NBSIR 76-1070 Evaluation of Backflow Prevention Devices: A State-of-the-Art Report Grover C. Sherlin Robert W. Beausoliel Center for Building Technology Institute for Applied Technology National Bureau of Standards Washington, D. C. 20234 June 1976 Final Report Prepared for Water Supply Division Environmental Protection Agency Washington, D. C. 20460
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NBSIR 76-1070
Evaluation of BackflowPrevention Devices:
A State-of-the-Art Report
Grover C. Sherlin
Robert W. Beausoliel
Center for Building Technology
Institute for Applied Technology
National Bureau of Standards
Washington, D. C. 20234
June 1976
Final Report
Prepared for
Water Supply Division
Environmental Protection AgencyWashington, D. C. 20460
NBSIR 76-1070
EVALUATION OF BACKFLOWPREVENTION DEVICES:A STATE-OF-THE-ART REPORT
Grover C. Sherlin
Robert W. Beausoliel
Center for Building Technology
Institute for Applied Technology
National Bureau of Standards
Washington, D. C. 20234
June 1976
Final Report
Prepared for
Water Supply Division
Environmental Protection AgencyWashington, D. C. 20460
U.S. DEPARTMENT OF COMMERCE, Elliot L. Richardson, Secretary
Edward O. Vetter, Under Secretary
Dr. Betsy Ancker-Johnson. Assistant Secretary for Science and Technology
NATIONAL BUREAU OF STANDARDS, Ernest Ambler, Acting Director
CONTENTS
Abstract 1
1. Introduction 2
1.1 Purpose and Scope 2
1.2 Fundamentals of Backflow 3
2. Background Information 7
2.1 Historical Background and Recorded Incidentsof Backflow through Backflow Connection andCross-Connections 7
2.2 Navy Study of FCCCR Certification Procedures 9
2.3 A.S.S.E. Concern for Backflow Problems 10
2.4 Backflow Prevention Devices and PipingArrangements 12
3. Elements in the Evaluation of Backflow Prevention Devices... 18
3.1 The Product Standards 18
3.2 The Plumbing Codes 19
3.3 The Manufacturers of Backflow Prevention Devices 23
3.4 Testing Laboratories 23
3.5 A Conceptual Model Cross-Connection Control
Program 36/
4. Evaluation of Devices 39
4.1 Design Considerations that Affect Reliability 39
4.2 Methods that Test Appropriate Attributes 45
5. Summary of Findings 56
5.1 Air Gap (AG) 56
5.2 The Reduced Pressure Backflow Device (RPBD) 56
5.3 Fail-Safe Devices 56
5.4 Realistic and Useable Test Methods 57
6. Conclusion and Recommendations .....58
6.1 Conclusions 58
6.2 Recommendation 59
7. Abbreviations and Definitions 62
8. References 71
9. Acknowledgement 75
10. Appendix 76
10.1 Vacuum Dissipation Calculations 76
10.2 Navy Survey Form 79
10.3 Procedures for a National Voluntary LaboratoryAccreditation Program 83
10.4 Hose Connection Vacuum Breaker Test 100
10.5 Reduced-Pressure Backflow Prevention Device Test .104
10.6 Analysis of Test Methods in A.S.S.E. Standardsfor Backflow Prevention Devices 108
10.7 Units of Measure and S.I. Conversion Factors 137
EVALUATION OF BACKFLOW PREVENTION DEVICES:
A STATE-OF-THE-ART REPORT
by
Grover C. Sherlin and Robert W. Beausoliel
ABSTRACT
A significant potential for potable water supply contaminationexists within all water supply systems due to backflow and cross-connections. Surveillance of the water supplies to protect from suchhazards requires continuing vigilance by the administrators of cross-connection control programs, and continuing upgrading of technicalcriteria and methods of evaluation.
The Environmental Protection Agency assists local (usuallymunicipal) authorities, through the State water supply agency, inestablishing and operating cross-connection control programs.Essential to these programs are (1) information on the suitability ofcommercially available devices for use in potentially high-hazardlocations, and (2) practical and effective standardized test methodsfor evaluation of devices. The National Bureau of Standards investi-gation reported herein addresses the two needs identified.
This study includes a systematic review of the literature,together with consultations and visits with water purveyors, plumbingofficials, laboratory officials and researchers in this field. Emphasishas been placed on those devices, test methods, and laboratorypractices considered most essential to an effective assessment of thestate-of-the-art. Also, test development needs were identified in a fewareas of greatest concern.
Key Words: Backflow; backflow preventers; back pressure; back-siphonage; cross-connections; health hazard; potable water; vacuumbreaker; water supply.
1
1. INTRODUCTION
1.1 Purpose and Scope
5 As approved Dec. 16, 1974, Public Law 93-523 (called the "Safe
Drinking Water Act") marks the first time a national commitment has beenmade to safeguard public drinking water supplies. It provides that the
Federal Government - U.S. Environmental Protection Agency (EPA) - set
national standards, and that the states enforce those standards and
10 otherwise supervise public water supply systems and sources of drinkingwater. The Act gives EPA responsibility for setting minimum nationaldrinking water standards for all public water systems throughout the
United States having at least 15 service connections or regularlyserving at least 25 people. EPA is also authorized to help States
15 improve their drinking water programs by providing technical assistance,employee training and financial support.
Although the Safe Drinking Water Act is primarily concerned withthe contaminants — that must be processed out of the raw water by those
20 persons who own and operate a public water supply system, EPA has long
been concerned with contaminants that may enter a potable water system bybackflow from a consumer's pipeline through a cross-connection.
In this particular concern, EPA assists local (usually municipal)25 authorities, through the State water supply agency, in establishing and
operating cross-connection control programs. Essential to these programsare (1) up-to-date information on the suitability of various types of
commercially available protective devices for use in potentially high-hazard locations, and (2) practical and effective standardized test
30 methods for use in evaluating such devices. The collective experienceof EPA, other federal agencies, and state agencies has shown that a sig-nificant potential for potable water supply contamination exists withinall water supply systems, and that minimization of such hazards requirescontinuing vigilance by the administrators of cross-connection control
35 programs, and continuing upgrading of the state-of-the-art in mattersof technical criteria and methods of evaluation. EPA has requested theNational Bureau of Standards (NBS) to provide assistance in meeting theneeds identified above.
NBS has undertaken to perform the tasks of (1) producing a state-40 of-the-art survey and report, drawing upon available NBS laboratory
findings to evaluate existing or modified test procedures, and (2) of
developing guide criteria for the laboratory evaluation of backflowprotection devices and examining protocols required for evaluationpurposes.
45
This report assesses the state-of-the-art for the evaluation ofdevices used to protect potable water supplies against backflow con-tamination. Backflow contamination of a water supply can arise in
— A number of terms and abbreviations have been defined in section 7.
2
either of two plumbing system configurations. In the first configurationa so-called "direct cross-connection" exists where the potable watersupply piping is mechanically joined to piping or pressurized deviceswhich may contain potential contaminants. Examples of direct cross-con-nections are inter-connections between dual-purpose water distributingsystems (potable system and a protection system, laboratory water system,etc) ; completely submerged inlets from water supply lines to closedplumbing fixtures, tanks or vats; and continuous water connectionsbetween supply and drain systems, pump priming lines, etc.
In the second configuration, an " indirect cross-connection" or a
"potential cross-connection" exists. This is one in which the inter-connection is not continuous and the completion of the cross-connectiondepends upon certain possible occurrences. Examples: water closets withdirect flush valve supply, bathtubs or lavatories with faucet openingsthat may become submerged, etc. [1, 2], 2/
In either case, i.e., direct or indirect cross-connection, backflowresults from an adverse pressure differential across the cross-connectionThus, the necessary conditions for potable water contamination by back-flow are the simultaneous occurrence of events which produce (a) a cross-connection, (b) an adverse pressure differential across the connection,and (c) the presence of a contaminant on the normal downstream side of
the cross-connection. If prevention of conditions (b) and (c) abovecould be assured, special backflow prevention devices would not benecessary. However, many of the types of events which give rise to
either the presence of a contaminant or an adverse pressure differentialor both appear unexpectedly beyond human control; therefore, there are
many design situations where adequate backflow protection devices mustbe used.
This study has involved collection of information from a number of
sources. These include a systematic review of the literature, togetherwith consultations and visits with water purveyors, plumbing officials,laboratory officials and researchers in this field. To the extent that
the scope of these investigations was restricted by the resourcesavailable for this study, emphasis has been placed on those devices,
test methods, and laboratory practices considered most essential to an
effective assessment of the state-of-the-art. Also, test development
needs were identified in a few areas of greatest concern.
1.2 Fundamentals of Backflow
Backflow can result when either a direct or an indirect cross-
connection to a potable water supply experiences an adverse pressure
differential. In other words, backflow can occur when the pressure in
the potable water system is, or momentarily becomes, less than that in
2/ Numbers in brackets refer to sequential listing of references in
section 8.
the system to which it is connected. For example, consider the hypo-thetical and typical illustration of a backflow situation depicted onfigure 1. Here an upfeed water supply riser serves a number of fixturesin a tall building. Assuming that all fixtures are closed and theline supplying water to the building is broken in the street, the columnof water in the riser will fall to a level of approximately 33 feet to
balance the atmospheric pressure on the broken end of the pipe thuscreating a vacuum in the upper levels of the riser. Then if, as shownon this figure, the water supply faucet of fixture "A" (with hose sub-merged in laboratory sink) were opened, the contents of the sink would,under the atmospheric pressure, be "sucked" or back-siphoned into theriser. This volume of non-potable liquid would be distributed to otherwater outlets in the building after the water service was restored;consequently, a health hazard for occupants of the building served bythat riser would result. It is conceivable that this slug of non-potableliquid could travel through the riser and the service piping to thestreet main where it would subsequently be transferred to the servicepiping of other premises and thereby create a widespread health hazard.
Dawson and Kalinske have demonstrated that a column of water in a
closed riser as shown in figure 1 would fall to its final position shownin about seven seconds [3]. The falling column of water would first ac-celerate, then decelerate to zero velocity at the 33-foot level shown.
Therefore, it is seen that the potential back-siphonage hazard can occurquite rapidly. It is interesting to note that a subatmospher ic conditionwould exist temporarily inside the riser as the water column fell evenif the riser were completely open at the top. This condition would occurbecause the atmospheric air flowing into the riser would experience a
loss of pressure due to the entrance loss (frictional loss) and also a
loss of pressure in the direction of flow due to pipe friction andvelocity head. Therefore, even if means were developed to completelyvent a riser, some degree of back-siphonage potential would exist duringthe transient period when the water column was falling. Of course, if
the riser were vented, all of the water in the riser would flow into the
excavation shown and no potential back-siphonage hazard would exist afterflow ceased.
If, as indicated by figure 1, a faucet "B" were open at the instantthe water main were broken, air would immediately begin entering theriser as the water fell from the riser. This, of course, would greatlyreduce the peak magnitude of the vacuum in the riser as well as its
duration. Assuming that the volume of vacuum was initially about 7 1/3gallons (internal volume of the pipe) , the method of Dawson and Kalinske[3] indicated that the time to dissipate the vacuum from 29 inches of
mercury to atmospheric pressure would be 4.6 seconds through a 3/8- inchdiameter opening at the faucet. See Appendix Section 10.1 for detailsconcerning the sample calculation and applicable equation.
Referring again to figure 1, we may assume that faucets "A" and "B"were closed and the interconnection "c", a check valve between the heatingsystem and the water system, was leaking. Then chemically treated heating
2" DIA. STD. WT. GALVANIZEDSTEEL PIPE (RISER) CLOSED AT TOP
POTENTIAL BACK-SIPHONAGEFROM CONTAINER IF VALVE IS
OPENED WHILE THE CONNECTINGHOSE IS SUBMERGED IN LIQUID
PARTIAL VACUUM (WATER.
VAPOR AT 0.3 PSIA)
WITH ALL FAUCETS CLOSED WATER.FALLS FROM TOP OF RISER TO THIS
LEVEL WHEN THE STREET MAIN IS
BROKEN
STREET
EXCAVATION
AIR FNTERS RISER
IF FAUCET IS OPEN
BUILDING WATERSUPPLY RISER
75'
RADIATORS
WATER IS AT
ATMOSPHERICPRESSURE
STREET MAIN IS BROKENIN THE EXCAVATION
>
Figure 1. Illustrating Two Examples of Backflow: (A) by Backsiphonageand (C) by Back Pressure
5
system water would backflow into the riser from the back pressure causedby the circulating pump and/or boiler. When the break in the street mainwas subsequently repaired and service restored, the slug of chemicallytreated water could be distributed through all potable water outletswithin the riser and perhaps to other premises connected to the streetmain.
There are, of course, many other more common situations which cangive rise to adverse pressure differentials of the types shown on figure1. For example, back-siphonage in cross-connections can occur by wayof a vacuum generated in the potable water piping of any building asfollows
:
a. Draining of hot water heaters and/or a water supply systemwithout venting air into the system can create vacuums withinthe system.
b. "Imperfections of workmanship at tee connections or couplingsmay produce restrictions which would cause high water veloc-ities with consequent reduction in pressure. The pressure maybe reduced sufficiently so as to produce a negative pressureat the side outlet of the tee and consequent siphonage fromthe submerged inlet fixture to which the side of the tee is
connected." [3] Excessive water demand can result in equallyhigh velocities in the main line and excessive reduction in
pressure in branch piping with similar back-siphonage.
This section has indicated that the possibility of backflow dependson a number of factors usually unique to a particular cross-connectionsituation. Unfortunately, very little data are known to exist on the
frequency-of-occurrence of adverse pressure differentials, contaminantpresence, or both, with or without backflow prevention devices installed.Therefore, no means exist presently to predict backflow hazard potentialor hazard reduction through use of backflow prevention devices. If such
data were available, analyses of this type would be straightforward and
quite useful not only in identifying high risk cross-connection situations,
but also in predicting the relative effectiveness of alternative methodsof backflow protection.
2. BACKGROUND INFORMATION
2.1 Historical Background and Recorded Incidents of Backflow ThroughBackflow Connections and Cross-Connections
5
The previous section has given an overview of the mechanisms of
the cross-connection problem. This section presents some actual backflowincidents chronologically and gives indication of what is being donepresently to prevent such incidents.
10A highly publicized and investigated incident involving backflow
resulted in an outbreak of amoebic dysentery in a hotel during the World'sFair in Chicago in 1933. This epidemic brought world-wide attention to
Chicago and stands as a landmark in the development of cross-connection15 control efforts. The most important outcome from the Chicago incident
was the recommendation that air-gap separation be used for preventingcontamination of the potable water supply [4] . Vacuum breakers were notavailable during the Chicago epidemic era, but by 1945 vacuum breakershad been developed and approved for use [4].
20
"Craun and McCabe [5] conducted a review of the causes of waterborne-disease outbreaks occurring in the U.S. during 1946-70. Duringthis 25 year period, there were 358 recognized outbreaks of disease or
chemical poisoning attributed to contaminated drinking water. These25 outbreaks affected 72,358 individuals and resulted in 36 deaths....
