate spare part number ATA-1002) V = Vent/bleed hole in thermowell 1/8”


11

INSTRUMENT MANIFOLDS

Tyco Anderson Greenwood M65TVDS-4-R3V-SSC-AM-U Precision General M3-673SLT-WAW9 (for Rosemount 3051C differential pressure transmitters with Coplanar flange) 5-valve instrument manifold 1/2" FNPT inlet connection Flange outlet connection 1/4" FNPT vent/test 0.375" orifice 316SS Rylon Cone soft seat (PGI), Delrin soft seat (AGCO) Teflon Pressure-Core seal (PGI), Teflon packing (AGCO) Mount kit for 2” pipe stand Tyco Anderson Greenwood M65TVDS-4-SSC-U (for Bristol Teleflow 3530-10B GFC) 5-valve instrument manifold 1/2" FNPT inlet connection Flange outlet connection 1/4" FNPT vent/test 0.375" orifice 316SS Delrin soft seat Teflon packing Tyco Anderson Greenwood M4TPVDS-4-R3V-SSC-AM-U Precision General M-617SDT-WAW9 (for Rosemount 3051C static pressure transmitters with Coplanar flange) 2-valve instrument manifold 1/2" FNPT inlet connection Flange outlet connection 1/2" FNPT vent/test 0.187" orifice 316SS Delrin Cone soft seat (PGI), Delrin soft seat (AGCO) Teflon Pressure-Core seal (PGI), Teflon bonnet packing (AGCO) Mount kit for 2” pipe stand (AGCO)


12

INSTRUMENT MANIFOLDS Continued . . . EPNG and CIG: Precision General Direct-Mount System for Rosemount 3051C differential pressure and static pressure transmitters, vertical installation, per PGI Dwg. No. HPLV1, to include the following components: AK-022-CO-MN-W9 stabilized connectors with dielectric isolation and 316SS bolts (2 ea.) M3-685SLT-W9 2-valve block manifold, standard straight style, with 316SS bolts M3-773SLT-WJ-W9 5-valve manifold, standard straight style, with 316SS bolts AK-700SZT-WD-W9 DP to SP bar adapter, extended length, with 316SS bolts Tyco Anderson Greenwood Direct Mount System for Rosemount 3051C differential pressure and static pressure transmitters, vertical installation, per AGCO Dwg. No. 01.4781, Rev. A, to include the following components: AGSF-S-S-V-DI-D-B316-U stabilized futbol connector (2 ea.) M65BVDS-SSC-U 2-valve manifold M65AVDS-U 5-valve manifold PCADVDS-R3V-SSC-U adapter Tyco Anderson Greenwood Direct Mount System for Rosemount 3051C differential pressure and static pressure transmitters, horizontal installation, per AGCO Dwg. No. 01.4782, Rev. 0, to include the following components: AGSF-S-S-H-DI-D-B316-U stabilized futbol connector (2 ea.) M65BVDS-SSC-U 2-valve manifold M659AVDS-SP-U 5-valve manifold PCADVDS-R3V-SSC-U adapter

MEASUREMENT EQUIPMENT SPECIFICATIONS

13

SMART MULTIVARIABLE TRANSMITTER

Emerson Fisher-Rosemount Model RS-w-x-y-z RS = Remote Multivariable Sensor w = Accuracy option: P = .075% of reading E = .10% of reading x = Differential Pressure range: 1 = 0-25 in. H20 2 = 0-250 in H20 ` 3 = 0-830 in H20 y= Static Pressure range: 3 = 0-800 psia 4 = 0-3626 psia C = 0-800 psig D = 0-3626 psig Z=Material of Construction: S = Stainless Steel H = Hastelloy C Note: Specify RTD immersion length; 2.5” or 4.5” Specify RTD cable length: 12 or 24 ft. (armored or not armored)


14


EPNG: Bristol Babcock 3808 MVT Multivariable Transmitter Model 3808-30A-141-111-111-022-100 Input differential pressure range: 0 - 300 In.WC Input static pressure range: 0 - 1,000 psig Materials of construction: 316SS Output: 4-20 mA/FSK Manifold adapter Neck mounted bracket EPNG and Mojave: Bristol Babcock 3808 MVT Multivariable Transmitter Model 3808-30A-142-111-112-022-100 Input differential pressure range: 0 - 300 In.WC Input static pressure range: 0 - 2,000 psig Materials of construction: 316SS Comm output: RS-485 Manifold adapter Neck mounted bracket


15


Rosemount Model 3095FB-2-x-A-y-A-1-z-A-B-1-0-0-A-N-S5 3095FB = Smart Multivariable Transmitter, RS-485 Modbus RTU 2 = Differential Pressure range : 0-2.5 to 0-250 in H2O x = Absolute/Gage Pressure range: 3 = 0-8 to 0-800 psia 4= 0-36 to 0-3,626 psis ` C = 0-8 to 0-800 psig D = 0-36 to 0-3,626 psig A = Isolator Material: 316L SST y = Flange style, Material: A = Coplaner, CS B = Coplaner, SST C = Coplaner, Hastelloy C 0 = None A = Drain/Vent Material: SST 1 = O-ring: Glass-filled TFE z = Process Temperature Input: 0 = Fixed Process Temperature (no cable) 1 = RTD input with 12 ft. of Shielded Cable 2 = RTD input with 24 ft. of Shielded Cable 3 = RTD input with 12 ft of Armored, Shielded Cable 4 = RTD input with 24 ft. of Armored, Shielded Cable 5 = RTD input with 21 in. of Armored, Shielded Cable 7 = RTD input with 75 ft. of Shielded Cable 8 = RTD input with 75 ft. of Armored, Shielded Cable A = Transmitter Housing Material: Polyurethane-covered Aluminum B = Terminal Block: With Integral Transient Protection 1 = Meter LCD Meter, Aluminum Housing 0 = Bracket None 0 = Bolts CS bolts A = Approvals Factory Mutual (FM) Explosion-Proof Approval N = EMS: Modbus RTU Process Variable Measurement S5 = Options Assembly with Model 305 Integral Manifold


16


Rosemount Model 0068-R-21-N-00-A-xxx-yyy-E5-V1 (remote mount transmitter from RTD) Model 0068-N-21-N-00-A-xxx-yyy-E5-XA-V1 (direct mount transmitter from RTD) 0068 = Platinum temperature sensor assembly R = Sensor lead wire termination: Aluminum connection head, six terminals, flat cover N = Sensor lead wire termination: Sensor only with 6” Teflon insulated, 22- guage lead

wires 21 = Sensor type and temp. range: Single element temperature sensor

-328 to 932 Deg.F Spring-loaded style N = No extension 00 = Extension length: 0.0" A = Material: Type 316 SST (Standard) xxx = Lengths: 020 for 2", 3", 4" meter tubes U = 2.0" 030 for 6" meter tubes U = 3.0" 040 for 8" meter tubes U = 4.0" 050 for 10" meter tubes U = 5.0"

060 for 12" meter tubes U = 6.0" yyy = Thermowell, mounting, and stem: T26 = Thread mount, 3/4 - 14 NPT, tapered stem T34 = Thread mount, 3/4 - 14 NPT, straight stem

(xxx = 020 only)

E5 = Hazardous locations certification: Factory Mutual (FM) explosion-proof approval V1 = Accuracy enhancement Callendar-Van Dusen constants XA = Mounting Assemble transmitter to sensor assembly (wrench tight,

Telflon (PTFE) tape, where appropriate, fully wired.


17


Yokogawa Model EJA430A-EBS4B-92EN/FF1/D1/ZFMP040 PeopleSoft Item ID: 89232 EJA430A = DPHARP Smart gauge pressure transmitter E = Output: 4-20 mA DC with digital Hart protocol communication B = Pressure range (URL): 0-20 to 0-2,000 psig (0-1,500 psig factory default setting) S = Wetted parts material: SCS14A Body (cover flange and process connector) SUS316L Capsule SUS316 Vent Plug Hastelloy C-276 Diaphragm 4 = Process connection 1/2'” NPT Female process connector B = Nuts and bolts material: SUS630 9 = Installation Horizontal impulse piping type, left side high pressure 2 = Electrical connection ½” NPT female, two electrical connections without blind plug E = Integral indicator Digital indicator with range setting switch N = Mounting bracket None FFI = Hazardous locations certification: Factory Mutual (FM) Explosion-proof approval D1 = Calibration units P calibration (psi unit) ZFMP040 = Bolt coating Xylan coated bolts Yokogawa Model EJA430A-EBS4B-92EN/FF1/D1/ZFMP040/E1 PeopleSoft Item ID: 106651 Offshore Applications (same as above except for): E1 = Stainless steel amplifier housing Amplifier housing material: SCS14A stainless steel


18


Yokogawa Model EJA110A-EMS4B-72EN/FF1/D1/ZFMP040 PeopleSoft Item ID: 89210 EJA430A = DPHARP Smart differential pressure transmitter E = Output: 4-20 mA DC with digital Hart protocol communication M = Pressure range (URL): 0-4” to 0-400” WC (0-200” WC factory default setting) S = Wetted parts material: SCS14A Body (cover flange and process connector) SUS316L Capsule SUS316 Vent Plug Hastelloy C-276 Diaphragm 4 = Process connection 1/2'” NPT Female process connector B = Nuts and bolts material: SUS630 7 = Installation Vertical impulse piping type, left side high pressure,

process connector downside 2 = Electrical connection ½” NPT female, two electrical connections without blind plug E = Integral indicator Digital indicator with range setting switch N = Mounting bracket None FFI = Hazardous locations certification: Factory Mutual (FM) Explosion-proof approval D1 = Calibration units P calibration (psi unit) ZFMP040 = Bolt coating Xylan coated bolts Yokogawa Model EJA110A-EMS4B-72EN/FF1/D1/ZFMP040/E1 PeopleSoft Item ID: 106649 Offshore Applications (same as above except for): E1 = Stainless steel amplifier housing Amplifier housing material: SCS14A stainless steel


19


Yokogawa Model YTA310-EA2DB/FU1/D2/CM1 PeopleSoft Item ID: 106653 YTA310 = Smart, high precision temperature transmitter (one input type) with sensor matching E = Output: 4-20 mA DC with digital Hart protocol communication A Always A 2 = Electrical connection: ½” NPT female D = Integral indicator: With digital indicator B = Mounting bracket: SUS304 Stainless steel 2-inch pipe mounting FU1 = Hazardous locations certification: Factory Mutual (FM) explosion-proof and Intrinsically-safe approval D2 = Calibration units: Degree F / Degree R unit CM1 = Sensor matching function RTD sensor matching function Yokogawa Model YTA310-EA2DB/FU1/D2/CM1/E1 PeopleSoft Item ID: 106654 Offshore Applications (same as above except for): E1 = Stainless steel amplifier housing Amplifier housing material: SCS14A stainless steel


20


Rosemount Model 0078-N-11-N-00-A-xxx-yyy-R11-V1 0078 = Platinum temperature sensor assembly N = Sensor lead wire termination: Sensor only with 6”, teflon-insulated, 22-gauge leadwires 11 = Sensor type and temp. range: Single element temperature sensor

-328 to 932 Deg.F General-purpose style N = Extension Type No extension 00 = Extension length: 0.0" A = Thermowell material: Type 316 SST xxx = Lengths: 020 for 2", 3", 4" meter tubes U = 2.0" 030 for 6" meter tubes U = 3.0" 040 for 8" meter tubes U = 4.0" 050 for 10" meter tubes U = 5.0"

060 for 12" meter tubes U = 6.0" yyy = Thermowell, mounting, and stem: T26 = Thread mount, 3/4 - 14 NPT, tapered stem (for xxx = 030, 040, 050, 060, 080) T34 = Thread mount, 3/4 - 14 NPT, straight stem (for xxx = 020) R11 = Thermowell vent-hole Thermowell vent-hole V1 = Accuracy enhancement Callendar-Van Dusen constants Model 0078-N-11-N-00-A-020-T34-R11-V1 PeopleSoft Item ID: 106747 Model 0078-N-11-N-00-A-030-T26-R11-V1 PeopleSoft Item ID: 106748 Model 0078-N-11-N-00-A-040-T26-R11-V1 PeopleSoft Item ID: 106749 Model 0078-N-11-N-00-A-050-T26-R11-V1 PeopleSoft Item ID: 106750 Model 0078-N-11-N-00-A-060-T26-R11-V1 PeopleSoft Item ID: 106751 Model 0078-N-11-N-00-A-080-T26-R11-V1 PeopleSoft Item ID: 106752


21


Rosemount Model 0091-A-xxx-yyy-T000-P-R06-R11 0091 = Series 91 Thermowell A = 316 SST xxx = Length: 020 for 2", 3", 4" meter tubes U = 2.0" 030 for 6" meter tubes U = 3.0" 040 for 8" meter tubes U = 4.0" 050 for 10" meter tubes U = 5.0"

060 for 12" meter tubes U = 6.0" 080 for 16" meter tubes U = 8.0" yyy = Thermowell, mounting, and stem: T26 = Thread mount, 3/4 - 14 NPT, tapered stem (for xxx = 030, 040, 050, 060, 080) T34 = Thread mount, 3/4 - 14 NPT, straight stem (for xxx = 020) T000 = Lagging length T= 0.0” P = Instrument connection thread ½” – 14 NPT R06 = SST plug and chain R11 = Thermowell vent-hole Model 0091-A-020-T34-T000-P-R06-R11 PeopleSoft Item ID: 106933 Model 0091-A-030-T26-T000-P-R06-R11 PeopleSoft Item ID: 106934 Model 0091-A-040-T26-T000-P-R06-R11 PeopleSoft Item ID: 106935 Model 0091-A-050-T26-T000-P-R06-R11 PeopleSoft Item ID: 106936 Model 0091-A-060-T26-T000-P-R06-R11 PeopleSoft Item ID: 106937 Model 0091-A-080-T26-T000-P-R06-R11 PeopleSoft Item ID: 106938


22

TRANSIENT PROTECTORS

Texas Electronic Resources Model TER-222.0 PeopleSoft Item ID: 107047 Transient protector, inductive, for Yokogawa EJA Series static pressure and differential pressure transmitters Texas Electronic Resources Model TER-223.0 PeopleSoft Item ID: 107048 Transient protector, inductive, for Yokogawa YTA Series temperature transmitters


23

GFC ASSEMBLY

Gas flow computer assemblies shall be fabricated in accordance with the following specifications and standard drawings: TYP-GFCD-000 0 EPTB3330 / Wall Mount / AC Power TYP-GFCD-0100 EPTB3330 / Rack Mount / AC Power TYP-GFCD-0200 EPTB3330 / Enclosure Mount / Solar Power TYP-GFCD-0300 EPOR3330 / Wall Mount / AC Power TYP-GFCD-0400 EPOR3330 / Rack Mount / AC Power TYP-GFCD-0500 EPOR3330 / Enclosure Mount / Solar Power TYP-GFCD-0600 Bristol RTU 3310 Data Concentrator TYP-GFCD-0700 Bristol Teleflow 3530-10B and Telecorrector 3530-50B TYP-GFCD-0800 Thermo Electron AutoPilot and AutoMate TYP-GFCD-0900 EPTB3330 / Enclosure Mount / AC Power TYP-GFCD-0930 EPTB3330 with Sixnet Ethertrak / Wall Mount / AC Power TYP-GFCD-0950 EPTB3330 / Wall Mount / Solar Power TYP-GFCD-0970 EPTB3330 with Sixnet Ethertrak / Wall Mount / Solar Power Bill of Materials

TYP-GFCD-0001, 0101, 0201, 0301, 0401, 0501, 0901, 0931, 0951, 0971 Equipment Layouts

TYP-GFCD-0002, 0102, 0202, 0302, 0402, 0502 , 0902, 0932, 0952, 0972 GFC Enclosure Layouts

TYP-GFCD-0003, 0103, 0203, 0303, 0403, 0503 , 0903, 0933, 0953, 0973 Field Termination Enclosure Layouts

TYP-GFCD-0004, 0104, 0204, 0304, 0404, 0504 , 0904, 0934, 0954, 0974 GFC Enclosure Wiring Diagrams

TYP-GFCD-0005, 0105, 0205, 0305, 0405, 0505 , 0905, 0935, 0955, 0975 Field Termination Wiring Diagrams

TYP-GFCD-0006, 0106, 0206, 0306, 0406, 0506 , 0906, 0936, 0956, 0976 Equipment Rack Fabrications

TYP-GFCD-0107, 0407 DC Equipment Layout and Wiring Diagrams

TYP-GFCD-0601 thru 0603 Teleflow / Telecorrector Installation Drawings and Wiring Diagrams

TYP-GFCD-0701 thru 0703 AutoPilot / AutoMate Installation Drawings and Wiring Diagrams

TYP-GFCD-0801 thru 0808


24

GAS FLOW COMPUTER

Bristol Babcock DPC 3330, EPTB3330 Version Model 3330-10A-3101-242-1-1-AB-F8-DF-00-E5-E5-200-M04-0-0 (No analog outputs) Model 3330-10A-3101-242-1-1-AB-F8-DF-B2-E5-E5-200-M04-0-0 (With analog outputs) 3330-10A = DPC 3330 3 = Base unit 6 I/O slots, NEMA 1 1 = Internal power supply +12 VDC (2 for +24 VDC) 0 = Not used 1 = Certification FM approved 242 = CPU 24 MHz., 386 Protected Mode CPU, 512 KB base RAM,

2 BIP ports, w/o FPP, external BIP, 2 MB expansion RAM 1 = Communication ports A and B Port A = Enhanced RS-232/485 and Port B = RS-232/485 1 = Communication ports C and D Port C = Enhanced RS-232/485 and Port D = RS-232/485 I/O modules: AB = Slot 1, analog input, 8 1-5 VDC / 4-20 mADC F8 = Slot 2, high speed counter, 8 12V (F7 for 24 VDC) DF = Slot 3, discrete input, 16 12 VDC (DE for 24 VDC) 00 = Slot 4, not used B2 = Slot 4, analog output, 2 1-5 VDC / 4-20 mADC E5 = Slot 5, discrete output, 8 12 or 24 VDC solid state relay E5 = Slot 6, discrete output, 8 12 or 24 VDC solid state relay 200 = Built-in display / keypad M04 = EPTB3330 version of firmware / software


25

GAS FLOW COMPUTER

Bristol Babcock DPC 3330, EPOR3330 Version Model 3330-10A-3101-242-1-1-AB-AB-DF-00-E5-E5-200-M05-0-0 (No analog outputs) Model 3330-10A-3101-242-1-1-AB-AB-DF-B2-E5-E5-200-M05-0-0 (With analog outputs) 3330-10A = DPC 3330 3 = Base unit 6 I/O slots, NEMA 1 1 = Internal power supply +12 VDC (2 for 24 VDC) 0 = Not used 1 = Certification FM approved 242 = CPU 24 MHz., 386 Protected Mode CPU, 512 KB base RAM,

2 BIP ports, w/o FPP, external BIP, 2 MB expansion RAM 1 = Communication ports A and B Port A = Enhanced RS-232/485 and Port B = RS-232/485 1 = Communication ports C and D Port C = Enhanced RS-232/485 and Port D = RS-232/485 I/O modules: AB = Slot 1, analog input, 8 1-5 VDC / 4-20 mADC AB = Slot 2, analog input, 8 1-5 VDC / 4-20 mADC DF = Slot 3, discrete input, 16 12 VDC (DE for 24 VDC) 00 = Slot 4, not used B2 = Slot 4, analog output, 2 1-5 VDC / 4-20 mADC E5 = Slot 5, discrete output, 8 12 or 24 VDC solid state relay E5 = Slot 6, discrete output, 8 12 or 24 VDC solid state relay 200 = Built-in display / keypad M05 = EPOR3330 version of firmware / software


26

GAS FLOW COMPUTER

Bristol Babcock Teleflow Model 3530-10B-03-02-501-1-x-y, H20, S303 300 In.WC differential pressure 2000 psig static pressure Standard enclosure and mounting kit TGP ACCOL firmware and software 6 VDC, 7 AH lead cell battery, 6.5 watt solar panel with 15 ft. cable RS-232 communication NEC Class I, Division 1 certification x = flange orientation 1 = upstream left 2 = upstream right y = expansion 0 = none

3 = analog output board

Bendable RTD, spring loaded, 100 ohm platinum, DIN 43760, 316SS Armored cable 15 ft., insertion length up to 10"

Requires IStran intrinsic safety interface, Bristol Babcock part number 396166-01-6, which may be included with the power/communications assembly.