The majority of the outbreaks (71 percent) resulted from con-tamination of private, individual water systems; but most of the illnesses
(83 percent) occurrred as the result of outbreaks in community water30 systems. The major cause of outbreaks in community water systems was
contamination of the distribution system, primarily through cross-connections and back siphonage; however, few illnesses resulted from this
source because the contamination was confined to rather small areas."
[6] Table 1 lists some of the more sensational, recently recorded,35 incidents of backflow.
The U.S. Environmental Protection Agency publication, "Cross-
Connection Control Manual," cites a number of interesting incidents
including the following concerning the sill faucet or hose bibb [7].
40
"A California laborer had been using an aspirator, attachedto a garden hose, to spray a driveway with weed killercontaining arsenic. Sometime while he was at the job, thewater pressure reversed. Taking no notice of the incident,
45 the man disconnected the hose and, feeling thirsty, drankfrom the bibb of the hose connection at the house. Arsenicin the waterline killed him."
7
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8
Hutchinson, speaking to the American Water Works Association [8]
and earlier to the American Society of Sanitary Engineering [9] , statedthat there is no organized cross-connection incident reporting system.It is conceivable that if some mechanism for reporting such incidents
5 existed, it would be found that the number of backflow and cross-connection incidents is actually many times larger than current knowledgeindicates. If practical, a reporting system would be invaluable in
setting priorities for device usage and for pinpointing and correctingcauses. Such a system might include records of low water pressure and
10 vacuum in the water piping to hazardous premises such as sewage treat-ment plants and industrial plants. Recurring low pressure would indicatesystem deficiencies requiring correction.
During a cross-connection survey in Calhoun County, Michigan, [10]
15 pressure-vacuum recording gages were installed in some 45 differentlocations. A total of ninety (90) charts were obtained during the surveyand sixteen of these showed low or negative pressure. The existence of
low pressure in the potable water supply indicates potential for backflow.
20 2.2 Navy Study of FCCCR Certification Procedures
During World II, according to Navy Technical Note N-1169 [11]
there were numerous backflow occurrences caused by docked Naval andand merchant vessels accidentally pumping harbor water through on-shore
25 water lines. Sanitary protection of the water supply was frequentlyneglected due to the urgency of wartime schedules. As a result, a groupof individuals concerned with backflow prevention proposed in 1944 to
establish a foundation 3/ at the University of Southern California to
study the problem. On 14 September 1944, the Board of Trustees of the30 University established the FCCCR as a formal arm of the University.
The FCCCR adopted definitions and specifications for backflowprevention devices as early as 1948 when Paper Number 5 [12] was pub-lished. In 1959, an expanded set of definitions and specifications was
35 published as USCEC Report 48-101. [13] Shortly thereafter, a jointcommittee representing numerous Southern California water utilitiesexpanded USCEC Report 48-101 into what became known as the Manual forCross-Connection Control - Recommended Practice. [14] This manual, whichcontains additional information on the application of backflow pre-
40 venters, was first published in 1960. The 2nd and 3rd Editions werepublished in 1965 and 1966, respectively , with minor revisions. During1967 and 1968, the manual (particularly Section 10 covering specifica-tions) was thoroughly reviewed by a committee representing water util-ities, local health authorities, manufacturers, and the Foundation.
45
3/ At the time of the Navy report the name was Foundation for Cross-Connection Control Research (FCCCR)
.
9
The major changes which resulted were incorporated in the 4th Edition
of the Manual, [15] published in 1969.
Navy Technical Note N-1169 [11] resulted from the need to under-5 stand better the impact of a change in certification procedure by FCCCR.
The Naval Civil Engineering Laboratory at Port Hueneme, California con-
ducted a survey of authorities concerned with backflow prevention, in-
cluding persons in city, county, state and federal governments. Responses
from 62 localities are summarized in Table 2. The column headings in the10 table are of necessity cryptic, but by following the arrangement of the
survey questions (reproduced here as Appendix 10.2) possible confusion
of meanings is minimized. Nearly half of those responding indicated that
the reduced pressure principle backflow preventer was the minimum
protection required for a health hazard to the potable water supply.1~* Although the Navy has relied heavily on certification procedures to
assure that the very best protection would be provided at its bases and
docks, it may find that periodic field testing of devices is more
certain assurance of best protection.
20 2.3 The A.S.S.E. Concern for Backflow Problems
The American Society of Sanitary Engineering (A.S.S.E.) wasfounded in Washington D.C. in 1906, eight years prior to the advent of
the first U.S.PHS standards for drinking water. Although the member-25 ship of the society for many years was small, the yearbooks indicate that
active members concerned themselves with many aspects of water supplyand waste disposal with primary concern for public health.
In the NBS file is a collection of three papers prepared by30 William C. Groeniger, [16, 17, 18] who in the early thirties was for
several years Chairman of the Research Committee of A.S.S.E., and earlieran Ohio State inspector of plumbing. He and the Research Committeepioneered activities toward solution of cross-connection problems. In
1932, Major Groeniger, in the capacity of Chairman of the Research35 Committee, served as Chairman of an A.S.S.E. conference on "Cross Con-
nections" [19] held at NBS on February 24 and 25. The conferenceregistration list of 54 included a broad sampling of concerned persons:physicists, engineers, plumbing contractors, plumbing component manu-facturers, and public health officials. Of particular interest was the
40 presence of H. H. Matthieson, Chief Sanitary Engineer of the Los AngelesHealth Department because other authors have indicated that Los Angeleswas early the center of activity in testing and evaluating mechanicalbackflow preventers — as early as 1934.
45 The first national standards for devices to prevent or to controlbackflow (ASA A40.4 - 1942 "Air Gaps" and ASA - A40.6 - 1943 "BackflowPreventers in Plumbing Systems" were published by the American StandardsAssociation (ASA). A.S.S.E. did not have representatives on the A40committee of ASA but became a sponsor with the American Society of
50 Mechanical Engineers (ASME) when part of A40 was changed to A112,Committee on Standardization of Plumbing Material and Equipment, in 1958.
10
2. Results of a Survey Made by the Naval Civil Engineering Laboratoryand Reported in Navy Technical Note N 1169
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11
The first output of the A.S.S.E. Standards Committee on May 1966, A.S.S.E.
1001, "Pipe Applied Atmospheric Type Vacuum Breakers," received approvalof the American National Standards Institute — A112 Committee to becomeANSI A112.1.1 - 1971. [20]
5
The A.S.S.E. 1002 covering standards and tests procedures for
water closet flush tank anti-siphon ball cocks was issued in October1964 and revised in 1968 but has not yet met the approval of ANSI.
10 More recently the Standards Committee has focused its attentionon five additional standards for backflow preventers and has publishedthem as A.S.S.E. 1011, 1012, 1013, 1015, and 1020 [21, 22, 23, 24, 25].
All of these are now being considered by the ANSI A112 Committee for
adoption .
15
Backflow preventers include devices and arrangements such as theair gap, the barometric loop, double check valve assemblies, reducedpressure zone back pressure backflow preventers, and vacuum breakers.Each of these types will be described and categorized.
20
2.4 Backflow Prevention Devices and Piping Arrangements
Figure 2 shows two applications of an air gap whereby protectionagainst back siphonage can be assured as long as there is no tampering
25 with the gap. For example it is quite possible to slip a short lengthof rubber tubing or rubber hose into the faucet of the lavatory, or
sink without anticipating the hazards. The hose could lie in the stop-ped sink filled to the overflow outlet with contaminated wash water,and the faucet could be partially opened to supply water for a contin-
30 uously flowing wash operation. Should a sudden vacuum occur on thewater supply line contaminated wash water would back-siphon out of thesink into the potable system.
When water is needed to be under pressure for a particular ap-35 plication water is delivered to a tank through an air gap as illustrated
in Figure 2 and a booster pump, located between the tank and point of
use, can provide the necessary pressure. However, when the booster pumpfails to operate and repair or replacement is not immediately possible,maintenance men have piped across the air gap to make use of the pressure
40 in the potable supply line. Such an action could be more hazardous to
human life than the act of putting a copper penny behind a blownelectrical fuse.
V45 — Founded in 1918 as the American Engineering Standards Committee, it
became the American Standards Association (ASA) in 1928, the UnitedStates of America Standards Institute (USASI) in 1966 and now AmericanNational Standards Institute (ANSI) since October 1969.
12
OUTLET AT AN ANGLE
AN AIR GAP IS PROVIDED BETWEEN THE FLOOD RIM
OF A FIXTURE AND THE SUPPLY FAUCET35 FEET
OR MORE
POTABLEWATER
BUTTERFLY
VALVEyTO CHEMICAL PROCESSOR OTHER NON POTABLE
USE FIXTURE
AN AIR GAP SEPARATES POTABLE WATER ANDPROCESS WATER THAT MUST BE UNDER PRESSURE
BAROMETRIC LOOP MADE BY THE
ELEVATION OF A LOOP OF PIPE
Figure 2. Showing Examples of the Air Gap and the Barometric Loop
13
Work began in 1938 to develop a national standard for airgaps in water distribution piping systems suitable for all water-con-nected devices and fixtures. The initial American Standard ASA 40.4 -
1942 for air gaps was recently updated to be ANSI A112.1.2 - 1973. [26].
5
A sketch of a barometric loop is also shown in Figure 2.
Following the principle of operation, an elongated U-bend in the waterpiping is extended to a height beyond which siphonic action can notoccur. In practical application the top of the U-bend would be about
10 35 feet above the highest outlet supplied by the water piping.
De Roos and Michaelsen [27] studied the barometric loop andparticularly the air-lift effect — which, should it occur in the simpleloop, could make the piping arrangement ineffective at preventing back-
15 siphonage. In their experiments they installed an air-water separatorin the base of the loop on the downstream side and vented the separatorthrough 1/2-inch copper tubing to the top of the downstream leg of theloop. Properly designed, it appears from that research that air enteringthe piping downstream of the separator will be removed by the separator-
20 vent arrangement and will not enter the downstream leg of the loop tocreate the air-lift effect.
25
30
Additional matters of concern were not explored by the experi-ments but were noted by the authors:
1. It was not determined whether or not diffusion causeda transfer of contaminants from the downstream to theupstream side of the loop.
2. Any effect temperature gradients might have on the
transfer of contaminants over the loop was not determined,and
3. Unanswered is the question of the amount of contaminationtransferred over the loop by air separated from waternear the top of the loop.
For specific applications the barometric loop could be aninexpensive way to protect against backsiphonage. It can not be usedwhen there is any possibility of back pressure occurring on the down-stream side.
On the air-lift effect, air enters the downstream leg of the loopthrough an open outlet or leaky connection. An air bubble of suf-ficient size may form to rise in the pipe and lift a quantity of waterover the U-bend into the potable water.
14
2.4.1 Backflow prevention devices
A backflow preventer has been defined as any mechanical device,
whether used singly or in combination with other controls, that will
5 automatically forestall the possibility of an unintentional reverse
flow in a potable water distribution system. Depending upon the degreeof redundancy desired, each backflow preventer is comprised of one or
more check valves, atmospheric relief valves (air inlet valves) or
pressure differential relief valves, together with test cocks and gate10 valves. Among the less complicated devices are the vacuum breakers
which are used primarily to protect against the hazard of back-siphonage.
Three standards for vacuum breakers have originated with the
American Society of Sanitary Engineering (ASSE) to cover the pipe-15 applied atmospheric-type [20], the hose-connection type [21 J and the
pressure-type [25] vacuum breakers. The International Association of
Plumbing and Mechanical Officials (IAPMO) has published a standard for
backflow prevention devices [28] which includes design and operationalspecifications together with laboratory and/or field test procedures
20 for the pipe-applied atmospheric type, the single check valve pressuretype and the double check valve pressure-type vacuum breakers. Also in
the fifth edition of the Manual of Cross-Connect ion Control [29]
published by the Foundation for Cross-Connection Control and HydraulicResearch (FCCCHR) , specifications and test procedures for pressure
25 type vacuum breakers have been included for the first time.
A.S.S.E. also has published a standard for Water ClosetAnti-siphon Ball Cocks [30], in this standard the anti-siphon devicemay be an air gap or a vacuum breaker.
30
In Figure 3, sketches and schematic drawings are used to aid
the reader in the differentiation of the several types of vacuumbreakers using combinations of atmospheric relief valves, check valves,and gate valves. The pipe-applied atmospheric type and the hose-con-
35 nection type are designed for use downstream of the last flow controlvalve. With the pressure type vacuum breaker a control valve may belocated downstream of the device.
Test cocks are an integral part of the device in some designs.They are required for double check valve assemblies and for reduced-pressure principle backflow prevention devices.
Table 3 summarizes the sizes, working pressures , temperatureservices, operational features and applications for each type of
45 backflow preventer identified by an illustration and the correspondingA.S.S.E. standard number.
50
15
FLOW | FLOW |
PRESSURE TYPE VACUUM BREAKER PIPE-APPLIED ATMOSPHERIC TYPE
VACUUM BREAKER
FLOW | ^ FLQW |
o o a o o oSINGLE CHECK VALVE PRESSURE VACUUM
BREAKER WITH TEST COCKS DOUBLE CHECK VALVE ASSEMBLY
FLOW |
BACKFLOW PREVENTER WITH INTERMEDIATE
ATMOSPHERIC VENT —
DOUBLE CHECK VALVE PRESSURE VACUUM BREAKER
ASSEMBLY WITH TEST COCKSFLOW >
REDUCED-PRESSURE ZONE PRINCIPLE BACK PRESSURE
BACKFLOW PREVENTER
FLOW }
SINGLE CHECK VALVE PRESSURE VACUUM BREAKER IN TANDEM WITH A REDUCEDPRESSURE ZONEPRINCIPLE BACK PRESSURE BACKFLOW PREVENTER (SEE B O C A. -1975 SECTION P1605.11.8
Figure 3. Schematic Drawings of Backflow Prevention Devices that Utilize
Check Valves, Gate Valves, Relief Valves and Test Cocks
16
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.
17
3. ELEMENTS IN THE EVALUATION OF BACKFLOW PREVENTION DEVICES
3.1 The Product Standards
The first widely used standards for backflow preventers appears to
5 be those of the Foundation for Cross-Connection Control Research at theUniversity of Southern California. The other entries in the standardsfield were A. W.W. A. [31], A.S.S.E. [20,21,22,23,24,25,30] and
I.A.P.M.O. [28].
10 3.1.1 Foundation for Cross-Connection Control and HydraulicResearch (FCCCHR)
The 5th edition, (March, 1974) of the Manual of Cross-ConnectionControl [29] incorporated editing of Section 10 to make the original
15 intent of the formulating committee a bit clearer. Also in Sections 9
and 10, the pressure type vacuum breakers were included for the first
time. The Manual is a volume of 150 pages compiled to provide for uniformcross-connection control practices as they impact upon health agencies,water purveyors, water users (consumers) and inspectors of backflow
20 prevention devices. The following subjects are included:
° A statement of policy 0 Cross-connection control
o n jv-t-.^' c practicesResponsibilities of purvey-
25 ors, consumers and officials ° Samples of standard letters
o j. . . . . c j , and formsDefinitions of words and
phrases ° Field testing procedures
30
° Examples of cross connections ° Specifications for devices
° Results of noncompliance ° Case histories
The survey made by the Navy [11] in 1968, summarized in Table 2
gives some idea of the extent of use of this particular cross-
25 connection control manual throughout the United States.
3.1.2 American Water Works Association (AWWA or A. W.W. A.)
The A. W.W. A. has a standard, C 506-69, [31] for two types of
devices that are designed especially for protection of water in thewater mains. The work toward development of the standard appears to
have started in 1959 with the first output being a manual: "AWWA M14 -
Recommended Practices for Backflow Prevention and Cross-ConnectionControl."
The subsequent AWWA standard C 506-69"Backflow Prevention Devices -
Reduced Pressure Principle and Double Check Valve Types" describesessentially the same devices as does A.S.S.E. 1013 and 1015.
5018
3.1.3 American Society of Sanitary Engineering (ASSE or A.S.S.E.)
In 1953 the Standards Committee of A.S.S.E. was appointed. Theoutput of backflow prevention standards began in 1964 with A.S.S.E.1001 [20] and A.S.S.E. 1002 [30], followed later in 1970 by A.S.S.E.
5 1011 [21], in 1971 by A.S.S.E. 1013 [23], in 1972 by A.S.S.E. 1012 [22]
and A.S.S.E. 1015 [24]; and the latest A.S.S.E. 1020 [25] in 1974. TheCanadian Standards Association voted to adopt these standards as thebasis for their standards.
10 3.1.4 International Association of Plumbing and Mechanical Officials(IAPMO or I.A.P.M.O.)
The IAPMO standards are related to the need for backflow preventerstandards in the IAPMO Plumbing Code. In the development of the IAPMO
15 Specification PS 31-74 [28] many of the advisors to the FCCCHR programs,including Dr. Springer, aided in formulating the standard. Four types of
backflow preventers are identified with criteria and test requirements
:
Reduced-pressure principle backflow prevention device, Double checkvalve assembly, Single check valve pressure vacuum breaker, and Double
20 check valve pressure vacuum breaker assembly.
3.1.5. Summary of Applications of Product Standards
Table 4 is a matrix arrangement of the information found in plumb-
25 ing codes and various other publications relating the type of backflowpreventer (identified by standard when available) to the type of hazardat a cross-connection. This table illustrates how these complex relation-ships can be visually presented. When the environmental, engineering andeconomic considerations are sharply defined for each specific application,
39 the blanks and the small squares (indicating acceptable applications)and the large squares (indicating primary applications) might fit intodifferent cells from those shown in table 4. The absence of a square,therefore, does not necessarily mean that such application is undesirable.
35 3.2 The Plumbing Codes
Some regulation of cross-connection hazards is provided by theordinances or the state laws that adopt model plumbing codes. Modelplumbing codes have been developed by the following sponsors:
40American Society of Plumbing Engineers (ASPE) with the
National Association of Plumbing-Heating-Cooling Contractors1016 20th Street, N.W. , Washington, D.C. 20036 (NAPHCC)
In those localities where plumbing codes have been adopted into
law, plumbing inspectors are employed to effectuate the requirementsof the code. As technology and economics interact, products such as
backflow prevention devices are modified or new ones are introduced.
In either case the compilers of plumbing codes are called upon to make
changes in the codes so that acceptable innovations may be passed by the1^ plumbing inspector. The procedures for making changes varies with
each of the sponsors and is a time consuming operation.
At the Annual Meeting of the A.S.S.E. in 1974 representatives of
the four model codes gave the following brief descriptions of procedures
20 for making code changes as recorded in the 1974 A.S.E.E. Yearbook:
Milton Snyder, Chairman of the Joint NAPHCC-ASPE Plumbing Codecommittee stated:
10
25
30
'Changes and additions to the National Standard Plumbing Code can bemade upon initiation by Code Committee members or can be initiated byany interested party. There are public meetings at least once a year.Chairmanship of the committee rotates between the National Association of
Plumbing Contractors and the American Society of Plumbing Engineers.Actions of the committee are submitted to our Board of Directors andannually the actions of the Board are submitted to the entire membership.Since our membership has a broad base of Contractors, Engineers, andInspectors — all of whom vote — we cannot conceive that any model codehas a broader base of members with full voting privileges. And there is
35 of course another review by any locality using our information."
Clarence R. Bechtel, Managing Director of BOCA spoke to the point:
40
45
50
"Code changes can be submitted by anyone on forms supplied by BOCA.
The Plumbing Code is not changed by staff, only BOCA members change BOCAcodes. The Plumbing Code changes are reviewed in a public hearing andfollowed by a vote of active members. The approved changes are thenincorporated into the code.
The code is established and maintained according to National
Standards and practices, that is a system or device acceptable in a
distant community should be acceptable in another community providing the
performance can be proven to be identical. The local or regional influ-
ence is minimized.
21
The responsibility for enforcement lies solely and ultimately withthe local municipality.
The individuals with the duty and responsibility of enforcing the
code in the local level have a voice and a vote in determining the
content of the code by a democratic process.
Our technical staff provides the necessary back-up services such
as code interpretations, plumbing code seminars and a plumbing code
correspondence course to enhance the officials knowledge and use of
the code.
"
R.E. Sullivan, Director of Education for Southern Building Code
Congress International spoke as follows:
" We believe that a code can best be written and amended by thosepeople who use it from day to day, utilizing the advice and assistancemade available from industry and the architectural and engineering prof-fessions. Consequently, every member of the Southern Building CodeCongress is afforded the opportunity to participate in the revisionprocess at every annual research conference, and to vote on code changesrecommended by our code revision committee."
Neil A. Mac Lean, Executive Vice President of I.A.P.M.O.
"Our code changes procedure is not much different from that of anyother code agency other than the fact that - and this may be true of theother agencies but it wasn't brought out - we will accept a code changefrom anyone in the world, anyone. When we receive a code change to theUniform Plumbing Code, it is printed just the way it is submitted to usby the photocopier. We don't take a chance that in retyping that we maychange your words. We use a photocopier to reproduce enough copiesof these code changes for the code changers committee. We have a dead-line of March 1st of each year, and all code changes that have come inprior to March 1st, usually by the 1st of April are reviewed by a crosssection of the code changing committee; still having the only votingprivilege are people who have a nonvested interest, the inspectors fromour jurisdiction. The code change receives a recommendation at thatpoint, a recommendation to either accept, reject, or hold for furtherstudy. Within 30 days prior to the annual conference - but more actually,usually within 30 days after that code changes committee - all of thesecode changes are then printed in a code changes document and mailed outto our entire membership, or to anyone else if they have an interest inthe Uniform Plumbing Code - they may not be a member. These changes arethen voted on at the conference, and we have remained anonymous in thesecode changes."
10
"We specify that a code change has to be done In a specific manner,and if a stranger to our code-changes procedure submits a code changeto us, and it is incorrect, we inform him of how to do it correctlyand assist him to do it correctly. We then make it anonymous.
3.2.2 Backflow prevention requirements in model plumbing codes
The plumbing codes determine the utilization of backflow preventersin a building at the time of the design of the structure. An effectivecross-connection control program must encourage the designers to installsuitable devices , where needed, at the time of construction to obviatethe resistance to change later.
Table 5 presents a listing of paragraphs from four model plumbingcodes pertinent to specific types of cross-connections.
3.3 The Manufacturers of Backflow Prevention Devices
A complete listing of manufacturers of all backflow preventiondevices is beyond the scope of this document. In table 6 the names of
manufacturers have been compiled from the latest listings of approveddevices of the American Society of Sanitary Engineering and from a
similar list of the Foundation for Cross-Connection Control and Hydrau-lic Research. Additional names were obtained from advertisementsfound in recent technical publications and magazines.
25 In table 7, the matrix presentation is only as up-to-date as oursource of information.
3.4 Testing Laboratories
15
20
30
35
40
There currently exist two modes for the certification of backflowprevention devices. The Foundation for Cross-Connection Control andHydraulic Research tests for compliance of backflow prevention deviceswith criteria published in its Manual of Cross-Connection Control [29].
The American Society of Sanitary Engineering has working arrangementswith three testing laboratories to test devices and to authorize a sealof approval. Just recently a procedure for accrediting testinglaboratories was established within the Department of Commerce, effec-tive February 25, 1976. The complete procedure, as published in theFederal Register of Wednesday, February 25, 1976 has been arranged by
the authors of this document to provide sidenotes and a special format
as explained in Appendix Section 10.3.
Each of the above procedures will be discussed in the followingparagraphs
.
45
23
Table 5. A Listing of Paragraphs from Four Model Plumbing Codes Pertinent
to Specific Types of Cross Connections
Pcints of Contact Where a Potable Water System May Become
Contaminated by Backflow from a Non-potable Source
A Matrix Presentation Relating Manufacturers with the Types of
Backflow Prevention Devices that Each Manufactures.
Types of Backflow
Preventers
AirGap
Atmospheric TypeVacuum Breakers
Pressure TypeVacuum Breakers
Backflow PreventersIntel
mediate
DoubleCheck
ReducedPressurePrinciple
Representative
\ Standards
Makers of
Backflow \.
Preventers \.ANSI
A
112.1.2
1973
Pipe
Applied
ANSI
A
112.1.1
1971
Antisiphon
Ball
Cock
A.S.S.E.
1002
1963
Hose
Connection
A.S.S.E.
1011
1970
Single
Check
Valve
IAPMO
PS
31
1974
Single
Check
Valve
A.S.S.E.
1020
1974
Double
Check
Valve
IAPMO
PS
31
1974
Double
Check
Valve
A.S.S.E.
1020
1974
Atmospheric
Vent
A.S.S.E.
1012
1972
Valve
Assemblies
IAPMO
PS
31
1974
Valve
Assemblies
A.S.S.E.
1015
1972
IAPMO
PS
31
1974
A.S.S.E.
1013
1971
Alsons Products Corp
AMA Enterprises
American Standard , Inc
.
Badger Meter, Inc.
N
N
N
N
&
Beacon Valve Company
Belvedere Products , Inc.
Bidoro Manufacturing Co.
Buckner Sprinkler Co.
N
#
N
N
Burlington Brass Works, Inc.
A. W. Cash Valve Mfg. Corp.
Champion Brass Mfg. Co.
Chicago Faucet Company
// &
#
N
& &
Chicago Specialty Mfg. Co.
Cla-Val Co., Backflow Div.
Clayton Mark & Co.
Consolidated Brass Co. # &
N
&
// //
Coyne & Delany Company
Crane Company
Eastman Central D Div.
Fluidmaster, Inc.
N
N
N
N
N
N
//
Frost Company
G. C. G. Mfg. Co. ,Ltd.
H. L. Gee Mfg. Co.
Grinnell Company, Inc.
N
f
&
1
Griswold Controls
Hamilton Industries Div.
Hersey Products, Inc.
Jayco, Inc.
N
N
//
& &
Meaning of Symbols: // = FCCCHR Listed & = A.S.S.E. Listed N = Advertized but not listed
2°
Table 7 (Continued)
Types of Backflow
PreventersAirGap
Atmospheric TypeVacuum Breakers
Pressure TypeVacuum Breakers
Backflow PreventersIntermediate
DoubleCheck
ReducedPressurePrinciple
Representative
N. Standards
Makers of N.
Backflow N.
Preventers n.
ANSI
A
112.1.2
1973
Pipe
Applied
ANSI
A
112.1.1
1971
Antisiphon
Ball
Cock
A.S.S.E.
1002
1963
Hose
Connection
A.S.S.E.
1011
1970
Single
Check
Valve
IAPMO
PS
31
1974
Single
Check
Valve
A.S.S.E.
1020
1974
Double
Check
Valve
IAPMO
PS
31
1974
Double
Check
Valve
A.S.S.E.
1020
1974
Atmospheric
Vent
A.S.S.E.
1012
1972
Valve
Assemblies
IAPMO
PS
31
1974
Valve
Assemblies
A.S.S.E.
1015
1972
IAPMO
PS
31
1974
A.S.S.E.
1013
1971
Johns-Manville Corp.
Josam Manufacturing Co.
Kirkhill.Inc.
Kohler CompanyN
N
N
N
# # & &
Lawler ITT
Lear Siegler, Inc.
Mansfield Sanitary, Inc.
Modern Faucet Mfg. Co. JLit
N
N &
& &
Mueller Steam Specialty Co.
L. R. Nelson Corporation
Neptune Water Meter Co.
Nibco, Inc.
&
&
&
&
& &
Nidel Company
Powers Regulator Co.
Rain Bird Sprinkler Mfg. Co.
Rockwell International Corp.
N
// &
&
& & &
&
&
&
Sloan Valve Company
Surgical Mech. Research, Inc.
Taco, Incorporated
Tempstat Corporation
# &
#
# #
&
T & S Brass & Bronze Works
Toro Technology
Twentieth Century Products
Water Saver Faucet Company
N
#
&
N N
Watts Regulator Company
Wolverine Brass Works
Woodford Mfg. Company
Zurn Industries, Inc.
# & £>
&
&
&
N & &
Meaning of Symbols: # = FCCCHR Listed & = A.S.S.E. Listed N = Advertized but not listed
29
3.4.1 Foundation for Cross-Connection Control and Hydraulic Research
10
40
45
It was mentioned in Section 2.2 that the Foundation for Cross-
Connection Research was established as an arm of the University of
Southern California in 1944. In a publication dated April, 1948 it was
stated that the Research Foundation for Cross-Connection Control
established at the University of Southern California is properly
equipped to make all the necessary studies and tests on antisiphon
and backflow prevention devices and has been engaged in the work since
1944. [12]
The name of the foundation was later changed to appear in the
fourth edition of the Manual of Cross-Connection Control [15] as Founda-
tion for Cross-Connection Control Research (FCCCR) . In the latest
edition of the Manual the name is given as Foundation for Cross-
15 Connection Control and Hydraulic Research (FCCCHR) . As reported by
Bibbens [11]
:
"A financial grant originally equipped the FCCCR laboratory andprovided staff salaries for the first few years. Laboratory equipment
20 and instrumentation were expanded and improved in following yearsthrough gifts from water equipment manufacturers. There is now a
written agreement with the Southern California Water Utilities Associ-ation which provides financial support for the Foundation in the formof annual membership subscriptions by water utilities, cities, and
25 county, state, and federal agencies. Memberships range from $50 to
$500 per year, depending on utility size. The Southern CaliforniaWater Utilities Association is a non-profit organization which supports
an educational institution (the FCCCR)." [11]
30 "The FCCCR laboratory was originally located on the USC campus butwas removed in the mid-1960' s to make way for other campus expansion.Being without laboratory facilities for a few years, the FCCCR con-tracted for the use of private facilities when laboratory tests wererequired. In, 1968, the laboratory was reestablished in an old pumpingstation on Riverside Drive in Los Angeles. The FCCCR currently con-ducts backflow evaluation tests and other related research at thisfacility. Pressures of 45 and 150 psi are available directly from thecity's water supply system. Headers up to 16" are installed for
testing the various sizes of devices. A 200 HP diesel engine drivenpump will soon be included in the system to provide a 4600 gpm re-circulating flow capacity. The Foundation's laboratory was inspectedby the NCEL Project Engineer in June 1969 and was found to havefacilities adequate for the testing of backflow preventers as prescribedby the 4th Edition of the "Manual." During this inspection, it wasobserved that extensive equipment modification and improvement wereunderway and much new instrumentation was being installed in the lab-oratory. Half of the laboratory space was occupied by the Los AngelesDepartment of Water and Power for meter flow testing, but the remaining
30
half of the laboratory had enough space for considerable futureexpansion by the FCCCHR for further testing or research." [11]
10
Summarizing from Dr. Springer's paper [32] for testing under theFCCCHR procedures, a proposer must:
11(a) Submit a complete set of drawings and specification to
FCCCHR for review. If the review discloses that thedesign is weak or contradicts the specifications of FCCCHR,FCCCHR will make these weaknesses or non-compliance aspectsknown to the proposer.