VOLUME CORRECTOR Bristol Babcock Telecorrector Model 3530-50B-28-02-501-1-1-1-0-3-y, H20, S303 2000 psig static pressure Standard enclosure and mounting kit TGP ACCOL firmware and software 6 VDC, 7 AH lead cell battery, 6.5 watt solar panel with 15 ft. cable Telecounter, 10 cf/rev. CW rotation RS-232 communication NEC Class I, Division 1 certification y = expansion 0 = none

3 = analog output board Bendable RTD, spring loaded, 100 ohm platinum, DIN 43760, 316SS Armored cable 15 ft., insertion length up to 10"

Requires IStran intrinsic safety interface, Bristol Babcock part number 396166-01-6, which may be included with the power/communications assembly.


27

GAS FLOW COMPUTER

Thermo Electron AutoMate Part #2-0490-0750 with Part #9-9480-054 El Paso EPROM (dual run orifice or linear meter applications), which includes: Part #8-0480-197: AutoMate modular basic with 4M RAM, +6 VDC NEC Class I Division 2, Group D 7 AI, 2 DI, 2 DO, 2 RS-232 comm ports Part #3-0480-195: Expansion board (2 DI, 2 DO, 2 PI, 1 AO, 1 RS-232 comm port) Part #3-0480-190: Solid state relay board (4 DO) Thermo Electron AutoPilot Part #2-0485-2031 with Part #9-9485-053 El Paso EPROM (single run orifice meter applications), which includes: Part #8-0485-380: AutoPilot basic with 4M RAM and keypad, +6 VDC NEC Class I Division 1 (intrinsically safe) Group D 3 AI, 2 RTD inputs, 2 RS-232 comm ports Part #3-0485-071: AP DI/DO option (2 DI, 2 DO) Part #3-0485-391: Honeywell smart multi-variable integrated transmitter, stainless steel, 0-400 In.WC differential pressure, 0-1500 psia static absolute pressure Part #3-0465-029: AP standard temperature probe Part #3-0465-073: AP RTD cable, 15’ flex conduit Part #3-0485-034: 2” pole mount kit Part #6-9596-896: PGI 5-valve manifold for Honeywell transmitters 316SS, P/F, dielectric isolators

VOLUME CORRECTOR Thermo Electron AutoPilot Part #2-0485-2032 with Part #9-9485-053 El Paso EPROM (single run linear meter applications), which includes: Part #8-0485-380: AutoPilot basic with 4M RAM and keypad, +6 VDC NEC Class I Division 1 (intrinsically safe) Group D 3 AI, 2 RTD inputs, 2 RS-232 comm ports Part #3-0485-234: AP pulse input kit (2PI) Part #3-0485-071: AP DI/DO option (2 DI, 2 DO) Part #3-0485-391: Honeywell smart multi-variable integrated transmitter, stainless steel, 0-1500 psia static absolute pressure Part #3-0465-029: AP standard temperature probe Part #3-0465-073: AP RTD cable, 15’ flex conduit Part #3-0485-034: 2” pole mount kit Part #3-0474-052: IScom kit , intrinsically safe power and communications interface

8-16 VDC input, 6 VDC output


28

POWER / COMMUNICATIONS ASSEMBLY

Southwest Photovoltaic (PV) Systems Part # AC/1B (AC power and dial-up communications) Battery, MK27, Gel Cell, 86 AH, 12V Battery charger, True Charge 10+, 120 VAC input, 12 VDC output, 10 A Intrinsically safe transceiver: IStran 396-166-01-6 for Teleflow or IScom 3-0474-052 for AutoMate or AutoPilot Modem, Telenetics MIU-14.4LV, Telco phone black box (optional) Enclosure, NEMA 3R/4, 20” x 15” x 15”, two compartment with backplate Wired with circuit breakers, terminal strips, and hardware Southwest Photovoltaic (PV) Systems Part # AC/2B (AC power and radio communications) Battery, MK27, Gel Cell, 86 AH, 12V (2 ea.) Battery charger, True Charge 10+, 120 VAC input, 12 VDC output, 10 A Intrinsically safe transceiver: IStran 396-166-01-6 for Teleflow or IScom 3-0474-052 for AutoMate or AutoPilot Enclosure, NEMA 3R/4, 46” x 26” x 17”, two compartment with backplate Wired with circuit breakers, terminal strips, and hardware Southwest Photovoltaic (PV) Systems Part # SOLAR2/2B (solar power and radio communications) Battery, MK27, Gel Cell, 86 AH, 12V (2 ea.) Solar panel, BP 80 watt, 5 A @ 17.2 VDC (2 ea.) Regulator, ASC 12/16 AE Charge Control Intrinsically safe transceiver: IStran 396-166-01-6 for Teleflow or IScom 3-0474-052 for AutoMate or AutoPilot Enclosure, NEMA 3R/4, 46” x 26” x 17”, two compartment with backplate Mount kit, system cable kit, pole and ground mount plate NEC Class I, Division 2, Group D

Explosion-proof conduit fitting to house circuit breakers or Div. 2 circuit breakers Wired with circuit breakers, terminal strips, and hardware Southwest Photovoltaic (PV) Systems Part # SOLAR3/3B (solar power and radio communications) Battery, MK27, Gel Cell, 86 AH, 12V (3 ea.) Solar panel, BP, 80 watt, 5 A @ 17.2 VDC (3 ea.) Regulator, ASC 12/16 AE Charge Control Intrinsically safe transceiver: IStran 396-166-01-6 for Teleflow or IScom 3-0474-052 for AutoMate or AutoPilot Enclosure, NEMA 3R/4, 46” x 26” x 17”, two compartment with backplate Mount kit, system cable kit, pole and ground mount plate NEC Class I, Division 2, Group D

Explosion-proof conduit fitting to house circuit breakers or Div. 2 circuit breakers Wired with circuit breakers, terminal strips, and hardware


29

DATA CONCENTRATOR

Bristol Babcock RTU 3310 Model 3310-10A-331-0A2-1-00-00-00-00-000-00 3310-10A = RTU 3310 Base unit: 3 = 386 CPU Package 3 = +12 VDC Power Supply (4 for 24 VDC) 1 = FM Certification CPU Option: 0A2 = 24 MHz., 386 Protected Mode CPU, 2 MB RAM, 2 BIP ports, w/o FPP Communications ports: 1 = RS-485 (2 ea.), RS-232 (2 ea.) NEMA 1 enclosure, no I/O modules, no display/keypad.

Telebyte 268, RS-232 opto-isolation module

ANALOG SIGNAL ISOLATOR Action Instruments TransPak T703-2000 DC input isolating, field configurable, two-wire transmitter, 4-20 mADC, with T910 bulkhead mounting plate


30

GAS FLOW COMPUTER

Fisher ROC 364 RTU Model FSROC-364H/MCUH/FP1/CMA1H/CMB1H/IR1H/BP2H/FSAI-1H/FSAO-1H/ FSDO-4H/FSDI-1H ROC Type: ROC364 Remote Controller 64 I/O slots, +24 VDC MCU: MCUH ROC364 Master Control Unit I/O Rack(s): IR1H 1I/O Rack for 16 Points ROCPAC: FP1 FLASHPAC w/512 RAM COM Port 1: CMA1H EIA-232 Card COM Port 2: CMB1H EIA-232 Card Backplate: BP2H Backplate for 1-2 I/O Racks FSAI-1H ROC Type: I/O Modules I/O Module Type: AI-1H Analog In Loop FSAO-1H ROC Type: I/O Modules I/O Module Type: AO-1H Analog Out Source 4 – 20 mADC FSDO-1H ROC Type: I/O Modules I/O Module Type: DO-4H Discrete Out Relay 24 VDC FSDI-1H ROC Type: I/O Modules I/O Module Type: DI-1H Discrete In Source Additional Modules Fisher Part Number PeopleSoft Item ID Pulse In Source FSPI-1H Analog In Differential FSAI-2H GC Serial I/O Module - RS-232 GC Serial - 232


31

GAS FLOW COMPUTER

Fisher ROC 312 RTU Model FSROC-300H/312H/FP1/CMA1H/FSAI-1H/FSAO-1H/FSDO-4H/FSDI-1H ROC Type: ROC312 Remote Controller 6 Fixed I/O, plus 6 expansion slots, +8-30 VDC ROCPAC: FP1 FLASHPAC w/512 RAM COM Port 1: CMA1H EIA-232 Card FSAI-1H ROC Type: I/O Modules I/O Module Type: AI-1H Analog In Loop FSAO-1H ROC Type: I/O Modules I/O Module Type: AO-1H Analog Out Source 4 – 20 mADC FSDO-1H ROC Type: I/O Modules I/O Module Type: DO-4H Discrete Out Relay 24 VDC FSDI-1H ROC Type: I/O Modules I/O Module Type: DI-1H Discrete In Source Additional Modules ROC Part Number PeopleSoft Item ID Pulse In Source FSPI-1H Analog In Differential FSAI-2H GC Serial I/O Module - RS-232 GC Serial - 232


32

GAS FLOW COMPUTER

Fisher ROC 407 RTU Model FSROC-407/407H/CMB1H/FSAI-1H/FSAO-1H/FSDO-4H/FSDI-1H/MVS Sensor ROC Type: ROC407 Remote Controller 1 Fixed AI, 1 Fixed AI/PI 6 expansion I/O slots 8-30 VDC COM Port 2: CMB1H EIA-232 Card FSAI-1H ROC Type: I/O Modules I/O Module Type: AI-1H Analog In Loop FSAO-1H ROC Type: I/O Modules I/O Module Type: AO-1H Analog Out Source 4 – 20 mADC FSDO-1H ROC Type: I/O Modules I/O Module Type: DO-4H Discrete Out Relay 24 VDC FSDI-1H ROC Type: I/O Modules I/O Module Type: DI-1H Discrete In Source Additional Modules Bristol Part Number PeopleSoft Item ID Pulse In Source FSPI-1H Analog In Differential FSAI-2H GC Serial I/O Module - RS-232 GC Serial - 232


33

GAS FLOW COMPUTER

Bristol Babcock DPC 3335 4-Run Standard Version Model 3335-10A-210110-73-1-1-1-AB-F1-BB-B2-DE-E2-E2-AB-U1-00 9-slot I/O chassis w/ front cover CPU: Protected Mode (PM), 2MB RAM, 386 CPU w/ Floating Point Processor Port A/B: RS-232/485 Port C/D: RS-232/485 I/O Modules: AB = Analog Inputs, 8-points, 1-5 VDC / 4-20 mADC F1 = High Speed Counters, 4-points, 24 VDC BB = Analog Outputs, 4-points, 1-5 VDC / 4-20 mADC B2 = Analog Outputs, 2-points, 1-5 VDC / 4-20 mADC DE = Discrete Inputs, 16 points, 24 VDC, 30 ms E2 = 4 points, 24 VDC coil relays E2 = 4 points, 24 VDC coil relays AB = Analog Inputs, 8-points, 1-5 VDC / 4-20 mADC U1 = BBTI Module, 4-Points, 3508 TX inputs


34

GAS FLOW COMPUTER

Bristol Babcock TeleRTU Plus 3530 Model 3530-25B-02-02-310-0-2111-J100-S106 Two-Run Gas Flow Computer El Paso Special Packaging ACCOL 12 volts, 40AH lead battery, 40 watt solar panel Radio ready (without radio) Certification, none I/O expansion board Relay board Power distribution board Low bower TIB Polyphaser Requires ISTran intrinsic safety interface, Bristol Babcock part number 396166-01-6, which is included with the Standard Radio Communications Package. Bristol Babcock TeleRTU Plus 3530 Model 3530-25B-02-02-310-0-2011-J100-S106 One-Run Gas Flow Computer El Paso Special Packaging ACCOL 12 volts, 40AH lead battery, 40 watt solar panel Radio ready (without radio) Certification, none I/O expansion board Power distribution board Low power TIB Polyphaser Bristol Babcock Part #395524-04-0 Custom battery enclosure 60W solar panel and solar regulator 100 AH battery, enclosure All mounting hardware


35

STANDARD RADIO COMMUNICATIONS PACKAGE

MDS 9710B Data Transceiver 928/952 MHz, W/9600 baud modem, loop-back & Diagnostics - 30 feet, 1/2" Heliax cable w/ N female connector at top and N male connector at bottom - Ground Kits,1/2” Heliax (2- required) - 30” RG 213 Coaxial Cable (Antenna to Heliax) - Antenna, SCALA, Model # TY900, 10 db gain, Yagi - Intrinsically safe transceiver, Istran 396-166-01-6 For Spread Spectrum Radio use: - MDS9810 Spread Spectrum radio with 1200-baud modem, loop-back, and diagnostics - Antenna, Model # MYG9303-ED, 6 db gain, Yagi

POWER SUPPLY MajorPower 28 VDC Linear Power Supply Model LSRM-18A 12 Amps Continuous Duty 18 Amps ICS 5 1/4”H x 19W x 12 1/2”D 38 lbs Note: This power supply should be ordered when one or more Ultrasonic Meters are included in the project, and a Bristol DPC 3335 controller will be used.


36

GAS FLOW COMPUTER

Mojave Pipeline Co.

Bristol Babcock DPC 3330 3 - Run Version Model 3330-10A-1201-292-1-1-AB-F1-BB-B2-DD-E5-E5-AB-200 3330-10A = DPC3330 1 = Base unit, 12 I/O slots, NEMA4 2 = Internal power supply, 24 VDC 0 = Not used 1 = FM approved 29 = CPU 386 Protected Mode, with FPP 2 = 2 MB memory 1 = Comm. Port A, B A - RS-232/485 B - RS-232/485 1 = Comm. Port C,D C - RS-232/485 D - RS232/485 I/O AB Slot 1 8 point analog input F1 Slot 2 24 VDC high speed counter BB Slot 3 4 channel analog output B2 Slot 4 2 channel analog output DD Slot 5 16 channel discrete input E5 Slot 6 8 channel solid state discrete output E5 Slot 7 8 channel solid state discrete output AB Slot 8 8 point analog input 200 Keypad and Display


37

GAS FLOW COMPUTER

Bristol Babcock 12-Slot 3330 in Carbon Steel Cabinet RTU Model 3330-10A-1201-282-20-A4-A4-00-00-D2-00-E2-00-00-00-00-00-200 Enclosure Model CSLL5RO PeopleSoft Item ID 89096 3330-10A = DPC 3330 1 = Base unit 12 I/O slots, NEMA 1 2 = Internal power supply +24 VDC 0 = Not used 1 = Certification FM approved 282 = CPU 24 MHz., 386 Protected Mode CPU, no FPP 2 = Communication ports A and B Port A = Enhanced RS-232/485

Port B = 1200 baud modem (radio keying) 0 = No C and D Communication ports C & D Ports may be added

I/O modules: A4 = Slot 1, analog input, 4 1-5 VDC / 4-20 mADC, 180 VDC Common Mode A4 = Slot 2, analog input, 4 1-5 VDC / 4-20 mADC, 180 VDC Common Mode 00 = Slot 3, not used (Slot Reserved for 2-point Analog Output board) 00 = Slot 4, not used (Slot Reserved for 4-point High Speed Counter board) D2 = Slot 5, discrete input, 8 24 VDC / VAC, 1mS filter 00 = Slot 6, not used (Slot Reserved for 2-point Analog Output board) E2 = Slot 7, discrete output, 4 24V relay 00 = Slot 8, not used (Slot Reserved for 4-point Discrete Output board) 00 = Slot 9, not used (Slot Reserved for 4-point Discrete Output board) 00 = Slot 10, not used (Slot Reserved for 4-point Discrete Output board) 00 = Slot 11, not used (Slot Reserved for 4-point Analog Input board) 00 = Slot 12, not used (Slot Reserved for 2-point Analog Output board) 200 = Built-in display / keypad Additional Modules Bristol Part Number PeopleSoft Item ID Analog Input (4 pt) 392544-11-1 89501 Analog Output (2 pt) 392547-02-3 89506 Discrete Input (8 pt) 392000-03-2 89514 Discrete Output (4 pt) 392006-04-9 89510 High Speed Counter (4 pt) 392008-04-1 89497


38

GAS FLOW COMPUTER

Bristol Babcock 12-Slot 3330 in Stainless Steel Cabinet RTU Model 3330-10A-1201-282-20-A4-A4-00-00-D2-00-E2-00-00-00-00-00-200 Enclosure Model SSWL5RO PeopleSoft Item ID 89112 3330-10A = DPC 3330 1 = Base unit 12 I/O slots, NEMA 1 2 = Internal power supply +24 VDC 0 = Not used 1 = Certification FM approved 282 = CPU 24 MHz., 386 Protected Mode CPU, no FPP 2 = Communication ports A and B Port A = Enhanced RS-232/485




39

GAS FLOW COMPUTER

Bristol Babcock 12-Slot 3330 no Cabinet RTU Model 3330-10A-1201-282-20-A4-A4-00-00-D2-00-E2-00-00-00-00-00-200 PeopleSoft Item ID 89385 3330-10A = DPC 3330 1 = Base unit 12 I/O slots, NEMA 1 2 = Internal power supply +24 VDC 0 = Not used 1 = Certification FM approved 282 = CPU 24 MHz., 386 Protected Mode CPU, no FPP 2 = Communication ports A and B Port A = Enhanced RS-232/485




40

DATA CONCENTRATOR

Bristol Babcock 0-Slot 3330 Data Concentrator (for chromatograph) RTU Model 3330-10A-5201-282-21-000 PeopleSoft Item ID 89215 3330-10A = DPC 3330 5 = Base unit 0 I/O slots, NEMA 1 2 = Internal power supply +24 VDC 0 = Not used 1 = Certification FM approved 282 = CPU 24 MHz., 386 Protected Mode CPU, no FPP 2 = Communication ports A and B Port A = Enhanced RS-232/485

Port B = 1200 baud modem (radio keying) 1 = Communication ports C and D Port C = Enhanced RS-232/485

Port D = RS-232/485 000 = No display / keypad


1

FLOW CONTROL VALVE or PRESSURE REGULATOR

Becker Precision Equipment (bpe) Conditions: Sch. 80 inlet and outlet pipe Open = 9 - 81º or 10 - 90% DP = 20 psid @ Qmax. for FC D/S pipe velocity = 100 fps max.