20
(b) If the manufacturer or proposer passes step (a) , he mustthen submit one device or preferably three devices to
FCCCHR for laboratory evaluation. The device is inspectedto see that it is in compliance with FCCCHR' s speci-fication and the manufacturer's drawings. The manufactureris invited to have his representative present to witnessthe evaluation procedure and results.
(c) If the device(s) pass the hydraulic laboratory evaluation,the manufacturer must next arrange for the installation of
at least three (3) devices of this same model and size in
the field. The field location must be approved by FCCCHR(Such location(s) cannot be on fire service where staticconditions may exist continuously from one year to the
25 next). Also, a service where the flow is maximum continu-ously is not acceptable. Also the device under test cannotbe placed in a position where it would be expected to
protect the potable water supply against potential back-flow of any hazardous materials or contaminant. Such con-taminant could backflow if the unproven device failed.Also, the device cannot be placed in a water supply thatcannot be shutoff temporarily as may be required duringthe field evaluation.
(d) The field installed devices are tested monthly:
— The tightness of each check valve for double check valveassemblies is determined by test to see that each checkwill hold a 1 psig differential in the direction of flow,
30
40
45
— The opening pressure differential of the relief valve,
the pressure differential across number one checkvalve, and the drip tightness of number two check valveare all checked for the RPBD device."
(e) If any type of malfunction is observed during the field test,the test is terminated and such devices are returned to themanufacturer for corrective measures.
31
(f) After the device has been corrected or redesigned, the device
must go through the complete hydraulic laboratory evaluation
again just as though it were a completely new device. Then if
a successful laboratory test is again realized, the device is
field tested a second time. When the device satisfies FCCCHR
requirements, the manufacturer receives a "Certificate of
Approval" for the particular model and size of device passing
5 the tests.
10
15
20
3.4.2 Laboratories testing in the A.S.S.E. Seal Program
The American Society of Sanitary Engineering (A.S.S.E.) wasestablished in 1906 with its main endeavor being in the field of Plumbingand Sanitary Research. A.S.S.E. main office is located in Cleveland,Ohio [21].
The A.S.S.E. has authorized three independent testing laboratoriesto test products for compliance with the A.S.S.E. Standards mentionedpreviously in this report. These laboratories are:
(a) The Twining Laboratories, Incorporated,Fresno, California
(b) The National Sanitation Foundation,Ann Arbor, Michigan
2^ (c) Factory Mutual Research Corporation,Norwood, Massachusetts.
30
35
When a product is approved in one of these authorized laboratoriesthe A.S.S.E. seal may be displayed on the product. The seal indicatesthat the product has been certified to be in compliance with the appropriateA.S.S.E. standard as a result of satisfactory laboratory tests. Authori-zation for the use of the seal is obtained from the Seal Control Boardat the A.S.S.E. Central Office.
The seal is issued for a period of five (5) years but must berenewed annually by the manufacturer. The manufacturer must prove to the
satisfaction of the Seal Control Board that the product has not beenchanged or modified in any way that would affect compliance with the
requirements under which it was tested. Extension of the seal usage
40 beyond five years may be negotiated with the Seal Control Board. Themanufacturer makes all arrangements for testing at an A.S.S.E. approvedlaboratory and defrays all costs involved. If the manufacturer changesor alters his product without notification, the Board will cancel themanufacturer's right to display the seal.
45
32
3.4.3 Procedures for a National Voluntary Laboratory AccreditationProgram
During the fall and winter of 1972, R.W. Beausoliel visited fivelaboratories in expectation that such visits would provide critical
5 information needed to perform an evaluation of each laboratory. We knownow that in the half-day alloted for each of the visits, we did not andprobably could not have obtained the essential information needed for
such evaluations. We know that the business of evaluating laboratoriesis a complex one, for we have become aware of the work being done by
10 others at NBS to define an acceptable laboratory evaluation program.
The evaluation and accreditation program is now established and is
presented in detail , with special formatting, in the Appendix,Section 10.3.
15 Concisely, the ten steps needed to develop a list of accreditedlaboratories to test backflow prevention devices are as follows:
(1) Some person or organization must request the Secretary of
Commerce to find that there is a need for accrediting
2Q laboratories to test backflow prevention devices (Sec. 7. 4 (a))
(2) Such request will have to show:
(a) that standards and test methods exist for the evaluationof backflow prevention devices,
(b) the number of testing laboratories believed desiring to25 be accredited to test backflow prevention devices,
(c) and the number of anticipated users of the testinglaboratories service. (Sec. 7.4(b))
(3) Public hearings will be held to provide a forum for any and
2Q all opinions to be expressed. (Sec. 7.4(f))
(4) Based on the expressions that come from the hearings, theSecretary of Commerce will either decide to proceed or to
withdraw. (Sec. 7.4(g)).
35 (5) If the Secretary proceeds he will form a National LaboratoryAccreditation Criteria Committee for Backflow PreventionDevices. (Sec. 7.4(h)(3)).
(6) The Committee will be directed by the Secretary of Commerceto develop and recommend to him, general and specific criteria
40 to accredit testing laboratories that serve backflowprevention devices. (Sec. 7.6(d)).
(7) When the specific and general criteria have been prepared for
the Secretary of Commerce, he will consider them and invite45 comments from the public. (Sec. 7.8(a))
(8) The input from the hearings will be turned over to theCriteria Committee to evaluate and to advise the Secretary ofCommerce (Sec. 7.8(c)).
33
(9) Should the Secretary of Commerce accept the CriteriaCommittee's work, the criteria will be accepted and
laboratories will be invited to apply for accreditation.
(Sec. 7.10(b))
5 (10) The Secretary of Commerce will report to the public monthly,
via the Federal Register, all actions which grant, revoke,
terminate, or result in the withdrawal of the accreditation
of a laboratory. (Sec. 7.17(c)).
In the above procedures, the initiating action requires that10 standards and test methods exist for the evaluation of the devices.
The A.S.S.E. standards have been submitted to the American NationalStandards Institute (ANSI) for consideration by the A 112 Committee.
For only two of these has the approval process progressed to thestage of final approval.
15
The correlation of A.S.S.E. standards with the ANSI numbers are:
A.S. S. E. 1001 . . ANSI A 112. 1. 1 - 1971A.S. s. E. 1011 ANSI A 112. 1. 3 - 1976A.S. s. E. 1012 . . ANSI A 112. 1. 4 -
A.S. S. E. 1013 ANSI A 112. 1. 5 -
A.S. s. E. 1015 . . ANSI A 112. 1. 6 -
A.S. s. E. 1020 ANSI A 112. 1. 7 - 1976
2^ Also required to exist for the initiating action is informationon the number of testing laboratories desiring to be accredited. To
explore the possibility of developing such information, reference wasmade to the 1976 Directory of the American Council of IndependentLaboratories, Inc., 1725 K Street, N.W. , Washington, D.C. 20006.
30 (202) 659-3766.
The Directory has a classified index of its membership whereinthose laboratories doing qualification testing, hydraulic testing,hydrostatic testing, and also carrying out certification programs
35 are identified by the page number of their advertisement in thedirectory. All laboratories identified as being in each of the four
classifications were selecting for listing here. With the names of
the laboratories and three others taken from our files, table 8
Value Engineering Laboratory2550 Huntington AvenueAlexandria, Virginia 22303
(703) 960-4600
Wingerter Laboratories, Inc.
1820 N.E. 144th Street Drawer LNorth Miami, Florida, 33161
(305) 944-3401
York Research CorporationOne Research DriveStamford, Connecticut 06904
(203) 325-1371
35
3.5 A Conceptual Model Cross -Connection Control Program
In recent months a conceptual model for a realistic cross-connection control program has been evolving. The necessary elementsare even now developing, with a minimum of input from the authors.The model is shown as figure 4.
I. In the model, credit is given to EPA as being the source ofactivity needed to bring all elements together into a workable program.The line of action indicates that EPA would provide guidelines to stateor municipal authorities who would in turn develop the appropriatelegislation or ordinance to establish the cross-connection controlprogram.
II. The enabling laws will require funds for the operation of theprogram. The funding would pay for two activities:
(a) An inspection program that:
1. Authorized installation of particular backflow pre-
vention devices where needed.2 . Inspected the installation of the device at time of
construction
.
3 . Carried out a regular schedule of reinspection andtesting to determine that backflow protection deviceswere performing adequately.
(b) A contractual arrangement with an independent testinglaboratory to
:
1. Audit or monitor the cross-connection control programon a annual or semi-annual basis to assure that theprogram was being carried out under (a) above as
required by law, and2 . To provide technical guidance and training to the
inspection staff as needed and as contracted for.
III. To be qualified to make decisions or judgments on suitablebackflow protection devices the inspection staff will need technicalguidance for the approval of devices. Such guidance could come from:
1 . Knowledge that suitable devices are available in a
competitive market to fill needs in most applications.2 . Knowledge of existence of nationally recognized product
standards that assure quality and dependability for
the several types of devices
.
3. Knowledge of the existence of a certification programthat verifies on a continuing basis that devices claim-ing to meet the requirement of the standards actuallydo so.
37
IV. The existence of a competitive market depends upon a demand for
the devices. The demand may be expected to increase as the number of
cross-connection control programs increase. The demand could then beexpected to motivate new designs - utilizing new materials - andnecessitating evaluation of the new products.
5
V. The product standards currently in existence need to be improvedfrom the present stage to assure that testing and certification may becarried out uniformly by any certified independent testing laboratory.
To provide for approval of suitable innovative devices, the requirementsfor backflow protection devices need to be stated in performance
10 language. Another document of NBS, NBSIR 76-1020 "Guide Criteria for
Laboratory Evaluation of Backflow Prevention Devices for Protection of
Potable Water Supplies" by Grover C. Sherl in, Robert W. Beausoliel, andLawrence S. Galowin will aid in the develop of the performancelanguage.
15VI. Certification of the backflow protection devices would be carriedout by authorized independent testing laboratories who receive compen-sation for such certification from the manufacturers. Authorization of
the certifying laboratories could be accomplished through the U.S.
20 Department of Commerce Accreditation Program.
VII. The National Voluntary Laboratory Accreditation Program is nowavailable to accredit testing laboratories to test backflow preventiondevices. In Section 3.4.3 a concise listing is given of steps required
25 to initiate the program. The complete program is presented as AppendixSection 10.3.
38
4.0 EVALUATION OF DEVICES
4.1 Design Considerations that Affect Reliability
4.1.1 Air Gaps
5The design of air gaps in a potable water distribution line
depends upon the size of the effective opening and the distancebetween the supply fitting outlet (spout or faucet) and a near-bywall. Above one-inch diameter of effective opening the length ofair gap is specified to be twice the diameter; except when affected
±0 by a near-by wall it is to be three times the diameter. See figure 3.
The primary function of the air gap may be defeated by attachinga hose , a pipe , or a tube between the potable water outlet and a non-potable source. Possible means to prevent such practices are by
]_5designing or modifying outlets of faucets to discourage the attachmentof hoses and by initiating educational programs to apprise the publicthat attachment of such hoses can create potential health hazards
.
4.1.2 Barometric Loops
20The Environmental Services Branch, National Institutes of
Health, in cooperation with the Division of Environmental Health andSafety, University of Minnesota Health Service investigated thebarometric loop [27] . The investigation showed that air bubbles
25 could transfer contaminated water through the loop when back-siphonageoccurred. They developed an air-water separator that proved effectivein preventing such transfer. Additional studies were recommended todetermine the effect diffusion might have in the transfer of con-taminants through the. loop. There are no data on how widely
30 barometric loops are used or on how many loops are used with air-separators. The use of the separators with loops does not appearin the model plumbing codes.
4.1.3 Pipe Applied Vacuum Breakers
35The pressure type vacuum breakers (PVB) and the atmospheric
type vacuum breakers (AVB) are vulnerable to air port blockage byrags, etc. Such blockage would render the device ineffective.Suggested countermeasures are educational efforts to explain the
40 need to keep the air ports or air inlets of the vacuum breakers open,
and frequent periodic inspection, test and repair. Although PVB
has means for testing the device in line, standards do not requiresimilar test arrangement for AVB.
45
39
4.1.4 Hose Connection Vacuum Breakers
10
20
25
There are two types of hose connection vacuum breakers (HCVB)
.
One type has a diaphragm to seal the air inlets but does not have a
check valve to seal the water inlet. This type of HCVB is essentiallya special design of AVB which is not intended to be subjected to backpressure. The other type of HCVB has both a diaphragm and check valve,
For such devices a nationally recognized standard ASSE 1011 specifiesthe following test requirements which are unique for vacuum breakers
:
° The outlet of the device is subjected to a back pressurecreated by a ten-foot column of water within an elevatedgarden hose. Backflow through the check must not takeplace under this pressure.
° Leakage of water from the hose through the HCVB at the rateof 1/4-pint per minute is permitted to flow through the ventports to the ambient in order to relieve back pressurecaused by the column of water in the hose. (The checkvalve prevents backflow into the inlet of the device whenthe water is discharged from the vent ports)
.
The objectives of these two tests conflict with the principlesset forth by two authorities concerned with vacuum breakers . Forinstance, the following attitudes were found concerning the firstand second test methods respectively:
HCVB exposure to back pressure is not allowed under AWWA'sPacific Northwest Sections Manual [1]. The Manual depictsthis HCVB (with the check valve) as an AVB which themanual states is not effective against backflow due to back
3Q pressure.
° Dawson and Kalinske have said that the air inlets of vacuumbreakers should not be used to convey water as lime depositsmay cause closure of the air inlets. Also the air inlets
35 should not be placed where they would get exposed topolluted water [3].
A third test method concerns the fouling of the check with awire (a common test for vacuum breakers) [20] to simulate check valve
40 leakage resulting from check material failure or a foreign substancelodged between the check and its seat. The test is summarized as
follows
:
The back-siphonage test with vacuum applied at the inlet
45 to HCVB requires the check to be fouled.
40
° In the back pressure portion of the test method, the checkvalve is not fouled. (The standard does not say thatbackflow will occur if the check leaks)
.
It seems reasonable that if the device effectively preventsbackflow under back-siphonage conditions with a fouled check , thedevice should also effectively prevent backflow due to combinedback-siphonage and back pressure because the standard indicates thatthe device effectively relieves back pressure . The standard doesnot consider the simultaneous application of both vacuum at theinlet and back pressure at the outlet. Such likely conditions couldoccur when filling a back yard swimming pool with an elevated gardenhose. Because the standard test methods did not address this likelycondition, a simple test, as explained in Appendix Section 10.4, wascarried out to see how effective the device would be in relievingback pressure and preventing backflow with the simultaneous applicationof vacuum at the inlet and back pressure at the outlet with the checkfouled in the manner of the standard test method. Backflow occurredat 0.2 gpm. The test results indicate that backflow remained constantwith increasing elevation of the terminal end of the hose (increasingback pressure) . Such a constant backflow rate into the inlet of thedevice does indicate that the device is effective in relieving backpressure. However, the results also indicate that a tight checkvalve is required to prevent backflow under these conditions. It
would seem reasonable that the standard consider this limitation ofthe device
.
It appears that the HCVB which includes the check valve is
superior to the type that does not have a check valve . The useof garden hoses with HCVB naturally subjects HCVB to back pressure.The HCVB without a check valve can not resist back pressure. Asimple test by the National Bureau of Standards in accordance to
ASSE 1011 [21] showed that the device would backflow when subjectedto atmospheric pressure at the inlet and a three -foot head of waterat the outlet. Because of this, NBS believes that HCVB without a
check should not be used with garden hoses. It is possible to
overly criticize this relatively inexpensive device (present cost
about four dollars) because obviously a garden hose installationis safer with HCVB than without it. Alternatives to present HCVBinstallation for garden hose applications could be the use of the
pressure vacuum breaker in the hose supply or, perhaps, a redesign
of the water supply piping such that the terminal end of a gardenhose under normal use would not be elevated above HCVB or othervacuum breaker. Such approaches would tend to increase the
cost of the installation; but it must be
41
10
20
25
remembered, however, that garden hose installation can cause deathsas shown by the example in section 2.1 of this report and the bestprotection must be provided. It may be that HCVB is quite adequate ifthe check valve does not leak. A study should be carried out todetermine the following:
° Will the air ports of the HCVB become blocked withlime deposits as mentioned by Dawson and Kalinske [3]?
0 Is there, in reality, a high risk of contaminationat the air ports of HCVB with the check valve ?6/
° How reliable is the check valve under serviceconditions?
0 Would the HCVB give additional protection if it15 were installed at the nozzle end of the garden
hose or at both the faucet end and nozzle end?
30
With any such change (s) , the manufacturers and/or administrativeauthorities should make the general public aware of the importance andfunction of HCVB and other devices (perhaps TV coverage from time totime and informative literature concerning backflow potential includedwith the water purveyors bills)
.
4.1.5 Double Check Valve Assemblies
The double check valve assembly (DCVA) gives no visual indicationof check-valve failure. Protection depends entirely on tight checkvalves. Good preventive maintenance will tend to preclude check-valveleakage
.
6/ It is interesting to note that if a 50-foot length of 1/2 -inchdiameter garden hose was used to fill an elevated swimming pool such
35 that water would backflow from the hose through the vent ports tothe surrounding atmosphere at the rate allowed in the standard, 1/4-pint per minute (approximately 29 cubic inches per minute) , all of thewater in the hose (about 118 cubic inches) would flow through the portsin about five minutes. At the end of this time, possibly non-potable
40 swimming pool water would be flowing in the hose and vent ports
.
42
4.1.6 Backflow Preventers with Intermediate Atmospheric Vent
Since the backflow preventers with intermediate atmosphericvent are relatively new, no feedback from installation experiencewas found
.
5
4.1.7 Reduced-Pressure Principle Back Pressure Backflow Preventers
Some authorities declare that a reduced-pressure principlebackflow preventer (RPBD) will permit backflow when its upstream anddownstream check valves both leak when there is vacuum at the inlet
10 and back pressure at the outlet. In light of such statements, andin view of the fact that existing standards for RPBD do not have testsfor back-siphonage , a limited NBS laboratory test of a 3/4-inch devicewas conducted to determine if it would permit backflow. See Appendix10.5 for details. With the check valves fouled with 0.042 -in
3-3 diameter wires in the manner normal during vacuum breaker tests [20] ,
with a vacuum of 11 centimeters of mercury absolute (about 25 inchesof mercury gage) at the inlet, and with low back pressure of 1.31 psig,and zone pressure of one inch of water column gage, an average backflowrate of 0.029 gpm into the inlet of the device occurred. The relief
20 valve was open under these conditions and discharged water from the
zone to drain at only 1.85 gpm indicating that the zone was notoverloaded (this rate was well below the 5 gpm allowed by the
standards) . It was noted that the soft rubber check valve materialused in the upstream check of this particular model of RPBD tended
25 to slowly seat around the wire thus preventing backflow into the inlet.
The results above are in agreement with those for a similartest of a 3/4-inch RPBD made at NBS over 20 years ago. 7/ Duringthat test the check valves of RPBD were fouled with 0.027-inch
30 diameter wire. The supply piping to the device was subjected to
vacuum up to 18-inches of mercury gage, and at the same time a
positive water pressure of 25 psig was maintained in the pipingdownstream of the device. The final paragraph concerning the test
results stated the following: "In none of the vacuum tests described35 above was there any indication whatsoever of backflow. Apparently
the resilient nature of the main valve seat and the force of thespring, which aids in closing the valve, are responsible, at least
in part, for good results obtained. Even when the piece of wire
40
7/ National Bureau of Standards Report on Test of Backflow PreventerRequested by the Federal Security Agency, National Institutes ofHealth, U. S. Public Health Service, Washington, D. C. on January 31,
1952. Prepared by R. S. Wyly.
43
was placed between the main valve and its seat, there was no apparentbackflow of either air or water. Inspection of the valve showed thatthe wire had merely been pressed into the valve seat , and when theunit was disassembeled , the wire fell out, leaving only an insignifi-cant mark on the valve seat .
" The final conclusion of the report5 states. "It is obvious that under extreme conditions, backflow could
take place in the unit tested; for example, with the check valve andthe main valve very poorly seated or held open, simultaneously witha high vacuum in the supply line. However, no backflow preventeror vacuum breaker known at this time is entirely perfect or foolproof.It is believed that in the great majority of cases serious imperfections
10 in valve seating will develop gradually; hence, in the device tested,visual evidence of this fact would be at hand long before any realdanger of backflow exists."
There appear to be four reasons for backflow during the test
15 presented in Appendix Section 10.5
( i) The fouling wires used were 0.042-inches in diameterversus 0.027-inches in diameter for the earlier NBStest. The smaller diameter would favor check valve
20 seating into the soft check material.
( ii) A vacuum of 11-centimeters of mercury absolute wasused in this work (about 25-inches of mercury gage)which is somewhat more severe than the 18 inches of
25 mercury gage used in the earlier NBS test.
(iii) The device used in this work was installed in avertical line (as sanctioned by the manufacturer)with the direction of normal flow "Down" . The older
30 device was installed in a horizontal line.
( iv) There were differences in manufactures designs, i.e.,
internal shape and size of the zone, discharge port,etc
.
35
It\ seems likely, that had the 0.042-inch diameter fouling wire beenused during the earlier test, backflow probably would have occurred.It must be said also that the rate of backflow occurring during the
test presented in Appendix 10.5 was very low. The likelihood of40 such fouling of the device is probably remote because the manufacturer
requires the use of a strainer upstream of the device and the upstreamcheck valve has two seats that have to be fouled simultaneously.Considerable difficulty was experienced during initial efforts to getthe wire to remain in position across both seats simultaneously.
4544
Additional tests should be carried out concerning RPBD of othersizes and from other manufacturers. Preliminary informationobtained from such tests would be of value in the developmentof a back-siphonage test for a RPBD. The present standards forRPBD do not have back-siphonage test methods or requirements;
5 however, the device is relied upon by many users to give effectiveprotection against back-siphonage.
It was beyond the scope and resources of this project todetermine the probability of the two check valves of an RPBD leakingsimultaneously or whether any RPBD of other manufacturers would
10 allow backflow or whether the size or configuration of the devicecontributed to the backflow failures. An attempt was made to get
information from the Los Angeles Department of Water and Power (DWP)
concerning the number of times in any one year period on an averagethat RPBD experiences the failure of both check valves. DWP has
15 computer records of inspection, test, and performance data on over3,000 backflow preventers [11]; however, a computer program wouldhave to be developed to retrieve this information. The Departmentof Public Utilities, City of Tacoma, Washington provided data for
yearly tests conducted on RPBD and double check valve assemblies(DCVA) for the past 2 1/2 years. Data collected from 114 RPBD testsshowed several failures of the RPBD relief valves; however, onlyone RPBD was found to have both check valves leaking simultaneously.This condition occurred because of debris under the checks. Onlytwo DCVA were found to have both checks leaking simultaneously out
25 of 59 tests of DCVA conducted during that period. Factory MutualFire Insurance Companies inspected 1,032 sets of DCVA and only four
sets were found out of this number to have both checks leakingsimultaneously [34]. The use of strainers ahead of RPBD may be a
precaution to reduce risk of check leakage due to debris. ASSE30 Standard 1013 for RPBD recommends the use of strainers but other
standards do not. It is believed by some that strainers introduceexcessive pressure drop.
The U. S. Navy has reported that on certain docks and piers35 the relief valves of RPBD have frozen. Such failures have become
an expensive and not completely solved problem [11]. Repiping for
installation of a RPBD within a heated space could be a solution.
20
404.2 Assessment of Standard Test Methods
In this section the test methods given in standards for thebackflow prevention devices will be evaluated against the followingcriteria
:
45
45
5 (a) Understandable, Usable and Fair: Can any normallyequipped laboratory perform the tests as describedin the standard? Can innovative devices be acceptedunder the test method described or would suchdevices be restricted from approval?
IQ (b) Methods that test appropriate attributes (life cyclephenomena) : Are the test methods realistic? Do theyexpose devices to water supply conditions of temperature,pressure, flow, chemistry, water borne inclusions, andactual or test contaminants that could pollute the
20 potable water?
(c) Repeatability and Accuracy: Are the test data repeatableand how many runs of test data are taken? How accurateare the measured data?
25(d) Limit testing, Failure Modes, Maintainability, and
Field Testing: Are tests used to determine commonmodes of device failure? Is level of maintenancedetermined? Do laboratory tests assure satisfactory
30 field performance?
(e) Cost/effectiveness: Are test methods periodicallyreviewed to determine if instrumentation techniquesor other newly developed techniques might substantially
35 reduce the cost of testing and improve data quality?
By the formulation of these criteria there has been establisheda "yard stick" against which the test methods may be evaluated. In
tables 9 , 10 and 11 the tests methods are summarized with comments
40 as appropriate. In the following subsections the tests methods willbe discussed in terms of the above criteria.
In Appendix 10.6 each of the ASSE Standards have beenanalysed in great detail to identify the test requirements, test
45 setup and preparation for testing, test procedure, observationsrecords and computations and basis for rejection of device. Thematrix format used facilitates the identification of missingelements
.
50 4.2.1 Understandable, Usable, and Fair Test Methods
The ASSE Standards have test setups and test methods for alaboratory to follow which are understandable and usable. The FCCCHRand IAPMO Standards imply identical hydraulic laboratory tests but
46
Table 9 Summary of Test Methods Found in Current Standards for Atmospheric Typesof Backflow Preventers - with Comments
Devices and
Standards
Test Methods Comments
Air Gap (AG)
ANSI A112.1.2 1973 [26]
° Measurement of the length of
the air gap between the flood
level rim of a plumbing fix-
ture or tank and the effective(minimum) diameter of the
water supply outlet
Adequate test methods
AtmosphericVacuumBreaker (AVB)
A.S.S.E. 1001,1970
ANSI A112.1.1 1971 [20]
° Nontoxic certification
° Positive pressure test
* Air port shield examination
° Air flow test
° Water rise test
Test methods are indirect,that is, a tracer .yieldingquantitative results is
not used to simulatecontaminants
.
AntisiphonVI nch Va 1 VP£ XUail Vd-LVC
Ball Cock (AFVBC)
A.S.S.E. 1002,1968 [30]
° General requirements
° Vacuum breaker equipped
° Air gap equipped ball cock
Barometric Loop (BL) (No test methods) This device has features
into the installation to
make it reliable and cost-effective.
Backflow Preventers
with IntermediateAtmospheric Vent (BPIA)
A.S.S.E. 1012,1972 [22]
ANSI A112.1.4 - 1976
0 Noise
0 Hydrostatic test - total
° Hydrostatic test - check valve
° Tightness of downstream check
° Tightness of inlet check
° Atmospheric vent valve leakage
° Backflow through inlet check
0 Atmospheric vent, openingpressure
° Back— s iphonage
° Flow and pressure loss
° Flow with low supply pressure
The standard does not havea test method to cover .the
likely condition of simul-tane'ous vacuum at the in-
let and back pressure at
the outlet
A tracer to simulate con-tamination could be usedto give quantitative mea-surements of check valveleakage. The colored watertracer called for can giveonly a qualitative value.
Hose ConnectionVacuum Breakers (HCVB)
A.S.S.E. 1011,1970 [21]
ANSI A112.1.3 - 1976
° Resistance to hydrostatic test
0 Noise
° Water flow capacity
° Leakage from vent ports
° Water hammer shock resistance
0 Backflow due to back pressure
° Backflow due to back-siphonage
° Resistance to bending
° Ability to resist and relieveback pressure
° Deterioration in hot and coldwater.
Although the test methodfor backflow, section2. 1.6, requires the use of
a colored water tracer,this is a qualitative testonly which depends onvisual ability to detectthe presence of the tracer.
A measureable tracer is
not used.
47
Table 10 Summary of Test Methods Found in Current Standards for Double Check Valve
Assemblies and for Pressure Type Vacuum Breakers - with Comments
Devices andStandards
Test Methods Comments
Double CheckValve Assembly (DCVA)
A q Q F 1015 1972 r 2 4
1
ANSI A112.1.6 - 1976
0 Hydrostatic test - full
° Hydrostatic back pressure testof check valves
° Tightness of check valvesagainst upstream pressureof 1 psi.
° Rated flow and pressure loss
Lacks realistic test forperformance under back-siphonage conditions, i.e.,vacuum 1<s not" annH pH f nvacuum -L o 11UL ClL/UlJ.Cu L. \J
the inlet of the device.
Double CheckValve Assembly (DCVA)
FCCCHR - 1974 [29]
IAPMO PS 31-74 [28]
AWWA C506 - 69 [31]
° Specifies similar requirementsas in A.S.S.E. 1015
° Also specifies but without a
test procedure:- shock and water hammer- hydrostatic test on all
barriers- 12 months field performance- no backflow under all condi-
tions of pressure differ-ential
- tolerance to sand, scale andother interfering materials
- devices for elevated temper-atures to be so tested
The FCCCHR and IAPMO testrequirements are very sim-ilar. The AWWA is lessdeveloped
.
Test requirments must havetest procedures to beuseful broadly
Periodic testing of de-vices in a cross-connection control programmay economically substi-tute for field testing.
AntisiphonPressure TypeVacuumBreakers (PVB)
A.S.S.E. 1020,1974 [25]
ANSI A112.1.7 - 1976
° Hydrostatic test , internal , total
° Hydrostatic test, check valveback pressure
° Check valve force loading
° Atmospheric vent , openingpressure
0 Air passageway areas
° Back-siphonage prevention
° Rated flow and allowablepressure loss
Test methods are indirect,that is, a tracer .yieldingquantitative results, is
not used to simulatecontaminants.