Tf = 60º F SPL = 85 dBA max. at valve SG = 0.600 SPL = 55 dBA max. at property line

Valve: bpe FPCV-T0, QTCV-T1, or QTCV-T2, ball valve, full opening, trunion mounted design, API 6D with monogram, RF x RF ANSI 600, face-to-face ANSI B16.10, testing ANSI B16.34, shutoff ANSI Class IV or V, carbon steel body, stainless steel throttling trim, metal seat, carbon steel fittings in body drain and sealant ports Actuator (as applicable): bpe RPDA rotary piston double-acting pneumatic actuator, vertical orientation, left (right) hand mounting, 100 psig power gas supply bpe RPSR rotary piston spring-return pneumatic actuator, vertical orientation, left (right) hand mounting, 100 psig power gas supply Positioner (for flow control from GFC): bpe HPP-5 double-acting pneumatic positioner, fail in open (close) position on loss of input signal, fail in open (close) position on loss of 100 psig power gas supply, action is open (close) on increasing signal, non-bleeding at steady state conditions, 3-15 psig input, discharge to atmosphere bpe DNGP-2 double-acting digital natural gas positioner, fail in open (close, last) position on loss of input signal, action is open (close) on increasing signal, non-bleeding at steady state and full open and full closed conditions, 12 (24) VDC power, 4-20 mADC input, digital linear valve position feedback transmitter Pilot (for self-operating pressure regulation): bpe VRP-x-B-CH double-acting pilot, fail in open (close) position on loss of measured variable, fail in open (closed) position on loss of 100 psig power gas supply, action is open (close) on increasing signal, non-bleeding at steady state conditions, discharge to atmosphere bpe VRP-x-SB-CH single-acting pilot, fail in open (close) position on loss of measured variable, fail in open (closed) position on loss of 100 psig power gas supply, action is open (close) on increasing signal, non-bleeding at steady state conditions, discharge to atmosphere bpe VRP-x-SB-PID single-acting three-mode controller, fail in open (close) position on loss of measured variable, fail in open (closed) position on loss of 100 psig power gas supply, action is open (close) on increasing signal, non-bleeding at steady state conditions, discharge to atmosphere x = setpoint range 175 = 1 - 175 psig 1000 = 550 - 1000 psig 600 = 50 - 600 psig 1300 = 800 - 1300 psig


2

FLOW CONTROL VALVE or PRESSURE REGULATOR Continued . . . Accessories (as required): bpe MCV-3L pneumatic manual control valve with locking provision bpe NBV-100 no bleed valve when either fully closed or open bpe FD-1 gas supply system with FD-1500 filter dryer, regulator, gauge, relief valve bpe VB-250 volume booster to increase actuator stroking speed bpe SLV-30 signal lock valve, fail in last position on loss of input signal Fisher 377 trip valve assembly and volume tank, fail in last position on loss of power gas supply (100 psig, DOT LP) bpe standard preparation (sandblast, primer, topcoat painting), 316SS tubing, fittings, and valves


3

FLOW CONTROL VALVE or PRESSURE REGULATOR

Fisher Control Conditions: Sch. 80 inlet and outlet pipe Open or Valve Travel = 10 - 90% DP = 5 psid @ Qmax. D/S pipe velocity = 100 fps max.


Valve (as applicable): Fisher, ‘V’ and ‘Hi’ Ball Series, rotary control ball valve, API 6D with monogram, RF x RF ANSI 600, pressure and temperature rated per ANSI B16.34, shutoff in accordance with ANSI B16.104, Class IV or V, full opening, trunnion mounted design, direct stem, standard trim, carbon steel fittings in body drain and sealant ports. Fisher, ‘E’ Body, sliding stem globe style control valve, API 6D with monogram, RF x RF ANSI 600, pressure and temperature rated per ANSI B16.34, shutoff in accordance with ANSI B16.104, Class IV or V, carbon steel body, stainless steel throttling trim, metal seat, carbon steel fittings in body drain and sealant ports. Actuator (as applicable): Fisher diaphragm linear actuator, Type 657/667, vertical orientation, left (right) hand mounting, 0 to 33 psig supply pressure to actuator, direct acting. Fisher rotary piston double-acting pneumatic actuator, Type 1061, vertical orientation, left (right) hand mounting, 90 - 150 nominal psig power gas supply, direct acting. Fisher rotary spring and diaphragm pneumatic actuator, Type 1052, vertical orientation, left (right) hand mounting, 0-33 nominal psig power gas supply, direct acting. Shafer rotary vane actuator, Gas/Hydraulic tanks, ASME certified and approved, Manual hydraulic hand pump with auto reset feature for local manual operation, Adalet XJL terminal box assembly per Shafer assembly # 08672, speed controls, remote 2-way electric control per Shafer drawing #4944-s, vertical stem position, horizontal line position, pilot and power gas pressure 700-900 psig. Positioner (for flow or pressure control from flow computer): Fisher DVC Series 6000 pneumatic positioner, HC Hart Communicating, fail in open (close) position on loss of input signal, fail in open (close) position on loss of 100 psig (nominal) power gas supply, action is open (close) on increasing signal, non-bleeding at steady state conditions, 4-20 mA input, FM explosion proof, with volume boosters as required. Accessories (as required): Fisher 377 trip valve assembly and volume tank, fail in last position, fail in open position or fail in closed position on loss of power gas supply (100 psig, ASME Approved volume tank)


4

MONITOR REGULATOR

Becker Precision Equipment (bpe) Conditions: Sch. 80 inlet and outlet pipe Open = 9 - 81 deg. or 10 - 90% Tf = 60º F D/S pipe velocity = 100 fps max.

SG = 0.600 Valve: bpe FPCV-T0, ball valve, full opening, trunion mounted design, API 6D with monogram, RF x RF ANSI 600, face-to-face ANSI B16.10, testing ANSI B16.34, shutoff ANSI Class IV or V, carbon steel body, stainless steel throttling trim, metal seat, carbon steel fittings in body drain and sealant ports Actuator: bpe RPSR rotary piston spring-return pneumatic actuator, vertical orientation, left (right) hand mounting, 100 psig power gas supply Pilot: bpe VRP-x-SB-CH single-acting pilot, fail in open (close) position on loss of measured variable, fail in open (closed) position on loss of 100 psig power gas supply, action is open (close) on increasing signal, non-bleeding at steady state conditions, discharge to atmosphere x = setpoint range 175 = 1 - 175 psig 600 = 50 - 600 psig 1000 = 550 - 1000 psig 1300 = 800 - 1300 psig Accessories (as required): bpe MCV-3L pneumatic manual control valve with locking provision bpe NBV-100 no bleed valve when either fully closed or open bpe FD-1 gas supply system with FD-1500 filter dryer, regulator, gauge, relief valve bpe VB-250 volume booster to increase actuator stroking speed bpe SLV-30 signal lock valve, fail in last position on loss of input signal Fisher 377 trip valve assembly and volume tank, fail in last position on loss of power gas supply (100 psig, DOT LP) bpe standard preparation (sandblast, primer, topcoat painting), 316SS tubing, fittings, and valves


5

OPP SHUT-IN VALVE

Wilson Valve Specialties TGP Valve:

WKM model 370 D4 21-YFF-21, (2” thru 6”) full port ball valve, API 6D with monogram, ANSI 600, RFFE connections, direct stem, standard trim, carbon steel fittings in body drain and sealant ports

Actuator: low pressure pneumatic, spring return, fail close

Morin B-023U-S100 for 2” Morin B-036U-S140 for 3” Morin B-135U-S080 for 4” Morin B-135U-S160 for 6”

Instrumentation and Accessories:

Power gas filter, high pressure regulator, low pressure regulator, relief valve, supply gauges, high pressure pilot/sensor (set point = X psig) with car seal, automatic reset relay, lockable valve in the tubing to the actuator cylinder, 2 SPDT limit switch, adaptors and couplings, 316SS tubing and fittings

Assembled in accordance with Wilson Dwg. No. LP-SR-FC-HPESD-2R-F-2G-RLF-RLY SNG Valve:

Any 2” thru 6” (for larger size valves, contact vendor) full port quarter-turn ball valve or restricted port quarter-turn plug valve at operating pressures of 150 psig to 1500 psig. Valve top works information is required for proper installation.

Actuator: high pressure direct gas operator, fail close on low or high pressure signals

Biffi GIG.3S75MHP75 (for vales 2” thru 6”) Instrumentation and Accessories:

Power gas dehydrating filter/condensate separator, dust excluder with check valve, high pressure pilot/sensor and low pressure pilot/sensor valve (set point = PSIG), high pressure shuttle valve, adapter and coupling for valve mounting, 316 SS tubing and fittings. Solenoids and limit switches provided upon request if applicable for remote operation or monitoring. High/low pressure set points for pilot valves to be provided when ordering.

Assembled in accordance with Wilson Dwg. No. L-LP-HP-CL-001


6

PRESSURE REGULATOR or FLOW CONTROL VALVE

Mooney Controls Conditions: Sch. 80 inlet and outlet pipe DP = 20 psid @ Qmin. D/S pipe velocity = 100 fps max.


Valve: Flowgrid single (double) port, x", 100 (75, 50, 35)% capacity, RF x RF ANSI 600, carbon steel Pilot (for self-operating pressure regulation): Series 20H, PRV, 303SS (forged brass), standard construction materials, standard trim options, standard orifice, 200 - 520 black (400 – 900 green) psi spring range Pilot (for flow control from GFC): Badger Meter, Research Control Valve, Type 807 valve assembly, 1/4", standard materials of construction, air to open (fail close), 3-15 psig signal, with Type 754 actuator assembly, 1/4", standard materials of construction Restrictor: Type 24S, 316SS, nitrile o-ring Filter: Type 30S, 303SS


7

TUBE SWITCHER

Valve: Ball valve, API 6D with monogram, RF x RF ANSI 600, full opening, direct stem, standard trim, carbon steel fittings in body drain and sealant ports Becker Precision Equipment (bpe) Actuator: Becker bpe RPDA rotary piston double-acting pneumatic actuator, vertical orientation, left (right) hand mounting, 100 psig power gas supply, MCV-3L pneumatic manual control valve with locking provision Pilot: Versa, VGG-4422-G-XX-D012 or D024, pneumatic pilot valve, 4-way, 2-position, 5-port, 3/8" NPT ports, inline, 2-solenoid actuated, 12 VDC or 24 VDC as applicable, continuous duty, hazardous location (NEC Class I, Division 1, Group D), guarded manual override, detented bpe standard preparation (sandblast, primer, topcoat painting), 316SS tubing, fittings, and valves Diode: 1N6389 (or equal), 50 V., 6 A., reverse bias Bettis Actuator: HD, G (Robotarm II), or CB series double-acting pneumatic scotch-yoke valve actuator, 100 psig operating pressure Pilot: Versa, VGG-4422-G-XX-D012 or D024, pneumatic pilot valve, 4-way, 2-position, 5-port, 3/8" NPT ports, inline, 2-solenoid actuated, 12 VDC or 24 VDC as applicable, continuous duty, hazardous location (NEC Class I, Division 1, Group D), guarded manual override, detented Pilot: Numatics, I34XX446B-24VDC, pneumatic pilot valve, 4-way, 2-position, 5-port, ½” FNPT ports, inline, 2-solenoid actuated, 12 VDC or 24 VDC as applicable, hazardous location (NEC Class I, Division 1, Group D), detented Manual Control: Becker MCV-3L pneumatic manual control valve with locking provision or Versa, VUL-4404, pneumatic pilot valve, 3-detent manually operated, hand centerline lever, 4-way, 3/8” NPT ports, inline, labeled “Local Open / Remote / Local Closed” 316SS tubing, fittings, and valves, and mounting hardware Diode: 1N6389 (or equal), 50 V., 6 A., reverse bias


8

TUBE SWITCHER Continued . . . Biffi / Morin Actuator: ALGA / B Series double-acting pneumatic scotch-yoke valve actuator, 100 psig operating pressure Pilot: Versa, VGG-4422-G-XX-D012 or D024, pneumatic pilot valve, 4-way, 2-position, 5-port, 3/8" NPT ports, inline, 2-solenoid actuated, 12 VDC or 24 VDC as applicable, continuous duty, hazardous location (NEC Class I, Division 1, Group D), guarded manual override, detented Pilot: Numatics, I34XX446B-24VDC, pneumatic pilot valve, 4-way, 2-position, 5-port, ½” FNPT ports, inline, 2-solenoid actuated, 12 VDC or 24 VDC as applicable, hazardous location (NEC Class I, Division 1, Group D), detented Manual Control: Becker MCV-3L pneumatic manual control valve with locking provision or Versa, VUL-4404, pneumatic pilot valve, 3-detent manually operated, hand centerline lever, 4-way, 3/8” NPT ports, inline, labeled “Local Open / Remote / Local Closed” 316SS tubing, fittings, and valves, and mounting hardware Diode: 1N6389 (or equal), 50 V., 6 A., reverse bias Morin Actuator: B Series double-acting pneumatic scotch-yoke valve actuator, 100 psig supply, with lock-out device

1. B-036U-D000 for use on a 4” Grove B-4D, API 6D, ANSI 600 ball valve 2. B-059U-D000 for use on a 6” Grove B-5, API 6D, ANSI 600 ball valve 3. B-135U-D000 for use on a 4” Grove B-5, API 6D, ANSI 600 ball valve 4. B-210U-D000 for use on a 4” Grove B-5, API 6D, ANSI 600 ball valve 5. B-270U-D000 for use on a 4” Grove B-5, API 6D, ANSI 600 ball valve

Pilot: Versa, VGG-4422-G-XX-D012 or D024, pneumatic pilot valve, 4-way, 2-position, 5-port, 3/8" NPT ports, inline, 2-solenoid actuated, 12 VDC or 24 VDC as applicable, continuous duty, hazardous location (NEC Class I, Division 1, Group D), guarded manual override, detented Manual Control: Becker MCV-3L pneumatic manual control valve with locking provision or Versa, VUL-4404, pneumatic pilot valve, 3-detent manually operated, hand centerline lever, 4-way, 3/8” NPT ports, inline, labeled “Local Open / Remote / Local Closed” 316SS tubing, fittings, and valves, and mounting hardware


9

ANCILLARY EQUIPMENT

for FLOW CONTROL VALVES, MONITOR REGULATORS, PRESSURE REGULATORS,

and TUBE SWITCHERS(as required)

Becker Precision Equipment Pressure Instrumentation Column 6" square base, 1/2" FNPT inlet connection, 316 SS tubing, fittings, and valves, and gauges First stage: Meco P-225 high-pressure regulator (100 psig output) bpe RV-150-B relief valve (125 psig setpoint) Second stage: Fisher 67AFR low-pressure regulator (20 psig output) bpe RV-25-B relief valve (25 psig setpoint) Third stage: Fisher 912 regulator for heater supply 3.5-5 In.WC spring range Heater: Bruest SS-B-120(12)-CGA-N catalytic heater NEC Class I, Division 1, Group D 120 VAC (12 VDC), explosion proof junction box,

safety shutoff valve, thermocouple, protective grill Filter dryer: bpe FD-1500 with bypass at inlet Welker Engineering Three Chamber Pressure Column 6" square base, 1/2" FNPT inlet connection, 316 SS tubing, fittings, and valves, and gauges First stage: Meco P-225 high-pressure regulator (100 psig output) Generant VRV SS relief valve (125 psig setpoint) Second stage: Fisher 67AFR low-pressure regulator (20 psig output) Generant VRV SS relief valve (25 psig setpoint) Third stage: Fisher 912 regulator for heater supply 3.5-5 In.WC spring range Heater: Bruest B624CGA120AC (12DC) catalytic heater NEC Class I, Division 1, Group D 120 VAC (12 VDC), explosion proof junction box

safety shutoff valve, thermocouple, protective grill Filter dryer: F-5B with bypass at inlet Becker Precision Equipment Gas Supply Post 2” post with 6” square base, 316 SS tubing, fittings, and valves as follows:

bpe FD-1 assembly to include FD-1500 filter dryer with bypass at inlet, pressure regulator set at 100 psig, relief valve set at 125 psig, gauge Bruest "Freeze-Fiter" Model 1800-CGA-N-120VAC (12 VDC), catalytic heater, single coil, CSA model, NEC Class I Division 1 Group D, explosion-proof junction box, pressure regulator, low pressure regulator, relief valve, gauge, tubing and mounting hardware


10

ANCILLARY EQUIPMENT for FLOW CONTROL VALVES, MONITOR REGULATORS, PRESSURE REGULATORS, and TUBE SWITCHERS Continued . . Fairchild 24X-F-S-10-x-4-00-0-2 Motor to pressure (M/P) converter, explosion-proof enclosure, FM approved, DC pulse control unit, Model 10 regulator, 0.5-30 (3-15) psig pressure range, stepper motor x = 7 24 VDC pulse input x = 8 12 VDC pulse input x = 9 12-24 VDC analog input Fairchild PLT8-10-DP-30-30 Panel loading (automatic-manual) station, transfer function, Model 10 regulator, 0.5-30 (3-15) psig pressure range, dual plain gauges (0-30 psig) Dahl Super Mite 71H Diaphragm operated pneumatic high-low selecting relay, 71H, non-bleed, 1/4" FNPT ports M*System M2SES-2AA-R/UL Electronic high/low signal selector, DIN rail mount, 4-20 mADC input/output, 24 VDC power AGM Electronics SF2-EA-PB-IA-OA Electronic high/low signal selector, NEMA 4 enclosure, 24 VDC power, 4-20 mADC input/output Welker Engineering DA-1SS (DA1BCOG) Dehydration assembly, with two F-5 filter dryers, two instrument regulators with relief, ¼" NPT inlet and outlet connections, pressure gauge, manifold completely assembled, 100 psig output Becker Precision Equipment FD-2 Supply gas system, with two FD-1500 filter dryers, two pressure regulators, two pressure gauges, relief valve set at 125 psig, all stainless steel hardware, tubing, fittings, and valves Bruest "Freeze-Fiter" 1800-CGA-N-12VDC Catalytic heater, single coil, CSA model NEC Class I, Division 1, Group D, explosion-proof junction box Fisher 1301F high-pressure regulator Fisher 912 low-pressure regulator Nupro SS relief valve, gauge, tubing and mounting hardware (Use on pressure regulator pilot supply line)