Pressure TypeVacuumBreakerAssemblies (PVB)
FCCCHR - 1974 [29]
IAPMO PS 31-74 [28]
° Specifies similar requirementsas in A.S.S.E. 1020
0 Also specifies but without a
test procedure:- shock and water hammer- hydrostatic test on all
barriers- 12 months field performance- tolerance to sand, scale and
other interfering materials- devices for elevated temper-
atures to be so tested
The FCCCHR and IAPMO testrequirements are verysimilar. IAPMO definitelysingle and double checkvalve types. FCCCHR (?)
Test requirements musthave test procedures to
be useful broadly.
Periodic testing of de-vices in a cross-connection control programmay economically substi-tute for field testing.
48
Table 11 Summary of Test Methods Found in Current Standards for Reduced Pressure
Principle. Back Pressure Backflow Prevention Devices - with Comments
test procedure:- shock and water hammer- hydrostatic test on all
barriers- 12 months field performance- no backflow under all condi-
tions of pressure differ-ential
- tolerance to sand, scale and
other interfering materials- devices for elevated temper-
atures to be so tested
The FCCCHR and IAPMO testrequirements are very sim-ilar. The AWWA is lessdeveloped.
Test requirements musthave test procedures to
be useful broadly.
Periodic testing of de-
vices in a cross-connection control programmay economically substi-tute for field testing.
49
they do not give test methods. Field test setups and field testmethods are given by FCCCHR and IAPMO, but these are not clearconcerning test site selection. ASSE Standards do not requirea field test but do invite the manufacturers to furnish recom-mendations for field testing upon request. The field test appears
5 to be a major difference between requirements of some standards.
The field test is an aspect of backflow preventer testing that
requires further study.
The standards are for particular product types and are
generally prescriptive concerning functional parts. The standards10 do not have a mechanism that would allow test of an innovative
device that may be entirely different than the particular productscovered which makes those standards difficult if not impossibleto apply to innovative devices.
15 4.2.2 Methods that Test Appropriate Attributes
4.2.2.1 Backflow Prevention
Although authorities claim the RPBD and DCVA prevent20 back-siphonage , the standards for RPBD and DCVA do not have back-
siphonage requirements or back-siphonage test methods. No standardtest requires that vacuum be applied to the inlet of RPBD and DCVA.
The standards do not give emphasis to the ability of RPBD to preventbackflow due to back-siphonage. In fact, the opposite impressionis given. The foreword to ASSE 1013 for RPBD states the following:"This standard covers only the type of device which is identifiedas a Reduced-Pressure Principle Backflow Preventer which is designedprimarily for the prevention of backflow due to back pressure .
"
(Underline added for emphasis).30
ASSE 1012, Backflow Preventers with Intermediate AtmosphericVent, requires a back-siphonage test for the very inexpensivedevice, about $17.00, as compared to RPBD which would cost severalhundred dollars. This device has two independently operating check
35 valves separated by an intermediate chamber with provision forautomatically venting it to the atmosphere. Therefore, althoughit does not incorporate a relief valve, it is similar to RPBD inconfiguration. ASSE standard 1012 has a test method to determinethat no back-siphonage will occur if both check valves leak whenvacuum is applied to the inlet of BPIA and the downstream pressureis atmospheric. (A basic purpose of this device is to protect thepotable water supply against backflow where contaminants locatedwithin the outlet piping are under pressure from such equipment as
^ a low pressure residential heating boiler). In light of the fact
40
50
that back pressure will exist continuously during normal operationof the device, it would seem that the above mentioned back-siphonagetest method would be more realistic if it were performed with backpressure on the downstream side in lieu of atmospheric pressure.
5 The test method concerning HCVB was discussed in section4.1.4. The basic conclusion concerning HCVB (without check valves)is that it would not pass the backflow test of HCVB (with checkvalves) ; consequently, it would not be approved under ASSE 1011test methods . The device is a special AVB that should as a minimumbe tested under the procedures of ASSE 1001. The test methods for
10 HCVB (with check valve) concerning backflow due to back-siphonageand back pressure appear adequate. However, the tests would bemore realistic if a quantitative tracer could be used that relatesto insecticides, herbicides, car wash soap, swimming pool water andperhaps other substances that are associated with garden hose
15 application.
The water rise test for AVB and PVB appears to be generallyeffective but could be improved upon if a quantitative tracer couldbe used that relates to sewage and other commonplace contaminants.
20 The ASSE Standards do not apply the water rise test to AVB, HCVBor BPIA when the devices are at operating temperatures. IAPMOhas no such test for PVB. It seems reasonable that moving parts ofdevices might bind due to material expansion or contraction whichcould cause device malfunction.
25
Additional backflow test improvements concerning all deviceswould encompass tests that show the device to meet all of theoperating requirements. These are as follows:
30 ° Functional operation under dynamic conditions
.
° Functional operation at design pressure temperaturecombinations
.
35 ° Functional operation would , of course , be under exposureto vacuum at the inlet, pressure at the outlet andcombinations of vacuum and back pressure
.
Generally standards for devices do not test the devices for failure
modes. RPBD failure is generally indicated by water flowing fromthe zone. However, the device does not have a means to warn of
failure unless someone actually sees the water discharging from the
zone. A remote -indicating device for RPBD located in hazardousareas such as sewage treatment plants would be an improvement
.
No standard for other devices considers failure detection.
51
4.2.2.2 Nontoxic Materials
Devices should be constructed of nontoxic materials. ASSEStandards are the only standard that consider nontoxic materials.However, ASSE looks for a statement from the manufacturers that allmaterials in contact with the potable water are nontoxic. Nocriteria such as that given in the U. S. Public Health ServiceDrinking Water Standards §/ is mentioned. No standard cites a
test method for this important parameter. FCCCHR, IAPMO, and AWWAStandards do not have requirements concerning toxicity of materials.The standards should address this aspect of devices definitivelybecause one of the most important attribute of devices is nontoxicity.
4.2.2.3 Design Temperature
The standards are not consistent concerning test methods atdesign temperatures. For instance, ASSE has design temperaturetests for AVB but no design temperature tests for RPBD and DCVA.On the other hand, FCCCHR and IAPMO have tests for RPBD and DCVA ifthe design temperature exceeds 110°F. Such tests are important forall devices because of possible binding of moving parts at elevatedoperating temperatures . It seems reasonable that standards shouldnot be inconsistent concerning temperature tests.
4.2.2.4 Rated Flow and Allowable Pressure Loss and HydrostaticPressure Resistance
The standards (ASSE, AWWA, FCCCHR and IAPMO) agree on theacceptable flow rates for RPBD and DCVA. ASSE test methods forpressure drop versus flow rate are defined and appear adequate.AWWA does not have test methods, FCCCHR and IAPMO have impliedtests but their methods are not defined. ASSE has acceptable flowrate and allowable pressure loss test methods for all devicesexcept AVB. It would seem reasonable that acceptable flow ratesand an acceptable test method be given for AVB.
— Under the Safe Drinking Water Act, Public Law 93-523, NationalInterim Primary Drinking Water Regulations were promulgatedDecember 24, 1975 to become effective 18 months later.
52
ASSE, FCCCHR, and IAPMO have hydrostatic pressure tests fordevices. However, there is some inconsistency in the duration ofthe time that internal pressure of two times working pressure(2 x 150 psig) is applied. FCCCHR and IAPMO require at least twominutes. ASSE requires a ten minute application. The basic purposeof this test is to observe any leaks in valve bodies and checkvalves or distortion of parts. The test time should be standardized.ASSE requires that AVB be subjected to a hydrostatic test at designtemperature extremes (32°F and 212°F for hot water devices and 32°Fand 110°F for cold water devices) but other devices such as RPBDwhich has identical operating requirements is not tested at a designtemperature
.
4.2.2.5 Water Hammer
The standards are inconsistent concerning test methods for
water hammer. ASSE has water hammer tests for HCVB but no tests for
RPBD and DCVA. FCCCHR and IAPMO indicate water hammer tests but donot give the methods for RPBD and DCVA.
Water hammer results in overpressure that could occurperiodically. In light of this, devices should be exposed to a
certain number of cycles of water hammer to determine possiblefailure of parts. A similar test method is used on shock absorbersthat prevent water hammer. This test method is detailed in the
standard for water hammer arresters [35]
.
4.2.2.6 Noise
ASSE has a noise test method for HCVB and BPIA but does notmention a test for RPBD and DCVA. The method basically depends onthe hearing ability of the test personnel. FCCCHR considers thatRPBD and DCVA should not "chatter" which implies noise but no testmethod is given. It is important that these devices not be noisy.
Users may defeat them or have them removed from service. Studywould be required to develop quantitative techniques to detectnoisy devices.
4.2.2.7 Resistance to Actual Contaminants or Simulated ContaminantsUnder Laboratory Conditions
No standard test method requires that contaminants such as
sewage or other toxic substance or an appropriate nontoxic tracer be
used to demonstrate quantitatively the ability of the devices to
prevent backflow of contaminants under realistic conditions. Forexample, such performance standard should include a tracer test forfunctional performance under various steady state normal flow, and
dynamic flow conditions (water hammer , etc . )
.
53
10
15
20
Although the standards for devices do not consider theserealistic conditions, such tests have been performed on one modelof RPBD by the Oak Ridge National laboratory (ORNL) using theprocedures of activation analysis [36] . The RPBD passed this testwhich had a sensitivity of about 0.2 parts per billion of manganese.The nonradioactive test was generally as follows:
(a) The water supply at the test setup was first sampledto determine the threshold level of manganese, if any.
(b) The manganese tracer was introduced down stream of thedevice and the device subjected to pressure differentials,fluctations water hammer, etc.
(c) The upstream side of the device was next sampled to
determine if manganese had backflowed. The samples wereirradiated in a nuclear reactor in order to determinethe amount of manganese present. The upstream samplesdid not indicate backflow. That is, the manganeseconcentration upstream did not increase over thethreshold value
.
No correlation was made between manganese tracer and otherhazardous substances. Further work is needed to validate anddevelop the practical application of this promising test method.
25 4.2.3 Repeatability and Accuracy
With the exception of ASSE 1001 and ANSI A112 . 1 . 1 . 1971
(pipe Applied Atmospheric Type Vacuum Breakers) , no other standardsrequire data repeatability (the average of three test runs arerequired) or measure accuracy. However, an acceptable value of data
30 repeatability is not mentioned (departure from the average)
.
4.2.4 Limit Testing, Failure Modes, Maintainability and FieldTesting
35 The standards do not require that devices be cycled to
failure over operating conditions of temperature, pressure, and flow
in order to detect failure modes. The standards do not require that
devices fail safe or that devices indicate when they have failed(except for RPBD) . RPBD discharges water from its ports on failure
40 of check valves or relief valve but this does not necessarily meansuch failure would be observed or detected. As noted earlier, notest methods determine whether a device can prevent backflow of a
pollutant when subjected to conditions of backflow under operatingconditions of temperature , pressure , and flow . Guidelines and tests
45
54
for mean time between failure, mean time to maintain, mean timeto repair, level of spare parts required, availability of repairparts are not considered.
FCCCHR and IAPMO Standards require a twelve-month fieldtest of RPBD and DCVA. Although the standards do not go intodetail concerning the tests, the following is the general procedureas given in an unpublished FCCCHR paper [32]: See Section 3.4.1.
(a) One or more units of each size and model are submitted
from the manufacturer's stock. These devicesshall pass the laboratory test prior to the fieldevaluation
.
(b) The manufacturer arranges for the placement of at
least three devices, of each size and model testedin the laboratory in the field installation. FCCCHRapproves of the selected field location. The locationmust not be on a fire service where normally a no-flowcondition exists almost continuously. The devicesmust not be placed where the flow is maximum all ofthe time. Also, an RPBD under test must not be placedin a pipeline where there is potential for hazardousbackflow if the RPBD should fail during the fieldtest. The devices must be located in pipelines wherethe water supply can be turned off for short periodsof time as required by test procedures
.
(c) The field evaluation consists of a monthly test of all
of the devices on the field test program.
The field test purpose is to assure that a device will function
under actual operating conditions . ASSE Standards do not require
a field test and as a result their standards do not give assurance
of satisfactory performance under operation conditions. Field
testing is presently performed only for RPBD, DCVA and PVB. AVB
is not field tested. It appears that this aspect of testingrequires additional study. Certainly, assurance should be given
that all devices will perform in the field.
55
5. SUMMARY OF FINDINGS
The following is a summary of findings concerning backflowprotection devices, test methods, and laboratories.
5.1 Air Gap (AG)
An air gap provides positive protection against backflow of
liquid and solid contaminants. However, authorities recognize that an
air gap may be defeated through attachment of by-passes [ 1] . Thisattribute of AG is no different than that of other devices such as
the electric fuse which can be defeated in households by use
of coins or other means that result in burned wiring and houses.
5.2 The Reduced Pressure Backflow Device (RPBD)
The RPBD provides good protection against backflow in high risksituations. This device is in its weakest mode of operation whensubjected to both back pressure and back-siphonage conditions simul-taneously. NBS tests have demonstrated that one RPBD would backflowwhen the check valves leaked under such conditions. The standardsfor RPBD do not have requirements or test methods for back-siphonage.However, one manufacturer's literature states that the RPBD is
absolute protection against back-siphonage conditions. Administrativeauthorities use RPBD for protection against both back-siphonage andback pressure within the water service lines to hazardous locationssuch as sewage treatment plants. The probability of simultaneous backpressure and back-siphonage conditions is unknown but is presumed to
be much smaller than the likelihood of either event singly. Thus,RPBD's clearly do provide protection. The RPBD's only means of
protection under simultaneous conditions of both back-siphonage andback pressure is the tightness of the check valve on the upstream sideof the zone. For this reason, a periodic test and maintenanceprogram is essential for RPBD (some authorities test RPBD at leastannually) [1]. The use of strainers is considered helpful by some,but others feel that strainers can cause excessive pressure drop(ASSE's standards require strainers ahead of both RPBD and DCVA butFCCCHR does not).
5.3 Fail Safe Devices
No device currently used to prevent backflow provides a positiveindication of the device function or malfunction in the way that a fuseor circuit-breaker protects an electrical circuit. An RPBD can beobserved to discharge fluid as an indicator only if an informed personhappens to be near the device at the time the backflow condition exists
56
The ASSE standard 1001 does not consider means to test AVB formalfunction in the field [20]
.
Although Barometric Loops are used in large laboratory complexesto protect against backflow of potentially hazardous substances, thereare questions concerning its adequacy to protect against transfer ofcontaminants by air bubbles if an air water separator is not used.Additional studies concerning transfer of pollutants by diffusion andby air have been recommended by the National Institutes of Health[27] .
HCVB with a check valve is in its weakest mode of operationwhen subjected to back pressure which occurs when the terminal endof the garden hose is elevated above the HCVB. In this situation the
device does give protection as long as the check valve does not leak.
More protection could occur if the devices were located above theterminal end of the hose, though such an arrangement may not be
practical in many cases. The HCVB without the check valve shouldnot be used on garden hoses because this type of HCVB does not preventbackflow caused by back pressure. This type HCVB (without a checkvalve) is merely a special AVB and should be tested under ASSE type 1001
methods
.
5.4 Realistic and Usable Test Methods
The AWWA standard for RPBD and DCVA does not contain testmethods or implied tests. FCCCHR and IAPMO indicate the type of teststhat are to be performed but do not give details of the test methods or
test setups for hydraulic laboratory tests. ASSE standards specify testmethods and test setups.
In the case of RPBD, the current standards do not considerback-siphonage conditions and yet the device is used for this conditionin actual practice. Similarly RPBD tests do not involve actual demon-stration of functional performance i.e., prevent backflow of actualcontaminants under simulated use conditions.
The RPBD standards are not consistent concerning the necessityfor field test. ASSE does not require a field test and FCCCHR andIAPMC require a twelve month field test. Further, FCCCHR and IAPMOstandards do not provide definitive detail concerning how to performthe tests. Although PVB is field tested, AVB is not field tested.
The standard for HCVB (check valve type) tests the device withwater discharging from its air inlet ports. This is reasonable in
light of the fact that the device is designed to relieve back pressurethrough its ports. However, some authorities, Dawson and Kalinske, [3]
have said that one of the main requirements to good vacuum breaker
57
design and installation is to prevent the discharge of water from the
air inlet ports. Such discharge is alleged to cause blockage of the
ports by a build up of lime deposits. Further study is required to
determine if this condition will occur with HCVB. Port pollutionpossibilities should also be studied.
No standard requires the use of actual or simulated
contaminants or an appropriate tracer to demonstrate quantitativelyor qualitatively the ability of the devices to prevent backflow. Allpresent tests are indirect in that they show that valves do not leakor that relief valves function. The water-rise test for AVB is the
most realistic test, but it is not concerned with upstream measurementsto determine if a contaminant (air, aerosol, etc.) has passed into the
inlet of the device
.
With the exception of the ASSE/ANSI Standard for AVB, no otherstandard specifies data repeatability or measurement accuracy.
Limit testing to determine failure modes or other tests to
determine mean-time -to -maintain or to-repair , and level of spares requiredor availability of spares are not considered by standards. Many ofthese devices are very expensive, costing thousands of dollars.
The standards do not explicitly require periodic review oftest methods/equipment.
6, CONCLUSIONS AND RECOMMENDATIONS
6.1 Conclusions
1. Existing backflow prevention devices do provide protectionagainst backflow. However, insufficient data appears to exist toevaluate quantitatively the effectiveness of these devices, the risksassociated with various types of system designs, or the relativeadvantages of various devices in particular installations.
2. None of the existing devices is fool proof. Most do not providepositive indication of failure, when it occurs, or device usage whenbackflow conditions arise; nor are any of the devices used fail-safe.There is some apparent misconception of the test methods regarding the
capabilities of the RPBD and HCVB (with check valves) in particualrconcerning functional performance under all normal service conditions(i.e., combined back pressure and back-siphonage conditions andpossible lime deposits blocking HCVB air ports) . HCVB (without a
check) should not be used with garden hoses.
58
3. A.S.S.E. Standards are the only standards that have detailedtest methods, i.e., definitive test procedures and test setups. However,
the standards are inconsistent concerning the application of realistictests. For instance (other examples are in section 4.2), if a deviceis designed to operate in water that is 32°F, the device should betested to demonstrate the ability to prevent backflow at that temper-ature. AVB's are tested at their operating temperatures for leaks anddistortion of parts but not back-siphonage . RPBD's do not have testmethods that show the device will operate at design temperatures.Although both AVB's and RPBD's are used to protect against back-siphonage, AVB's are tested with vacuum and RPBD's are not. In factno standard of FCCCHR, IAPMO, or AWWA specifies performance for RPBDunder vacuum conditions simulating back-siphonage. FCCCHR and IAPMOrequire a twelve month field test, but ASSE does not. Some standardsdo not explicity spell out test methods or equipment. Others areprescriptive and provide no means for testing of innovative devices.
No existing standards test devices for functional performance underfull actual or simulated service life conditions. The test methods,however, do show that devices provide protection. These test methodscould be much improved by the use of realistic service conditionsimulation
.
4. In fairness to the backflow prevention device industry and the
standards to which they adhere it is appropriate to note
:
(a) The backflow prevention device industry provides anextremely valuable National service in the manufactureand sales of devices which adhere to recognized standards.The purpose of this work was not to discredit any partyconcerned, but to present constructive criticismwhen required.
(b) Although the devices of a particular manufacturer may berecognized in this report, tests presented and discussedhere do not in any way discredit specific products.
6.2 Recommendations
6.2.1 First Order Priority
(a) It is recommended that a study be carried out concerningthe reliability of devices that have been field testedversus the reliability of devices that have not been fieldtested in order to resolve the apparent controversyconcerning whether to require field test or not.
59
(b) It is recommended that a functional performance test andperformance standard based on using a quantitative tracer(pollutant) be developed that would be applicable fortesting all classes of devices including innovative devicesunder simulated life cycle conditions. During the test,the devices would be subjected to a program of variouswater supply operating conditions including back-siphonage to determine the ability of the device to
prevent the backflow of the tracer or simulatedcontaminant. See Section 4.2.2.7.
(c) It is recommended that a program be undertaken to
develop a positive fail-safe means of indicating or callingoperator attention to any backflow condition particularlyin high-hazard locations. Ideally a device
corresponding to an electrical fuse or circuit breakerwould be desirable.
6.2.2 Second Order Priority
(a) It is recommended that means be developed that would allowthe homeowner or plumbing inspectors a ready means to
determine whether or not an AVB or HCVB or similar deviceis functioning properly and has not failed.
(b) It is recommended that manufacturers provide definitivedata concerning reliability, maintainability, mean-time-to-maintain, and mean-time-to-failure on their devicesfor various locations and water type, etc.
(c) It is recommended that a study be conducted to determinethe level of barometric loop usage and whether or not thebarometric loops in use are using air-water separators
[19].
(d) It is recommended that a study be carried out concerningthe use of strainers ahead of RPBD, DCVA, PVB, and AVB.
Such strainers would tend to prevent the passage of
particles that could foul the checks of devices.
(e) It is recommended that a back-siphonage detectionmonitoring system be developed. This should includesampling at statistically selected high-hazardlocations such as sewage treatment plants, hospitals,and hazardous industrial and commercial locations. Such
information would define the magnitude of the problem andpinpoint recurring low pressure conditions in the water
60
supply system that must be corrected. Better data onbackflow incidents is needed to provide a basis fordeveloping and evaluating alternative program optionsin this field.
It is recommended that a rational approach be developedto determine the order of magnitude of the risk presentedby any particular type of hazard on a premise as related toother premises and the water utility itself. For instance,hazardous condition on a premise of a given type locatedin the middle of a highly populated metropolitan areawould present a greater risk in terms of populationdensity alone than the same condition on a premiselocated outside the metropolitan area where the populationdensity is very much lower. This method would provide a
means of establishing priorities for the installation of
devices of various types. This approach would be basedon information on adverse water pressure fluctuationsand backflow incidents reported in paragraph (e) above.
It is recommended that the HCVB's be studied to obtainanswers to the following questions:
(i) Will the air ports become blocked with lime
deposits to make them ineffective.
(ii) Is there a high risk of contamination at the
air ports?
(iii) Would the device give greater protectioninstalled at the nozzle end of the hoseinstead of the sillcock end?
61
7. ABBREVIATIONS AND DEFINITIONS
The following Abbreviations have been used in this report. The source of
definitions are identified at the end of the section.
Air Gap AG
American National Standards ANSI
Institute
American Society of Mechanical ASME
Engineers
American Society of Plumbing ASPE
Engineers
American Society of Sanitary A.S.S.E.
Engineering or ASSE
American Standards Association A.S.A.or ASA
American Water Works A.W.W.AAssociation or AWWA
Antisiphon flush valve ball cock AFVBC
Atmospheric Type Vacuum Breaker AVB
Backflow Preventer with BPIA
Intermediate Atmospheric Vent
Ball Cock BC
Barometric Loop BL
Building Officials and Code B.O.C.A.Administrators International, or BOCAInc
.
Critical Installation Level C-I-L
Double Check Valve Assembly DCVA
Environmental Protection EPAAgency
Feet or foot ft
Foundation for Cross-Connect ion FCCCHRControl and Hydraulic Research
Foundation for Cross-Connection FCCCRControl Research
Gallons per minute
Hose Connection VacuumBreaker
Inch or inches
International Associationof Plumbing and
Mechanical Officials
Iron pipe size
Library of Congress "SciencePolicy, a working Glossary"
Los Angeles Department of
Water and Power
Milliliters
Minute
National Association of
Plumbing-Heating-Cooling Contractors
National Bureau of Standards
National SanitationFoundation
National StandardPlumbing Code
Oak Ridge NationalLaboratory
Pounds per square inch
Pounds per square inch, gage
Pressure type vacuumbreaker
Product Standard
g.p.m.
or gpm
HCVB
in
I.A.P.M.O.or IAPMO
l.p. s.
or ips
LCSPWG
DWP
ml
min
NAPHCC
NBS
NSF
NSPC
ONRL
p. s. i.
or psi
psig
PVB
PS
P.educed Pressure Principle RPBD or
Backflow Prevention Device or RP
62
7.2 Definitions
Administrative Authority ; The individual official, board, department,or agency established and authorized by a state, county, city or
other political subdivision created by law to administer and en-force the provisions of the plumbing code or of a cross-connectioncontrol program. (NSPC & NBS)
Air Gap : An air gap in a potable water distribution system is the un-obstructed vertical distance through the free atmosphere betweenthe lowest opening from any pipe or faucet supplying water to a
tank, plumbing fixture or other device and the flood level rim of
the receptacle. (NSPC)
Air Gap Separation : The physical separation between the free-flowingdischarge end of a potable water supply pipeline and an open or
non-pressure receiving vessel. The width of separation shall beat least that specified in ANSI A112.1.2 - 1973 (FCCCHR & NBS)
Air Inlet : The opening or series of openings through the body of a
vacuum breaker connecting the free atmosphere with the liquidpassageway of the device (ASSE 1001)
Ambience (noun) : The surroundings or environment of a place or thingused in experimental research to indicate, e.g. the temperature,humidity pressure, gases, and radiation in the space surroundingthe object of an experiment. (LCSPWG)
Analysis : The action of taking something apart and examining itscomponents. (The very extent of the use of the term may seem todeprive the word of much of its meaning. It is employed in a
great many different senses, and in many combinations. The mean-ing seems to depend somewhat on the discipline connected withits use.)The notion that analysis is an identifiable and describableprocess independent of the discipline involved or the item beinganalyzed is suggested by the large number of compound wordshyphenated with it, for example: value-, failure-, cost-effectiveness-, operations-, systems-, stress-, reliability-,maintainability-, etc. (LCSPWG & NBS)
Atmospheric Air : Air of the surrounding atmosphere and at its exist-ing" pressure. (ASSE 1013)
Backflow : The unintentional reversal of flow in a potable waterdistribution system which may result in the transport of harmfulmaterials or substances into the other branches of the distribu-tion system. (NBS)
Backflow Connection : The point of joining of potable water piping withequipment, fixtures, or other piping that may be contaminated. (NBS).
63
Backflow Preventer : Any mechanical device, whether used singly or incombination with other controls, that may automatically forestallthe possibility of an unintentional reverse flow in a potable waterdistribution system. (ASSE 1001)
Backflow Preventers with Intermediate Atmospheric Vent : These devices havetwo independently operating check valves separated by an intermediatechamber with a means for automatically venting the chamber to theatmosphere. 1 The check valves are force loaded to a normally closedposition and the venting means is force loaded to a normally openposition. These devices can operate under continuous or intermittentpressure conditions. (ASSE 1012)
Backflow Preventers, Reduced Pressure Principle, Back Pressure : These devicesconsist of two independently acting check valves, internally forceloaded to a normally closed position, and separated by an intermediatechamber (or zone) in which there is an automatic relief means for ventingto atmosphere, internally force loaded to a normally open position. Thesedevices are designed to operate under continuous pressure conditions.(ASSE 1013)
Backflow Preventers, Double Check Valve Type, Back Pressure : These devicesconsist of two independently acting check valves internally force loadedto a normally closed position and designed and constructed to operateunder intermittent or continuous pressure conditions.' (ASSE 1015)
Back Pressure : Pressure created by any means in the water distribution systemon the premises, which by being in excess of the pressure in the watersupply main could cause backflow. (NBS)
Back-Siphonage : The backflow of possibly contaminated water into the potablewater supply system as a result of the pressure in the potable watersystem becoming unintentionally less than the atmospheric pressure in theplumbing fixtures, pools, tanks or vats that may be connected to thepotable water distribution piping. (NBS)
Ball Cock : A water supply valve opened or closed by means of a float ora similar device and used to supply water to a tank. (ASSE 1001)
Ball Cock, Antisiphon : A ball cock that contains an antisiphon devicein the form of an approved air gap or a vacuum breaker which is anintegral part of the ball cock unit and which is positioned on thedischarge side of the water supply control valve. (ASSE 1001)
Check Valve Assembly : A combination of spring and weight loaded checkvalves with resilient discs for the intended purpose of preventingback pressure backflow in a water supply line. Assembly is usuallyfurnished with test cocks for field testing the tightness of the checkvalves. Some assemblies include a vacuum breaker to admit atmosphericair downstream of the assembly. (ASSE 1013)
64
Community Water System : A public water system which serves at least15 service connections used by year-round residents or regularlyserves at least 25 year-round residents. "Non-community watersystem" means a public water system that is not a community watersystem (EPA 141.2. (e)) (see public water system).