11

INDICATING PNEUMATIC PRESSURE CONTROLLER

Bristol Babcock Series 5453 with Mark II (624-II) Control Unit Model 5453-10G-230-012-x0y-z (5453-10G-231-012-00x-y) 5453-10G = Indicating pneumatic pressure controller with 624-II control unit Direct standard calibration Element input range and scale 0 – 1000 psig (0 – 1500 psig) Element type and material Helical, 316 SS Control mode 20 psi supply, gain + integral, 3-15 psi output Case finish Aluminum gray epoxy with gas vent x = Feedback 0 = None 1 = External feedback y = Automatic – manual station 0 = Without A/M station

1 = With A/M station z = Mounting 1 = Wall mount

3 = Pipe mount


12

BLOCK VALVES and BYPASS VALVES

Valves 2” thru 4": Ball valve, API 6D with monogram, RF x RF ANSI 600, full opening, lever operated, standard trim, double block and bleed, carbon steel fittings in body drain and sealant ports, with locking provisions Valves 6" and larger: Ball valve, API 6D with monogram, RF x RF ANSI 600, full opening, single reduction worm gear operated, standard trim, double block and bleed, carbon steel fittings in body drain and sealant ports, with locking provisions


13

SAFETY RELIEF VALVE

Direct spring-operated: AGCO Type 61, 63B, 81, 83, 83F Crosby Style JOS, JBS (flanged) Crosby Series 800, 900 (screwed) Material: Carbon steel body 316SS trim Viton seat Teflon seal Inlet: Size Type (screwed or flanged) ANSI rating for flange Outlet: Size Type (screwed or flanged) ANSI rating for flange Orifice size Set pressure Pilot-operated: AGCO Series 200, 400, 500, 600, 900 Crosby Series JPV, JPVM Axelson Type HL, HD, HF (all other data same as above) Pilot: Pop action or modulating Non-flowing Main valve: Full lift Other data that may be required: Service: 0.6 specific gravity gas, 1.32 ratio of specific heats Back pressure: 0 psig Overpressure: 10% accumulation Temperature: 60º F Capacity: SCFM Code: ASME Section VIII


1

CHROMATOGRAPH

For Eastern Pipelines, the gas chromatograph / EGM building and assembly shall be fabricated in accordance with the following Valtronics specifications and standard drawings: VAL-2005-0 Cover Sheet, Standard Valtronics Chromatograph Building, Type 3 VAL-2005-1 Conduit Schedule VAL-2005-2 Bill of Material VAL-2005-3 Building Exterior VAL-2005-4 Building Interior VAL-2005-5 Electrical Interconnect VAL-2005-6 Gas Sample Conditioning Cabinet A. Daniel Danalyzer Gas Chromatograph BTU Measurement System:

I. Chromatograph: • Model 570 analyzer • Chromatographic analysis of C1 through C6+, CO2 and N2 • NEC Class1, Division 1, Group D • Daniel pneumatic chromatograph valves - helium actuated • Micro-packed columns:

o 4 minute analysis cycle for CIG, EPNG, SNG o 6 minute analysis cycle for TGP

• Thermal conductivity detector • 115VAC, 60Hz, 260 Watts

II. Sample Conditioning System: • X vapor streams, plus one additional stream (for future expansion), plus calibration

gas stream • Stream switching performed by standard, single solenoid configuration • In-line particulate filters for each stream • All streams to have common sample flow control and flow indication

III. Chromatograph Controller: • Model 2350/2350A controller – general purpose, 19” rack mount without keypad or

display • Analysis results in mole% of C1 through C6+, CO2 and N2 per stream • Individual and total per AGA and GPA 2172/2145 of heating value in BTU, specific

gravity, and compressibility factors per stream • Repeatability ±0.5 BTU/1000 BTU over 24 hour test period in environmental chamber

cycled over temperature range of 0-130° F • Analog outputs (2) standard, 4-20 mADC, user-programmable • Analog inputs (4) standard, 4-20 mADC or 1-5 VDC • Serial communications, (4) standard configured RS-232. Additional serial ports

available on model 2350A, to be ordered as option as needed. No modem or Ethernet required.

• Serial ports 1-4 user configurable RS-232, 422, 485 • Digital outputs (5) standard • Digital inputs (5) standard • 115VAC, 60Hz, 260 Watts • MON 2000 software


2

CHROMATOGRAPH Continued . . .

IV. Documentation: • To include one (1) set of analyzer and controller operator manuals, operating

parameters, and system drawings

V. Customer acceptance testing:

• Notification three days prior to shipment for operational check-out and approval by Measurement Lab Services.

VI. Spare Parts:

• Valve repair kit; P/N 3-0500-373 includes:

Chromatograph 6-port valve repair kits (5); P/N 3-0500-108 Sample Shut-off valve repair kits (3); P/N 4-4000-179

VII. Crating and Packing B. Optional Chromatograph Equipment – not included with item “A”:

• Analyzer-controller Interconnect Cable, 15 conductor, P/N 6-4618-122 • Carrier gas helium manifold system, 316SS, no cylinders, P/N 3-5000-050

C. Optional Parts – not included with item “A”:

• Stream adder kit; P/N 3-0500-206 • Valve actuation solenoid; P/N 4-5000-369 • Stream switching solenoid; PN 4-5000-604


3

ANCILLARY EQUIPMENT for CHROMATOGRAPH

Valtronics Mustang / Pony Gas Conditioning System P53-1-1-0-1-1-1-0-1-1-0-1-x Basic single unit type 60 heated enclosures, remote mount A+ Genie Supreme membrane separator with liquid block, Model 123HP-006-SS-LB A+ Genie heated regulator, Model GHR-0SS-004-021 A+ Genie membrane probe, Model GP2-206-SS, ¾” NPT connection Relief valve (setpoint 45 psi), pressure gauge (0-60 psi), door mounted dial thermometer, electrical control system (120 VAC), sample line test port, sample cylinder fill port x = probe length 6 for 2” and 3” meter tubes 1 for 4” thru 8” meter tubes 2 for 10” and 12” meter tubes Welker Engineering Sample Spa Gas Conditioning System Model HR-4SSN HR-4SS heated regulator Relief valve, pressure gauge Thermostatically controlled heater, insulated fiberglass enclosure, pipe mount Welker Engineering integrated pitot sample probe, Model LE-2SSKO-ALS4 Liquid Eliminator membrane, Analyzer Liquid Shut-Off, insulating blanket, ¾” process connection Furon Dekoron Unitherm NEC Class I Division 1:

Part # 2C56-17AXX heat trace tubing for lengths ≤ 250 ft. 1/8" OD x 0.035" WT seamless, 316 SS, 5 W/ft. @ 120 VAC

Part # 2C56-27AXX heat trace tubing for lengths > 250 ft. 1/4" OD x 0.035" WT seamless, 316 SS, 5 W/ft. @ 120 VAC

Part # TSI-SB-2 tubing bundle end termination (2 ea.) Part # HAK-C-100 power / end connection sealing gland (2 ea.) Part # HAK-JB3 power / end junction box (2 ea.) Part # UMB mounting bracket for power / end kit (2 ea.)

Maximum distances: 270 ft. using 120 VAC, 30 A. circuit breaker 540 ft. using 240 VAC, 30 A. circuit breaker Cellex NEC Class I Division 1:

Part # SE2F1-18-8-ATP-035, self regulating heat trace tubing 1/4" OD x 0.035" WT seamless, 316 SS, 5 W/ft. @ 120 VAC

Part # D1-ECK-SR end termination kit (2 ea.), when end termination is within 12” of the classified area. If the end termination is more than 12” from the classified area, use the end kits, seal kits and power termination kits for Division 2 as stated below.

NEC Class I Divison 2:

Part # SE-2F1-18-0-ATP-035, self regulating heat trace tubing 1/4" OD x 0.035" WT seamless, 316 SS, 5 W/ft. @ 120 VAC

Part # ET-8C end termination kit (2 ea.) Part # TBX-3LC power termination kit (2 ea.) Part # FAK-7 seal kit (1 ea.) Part # PS-03 pipe strap for power connection kit (1 ea.)


4

ANCILLARY EQUIPMENT for CHROMATOGRAPH Continued . . . Matheson Model 8-350 (for calibration gas) Regulator, 1/4" FPT Matheson Model 8-250-580 (for carrier gas, 2 ea. required) Regulator, 1/4" FPT Matheson (calibration gas) Scott Specialty Gases (calibration gas) Primary standard gas mixture: Report BTU, specific gravity, and hydrocarbon dewpoint (cricondentherm) according to AGA Contact Measurement Services for the component details particular to each pipeline. Matheson (carrier gas) Scott Specialty Gases (carrier gas) Zero grade helium, 99.995% pure Matheson Model HQ2015-1A Therma-cal cylinder blanket for cal gas, thermostatically controlled, 120 VAC Part Number 10408-00720 insulating pad for gas cylinder Part Number MHOL0013AQ cylinder rack, 4-position, for 9” x 52” cylinders Best Ferrups FF010CC3AOAOAOA Uninterruptible Power System (UPS) 1.8 KVA, 1400 W Input: 120 V., 60 Hz., standard connection Output: 120 VAC, standard connection Includes standard batteries Extended run time 86 minutes at full load Detronics "Point Watch" hydrocarbon detector: Infrared detector PIR9400A3LA0 Transmitter U9500H 006265-003 Junction box 006264-013 Sieger-Zellweger Analytics Digi-Cat combustible gas transmitter with model 705 electrocatalytic combustible gas sensor: NEC Class I Division 1 Group D Part no. 00705-A-1733 sensor

Part no. 2414-0017 transmitter Part no. 2410-0001 relay assembly Part no. 00780-A-2076 housing Calibration kit (2.5% methane in air)

Mid America Air-gas combustible gas sensor NEC Class I Division 1 Group D P/N X02AI97CP101535 P/N AIZP10 bottle P/N A-14128CH enclosure


5

COMPOSITE SAMPLER

Welker Engineering Model GSS-4HCANR Heated bypass gas sampler Vanishing Chamber pump, inline relief, filter regulator, gauge 6 or 12 VDC solenoid operated, explosion-proof Therm Pak stainless steel insulated heated enclosure Catalytic heater, filter, regulator, thermostat, 12 VDC, valves, tubing, and fittings NEC Class I Division 1 Group D 2” pipe mount YZ Systems Model DP-2010UP DynaPak heated off-line sampler DP-2000 pump Z-65/6.1 timer/controller Filter/regulator, solenoid operated, and enclosure Catalytic heater, 12 VDC, adjustable thermostat, fuel gas filter and regulator Valves, tubing, and fittings NEC Class I Division 1 Group D 2” pipe mount PGI International Model PF3GD-M1 Interceptor NEMA 3R fiberglass enclosure G4000 Electronic Controller, with time-based sampling, ESD function Direct mount configuration Probe: 316 SS, ½” NPT stabilized connection Adjustable sample size to .5 cc

PGI International Model HE-3-P3E-A-L06-N3-S Heated Enclosure System Sample bottles up to 300 cc PF3GD pump style (installed) ¾” MNPT probe, 6” insertion length 316SS tubing and fittings Catalytic Heater, 12 VDC, 140º F controlled thermostat with 200º F overheat protection Sample probe and cylinder heated to between 100 deg F and 140 deg F Filter canister with moisture and H2S scrubber element NEC Class I Division I Group D


6

ANCILLARY EQUIPMENT for SAMPLERS and ANALYZERS

Welker Engineering Model LE-2SSK0B0x0AB Integrated pitot sample probe Liquid Eliminator membrane Isolation valves ¼” FNPT outlet (LE201), ¾” MNPT process connection (LE211) Insulating blanket Insertion length (x): 2 for 2”, 3, 4” meter tubes 3 for 6” meter tubes 4 for 8” meter tubes 5 for 10” meter tubes 6 for 12” meter tubes Welker Engineering Model ALS Analyzer Liquid Shut-Off, 316SS, 1/8" NPT connections, 1000 psi max. A+ Genie Model GP2-206-SS (-T) (-B) Membrane probe 1/8” FNPT outlet, with housing, viton, BTU membrane, ¾” process connection 4” probe / housing length for 4” thru 8” meter tubes T = short probe / housing length for 2” and 3” meter tubes B = 7” probe / housing length for 10” and 12” meter tubes A+ Genie Supreme Model 123HP-006-SS-LB Membrane separator with liquid block 1/4” FNPT inlet, outlet, and bypass ports 316SS, 2000 psig Bruest Model RPH-11013D-12V Catalytic heater, dual coil, 12 VDC start-up NEC Class I, Division 1, Group D, explosion-proof junction box Fisher 1301F high-pressure regulator, 20 psig setpoint Fisher 912 low-pressure regulator Fisher Type 67C pressure regulator, internal relief, 10 psig setpoint Maxitrol RV20L regulator Relief valve, gauges, ¼” tubing, rain shield flap, and mounting hardware Measurement Technology Limited MTL 7765ac or 7796+ intrinsic safety barrier MTL DX070 enclosure Welker Engineering Model SP-2 Standard sample probe 316SS, 3/4" NPT connection, 1/4" NPT outlet valve Insertion length x" to be approximately one half the nominal diameter of the pipe YZ Systems C5-0111 Single flow sample probe 316SS, 3/4" NPT connection, 1/4" NPT outlet valve Insertion length x" to be approximately one half the nominal diameter of the pipe


7

ANCILLARY EQUIPMENT for SAMPLERS and ANALYZERS Continued . . . Welker Engineering Model PP-2 Pitot sample probe 316SS, 3/4" NPT connection, 1/4" NPT outlet valve Insertion length x" to be approximately one half the nominal diameter of the pipe YZ Systems C5-0131 Dual flow sample probe 316SS, 3/4" NPT connection, 1/4" NPT outlet valve Insertion length x" to be approximately one half the nominal diameter of the pipe


8

MOISTURE ANALYZER

Spectra Sensor Model SS2000-311111 complete with Model SC402-11111 SS2000 Single channel laser analyzer 3 = Housing NEC Class I, Division 2, Group D NEMA 4X stainless steel enclosure 1 = Measured component H2O range 0.5 - 20 lbs/MMscf (10 - 420 ppmv) 1 = Background gas Natural gas 1 = Not used 1 = Not used 1 = Power supply 120 VAC SC402 Sample conditioning panel with valve, membrane separator, flow control valve, flowmeter (1 - 4 scfh), wall mount 1 = Panel type Analyzer mounted on panel 1 = Panel regulator 0-10 psig (max. inlet pressure 100 psig) 1 = Liquids trap with bypass Liquids trap with valve and bypass flowmeter (0.2 - 2.5 scfh) 1 = Sample port with valve ¼” swage port for grab sample or cal gas 1 = Mounting Sample conditioning on flat aluminum pane Options: P/N 01902-18100, alarm relays, SPDT, (1) status and (1) high concentration Outputs: 4-20 mADC and RS232 CR4-1212, chilled mirror system for calibration Consult Measurement Services for moisture standard Spectra Sensor Model SS3000-312211 complete with Model SC402-21111 SS3000 Dual channel laser analyzer 3 = Housing NEC Class I, Division 2, Group D NEMA 4X stainless steel enclosure 1 = Measured component H2O range 0.5 - 20 lbs/MMscf (10 - 420 ppmv) 2 = Background gas Natural gas 2 = Gas inlets Two gas inlets, separate gas streams for each flow cell 1 = Background gas Natural gas 1 = Power supply 120 VAC SC402 Sample conditioning panel with valve, membrane separator, flow control valve, flowmeter (1 - 4 scfh), wall mount 2 = Panel type Two process streams conditioned, two sets of components, analyzer mounted on panel 1 = Panel regulator 0-10 psig (max. inlet pressure 100 psig) 1 = Liquids traps with bypass Liquids traps with valves and bypass flowmeters (0.2 - 2.5 scfh) 1 = Sample ports with valves ¼” swage ports for grab sample or cal gas 1 = Mounting Sample conditioning on flat aluminum pane Options: P/N 01902-18100, alarm relays, SPDT, (1) status and (1) high concentration Outputs: 4-20 mADC and RS232 CR4-1212, chilled mirror system for calibration Consult Measurement Services for moisture standard


9

H2S and TOTAL SULFUR ANALYZER

Galvanic Applied Sciences Model 802D2-TSXP-SPXP-TSSS-BPTS Advanced lead acetate tape based single stream hydrogen sulfide and total sulfur analyzer Standard equipment and features:

0 – 10 ppm H2S 110 VAC power 4-20 mADC isolated output signals (2) USB or RS232 serial ports (2) and RS485 isolated serial port SPDT alarm relays (4) Solenoid drivers (4)

D2 NEC Class I, Division 2, Group D hazardous area classification Analyzer: TSXP Total sulfur option (110 VAC, NEC Class I, Division 2, Group D) complete with furnace,

temperature control, separately mounted display SPXP Low hydrogen pressure switch Sample System: TSSS Total sulfur single stream sample system complete with SS filter, H2 flow meter, high

pressure SS regulator, gauge, and sweep valve installed Mounting and Enclosure: BPTS TS analyzer mounted on a steel painted backpan 27” x 48” Del Mar Scientific Model 1000 or 1200 Lead acetate tape hydrogen sulfide analyzer Electronic control unit with keypad interface, LCD display and manual calibration 0 – 50 ppm Range Response time: < 1 minute Repeatability: ± 1% Analyzer calibration: 0-20 ppm Power input:

Model 1000 - 24 VDC, 100 mA maximum Model 1200 - 120 VAC

Diagnostic alarm: dry contact, max. load 30 mA @ 24 VDC 4-20 mADC output signal for Model 1200 General purpose or NEC Class I, Division 2, Group D hazardous area classification


10

O2 (OXYGEN) ANALYZER

Teledyne Model 3300 TA Oxygen analyzer ranges: 0-10, 0-100 and 0-1000 ppm oxygen Two discrete alarms, fully adjustable, SPDT, non-latching, 3 amps Operating temperature range: 32º F to 122º F Output: 4 -20 mADC isolated Power: < 100 Watts @ 115 VAC Enclosure: rack mount Sample pressure: 40 psig normal / 100 psig max. Sample temperature: 120º F max. Carbon dioxide content: 0 – 2% max. Complete with B-2 Micro Fuel Cell Teledyne Insta Trans This unit should be utilized for monitoring purposes of trace amounts of oxygen (less than 50 ppm). Element Type: Teledyne Micro-Fuel Cell Signal Output: 4-20 mADC Power Requirements: 20-35 VDC Classification: NEC Class I, Div 1, Group D

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EL PASO PIPELINE GROUP

NAME

CITY, COUNTY, STATE

FILTER SEPARATOR SPECIFICATIONS MEASUREMENT FACILITIES

by ENGINEERING

FACILITY

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Date

Prepared By: Design Engineer Reviewed By: Project Engineer

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TABLE OF CONTENTS

1.0 GENERAL SCOPE 2.0 EQUIPMENT and SERVICES by VENDOR 3.0 EQUIPMENT and SERVICES by COMPANY 4.0 CODES, STANDARDS, and SPECIFICATIONS 5.0 DESIGN CRITERIA 6.0 DOCUMENTATION and DRAWINGS 7.0 INSPECTIONS and TESTING 8.0 SHIPPING and HANDLING 9.0 WARRANTY 10.0 ATTACHMENTS

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1.0 GENERAL SCOPE This specification describes the RFQ requirements for one (1) two-stage horizontal filter separator for

installation at location. Any exceptions and/or deviations from the requirements in this specification must be explicitly noted

in Vendor's equipment proposal. The following are the target date requirements: Quotations Due: Date PO Awarded: Date Issue Approval Drawings: Date Ship Filter Separator: Date The following are the abbreviations used in this document: (R) Required - No substitutions acceptable (P) Preferred - Substitutions must be clearly shown on proposal (V) Information to be supplied by Vendor with proposal 2.0 EQUIPMENT and SERVICES by VENDOR Design, fabrication, and assembly of one (1) filter separator as described herein. 3.0 EQUIPMENT and SERVICES by COMPANY El Paso (Company) will supply 30 psig instrument supply gas which will be clean and dry. Company

will provide concrete foundation upon which filter separator will be installed. Up to the filter separator’s gas inlet, gas outlet, liquid dump outlet, and supply gas inlet, Company will provide gas and liquid piping and valving.

4.0 CODES, STANDARDS, and SPECIFICATIONS ASME Boiler and Pressure Vessel Code, Section VIII ASME B31.8 - Gas Transmission and Distribution Piping System ASME/ANSI B16.5 - Pipe Flanges and Flanged Fittings ASME/ANSI B16.10 - Face-to-Face and End-to-End Dimensions of Valve MSS SP-44 - Steel Pipe Line Flanges MSS SP-75 - Large Steel Fittings ASTM A-193 Class 2A Grade B7 (for bolts) ASTM A-194 Class 2B Grade 2H (for nuts) Electrical Classification: NEC Class I, Division 1, Group D Coating Specification: SC-204 (for nuts and bolts) Paint Specification: AC-135 and Approved Coating Systems Welding Specification: EP WeldedFab All other applicable EP specifications 5.0 DESIGN CRITERIA 5.1 Site Conditions:

Elevation: feet Ambient Temperature Range: ºF Maximum Wind Speed: mph

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5.2 Service Conditions: Type of Gas: Natural Gas Specific Gravity: 0.600 5.3 Operating Conditions:

Condition Description

Flow Rate (MMscfd)

Pressure

(psig)

Temperature

(ºF)

Flange-to-FlangeCalculated ΔP (psid)

Minimum 40 (V)Maximum 100 (V)

5.4 Liquids: Type: Pipeline condensate Slug Flow: None expected 5.5 Performance: Maximum Allowable Pressure Drop: 2.0 psid (flange-to-flange ΔP based on design conditions) Guaranteed Unit Efficiency: 99.5% (percentage of all liquid and solids 1.0 micron and larger removed) 5.6 Vessel Design Data: Vessel Orientation: Horizontal Flanges: ANSI 600 RFWN Minimum Design Pressure: ` psig Design Temperature Range: ºF Design Factor: Hydrostatic Test Pressure Range: psig Vessel Corrosion Allowance: 0.125” Vessel Total Weight: (V)

5.6.1 The vessel shall be designed, built, and stamped in accordance with ASME Boiler

and Pressure Vessel Code, Section VIII, Division 1 (latest revision) and in accordance with Specification EP WeldedFab and all other applicable EP specifications.

5.6.2 All butt welds shall be 100% radiographed. Design joint efficiency shall be 100%. 5.6.3 The vessel shall be hydrostatically tested to a minimum of 1.5 times design pressure

for eight (8) hours with water temperature and pressure chart recorded. 5.6.4 Vessel Upper Barrel:

Gas inlet into upper barrel shall have a diverter plate to protect filter elements from

the fluid stream. Vessel shall include one (1) full opening closure for the upper barrel. Closures are to

be Peco, Modco, or Huber-Yale. The use of equivalent manufactured type requires approval by Company. All closures shall be quick-opening type with safety valves and davit assembly and manufactured in accordance with the codes and standards identified within this specification.

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If necessary, vessel upper barrel shall be equipped with lugs for a Company supplied ladder and platform.

5.6.5 Vessel Lower Barrel (Sump): If there is no liquids storage tank, the vessel lower barrel (sump) shall be

oversized to the next nominal larger pipe diameter size. Vendor shall include two (2) blind flanges for lower barrel clean-out. Liquid dumps connections on the lower barrel shall have vortex breakers to allow for

smooth liquid dumping. 5.6.6 Vessel shall be supplied with lifting lugs. 5.6.7 Vessel shall be supplied with a complete set of filter elements with necessary

hardware for complete mounting. An additional set of filter elements and two (2) closure o-rings shall be supplied as spare parts.

5.7 Filter Design Data: Total Number of Filter Elements: (V) Filter Element O.D. (inches): (V) Filter Element Length (inches): (V) Filter Mounting: (V) Total Filter Surface Area per MMscfd: 0.9 min. or (V) 5.8 Separator Design Data: Mist extractor shall be serpentine vane type or (V) Mist extractor material 316 SS: (R) 5.9 Vessel Upper Barrel Connections: Description Qty. Type Size Gas Inlet * 1 ea. ANSI 600 RFWN (V) Gas Outlet 1 ea. ANSI 600 RFWN (V) Filter Service 1 ea. Full Opening Closure (V) Vent / Blowdown 1 ea. 3000# Threadolet 1 in. Relief Valve 1 ea. 3000# Threadolet 1 in. Pressure Gauge 1 ea. 3000# Threadolet 1 in. ΔP Gauge with Alarm 2 ea. 3000# Threadolet 1 in. Thermometer 1 ea. 3000# Threadolet 1 in. Drain 1 ea. 3000# Threadolet 1 in. * Gas inlet shall be located on right (left) (top) side of vessel when facing downstream. 5.10 Vessel Lower Barrel Connections Description Qty Type Size Liquid Level Controller (1) 1 ea. 3000# Threadolet 1 in. Liquid Level Controller (2) 1 ea. 3000# Threadolet 1 in. Liquid Level Alarm (1) 2 ea. 3000# Threadolet 1 in. Liquid Level Alarm (2) 2 ea. 3000# Threadolet 1 in. Liquid Dump (1) 1 ea. 3000# Threadolet 2 in. Liquid Dump (2) 1 ea. 3000# Threadolet 2 in. Sight Glass (1) 2 ea. 3000# Threadolet 1 in.

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Sight Glass (2) 2 ea. 3000# Threadolet 1 in. Drain (1) 1 ea. 3000# Threadolet 1 in. Drain (2) 1 ea. 3000# Threadolet 1 in. Service / Clean-out 2 ea. ANSI 600 RF Blind (V) 1 = first stage sump 2 = second stage sump

5.11 Filter Separator Accessories: Liquid Level Controllers: Vendor shall supply two (2) liquid level controllers with external float

level displacers. Each level controller shall be piped with individual supply gas regulators and isolation valves. This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model.

Liquid Level Alarms: Vendor shall supply two (2) high liquid level alarms with external float

level displacers and with at least one (1) SPDT switch (dry electrical contacts). This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model. Magnetrol D75-1B20-BOK (P)

. Differential Pressure Gauge and Alarm: Vendor shall supply one (1) 0 to 10 psid differential

pressure gauge (316 SS housing, 316 SS internals, 4 1/2" dial) with at least one (1) adjustable SPDT switch (dry electrical contacts), 5-valve instrument manifold, and isolation valves at the vessel’s taps. This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model. Mid-West Instrument 120-SC-00-WJ-A for the gauge and AGCO M6AVDS-4 or PGI M3-573SLT for the manifold. (P)

Pressure Gauge: Vendor shall supply one (1) 0 to 1000 psig pressure gauge (316 SS

housing, 316 SS internals, 4 1/2" dial, and liquid filled) and isolation valve. This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model.

Thermometer: Vendor shall supply one (1) 0 to 200 ºF temperature gauge with bulb (316 SS

housing, 316 SS internals, and 3" dial). This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model.

Sight Glasses: Vendor shall supply two (2) armored sight glasses with valves. Gauge length

to be sized for no liquid level blind areas. This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model.

Thermal Relief Valve: Vendor shall supply one (1) direct spring-operated safety relief valve,

properly sized and configured for inlet, outlet, and orifice for thermal relief of vessel. Rupture disk with holder and two (2) spare disks may be substituted, if applicable. Isolation valve shall be installed immediately upstream of thermal relief device. Vendor to specify manufacturer type in proposal.

Valves: Vendor shall supply vent, blowdown, and drain valves properly sized and configured

accordingly. Quadrant Series S3-SS (R) for direct connections to vessel only. Instrumentation valves, piping, tubing, and fittings: Vendor shall supply such to properly

install and connect all accessories. All instrumentation valves 1” and smaller, tubing, and tubing fittings shall be 316 SS.

5.12 Paint and Coatings

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All Vendor supplied equipment and piping shall be painted in accordance with Paint Specification AC-135. All Vendor supplied nuts and bolts shall be coated in accordance with Coating Specification SC-204.

6.0 DOCUMENTATION and DRAWINGS Vendor shall provide the following documentation and drawings: Equipment Proposal - two (2) sets, outline drawings showing overall dimensions. Approval Drawings - three (3) sets, for approval ARO. Certified Drawings - three (3) sets, upon completion of fabrication. Operation and maintenance manuals - three (3) sets with shipment. Vendor shall provide all performed code inspection, hydrostatic test, x-ray, and NDT reports required

per this specification and codes and standards. Chart recorder and dead weight tester calibration certifications required for hydrostatic testing.

7.0 INSPECTIONS and TESTING Materials and fabrication shall be subject to Company's inspection. Company's representative shall

have access to vendor's facilities to inspect material and fabrication. The approval or waiver of inspection by Company shall not release the vendor of responsibility to

meet the requirements of this specification and referenced codes and standards. 8.0 SHIPPING and HANDLING Vendor shall ship the product to location. 9.0 WARRANTY The Vendor guarantees all equipment to be designed, constructed, and tested in accordance with the

requirements of this specification. Further, the Vendor guarantees the equipment to satisfactorily perform in accordance with this specification and to be free from defective materials and workmanship for a period of one (1) year after it is placed in normal operation or not more than eighteen (18) months after shipment. Defective material shall be replaced promptly and/or unsatisfactory workmanship or performance shall be corrected to the satisfaction of the Purchaser at the Vendor's expense.

10.0 ATTACHMENTS

None

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NAME

CITY, COUNTY, STATE

LIQUIDS STORAGE TANK (45 BBL.) SPECIFICATIONS MEASUREMENT FACILITIES

by ENGINEERING

FACILITY

PROJECT ID

Date Prepared By: Design Engineer Reviewed By: Project Engineer

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TABLE OF CONTENTS


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1.0 GENERAL SCOPE This specification describes the RFQ requirements for one (1) 45 barrel, welded, carbon steel, double

wall, liquids storage tank for installation at location. Any exceptions and/or deviations from the requirements in this specification must be explicitly noted

in Vendor's equipment proposal. The following are the equipment target date requirements: Quotations Due: Date PO Awarded: Date Issue Approval Drawings: Date Ship Tank: Date The following are the abbreviations used in this document: (R) Required - No substitutions acceptable (P) Preferred - Substitutions must be clearly shown on proposal (V) Information to be supplied by Vendor with proposal 2.0 EQUIPMENT and SERVICES by VENDOR Design, fabrication, and assembly of one (1) liquids storage tank as described herein. 3.0 EQUIPMENT and SERVICES by COMPANY El Paso (Company) will provide concrete foundation upon which liquids storage tank will be installed.

Up to the tank’s inlet and outlet, Company will provide piping and valving. 4.0 CODES, STANDARDS, and SPECIFICATIONS API 650 Appendix J – Welded Steel Tanks for Oil Storage API 5L Grade B (for pipe) ASME B31.8 - Gas Transmission and Distribution Piping System ASME/ANSI B16.5 - Pipe Flanges and Flanged Fittings ASME/ANSI B16.10 - Face-to-Face and End-to-End Dimensions of Valve ASME/ANSI B16.11 (for couplings) MSS SP-44 - Steel Pipe Line Flanges MSS SP-75 - Large Steel Fittings ASTM A-36 (for carbon steel plates) ASTM A-193 Class 2A Grade B7 (for bolts) ASTM A-194 Class 2B Grade 2H (for nuts) Electrical Classification: NEC Class I, Division 1, Group D Coating Specification: SC-204 (for nuts and bolts) Paint Specification: AC-135 and Approved Coating Systems All other applicable EP specifications AISC (American Institute of Steel Construction) AWS (American Welding Society) UL (Underwriter Laboratories) STI-F921 (Steel Tank Institute) API RP 651, Cathodic Protection of Aboveground Petroleum Storage Tanks API Standard 2000, Venting Atmospheric and Low-Pressure Storage Tanks

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5.0 DESIGN CRITERIA 5.1 Site Conditions: Elevation: feet Ambient Temperature Range: ºF Maximum Wind Speed: mph 5.2 Service Conditions: Type of Hydrocarbon Liquid: Natural gas pipeline condensate Liquid Specific Gravity: 0.68 Design Vessel Specific Gravity: 1.00 Gas Temperature Range: 40 to 100 ºF Design Gas Temperature: 60 ºF 5.3 Tank Design Data: Capacity: 45 barrels, nominal Flanges: ANSI 150 RFWN Minimum Design Pressure: 1 psig Design Temperature Range: -20 to 200 ºF Interior and Exterior Cone Bottom: 1/4” A-36 Interior and Exterior Shell: 1/4” A-36 Deck: 1/4” A-36 Corrosion Allowance: (V) Diameter and Height Dimensions: (V) Total Weight: (V)

5.3.1 The tank shall be designed and constructed in accordance with API 650 Appendix J. 5.3.2 The tank shall be supported by legs, minimum 3 ft. high, with square base plates. 5.3.3 The tank shall be equipped with an exterior caged ladder, 360 degree curved

handrails, 4” toe board, lifting lugs, and anchor bolts. 5.3.4 The tank shall be equipped with a 24” API roof man-way with an interior side ladder. 5.3.5 For cathodic protection, the tank with internal coating shall be equipped with four (4)

LL-48 zinc anodes with mounting hardware.

5.4 Tank Connections: Description Qty. Type Size Inlet (roof) 1 ea. ANSI 150 RFWN 4 in. Outlet (primary tank) 1 ea. ANSI 150 RFWN 4 in. Outlet (secondary tank) 1 ea. ANSI 150 RFWN 2 in. Overflow 1 ea. ANSI 150 RFWN 4 in. Leak Detection 1 ea. ANSI 150 RFWN 1 1/2 in. Test Connection 1 ea. 3000 # Threadolet 1 1/2 in. Pressure/Vacuum Relief 1 ea. ANSI 150 RFWN 4 in. Vent 1 ea. ANSI 150 RFWN 10 in. High Level Alarm 1 ea. ANSI 150 RFWN 3 in.

5.4.1 The roof inlet shall include a 4” Schedule 40 downcomer fill pipe.

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5.4.2 The primary tank outlet shall include one (1) 4” ANSI 150 RF gate valve, blind flange, gaskets, stud bolts, and nuts.

5.4.3 The secondary tank outlet, overflow, and leak detection connections shall include

blind flange, gasket, stud bolts, and nuts. 5.4.4 The test connection shall include 1 1/2” XH bull plug.

5.5 Tank Accessories: Pressure Gauge: Vendor shall supply one (1) 0 to 2 psig pressure gauge (316 SS housing, 316 SS internals, 4 1/2" dial, and liquid filled) and isolation valve. This accessory shall include all necessary hardware for installation. Vendor to specify manufacturer and model. Pressure/Vacuum Vent: Vendor shall supply one (1) 4” Varec Fig. 2010 pressure/vacuum vent. This accessory shall include all necessary hardware for installation. (P) Thief Hatch: Vendor shall supply one (1) 8” Sentinel S-10 thief hatch set at 16 oz. pressure and 0.4 oz. vacuum. This accessory shall include all necessary hardware for installation. (P) Flame Arrestor and Mushroom Free Vent: Vendor shall supply one (1) 10” Groth 7618-10-11-W00 flame arrestor and mushroom free vent. This accessory shall include all necessary hardware for installation. (P) Liquid Level Gauge: Vendor shall supply one (1) Varec Fig. 2500 automatic liquid level gauge with liquid seal. This accessory shall include all necessary hardware for installation. (P) Liquid Leak Sump Assembly: (Secondary tank outlet liquid drain) Vendor shall supply one (1) 2” ANSI 150 RFFE gate valve with 2” ANSI 150 RFFE Ernst cylinder glass, blind flange, gaskets, stud bolts, and nuts. This accessory shall include all necessary hardware for installation. (P) High Level Alarm: Vendor shall supply one (1) 3” ANSI 150 RFFE Magnetrol Model A15-2G3B-ANY high level alarm, SPST dry contact. The high level alarm shall be set at 50% of tank capacity. This accessory shall include all necessary hardware for installation. (P)



6.0 DOCUMENTATION and DRAWINGS Vendor shall provide the following documentation and drawings: Equipment Proposal - two (2) sets, outline drawings showing overall dimensions. Approval Drawings - three (3) sets, for approval ARO. Certified Drawings - three (3) sets, upon completion of fabrication. Operation and maintenance manuals - three (3) sets with shipment.

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Vendor shall provide all performed code inspection, hydrostatic test, x-ray, and NDT reports required per this specification and codes and standards. Chart recorder and dead weight tester calibration certifications required for hydrostatic testing.


have access to vendor's facilities to inspect material and fabrication. The approval or waiver of inspection by the Company shall not release the vendor of responsibility to



10.0 ATTACHMENTS

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NAME

CITY, COUNTY, STATE

LIQUIDS STORAGE TANK (200 GAL.) SPECIFICATIONS MEASUREMENT FACILITIES

by ENGINEERING

FACILITY

PROJECT ID

Date Prepared By: Design Engineer Reviewed By: Project Engineer

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TABLE OF CONTENTS


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1.0 GENERAL SCOPE This specification describes the RFQ requirements for one (1) 200 gallon, welded, carbon steel,

double wall, liquids storage tank for installation at location. Any exceptions and/or deviations from the requirements in this specification must be explicitly noted

in Vendor's equipment proposal. The following are the equipment target date requirements: Quotations Due: Date PO Awarded: Date Issue Approval Drawings: Date Ship Tank: Date The following are the abbreviations used in this document: (R) Required - No substitutions acceptable (P) Preferred - Substitutions must be clearly shown on proposal (V) Information to be supplied by Vendor with proposal 2.0 EQUIPMENT and SERVICES by VENDOR Design, fabrication, and assembly of one (1) liquids storage tank as described herein. 3.0 EQUIPMENT and SERVICES by COMPANY El Paso (Company) will provide concrete foundation upon which liquids storage tank will be installed.

Up to the tank’s inlet and outlet, Company will provide piping and valving. 4.0 CODES, STANDARDS, and SPECIFICATIONS API 650 Appendix J – Welded Steel Tanks for Oil Storage API 5L Grade B (for pipe) ASME B31.8 - Gas Transmission and Distribution Piping System ASME/ANSI B16.5 - Pipe Flanges and Flanged Fittings ASME/ANSI B16.10 - Face-to-Face and End-to-End Dimensions of Valve ASME/ANSI B16.11 (for couplings) MSS SP-44 - Steel Pipe Line Flanges MSS SP-75 - Large Steel Fittings ASTM A-36 (for carbon steel plates) ASTM A-193 Class 2A Grade B7 (for bolts) ASTM A-194 Class 2B Grade 2H (for nuts) Electrical Classification: NEC Class I, Division 1, Group D Coating Specification: SC-204 (for nuts and bolts) Paint Specification: AC-135 and Approved Coating Systems All other applicable EP specifications AISC (American Institute of Steel Construction) AWS (American Welding Society) UL (Underwriter Laboratories) STI-F921 (Steel Tank Institute) API RP 651, Cathodic Protection of Aboveground Petroleum Storage Tanks API Standard 2000, Venting Atmospheric and Low-Pressure Storage Tanks

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5.0 DESIGN CRITERIA 5.1 Site Conditions: Elevation: feet Ambient Temperature Range: ºF Maximum Wind Speed: mph 5.2 Service Conditions: Type of Hydrocarbon Liquid: Natural gas pipeline condensate Liquid Specific Gravity: 0.68 Design Vessel Specific Gravity: 1.00 Gas Temperature Range: 40 to 100 ºF Design Gas Temperature: 60 ºF 5.3 Tank Design Data: Capacity: 200 gallons, nominal Minimum Design Pressure: 1 psig or atmosphere (V) Design Temperature Range: -20 to 200 ºF or ambient (V) Ends, Shell, Supports: 1/4” SA-36 Internals: SA-36 Nozzles: SA-105 Corrosion Allowance: (V) Diameter and Height Dimensions: (V) Total Weight: (V)

5.3.1 The tank shall be designed and constructed in accordance with API 650 Appendix J. 5.3.2 Design joint efficiency shall be 70% for the shell and heads. The tank shall be air

pressure test to 1.5 psig. 5.3.3 The tank shall be supported by legs with square base plates and anchor bolts. The

tank shall be equipped with lifting lugs. 5.4 Tank Connections: Description Qty. Type Size Inlet 1 ea. 3000# coupling 2 in. Vent, inner tank 1 ea. 3000# coupling 1 in. Vent, outer tank 1 ea. 3000# coupling 2 in. Drain, inner tank 1 ea. 3000# coupling 2 in. Drain, outer tank 1 ea. 3000# coupling 2 in. Flame arrestor 1 ea. NPT threaded 3 in. Sight glass 2 ea. 3000 # coupling 1 in. High Level Alarm 1 ea. 3000# coupling 2 in.

5.5 Tank Accessories:

Pressure/Vacuum Vent: Vendor shall supply one (1) pressure/vacuum vent and include all necessary hardware for installation. Varec Fig. 2010 or equal (P) Flame Arrestor: Vendor shall supply one (1) flame arrestor and include all necessary hardware for installation. Groth 7618 or equal (P) Liquid Level Gauge: Vendor shall supply one (1) liquid level gauge (sight glass) with liquid seal and include all necessary hardware for installation. Varec Fig. 2500 or equal (P)

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Date

5

High Level Alarm: Vendor shall supply one (1) high level alarm with at least one (1) SPST dry contact and include all necessary hardware for installation. The high level alarm shall be set at 50% of tank capacity. Magnetrol Model A15 or equal (P)



6.0 DOCUMENTATION and DRAWINGS Vendor shall provide the following documentation and drawings: Equipment Proposal - two (2) sets, outline drawings showing overall dimensions. Approval Drawings - three (3) sets, for approval ARO. Certified Drawings - three (3) sets, upon completion of fabrication. Operation and maintenance manuals - three (3) sets with shipment. Vendor shall provide all performed code inspection, pressure test, x-ray, and NDT reports required

per this specification and codes and standards. Chart recorder and dead weight tester calibration certifications required for pressure testing.


have access to vendor's facilities to inspect material and fabrication. The approval or waiver of inspection by the Company shall not release the vendor of responsibility to



10.0 ATTACHMENTS

None


1

METAL BUILDING

Parkline Building Systems Steelox Systems Specification 13122/PAR Type TL-1 Type AL2C Gable Building specifications, design data, and drawings shall conform to that noted above or equivalent for metal buildings. They shall be applied as indicated these specifications. The buildings covered by these specifications shall be of self-framing design utilizing the roof and wall panels as the primary structural supporting members. Each building, shipped knocked down or completely assembled as required, shall be supplied with all necessary component parts, including foundation anchors, to form a complete building system. All parts shall be new and free from any defects or imperfections. The building width and length shall be measured from the outside of the building wall panels and the height (8 ft.) of the building shall be the distance measured from the bottom surface of the base channel to the exterior juncture of the roof and sidewall panels. The building supplier shall furnish a complete set of building erection drawings illustrating the step by step sequence for the erection of the building. The erection drawings shall be prepared specifically for the building covered by these specifications showing the exact location of all roof and wall accessories and the exact anchor bolt locations required for each accessory. All buildings shall be designed in accordance with the applicable sections of the latest edition of the AISC "Specifications for Structural Steel Buildings" and the AISI "Specifications for the Design of Cold Formed Steel Structural Members." They shall be water resistant and fire resistant. Each building shall be designed for the following loads, in addition to the stationary weight (dead load) of the building. Reduction of loads due to tributary loaded areas will not be permitted.

1. The vertical live load of the building shall be not less than 20 psf applied on the horizontal projection of the roof.

2. Unless otherwise specified, the horizontal wind load of the building shall be not less than 100 mph and shall be distributed and applied in accordance with the applicable edition of the Metal Building Manufacturers Association (MBMA) publication titled "Low Rise Building Systems Manual." For “as-needed” Gulf Coast applications, the horizontal wind loading may be 150 mph. For special building applications, additional requirements may be specified.

This type of building may be located in a general purpose (non-hazardous) area or a hazardous area location classification (NEC Class I, Division 1 or 2, Group D) per NEC Article 500 and AGA #XF0277. If located in a hazardous area, ventilation requirements must meet American Gas Association (AGA) Operating Section #XF0277 publication titled "Classification of Gas Utility Areas for Electrical Installations." This type of building is intended to house primary measurement devices and/or secondary measurement devices. This type of building may also be used to house flow/pressure control, overpressure protection, and/or gas quality equipment and their associated instrumentation.


2

On a project specific basis and as applicable, the following details shall be supplied by the design engineer and/or building manufacturer: 1. Roof panel design 2. Wall panel design 3. Panel coatings and color 4. Structural framing 5. Doors (solid, window, etc.) size and location 6. Hardware (lockset, panic bar, etc.) 7. Framed wall openings for piping, size and location 8. Windows (fixed, glazing, etc.) size and location 9. Louvers (gable and/or wall) size and location 10. Ridge vent requirements 11. Insulation requirements 12. Partition(s) location 13. Electrical requirements (lighting and power distribution) 14. HVAC requirements 15. Foundation (concrete or skid mount)

METER CAPACITY TABLES

i

TABLE of CONTENTS

Ultrasonic Meters Tab Turbine Meters Tab Sensus T-10-HP and Auto-Adjust II Turbo-Meters Daniel Turbine Meters Orifice Meters Tab Rotary and Diaphragm Meters Tab Dresser Roots B3-HPC Rotary Meters Instromet IRM Rotary Meters Energy Economics HP3000 Diaphragm Meters

Multipath Ultrasonic Meters

P(atm.) = 14.4 psia SG = 0.600 Capacities = MscfdPb = 14.73 psia CO2 = N2 = 0 mole% Max. @ 70 fpsTb = Tf = 60 deg.F Fpv AGA-8 (gross) Min. @ 10 fps

Pressure(PSIG) Max. Min. Max. Min. Max. Min. Max. Min. Max. Min.

100 4,210 601 9,554 1,365 16,544 2,363 26,077 3,725 37,015 5,288125 5,151 736 11,689 1,670 20,241 2,892 31,904 4,558 45,287 6,470150 6,099 871 13,841 1,977 23,968 3,424 37,779 5,397 53,626 7,661175 7,055 1,008 16,011 2,287 27,726 3,961 43,702 6,243 62,034 8,862200 8,019 1,146 18,199 2,600 31,515 4,502 49,674 7,096 70,511 10,073225 8,991 1,284 20,405 2,915 35,334 5,048 55,695 7,956 79,058 11,294250 9,971 1,424 22,629 3,233 39,185 5,598 61,765 8,824 87,675 12,525275 10,960 1,566 24,872 3,553 43,068 6,153 67,886 9,698 96,362 13,766300 11,956 1,708 27,133 3,876 46,984 6,712 74,058 10,580 105,124 15,018325 12,960 1,851 29,413 4,202 50,932 7,276 80,280 11,469 113,955 16,279350 13,973 1,996 31,712 4,530 54,913 7,845 86,555 12,365 122,863 17,552375 14,995 2,142 34,030 4,861 58,927 8,418 92,882 13,269 131,844 18,835400 16,025 2,289 36,367 5,195 62,975 8,996 99,263 14,180 140,901 20,129425 17,064 2,438 38,724 5,532 67,056 9,579 105,696 15,099 150,033 21,433450 18,111 2,587 41,100 5,871 71,170 10,167 112,181 16,026 159,238 22,748475 19,167 2,738 43,497 6,214 75,320 10,760 118,722 16,960 168,524 24,075500 20,231 2,890 45,914 6,559 79,505 11,358 125,319 17,903 177,887 25,412525 21,305 3,044 48,350 6,907 83,723 11,960 131,968 18,853 187,325 26,761550 22,388 3,198 50,807 7,258 87,979 12,568 138,675 19,811 196,846 28,121575 23,479 3,354 53,284 7,612 92,268 13,181 145,436 20,777 206,443 29,492600 24,580 3,511 55,781 7,969 96,592 13,799 152,251 21,750 216,117 30,874625 25,689 3,670 58,300 8,329 100,953 14,422 159,126 22,732 225,876 32,268650 26,808 3,830 60,839 8,691 105,350 15,050 166,056 23,722 235,712 33,673675 27,936 3,991 63,399 9,057 109,783 15,683 173,044 24,721 245,631 35,090700 29,073 4,153 65,979 9,426 114,251 16,322 180,087 25,727 255,629 36,518725 30,220 4,317 68,581 9,797 118,757 16,965 187,189 26,741 265,710 37,959750 31,375 4,482 71,204 10,172 123,298 17,614 194,347 27,764 275,871 39,410775 32,540 4,649 73,847 10,550 127,875 18,268 201,561 28,794 286,111 40,873800 33,714 4,816 76,511 10,930 132,487 18,927 208,831 29,833 296,431 42,347825 34,897 4,985 79,196 11,314 137,138 19,591 216,162 30,880 306,836 43,834850 36,089 5,156 81,901 11,700 141,822 20,260 223,545 31,935 317,317 45,331875 37,291 5,327 84,629 12,090 146,545 20,935 230,989 32,998 327,884 46,841900 38,501 5,500 87,376 12,482 151,301 21,614 238,486 34,069 338,526 48,361925 39,721 5,674 90,143 12,878 156,094 22,299 246,041 35,149 349,248 49,893950 40,950 5,850 92,932 13,276 160,923 22,989 253,652 36,236 360,053 51,436975 42,187 6,027 95,740 13,677 165,785 23,684 261,316 37,331 370,932 52,990

1000 43,433 6,205 98,567 14,081 170,681 24,383 269,032 38,433 381,885 54,5551025 44,688 6,384 101,415 14,488 175,612 25,087 276,806 39,544 392,919 56,1311050 45,951 6,564 104,282 14,897 180,577 25,797 284,632 40,662 404,028 57,7181075 47,222 6,746 107,166 15,309 185,572 26,510 292,505 41,786 415,203 59,3151100 48,502 6,929 110,072 15,725 190,602 27,229 300,434 42,919 426,459 60,9231125 49,790 7,113 112,994 16,142 195,662 27,952 308,409 44,058 437,779 62,5401150 51,085 7,298 115,932 16,562 200,751 28,679 316,430 45,204 449,164 64,1661175 52,388 7,484 118,889 16,984 205,871 29,410 324,501 46,357 460,621 65,8031200 53,699 7,671 121,865 17,409 211,023 30,146 332,622 47,517 472,149 67,450

12" (11.938")4" (4.026") 6" (6.065") 8" (7.981") 10" (10.020")

Issued: 1998Revised: 2000, 2002, 2003, 2004, 2006, 2008

Sensus T-10-HP and Auto-Adjust II Turbo-Meters * Turbine Meters

P(atm.) = 14.4 psia SG = 0.600 Capacities = Mscfd Pb = 14.73 psia CO2 = N2 = 0 mole% Max. = 90% Q(max. published) Tb = Tf = 60 deg.F Fpv AGA-8 (gross) Min. = 10% Q(max. published)

Pressure (10,000 acfh) (18,000 acfh) (35,000 acfh)(PSIG) Max. Min. Max. Min. Max. Min.

100 1,709 190 3,067 341 5,954 662125 2,096 233 3,760 418 7,295 811150 2,477 275 4,456 495 8,648 961175 2,858 318 5,152 572 10,001 1,111200 3,239 360 5,848 650 11,354 1,262225 3,639 404 6,568 730 12,753 1,417250 4,040 449 7,288 810 14,153 1,573275 4,440 493 8,008 890 15,552 1,728300 4,841 538 8,728 970 16,952 1,884325 5,250 583 9,466 1,052 18,394 2,044350 5,660 629 10,204 1,134 19,836 2,204375 6,069 674 10,942 1,216 21,278 2,364400 6,479 720 11,680 1,298 22,721 2,524425 6,906 767 12,447 1,383 24,210 2,690450 7,334 815 13,214 1,468 25,700 2,855475 7,761 862 13,981 1,553 27,189 3,021500 8,189 910 14,749 1,639 28,679 3,186525 8,630 959 15,543 1,727 30,218 3,357550 9,071 1,008 16,337 1,815 31,757 3,528575 9,512 1,057 17,131 1,903 33,295 3,699600 9,953 1,106 17,926 1,992 34,834 3,870625 10,407 1,156 18,740 2,082 36,427 4,047650 10,862 1,207 19,555 2,173 38,020 4,224675 11,316 1,257 20,369 2,263 39,613 4,401700 11,771 1,308 21,184 2,354 41,206 4,578725 12,241 1,360 22,032 2,448 42,853 4,761750 12,711 1,412 22,880 2,542 44,500 4,944775 13,181 1,465 23,728 2,636 46,147 5,127800 13,652 1,517 24,577 2,731 47,794 5,310825 14,138 1,571 25,452 2,828 49,491 5,499850 14,624 1,625 26,327 2,925 51,187 5,687875 15,110 1,679 27,202 3,022 52,884 5,876900 15,596 1,733 28,078 3,120 54,580 6,064925 16,093 1,788 28,973 3,219 56,328 6,259950 16,590 1,843 29,869 3,319 58,077 6,453975 17,087 1,899 30,764 3,418 59,825 6,647

1000 17,585 1,954 31,660 3,518 61,573 6,8411025 18,098 2,011 32,584 3,620 63,366 7,0411050 18,611 2,068 33,509 3,723 65,160 7,2401075 19,124 2,125 34,434 3,826 66,953 7,4391100 19,637 2,182 35,358 3,929 68,746 7,6381125 20,165 2,241 36,303 4,034 70,589 7,8431150 20,694 2,299 37,248 4,139 72,432 8,0481175 21,223 2,358 38,193 4,244 74,274 8,2531200 21,752 2,417 39,138 4,349 76,117 8,457

1. Use the lowest expected pressure when determining the maximum capacity.2. Use the highest expected pressure when determining the minimum capacity.3. Some capacities are calculated using first-order linear interpolation.4. Consult Measurement Services regarding the 4" AAT-27 and 6" AAT-57.

2" T-10-HP 4" AAT-18 6" AAT-35

Issued: 1994Revised: 1996, 2000, 2002, 2003, 2004, 2008

Daniel Turbine Meters

P(atm.) = 14.4 psia SG = 0.600 Capacities = Mscfd Pb = 14.73 psia CO2 = N2 = 0 mole% Max. = 90% Q(max. published) Tb = Tf = 60 deg.F Fpv per AGA-8 (gross) Min. = 10% Q(max. published)

Daniel 3" Mini Daniel 4"Pressure (14,200 acfh) (18,000 acfh)(PSIG) Max. Min. Max. Min.

100 2,428 270 3,077 342125 2,969 330 3,763 418150 3,519 391 4,460 496175 4,069 452 5,158 573200 4,619 513 5,855 651225 5,185 576 6,572 730250 5,751 639 7,290 810275 6,317 702 8,007 890300 6,883 765 8,724 969325 7,468 830 9,466 1,052350 8,053 895 10,208 1,134375 8,638 960 10,950 1,217400 9,223 1,025 11,691 1,299425 9,828 1,092 12,458 1,384450 10,433 1,159 13,225 1,469475 11,038 1,226 13,992 1,555500 11,643 1,294 14,759 1,640525 12,268 1,363 15,552 1,728550 12,894 1,433 16,344 1,816575 13,519 1,502 17,137 1,904600 14,144 1,572 17,930 1,992625 14,791 1,643 18,749 2,083650 15,437 1,715 19,568 2,174675 16,083 1,787 20,387 2,265700 16,730 1,859 21,207 2,356725 17,397 1,933 22,053 2,450750 18,065 2,007 22,899 2,544775 18,732 2,081 23,745 2,638800 19,399 2,155 24,591 2,732825 20,088 2,232 25,463 2,829850 20,776 2,308 26,335 2,926875 21,464 2,385 27,208 3,023900 22,152 2,461 28,080 3,120925 22,861 2,540 28,979 3,220950 23,570 2,619 29,877 3,320975 24,279 2,698 30,776 3,420

1000 24,988 2,776 31,675 3,5191025 25,717 2,857 32,598 3,6221050 26,445 2,938 33,522 3,7251075 27,174 3,019 34,446 3,8271100 27,903 3,100 35,370 3,9301125 28,649 3,183 36,316 4,0351150 29,396 3,266 37,263 4,1401175 30,143 3,349 38,209 4,2451200 30,889 3,432 39,155 4,351

1. Use the lowest expected pressure when determining the maximum capacity.2. Use the highest expected pressure when determining the minimum capacity.3. Some capacities are calculated using first-order linear interpolation.

Issued: 1996 Revised: 2000, 2002, 2003, 2004, 2008

Orifice Meters

DP = In.WC SG = 0.600 Flange TapsP(atm.) = 14.4 psia CO2 = N2 = 0 mole% Static Pressure D/SPb = 14.73 psia Fpv per AGA-8 (gross) Single TubeTb = Tf = 60 deg.F Nominal Size

Capacities = Mscfd

Pressure(psig) 0.6 Beta 0.2 Beta 0.6 Beta 0.2 Beta

270" 225" 30" 25" 30" 25" 270" 225" 30" 25" 30" 25"100 1,766 1,608 582 532 59 54 3,962 3,608 1,307 1,193 133 121125 1,948 1,775 644 588 66 60 4,371 3,983 1,445 1,319 147 134150 2,116 1,929 700 639 71 65 4,748 4,328 1,572 1,435 160 146175 2,273 2,072 753 688 77 70 5,101 4,650 1,690 1,543 172 157200 2,421 2,208 803 733 82 75 5,433 4,954 1,801 1,644 183 167225 2,562 2,336 850 776 87 79 5,748 5,242 1,907 1,741 194 177250 2,696 2,459 895 817 91 83 6,049 5,517 2,008 1,833 204 186275 2,825 2,577 938 856 96 87 6,338 5,781 2,105 1,921 214 195300 2,949 2,690 979 894 100 91 6,617 6,036 2,198 2,007 224 204325 3,069 2,800 1,020 931 104 95 6,887 6,282 2,288 2,089 233 213350 3,186 2,906 1,059 967 108 98 7,148 6,521 2,376 2,169 242 221375 3,299 3,010 1,097 1,001 112 102 7,403 6,754 2,461 2,247 250 229400 3,410 3,111 1,134 1,035 116 105 7,651 6,980 2,544 2,322 259 236425 3,517 3,209 1,170 1,068 119 109 7,893 7,201 2,625 2,396 267 244450 3,623 3,306 1,205 1,100 123 112 8,129 7,417 2,704 2,469 275 251475 3,726 3,400 1,239 1,132 126 115 8,361 7,629 2,782 2,539 283 258500 3,827 3,492 1,273 1,163 130 118 8,588 7,836 2,858 2,609 291 265525 3,927 3,583 1,307 1,193 133 122 8,812 8,040 2,932 2,677 298 272550 4,025 3,673 1,339 1,223 136 125 9,031 8,241 3,006 2,744 306 279575 4,121 3,760 1,372 1,252 140 128 9,247 8,438 3,078 2,810 313 286600 4,216 3,847 1,403 1,281 143 130 9,460 8,632 3,149 2,875 320 292625 4,309 3,931 1,435 1,310 146 133 9,669 8,823 3,220 2,939 327 299650 4,401 4,016 1,465 1,338 149 136 9,876 9,012 3,289 3,003 334 305675 4,492 4,099 1,496 1,366 152 139 10,080 9,198 3,357 3,065 341 312700 4,582 4,181 1,526 1,393 155 142 10,281 9,383 3,425 3,127 348 318725 4,671 4,262 1,556 1,420 158 145 10,481 9,564 3,492 3,188 355 324750 4,758 4,343 1,585 1,447 161 147 10,678 9,744 3,558 3,248 362 330775 4,845 4,422 1,614 1,474 164 150 10,872 9,922 3,623 3,308 368 336800 4,931 4,500 1,643 1,500 167 153 11,065 10,098 3,688 3,367 375 342825 5,016 4,578 1,672 1,526 170 155 11,256 10,272 3,752 3,425 381 348850 5,101 4,655 1,700 1,552 173 158 11,445 10,445 3,815 3,483 388 354875 5,184 4,731 1,728 1,578 176 161 11,632 10,616 3,878 3,541 394 360900 5,267 4,807 1,756 1,603 179 163 11,818 10,785 3,940 3,598 400 365

2" Tube 3" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Orifice Meters


270" 225" 30" 25" 30" 25" 270" 225" 30" 25" 30" 25"925 5,349 4,881 1,783 1,628 181 166 12,002 10,953 4,002 3,654 407 371950 5,430 4,956 1,811 1,653 184 168 12,184 11,120 4,064 3,710 413 377975 5,511 5,029 1,838 1,678 187 171 12,365 11,285 4,124 3,766 419 382

1000 5,591 5,102 1,865 1,702 190 173 12,545 11,449 4,185 3,821 425 3881025 5,670 5,175 1,891 1,727 192 176 12,733 11,612 4,245 3,875 431 3941050 5,749 5,247 1,918 1,751 195 178 12,899 11,773 4,304 3,930 437 3991075 5,827 5,318 1,944 1,775 198 181 13,075 11,933 4,363 3,983 443 4041100 5,904 5,389 1,970 1,799 200 183 13,249 12,092 4,422 4,037 449 4101125 5,981 5,459 1,996 1,822 203 185 13,421 12,250 4,480 4,090 455 4151150 6,058 5,529 2,022 1,846 206 188 13,593 12,406 4,538 4,143 461 4201175 6,134 5,598 2,047 1,869 208 190 13,763 12,561 4,595 4,195 466 4261200 6,209 5,667 2,073 1,892 211 192 13,932 12,716 4,652 4,247 472 431

1. For general use only as tube sizes are nominal and plate sizes are such that the beta ratio is exact. Use "Flocon" for precise calculations2. Use the lowest expected pressure when determining the maximum capacity3. Use the highest expected pressure when determining the minimum capacity4. For a 300 In.WC differential pressure transmitter, 270 In.WC is 90% of range and 30 In.WC is 10% of range.5. For a 250 In.WC differential pressure transmitter, 225 In.WC is 90% of range and 25 In.WC is 10% of range.

2" Tube 3" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Orifice Meters


Capacities = Mscfd


270" 225" 30" 25" 30" 25" 270" 225" 30" 25" 30" 25"100 7,032 6,406 2,321 2,118 236 216 15,798 14,390 5,215 4,760 532 485125 7,759 7,071 2,566 2,342 261 238 17,431 15,884 5,765 5,263 588 537150 8,429 7,683 2,791 2,548 284 259 18,935 17,260 6,272 5,725 640 584175 9,054 8,255 3,001 2,740 306 279 20,340 18,544 6,744 6,157 688 628200 9,644 8,793 3,199 2,920 326 297 21,664 19,754 7,189 6,563 733 669225 10,204 9,305 3,387 3,092 345 315 22,922 20,903 7,611 6,948 776 708250 10,738 9,794 3,566 3,256 363 331 24,123 22,001 8,014 7,316 817 746275 11,252 10,263 3,738 3,413 381 347 25,277 23,055 8,401 7,669 857 782300 11,747 10,715 3,904 3,564 397 363 26,389 24,071 8,774 8,010 895 817325 12,225 11,152 4,064 3,711 414 378 27,464 25,053 9,134 8,339 931 850350 12,690 11,577 4,220 3,853 430 392 28,507 26,006 9,484 8,658 967 883375 13,141 11,989 4,371 3,991 445 406 29,522 26,933 9,824 8,968 1,002 914400 13,581 12,391 4,518 4,125 460 420 30,510 27,835 10,155 9,271 1,035 945425 14,011 12,783 4,662 4,257 475 433 31,475 28,717 10,479 9,566 1,068 975450 14,431 13,167 4,803 4,385 489 446 32,419 29,579 10,795 9,855 1,100 1,005475 14,842 13,543 4,941 4,511 503 459 33,343 30,423 11,105 10,138 1,132 1,033500 15,246 13,911 5,076 4,634 517 472 34,250 31,251 11,409 10,415 1,163 1,062525 15,642 14,273 5,209 4,755 530 484 35,140 32,064 11,707 10,688 1,193 1,089550 16,032 14,629 5,339 4,875 543 496 36,015 32,863 12,001 10,956 1,223 1,117575 16,415 14,979 5,468 4,992 556 508 36,876 33,649 12,289 11,219 1,252 1,143600 16,792 15,323 5,594 5,107 569 520 37,724 34,424 12,574 11,479 1,281 1,170625 17,165 15,663 5,719 5,221 582 531 38,560 35,187 12,854 11,735 1,310 1,196650 17,531 15,998 5,842 5,334 594 543 39,384 35,940 13,131 11,988 1,338 1,221675 17,894 16,329 5,964 5,445 607 554 40,198 36,683 13,404 12,237 1,366 1,247700 18,251 16,656 6,084 5,554 619 565 41,001 37,417 13,674 12,484 1,393 1,272725 18,605 16,979 6,202 5,663 637 576 41,796 38,142 13,941 12,727 1,420 1,296750 18,955 17,298 6,320 5,770 643 587 42,581 38,859 14,205 12,968 1,447 1,321775 19,300 17,613 6,436 5,876 655 598 43,358 39,568 14,466 13,206 1,473 1,345800 19,643 17,926 6,551 5,981 666 608 44,127 40,270 14,724 13,442 1,500 1,369825 19,981 18,235 6,665 6,085 678 619 44,888 40,965 14,980 13,676 1,526 1,393850 20,317 18,541 6,777 6,188 689 629 45,642 41,653 15,234 13,907 1,551 1,416875 20,649 18,845 6,889 6,290 700 639 46,388 42,335 15,485 14,137 1,577 1,439900 20,979 19,146 7,000 6,391 712 650 47,129 43,011 15,734 14,364 1,602 1,462

4" Tube 6" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Orifice Meters


270" 225" 30" 25" 30" 25" 270" 225" 30" 25" 30" 25"925 21,305 19,444 7,110 6,491 723 660 47,862 43,681 15,981 14,590 1,627 1,485950 21,629 19,740 7,219 6,590 734 670 48,590 44,345 16,226 14,813 1,652 1,508975 21,950 20,033 7,327 6,689 745 680 49,311 45,004 16,469 15,035 1,676 1,530

1000 22,269 20,324 7,434 6,787 755 690 50,027 45,658 16,710 15,255 1,701 1,5521025 22,585 20,613 7,541 6,884 766 699 50,737 46,306 16,949 15,474 1,725 1,5741050 22,899 20,899 7,646 6,981 777 709 51,442 46,949 17,187 15,690 1,749 1,5961075 23,210 21,183 7,751 7,076 787 719 52,141 47,588 17,423 15,906 1,773 1,6181100 23,519 21,465 7,855 7,172 798 728 52,835 48,221 17,657 16,119 1,796 1,6401125 23,826 21,745 7,959 7,266 808 738 53,524 48,850 17,889 16,332 1,820 1,6611150 24,130 22,023 8,061 7,360 819 747 54,208 49,475 18,120 16,542 1,843 1,6821175 24,432 22,299 8,163 7,453 829 757 54,886 50,094 18,349 16,752 1,866 1,7041200 24,732 22,573 8,264 7,545 839 766 55,560 50,710 18,577 16,959 1,889 1,724

1. For general use only as tube sizes are nominal and plate sizes are such that the beta ratio is exact. Use "Flocon" for precise calculations.2. Use the lowest expected pressure when determining the maximum capacity3. Use the highest expected pressure when determining the minimum capacity4. For a 300 In.WC differential pressure transmitter, 270 In.WC is 90% of range and 30 In.WC is 10% of range5. For a 250 In.WC differential pressure transmitter, 225 In.WC is 90% of range and 25 In.WC is 10% of range

4" Tube 6" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Orifice Meters


Capacities = Mscfd


270" 225" 30" 25" 30" 25" 270" 225" 30" 25" 30" 25"100 28,061 25,559 9,263 8,455 946 863 43,821 39,914 14,466 13,204 1,478 1,349125 30,962 28,213 10,242 9,349 1,046 954 48,351 44,059 15,995 14,600 1,634 1,491150 33,634 30,657 11,142 10,171 1,137 1,030 52,524 47,876 17,401 15,884 1,778 1,622175 36,129 32,938 11,981 10,937 1,223 1,116 56,421 51,438 18,711 17,081 1,911 1,745200 38,481 35,088 12,771 11,658 1,304 1,190 60,094 54,794 19,945 18,207 2,037 1,860225 40,715 37,129 13,521 12,343 1,380 1,260 63,582 57,983 21,117 19,277 2,157 1,969250 42,849 39,080 14,237 12,997 1,453 1,327 66,915 61,028 22,236 20,298 2,271 2,073275 44,898 40,952 14,924 13,624 1,523 1,391 70,115 63,952 23,309 21,279 2,381 2,173300 46,873 42,756 15,588 14,229 1,591 1,452 73,199 66,770 24,344 22,223 2,486 2,270325 48,783 44,501 16,227 14,814 1,656 1,512 76,182 69,495 25,345 23,137 2,588 2,363350 50,636 46,194 16,849 15,381 1,720 1,570 79,076 72,138 26,315 24,023 2,687 2,453375 52,438 47,839 17,453 15,933 1,781 1,626 81,890 74,708 27,259 24,884 2,784 2,541400 54,194 49,443 18,041 16,470 1,841 1,681 84,631 77,212 28,178 25,724 2,877 2,627425 55,908 51,009 18,616 16,995 1,900 1,734 87,308 79,657 29,076 26,543 2,969 2,710450 57,584 52,540 19,178 17,508 1,957 1,786 89,926 82,048 29,954 27,345 3,058 2,792475 59,226 54,039 19,729 18,011 2,013 1,838 92,490 84,390 30,814 28,130 3,146 2,872500 60,836 55,510 20,269 18,504 2,068 1,888 95,005 86,687 31,658 28,900 3,232 2,950525 62,418 56,954 20,799 18,988 2,122 1,937 97,474 88,942 32,486 29,657 3,316 3,027550 63,972 58,373 21,321 19,464 2,175 1,986 99,902 91,159 33,301 30,400 3,399 3,103575 65,501 59,770 21,834 19,933 2,227 2,033 102,290 93,340 34,102 31,132 3,481 3,178600 67,008 61,145 22,339 20,394 2,279 2,080 104,642 95,488 34,892 31,853 3,561 3,251625 68,492 62,501 22,838 20,849 2,329 2,126 106,961 97,605 35,670 32,564 3,640 3,323650 69,957 63,838 23,329 21,298 2,379 2,172 109,248 99,693 36,438 33,265 3,719 3,394675 71,402 65,158 23,815 21,741 2,429 2,217 111,505 101,754 37,196 33,957 3,796 3,465700 72,830 66,462 24,294 22,179 2,477 2,261 113,734 103,790 37,946 34,641 3,872 3,534725 74,240 67,750 24,768 22,612 2,526 2,305 115,937 105,802 38,686 35,317 3,947 3,603750 75,635 69,024 25,237 23,040 2,573 2,349 118,116 107,791 39,418 35,986 4,021 3,671775 77,015 70,284 25,701 23,463 2,620 2,392 120,271 109,758 40,143 36,647 4,095 3,738800 78,381 71,531 26,160 23,882 2,667 2,434 122,403 111,706 40,860 37,302 4,168 3,804825 79,733 72,765 26,615 24,298 2,713 2,476 124,515 113,634 41,570 37,950 4,240 3,870850 81,072 73,988 27,066 24,709 2,759 2,518 126,606 115,543 42,274 38,593 4,311 3,935875 82,398 75,199 27,512 25,116 2,804 2,559 128,677 117,434 42,972 39,229 4,382 4,000900 83,713 76,399 27,955 25,520 2,849 2,600 130,730 119,309 43,663 39,861 4,452 4,064

8" Tube 10" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Orifice Meters


270" 225" 30" 25" 30" 25" 270" 225" 30" 25" 30" 25"925 85,016 77,589 28,393 25,921 2,893 2,641 132,766 121,167 44,348 40,486 4,521 4,127950 86,309 78,769 28,829 26,318 2,937 2,681 134,784 123,010 45,028 41,107 4,590 4,190975 87,590 79,939 29,261 26,713 2,981 2,721 136,785 124,837 45,703 41,723 4,659 4,253

1000 88,861 81,100 29,689 27,104 3,024 2,761 138,771 126,650 46,372 42,334 4,726 4,3141025 90,123 82,252 30,114 27,492 3,067 2,800 140,740 128,448 47,037 42,941 4,794 4,3761050 91,374 83,394 30,536 27,877 3,110 2,839 142,695 130,233 47,696 43,542 4,860 4,4371075 92,616 84,528 30,955 28,260 3,152 2,878 144,634 132,004 48,350 44,140 4,926 4,4971100 93,849 85,654 31,371 28,640 3,194 2,916 146,560 133,762 49,000 44,733 4,992 4,5571125 95,073 86,771 31,784 29,017 3,236 2,954 148,470 135,506 49,645 45,322 5,057 4,6171150 96,287 87,880 32,194 29,391 3,277 2,992 150,367 137,238 50,286 45,907 5,122 4,6761175 97,493 88,981 32,602 29,763 3,319 3,029 152,250 138,957 50,922 46,488 5,186 4,7341200 98,690 90,074 33,006 30,132 3,359 3,067 154,120 140,664 51,554 47,064 5,250 4,793

1. For general use only as tube sizes are nominal and plate sizes are such that the beta ratio is exact. Use "Flocon" for precise calculations.2. Use the lowest expected pressure when determining the maximum capacity3. Use the highest expected pressure when determining the minimum capacity4. For a 300 In.WC differential pressure transmitter, 270 In.WC is 90% of range and 30 In.WC is 10% of range5. For a 250 In.WC differential pressure transmitter, 225 In.WC is 90% of range and 25 In.WC is 10% of range

8" Tube 10" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Orifice Meters


Capacities = Mscfd

Pressure(psig) 0.6 Beta 0.2 Beta

270" 225" 30" 25" 30" 25"100 63,078 57,454 20,824 19,008 2,128 1,943125 69,598 63,420 23,025 21,017 2,353 2,148150 75,606 68,914 25,049 22,865 2,560 2,337175 81,214 74,041 26,936 24,588 2,753 2,513200 86,501 78,874 28,713 26,210 2,934 2,678225 91,523 83,463 30,399 27,750 3,107 2,836250 96,320 87,847 32,010 29,221 3,271 2,986275 100,926 92,055 33,556 30,632 3,429 3,130300 105,366 96,111 35,045 31,992 3,581 3,269325 109,660 100,034 36,486 33,307 3,728 3,403350 113,826 103,839 37,883 34,583 3,871 3,533375 117,876 107,538 39,241 35,823 4,009 3,660400 121,822 111,143 40,565 37,032 4,144 3,783425 125,676 114,663 41,858 38,212 4,276 3,903450 129,444 118,104 43,122 39,366 4,405 4,021475 133,125 121,475 44,360 40,496 4,531 4,136500 136,755 124,781 45,575 41,605 4,655 4,249525 140,309 128,027 46,767 42,694 4,776 4,360550 143,803 131,218 47,940 43,765 4,896 4,469575 147,241 134,358 49,094 44,818 5,013 4,576600 150,227 137,450 50,231 45,856 5,129 4,682625 153,964 140,497 51,352 46,879 5,243 4,786650 157,256 143,503 52,458 47,889 5,355 4,889675 160,505 146,470 53,549 48,886 5,467 4,990700 163,715 149,400 54,628 49,870 5,576 5,090725 166,886 152,296 55,694 50,843 5,684 5,189750 170,022 155,159 56,748 51,806 5,792 5,287775 173,123 157,992 57,791 52,758 5,898 5,384800 176,193 160,795 58,824 53,701 6,002 5,479825 179,232 163,570 59,847 54,635 6,106 5,574850 182,242 166,273 60,860 55,560 6,209 5,668875 185,224 169,041 61,864 56,476 6,311 5,761900 188,180 171,739 62,859 57,385 6,412 5,853925 191,109 174,414 63,846 58,286 6,512 5,944950 194,014 177,066 64,825 59,180 6,611 6,035975 196,895 179,697 65,797 60,066 6,709 6,125

1000 199,753 182,306 66,760 60,946 6,807 6,2141025 202,588 184,895 67,717 61,819 6,904 6,3021050 205,402 187,464 68,666 62,686 7,000 6,3901075 208,194 190,013 69,608 63,546 7,095 6,4771100 210,965 192,543 70,544 64,400 7,190 6,5631125 213,716 195,054 71,473 65,248 7,284 6,6491150 216,446 197,547 72,395 66,090 7,377 6,7341175 219,157 200,022 73,311 66,926 7,470 6,8191200 221,848 202,479 74,220 67,757 7,561 6,903

1. For general use only as tube sizes are nominal and plate sizes are such that the beta ratio is exact Use "Flocon" for precise calculations2. Use the lowest expected pressure when determining the maximum capacity3. Use the highest expected pressure when determining the minimum capacity4. For a 300 In.WC differential pressure transmitter, 270 In.WC is 90% of range and 30 In.WC is 10% of range5. For a 250 In.WC differential pressure transmitter, 225 In.WC is 90% of range and 25 In.WC is 10% of range

12" Tube

Issued: 1994Revised: 1996, 1998, 2000, 2002, 2006, 2008

Dresser Roots B3-HPC * Positive Displacement Rotary Meters

P(atm.) = 14.4 psia SG = 0.600 Capacities = MscfdPb = 14.73 psia CO2 = N2 = 0 mole % Max. = 90% calculated from base rateTb = Tf = 60 deg.F Fpv per AGA-8 (gross) Min. = calculated operational rangeability

Pressure 1M (1000 acfh) 2" 3M (3000acfh) 2" 5M (5000 acfh) 3" 7M (7000 acfh) 3"(PSIG) Max. Min. Max. Min. Max. Min. Max. Min.

100 170.47 5.66 511.42 3.97 852.37 18.21 1193.31 11.89125 208.57 6.28 625.70 4.40 1042.83 20.18 1459.96 13.18150 246.98 6.85 740.95 4.80 1234.91 22.00 1728.87 14.38175 285.73 7.38 857.20 5.17 1428.67 23.72 2000.14 15.49200 324.77 7.88 974.31 5.53 1623.85 25.34 2273.39 16.55225 364.15 8.36 1092.45 5.87 1820.75 26.88 2549.05 17.56250 403.84 8.83 1211.53 6.19 2019.22 28.37 2826.91 18.53275 443.85 9.27 1331.56 6.50 2219.27 29.80 3106.97 19.47300 484.18 9.70 1452.54 6.81 2420.89 31.19 3389.25 20.38325 524.92 10.13 1574.76 7.10 2624.59 32.55 3674.43 21.26350 565.93 10.54 1697.80 7.39 2829.67 33.86 3961.54 22.12375 607.33 10.94 1821.99 7.67 3036.65 35.16 4251.32 22.97400 649.00 11.33 1946.99 7.95 3244.98 36.42 4542.97 23.79425 691.11 11.72 2073.34 8.22 3455.56 37.66 4837.79 24.60450 730.16 12.04 2190.48 8.44 3650.81 38.70 5111.13 25.29475 776.29 12.47 2328.86 8.75 3881.43 40.08 5434.00 26.19500 819.41 12.84 2458.23 9.00 4097.05 41.27 5735.88 26.96525 862.95 13.20 2588.86 9.26 4314.76 42.44 6040.66 27.73550 906.84 13.56 2720.51 9.51 4534.19 43.60 6347.87 28.49575 950.98 13.92 2852.95 9.76 4754.91 44.74 6656.87 29.23600 995.55 14.27 2986.66 10.01 4977.77 45.88 6968.87 29.97625 1040.56 14.62 3121.69 10.26 5202.81 47.01 7283.94 30.71650 1085.92 14.97 3257.77 10.50 5429.62 48.12 7601.47 31.44675 1131.54 15.31 3394.61 10.74 5657.69 49.23 7920.76 32.16700 1177.60 15.66 3532.80 10.98 5887.99 50.33 8243.19 32.88725 1224.12 16.00 3672.36 11.22 6120.61 51.42 8568.85 33.60750 1270.89 16.34 3812.67 11.46 6354.45 52.51 8896.23 34.30775 1318.13 16.67 3954.38 11.69 6590.64 53.59 9226.89 35.01800 1365.60 17.01 4096.81 11.93 6828.02 54.66 9559.23 35.71825 1413.56 17.34 4240.67 12.16 7067.78 55.73 9894.90 36.41850 1461.87 17.67 4385.60 12.39 7309.34 56.80 10233.07 37.11875 1510.41 18.00 4531.22 12.62 7552.04 57.85 10572.85 37.80900 1559.43 18.33 4678.30 12.85 7797.17 58.91 10916.04 38.49925 1608.82 18.65 4826.46 13.08 8044.10 59.96 11261.73 39.17950 1658.56 18.98 4975.69 13.31 8292.82 61.01 11609.95 39.86975 1708.67 19.30 5126.00 13.54 8543.34 62.05 11960.67 40.54

1000 1759.13 19.63 5277.39 13.76 8795.65 63.09 12313.92 41.221025 1809.95 19.95 5429.86 13.99 9049.77 64.13 12669.67 41.901050 1861.13 20.27 5583.40 14.22 9305.67 65.16 13027.94 42.571075 1912.52 20.59 5737.55 14.44 9562.58 66.19 13387.61 43.241100 1964.41 20.91 5893.24 14.67 9822.06 67.22 13750.89 43.911125 2016.50 21.23 6049.50 14.89 10082.51 68.24 14115.51 44.581150 2068.94 21.55 6206.83 15.11 10344.71 69.26 14482.59 45.251175 2121.56 21.86 6364.68 15.33 10607.80 70.27 14850.92 45.911200 2174.70 22.18 6524.10 15.55 10873.51 71.28 15222.91 46.57

1. Use the lowest expected pressure when determining the maximum capacity.2. Use the highest expected pressure when determining the minimum capacity.3. Minimum capacities are calculated using reasonable approximation for meter rangeability at elevated pressure.

Issued: 1994 Revised : 2000, 2002, 2003, 2008

Instromet IRMS * Positive Displacement Rotary Meters

P(atm.) = 14.4 psia SG = 0.600 Capacities = MscfdPb = 14.73 psia CO2 = N2 = 0 mole % Max. = 90% Q(max. published)Tb = Tf = 60 deg.F Fpv per AGA-8 (gross) Min. = published

Pressure 1M (1000 acfh) 1.5" 1.5M (1500 acfh) 1.5" 2.5M (2500 acfh) 2" 3.5M (3500 acfh) 2" 6M (6000 acfh) 3" 9M (9000 acfh) 3" or 4"(PSIG) Max. Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Min.

100 170.47 9.47 255.71 14.21 426.18 14.21 596.66 18.94 1022.84 23.68 1534.26 23.68125 208.57 11.59 312.85 17.38 521.41 17.38 729.98 23.17 1251.39 28.97 1877.09 28.97150 246.98 13.72 370.47 20.58 617.45 20.58 864.44 27.44 1481.89 34.30 2222.84 34.30175 285.73 15.87 428.60 23.81 714.34 23.81 1000.07 31.75 1714.40 39.69 2571.61 39.69200 324.77 18.04 487.16 27.06 811.93 27.06 1136.70 36.09 1948.62 45.11 2922.93 45.11225 364.15 20.23 546.22 30.35 910.37 30.35 1274.52 40.46 2184.90 50.58 3277.34 50.58250 403.84 22.44 605.77 33.65 1009.61 33.65 1413.45 44.87 2423.06 56.09 3634.59 56.09275 443.85 24.66 665.78 36.99 1109.63 36.99 1553.49 49.32 2663.12 61.65 3994.68 61.65300 484.18 26.90 726.27 40.35 1210.45 40.35 1694.62 53.80 2905.07 67.25 4357.61 67.25325 524.92 29.16 787.38 43.74 1312.30 43.74 1837.21 58.32 3149.51 72.91 4724.27 72.91350 565.93 31.44 848.90 47.16 1414.84 47.16 1980.77 62.88 3395.61 78.60 5093.41 78.60375 607.33 33.74 911.00 50.61 1518.33 50.61 2125.66 67.48 3643.98 84.35 5465.98 84.35400 649.00 36.06 973.49 54.08 1622.49 54.08 2271.49 72.11 3893.98 90.14 5840.96 90.14425 691.11 38.40 1036.67 57.59 1727.78 57.59 2418.89 76.79 4146.68 95.99 6220.01 95.99450 730.16 40.56 1095.24 60.85 1825.40 60.85 2555.57 81.13 4380.97 101.41 6571.45 101.41475 776.29 43.13 1164.43 64.69 1940.72 64.69 2717.00 86.25 4657.72 107.82 6986.57 107.82500 819.41 45.52 1229.12 68.28 2048.53 68.28 2867.94 91.05 4916.47 113.81 7374.70 113.81525 862.95 47.94 1294.43 71.91 2157.38 71.91 3020.33 95.88 5177.71 119.85 7766.57 119.85550 906.84 50.38 1360.26 75.57 2267.09 75.57 3173.93 100.76 5441.03 125.95 8161.54 125.95575 950.98 52.83 1426.47 79.25 2377.45 79.25 3328.44 105.66 5705.89 132.08 8558.84 132.08600 995.55 55.31 1493.33 82.96 2488.88 82.96 3484.44 110.62 5973.32 138.27 8959.98 138.27625 1040.56 57.81 1560.84 86.71 2601.41 86.71 3641.97 115.62 6243.38 144.52 9365.07 144.52650 1085.92 60.33 1628.89 90.49 2714.81 90.49 3800.74 120.66 6515.55 150.82 9773.32 150.82675 1131.54 62.86 1697.31 94.29 2828.84 94.29 3960.38 125.73 6789.22 157.16 10183.83 157.16700 1177.60 65.42 1766.40 98.13 2944.00 98.13 4121.60 130.84 7065.59 163.56 10598.39 163.56725 1224.12 68.01 1836.18 102.01 3060.30 102.01 4284.42 136.01 7344.73 170.02 11017.09 170.02750 1270.89 70.61 1906.34 105.91 3177.23 105.91 4448.12 141.21 7625.34 176.51 11438.01 176.51775 1318.13 73.23 1977.19 109.84 3295.32 109.84 4613.45 146.46 7908.77 183.07 11863.15 183.07800 1365.60 75.87 2048.41 113.80 3414.01 113.80 4779.62 151.73 8193.63 189.67 12290.44 189.67825 1413.56 78.53 2120.33 117.80 3533.89 117.80 4947.45 157.06 8481.34 196.33 12722.01 196.33850 1461.87 81.21 2192.80 121.82 3654.67 121.82 5116.54 162.43 8771.21 203.04 13156.81 203.04875 1510.41 83.91 2265.61 125.87 3776.02 125.87 5286.43 167.82 9062.45 209.78 13593.67 209.78900 1559.43 86.64 2339.15 129.95 3898.58 129.95 5458.02 173.27 9356.60 216.59 14034.90 216.59

Issued: 2000Revised: 2002, 2003, 2008

Instromet IRMS * Positive Displacement Rotary Meters

Pressure 1M (1000 acfh) 1.5" 1.5M (1500 acfh) 1.5" 2.5M (2500 acfh) 2" 3.5M (3500 acfh) 2" 6M (6000 acfh) 3" 9M (9000 acfh) 3" or 4"(PSIG) Max. Min. Max. Min. Max. Min. Max. Min. Max. Min. Max. Min.

925 1608.82 89.38 2413.23 134.07 4022.05 134.07 5630.87 178.76 9652.91 223.45 14479.37 223.45950 1658.56 92.14 2487.85 138.21 4146.41 138.21 5804.97 184.28 9951.38 230.36 14927.07 230.36975 1708.67 94.93 2563.00 142.39 4271.67 142.39 5980.34 189.85 10252.01 237.31 15378.01 237.31

1000 1759.13 97.73 2638.70 146.59 4397.83 146.59 6156.96 195.46 10554.78 244.32 15832.18 244.321025 1809.95 100.55 2714.93 150.83 4524.88 150.83 6334.84 201.11 10859.72 251.38 16289.58 251.381050 1861.13 103.40 2791.70 155.09 4652.84 155.09 6513.97 206.79 11166.81 258.49 16750.21 258.491075 1912.52 106.25 2868.77 159.38 4781.29 159.38 6693.81 212.50 11475.10 265.63 17212.64 265.631100 1964.41 109.13 2946.62 163.70 4911.03 163.70 6875.44 218.27 11786.48 272.84 17679.71 272.841125 2016.50 112.03 3024.75 168.04 5041.25 168.04 7057.75 224.06 12099.01 280.07 18148.51 280.071150 2068.94 114.94 3103.41 172.41 5172.35 172.41 7241.30 229.88 12413.65 287.35 18620.48 287.351175 2121.56 117.86 3182.34 176.80 5303.90 176.80 7425.46 235.73 12729.36 294.66 19094.04 294.661200 2174.70 120.82 3262.05 181.23 5436.75 181.23 7611.45 241.63 13048.21 302.04 19572.31 302.04

1. Use the lowest expected pressure when determining the maximum capacity.2. Use the highest expected pressure when determining the minimum capacity.3. Minimum capacities are calculated using reasonable approximation for meter rangeability at elevated pressure.

Issued: 2000Revised: 2002, 2003, 2008

Energy Economics HP3000 * Positive Displacement Diaphragm Meters

P(atm.) = 14.4 psia Case WP = 1500 psigPb = 14.73 psia 2" Connection

Tb = Tf = 60 deg.Fs = 1.0000

Pressure Capacity Maximum Max. Capacity @ * Minimum(psig) Factor Derated Capacity Qb = 1200 scfh Derated Capacity

(Mscfd) (Mscfd) (Mscfd)25 2.09 150.59 77.03 7.5350 3.02 217.69 125.91 10.8775 3.87 278.41 174.79 13.92

100 4.65 334.97 223.67 16.75125 5.40 388.49 272.55 19.42150 6.11 439.65 321.43 22.01175 6.79 488.89 370.31 24.44200 7.45 536.54 419.19 26.83225 8.09 582.81 468.07 29.14250 8.72 627.88 516.95 31.39275 9.33 671.90 565.83 33.59300 9.93 714.98 614.71 35.76325 10.52 757.21 663.59 37.86350 11.09 798.66 712.47 39.94375 11.66 839.42 761.35 41.97400 12.22 879.52 810.23 43.99425 12.76 919.02 859.11 45.95450 13.31 957.96 907.99 47.93475 13.84 996.39 956.87 49.82500 14.37 1034.32 1005.75 51.74525 14.89 1071.80 1054.63 53.59550 15.40 1108.84 1103.51 55.44575 15.91 1145.48 1152.39 57.27600 16.41 1181.73 1201.27 59.09625 16.91 1217.61 1250.15 60.88650 17.40 1253.15 1299.03 62.64675 17.89 1288.35 1347.91 64.42700 18.38 1323.23 1396.79 66.17725 18.86 1357.81 1445.67 67.89750 19.33 1392.10 1494.55 69.60775 19.81 1426.11 1543.43 71.31800 20.28 1459.85 1592.31 73.01825 20.74 1493.33 1641.19 74.67850 21.20 1526.57 1690.07 76.32875 21.66 1559.56 1738.95 77.98900 22.12 1592.33 1787.83 79.63925 22.57 1624.87 1836.71 81.24950 23.02 1657.19 1885.59 82.87975 23.46 1689.31 1934.47 84.47

1000 23.91 1721.22 1983.35 86.091025 24.35 1752.94 2032.23 87.651050 24.78 1784.47 2081.11 89.211075 25.22 1815.81 2129.99 90.791100 25.65 1846.98 2178.87 92.351125 26.08 1877.97 2227.75 93.901150 26.51 1908.79 2276.63 95.451175 26.94 1939.44 2325.51 96.971200 27.36 1969.93 2374.39 98.50

1. Use the lowest expected pressure when determining the maximum capacity.2. Use the highest expected pressure when determining the minimum capacity.3. Capacity factor = pressure factor to the 3/4 power

* 4. Minimum capacity published per manufacturer.5. Minimum capacity may be considered near zero at all pressures, if meter is in proof.

Issued: 1994Revised: 2002, 2003, 2004, 2008

STANDARD METER TUBE DRAWINGS

i

TABLE of CONTENTS

Meter Station Header Design Specifications STD-METR-0001 Standard Downstream Taps Details STD-METR-0002 Typical Hazardous Area Location Classification Plan TYP-METR-0003 Typical Meter Station Grounding and Plot Plan TYP-METR-0004 Typical Meter Station Grounding Details TYP-METR-0005 Typical Meter Station Grounding Details TYP-METR-0006

Ultrasonic Meters Tab Typical Ultrasonic Meter Tube with Flow Conditioner TYP-METR-1000 4” Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1001 6” Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1002 8” Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1003 10” Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1004 12” Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1005 4” Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1006 6” Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1007 8” Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1008 10” Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1009 12” Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1010 4” Bi-Directional Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1011 6” Bi-Directional Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1012 8” Bi-Directional Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1013 10” Bi-Directional Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1014 12” Bi-Directional Ultrasonic Meter Tube with CPA Flow Conditioner STD-METR-1015 4” Bi-Directional Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1016 6” Bi-Directional Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1017 8” Bi-Directional Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1018 10” Bi-Directional Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1019 12” Bi-Directional Ultrasonic Meter Tube with Gallagher Flow Conditioner STD-METR-1020

Contact TGP Engineering or Measurement Services for ultrasonic meter tube fabrication drawings using the Sick Maihak Flowsic600 ultrasonic meters.

Turbine Meters Tab Typical Turbine Meter Tube with Sonic Nozzle TYP-METR-2000 2” Sensus T-10-HP Turbine Meter Tube STD-METR-2002 3” Daniel Mini Turbine Meter Tube STD-METR-2003 4” Turbine Meter Tube (Sensus Auto-Adjust II and Daniel) STD-METR-2004 6” Sensus Auto-Adjust II Turbine Meter Tube STD-METR-2005

STANDARD METER TUBE DRAWINGS

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Orifice Meters Tab Typical Orifice Meter Tube with Flow Conditioner TYP-METR-3000 2” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3001 3” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3002 4” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3003 6” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3004 8” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3005 10” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3006 12” Orifice Meter Tube with CPA Flow Conditioner STD-METR-3007 2” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3008 3” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3009 4” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3010 6” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3011 8” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3012 10” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3013 12” Orifice Meter Tube with Gallagher Flow Conditioner STD-METR-3014 Rotary and Diaphragm Meters Tab Typical Rotary Meter Set, Vertical and Horizontal Orientation TYP-METR-4000 Typical Diaphragm Meter Set TYP-METR-4002

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Measurement Facility Design Specifications 2008-2009 · Measurement Facility Design Specifications Tab ... Condensate removal/storage/handling requirements ... DESIGN SPECIFICATIONS

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