The purpose of defining "Community water system" is to allowappropriate regulatory distinction between public water systemswhich serve residents on a year-round basis and public watersystems which principally serve transients or intermittent users.The possible health effects of a contaminant in drinking water inmany cases are quite different for a person drinking the water for
a long period of time than for a person drinking the water onlybriefly or intermittently. Different monitoring requirements areappropriate for the two types of systems. (EPA 141.2(e))
Constraint : A limiting condition to be satisfied in the design or
operation of a system. For example: the total cost may be a
constraint, or the percentage of system life consumed in down-time, or the compatability of a system with other systems.(LCSPWG)
Contamination : The admission of contaminants into a potable watersupply (ASSE 1013)
Contaminants (as applicable to standards for backflow preventiondevices) : Materials (solids or liquids or gases) which may beadded unintentionally (or intentionally) to the potable watersupply and cause it to be unfit for human or animal consumption.(ASSE 1013)
Contaminants (as applicable to the Safe Drinking Water Act) ; Anyphysical, chemical, biological, or radiological substance or
matter in water. (EPA 141.1(6))
This definition, in the. review of Section 141.2 of the NationalInterim Primary Drinking Water Regulations of December 24, 1975,
was critized for its breadth. The term as defined includesvirtually any constituent in water, including constituents con-sidered to be harmless or even beneficial. The definition wastaken directly from Section 1401(6) of the Safe Drinking Water Act.It is not intended to suggest that all constituents of water areundesirable, but rather is intended to permit the regulation of anyconstituent which may be harmful. (see definition of maximumcontaminant level)
65
Control Valve : A valve that is operated each time water is supplied toor shut off from a receptacle or plumbing fixture. Familiar examplesare faucets and sill cocks. (ASSE 1001)
Cost/Benefit Analysis ; The relation between social benefits and socialcosts associated with the operations of a technical system understudy. The benefits and the costs include direct and indirecteffects. Monetary equivalents are sometimes assigned to the non-materialistic values for the purpose of comparison and to clarifythe relationships between benefits and costs. (LCSPWG)
Cost/Effectiveness : This is a term widely used in systems analysis, andhas been carried over into budgeting analysis. It signifies theratio, over an explicit and finite time-span, of cost in dollarsand other tangible values to effectiveness. In the military area,in which cost/effectiveness analysis originated, the payoff wasdefined in terms of the effectiveness of the military system. In
the civilian area, "effectiveness" is replaced by "benefit."Admittedly, benefits in social systems are even more difficult to
define than effectiveness in military systems. (LCSPWG)
Criterion (plural Criteria) : A standard or an explicit measure by whichto evaluate any activity or thing. Criteria may be quantitative or
qualitative and objective or subjective. In effectiveness analysis,criteria are the elements to be measured to determine costs andbenefits. (LCSPWG)
Critical Installation Level : A designated operational limitation pre-scribing a safe height on installed vacuum breaker above the flood-level rim of the fixture or receptacle served. In the absence of a
physical mark on the device, indicating a height measurement re-ference point, the extreme bottom of the device shall be consideredthe height reference point. (ASSE 1001)
Cross Connection : Any physical connection or arrangement between two
otherwise separate piping systems, one of which contains potable
water and the other either water of unknown or questionable safety
or steam, gas, chemicals or other substances whereby there may be
a flow from one system to the other, the direction of flow depending
on the pressure differential between the two systems. By-passarrangements
,jumper connections, removable sections, swivel or change-
over devices and other temporary or permanent devicesthrough which or because of which backflow can or may occur are
considered to be cross-connections. (FCCCHR)
Cross Connection, Point of : The specific point or location in a potablewater distribution where a cross connection exists. (FCCCHR)
66
Effectiveness : In system analysis, the term effectiveness is anaggxegative expression intended to encompass all performancequalities of a system that is likely to be judged as relevant.The term describes a condition in which a system or programpossessing it has been designed to satisfy at some pre-determinedlevel all criteria selected as relevant. The term does not implyperfection but essential adequacy in all significant categoriesof performance. An effective design will result from the total ofdesign decisions among options, selecting the optimal trade-offat each decision point, to satisfy all conceivably relevantinternal and external criteria, quantitative and qualitative,tangible and intangible of performance and environmental compatibility.The concept includes such obvious criteria as cost, efficiency, andreliability. It also involves total life cost, maintainability,maintenance of the state-of-the-art modernity, compatibility withexpected operating environment, recycle or scrap value, and suchother criteria as the design engineer and the customer (or sponsor)consider relevant. (LCSPWG)
Flood Level Rim : That level from which liquid in plumbing fixtures,appliances or vats could overflow to the floor when all drain andoverflow openings built into the equipment are obstructed. (NBS)
Hazard: A possible source of danger or peril; also a condition thattends to create or increase the possibility of loss or harm. (NBS)
Hazard, Health : An actual or potential threat, of contamination orpollution of a physical or toxic nature to the potable water systemto such a degree that there would be a danger to health. (FCCCHR)
Hazard, Minimal : A connection made to the potable water system wherebythe risk from backflow occurring would entail the contamination ofthe potable water with objectionable but non-toxic substances suchas steam, air , food, beverage etc. (NBS)
Hazard, Plumbing : A plumbing type cross-connection in a consumer'spotable water system that has not been properly protected by a
vacuum breaker, air gap separation, or other suitable device. (FCCCHR)
Health Agency : The organization established by law to have jurisdictionover the water supply quality. (FCCCHR)
In the National Interim Primary Drinking Water Regulations, "State"means the agency of the State government which has jurisdiction overpublic water systems. During any period when a State does not haveprimary enforcement responsibility pursuant to Section 1413 of the
Safe Drinking Water Act, the term "State" means the Regional Admin-istrator, U. S. Environmental Protection Agency. (EPA 141.2(h))
67
Maximum Contaminant Level : The maximum permissible level of a
contaminant in water which is delivered to the free flowingoutlet of the ultimate user of a public water system, exceptin the case of turbidity where the maximum permissible levelis measured at the point of entry to the distribution system.Contaminants added to the water under circumstance controlledby the user, except those resulting from corrosion of pipingand plumbing caused by water quality, are excluded from thisdefinition. (EPA 141 . 2 (c)
)
Model: A simplified description of a process or system, or the
interaction of either with its environment. (LCSPWG)
Potable Water : Water from any source which has been approved for
human consumption by the health agency having jurisdiction.(FCCCHR)
Potable Water: Water that meets the maximum contaminant levelrequirements of the National Interim Primary Drinking WaterRegulations and which has been approved for human consumption bythe health agency having jurisdiction. (EPA)
Pollution : As used in this report the word is equivalent to
contamination in the sense that substances in the water areeither undesirable or harmful. FCCCHR credits the CaliforniaState Health and Safety Code with differentiating the two words:
contamination of water creates health hazards (q.v.) andpollution of water creates minimal hazards (q.v.). (NBS)
In view of the EPA definition of a contaminant, the word"pollutant" may provide the means of defining or designatingthe "contaminants" that are undesirable or harmful.
Pressure, Absolute : Pressure measured on a scale having a zero valueapproximately 14.7 lb/in^ below normal atmospheric pressure.
Pressure, Atmospheric : The pressure exerted in every direction at
any given point by the weight of the atmosphere.
Pressure, Hydrostatic : Pressure exerted by or existing within a
liquid at rest with respect to adjacent bodies.
Public Water System : A system for the provision to the public ofpiped water for human consumption, if such system has at least
fifteen service connections or regularly serves an average of
at least twenty-five individuals daily at least 60 days out ofthe year. Such term includes (1) any collection, treatment,storage, and distribution facilities under control of theoperator of such system and used primarily in connection with
68
such system and (2) any collection or pre-treatment storagefacilities not under such control which are used primarily inconnection with such system. A public water system is eithera "Community Water System" or a "Non-Community Water System"
.
(EPA 141.2(e))
Service Connection: The point at or near the water main where thewater purveyor delivers potable water to the consumer's watersystem. Usually the water purveyor loses jurisdiction andsanitary control over the water at the service connection.
Trade -off : The foregoing of some portion of one benefit in order toachieve some unused portion of another benefit: (or) foregoingsome portion of a benefit in order to achieve a reduction in someportion of a cost: (or) accepting an increased portion of onecost in order to receive a decrease in the portion of anothercost. Other more complicated permutations of this concept can be
suggested. The term is in wide usage. (LCSPWG)
Toxic : Poisonous [see Code of Federal Regulations, Title 21, Food andDrugs Parts 170 to 299, 21 CFR 170.1, Section 191.1, HazardousSubstances. Definitions.] (ASSE 1011)
Vacuum : Any space in a water-supply system from which water has beendisplaced by water vapor, air, or other gases, and in which thepressure is less than the prevailing atmospheric pressure.(RP 1086)
Vacuum Breaker, Atmospheric Type : A back-siphonage prevention devicewhich is designed to operate under pressure only when water is
flowing through the system and not under static, standingconditions. Must be installed upstream of any shut -off or controlvalve or means. (ASSE 1011)
Vacuum Breaker, Pressure Type : A back-siphonage prevention devicewhich can be subjected to continuous pressure, flowing, static,
or both. (ASSE 1011)
Vacuum Breaker, Hose Connection Type : A backflow prevention devicedesigned to be attached to an outlet having a hose connectionthread. It may be either atmospheric or pressure type. (ASSE 1011)
Water Hammer: The term used to identify the hammering noises and
severe shocks that may occur in a pressurized water system when
flow is halted abruptly by the rapid closure of a valve or faucet.
(NBS)
Water Purveyor: The owner or operator of the public potable watersystem supplying an approved water supply to the public. The
69
purveyor operates under a valid permit from the State Departmentof Public Health or the local health agency having jurisdiction.(FCCCHR)
Water Supply Approved : Any public potable water supply which hasbeen investigated and approved by the State Department of PublicHealth or the local health agency having jurisdiction. Thesystem must be operating under a valid health permit. (FCCCHR)
Sources of definitions are identified by code as follows:
ASSE 1001ASSE 1011
ASSE 1012
ASSE 1013 and 1015
-Standards of the American Societyof Sanitary Engineeringsee reference in Section[20] [21] [22] [23] [24]
EPA EPA, Water Programs, Part 141,
National Interim Primary DrinkingWater Regulations, dated Dec. 24, 1975
FCCCHR Foundation for Cross Connection Controland Hydraulic Research, see Reference [2 9]
LCSPWG Library of Congress "Science Policy-a Working Glossary" see Reference [37]
NBS When used alone, the definition wasgenerated by the authors, when used jointly,the definition was modified from onepublished by the other source.
NSPC- -National Standard PlumbingCode Reference [38]
RPI086- -Hunter, Golden, and EatonReference [2]
70
8. REFERENCES
[ 1] "Accepted Procedure and Practice in Cross Connection ControlManual ,
" Prepared and edited by the Cross Connection ControlCommittee of Pacific Northwest Section, American Water WorksAssociation, Published by Pacific Northwest Section, AWWA,October 1971.
[ 2] Hunter, R. B. , Golden, G. E., and Eaton, H. N. "Cross-Connectionsin Plumbing Systems" National Bureau of Standards (U. S.)
Research Paper RP 1086, Vol. 20, April 1938.
[ 3] Dawson, F. M. and Kalinske, A. A. "Report on Plumbing Cross-Connections and Back-Siphonage Research" State University ofIowa, National Association of Master Plumbers of the UnitedStates, Inc., (now NAPACC) Washington, D. C, Tech. BulletinNo. 1, 1938.
[ 4] Nielsen, L. S. Standard Plumbing Engineering Design , (McGraw-HillBook Company, Inc., New York, N . Y . , 1963.)
[ 5] Craun, G. F., and McCabe, L. J., "Review of the Causes ofWaterborne Disease Outbreaks .
" Journal American Water WorksAssociation, Vol. 65, 74 (1973).
[ 6] Craun, G. F. "Microbiology - Waterbourne Outbreaks" JournalWater Pollution Control Federation, Vol. 46, No. 6, June 1974.
[ 7] "Cross-Connection Control Manual," U. S. Environmental ProtectionAgency, Office of Water Programs, Water Supply Division, 1973,EPA-430/9-73-002.
[ 8] Hutchinson, Gary D. "The Problem of Cross-Connections ," Presented
at AWWA Cross-connections Control Seminar, Atlanta, Ga., March28, 1972.
[ 9] Hutchinson, G. D. "Cross-Connection Control Policy andRecommendations" American Society of Sanitary Engineers, 1970Yearbook, Vol. 48, pp 96-98.
[10] Stockton, E. L. "Cross-Connection in Calhoun County, Michigan,"The University of Missouri Bulletin, Engineering Series,Engineering Experiment Station Bulletin No. 32, 1943.
[11 ] Bibbens, R. N. "Backflow Prevention Devices for Potable WaterSystems at Naval Shore Facilities, Investigation throughJanuary 1971," Naval Civil Engineering Laboratory, PortHueneme, Calif., Technical Note N-1169, May 1971.
71
[12] Vivian, R. E. and Reynolds, K. C. "Objectives, General TestingProcedure, Specifications, Results of Tests," The ResearchFoundation for Cross-connection Control, University of SouthernCalifornia, Los Angeles, Calif., Paper No. 5, April 1948.
[13] Springer, E. K. and Reynolds, K. C. "Definitions and Specificationsof Double Check Valve Assemblies and Reduced Pressure PrincipleBackflow Prevention Devices," University of Southern California,School of Engineering, Report 48-101, January 30, 1959.
[14] Reynolds, K. C. "Manual of Cross-Connection Control RecommendedPractice," Research Foundation for Cross-Connection Control,University of Southern California, Los Angeles, California,August 1960.
[15] Springer, E. K. "Manual of Cross-Connection Control" Foundationfor Cross-Connection Control Research, University of SouthernCalifornia, Los Angeles, Calif., March 1969.
[16] Groeniger, W. C. , "Insurance Against Water-Born Diseases ThroughPlumbing Fixtures," Plumbers and Heating Contractors TradeJournal, September 1, 1927.
[17] Groeniger, W. C. "The Contamination of Water Supply Through CrossConnections," Plumbers and Heating Contractors Trade Journal,January 1, 1929.
[18] Groeniger, W. C. "Cross Connections," Read at Twenty-FourthAnnual Convention of the American Society of SanitaryEngineering, Detroit, Michigan, September 3, 1929.
[19] "Cross Connections" The American Society of Sanitary Engineering,Minutes of the Conference held at the Bureau of Standards atWashington, D. C. on February 24 and 25, 1932. Reported and
Prepared by Henry B. Weaver, Washington, D. C.
[20] ANSI - A112.1.1 - 1971 "Performance Requirements for Pipe-AppliedAtmospheric Type Vacuum Breakers," (A.S.S.E. 1001), AmericanSociety of Sanitary Engineering, 228 Standard Building,Cleveland, Ohio.
[21] A.S.S.E. 1011, "Hose Connection Vacuum Breakers," American Societyof Sanitary Engineering, 228 Standard Building, Cleveland, Ohio,
June 1970.
[22] A.S.S.E. 1012, "Backflow Preventers with Intermediate AtmosphericVent," American Society of Sanitary Engineering, 228 StandardBuilding, Cleveland, Ohio, May 1972.
72
[23] A.S.S.E. 1013, "Performance Requirements for Reduced PressurePrinciple Back Pressure Backflow Preventers," American Societyof Sanitary Engineering, 228 Standard Building, Cleveland, Ohio,June 1971.
[24] A.S.S.E. 1015, "Double Check Valve Type Back Pressure BackflowPreventers," American Society of Sanitary Engineering, 228Standard Building, Cleveland, Ohio, May 1972.
[25] A.S.S.E. 1020, "Performance Standard for Vacuum Breakers, Anti-siphon, Pressure Type," American Society of SanitaryEngineering, 228 Standard Building, Cleveland, Ohio, November1974.
[26] ANSI - A112.1.2 "Air Gaps in Plumbing Systems," American Societyof Mechanical Engineers, 345 East 47th St., New York, N. Y .
,
January 1973.
[27] DeRoos, R. L. and Michael sen, G. S. "Use of Barometric Loop forProtection of Potable Water Systems," Air Conditioning, Heatingand Ventilating, pp 99-103, June 1969.
[28] PS 31-74, "Specification for Backflow Prevention Devices"International Association of Plumbing and Mechanical Officials,Los Angeles, California, 1974.
[29] Springer, E. K. "Manual of Cross-Connection Control," Foundationfor Cross Connection Control and Hydraulic Research, Universityof Southern California, Los Angeles, California, 1974.
[30] A.S.S.E. 1002 "Standards and Test Procedures for Water Closet FlushTank Ball Cocks" American Society of Sanitary Engineering 228
Standard Building, Cleveland Ohio, Oct. 1964 (Rev Oct. 1968).
[31] AWWA C506-69 "Backflow Prevention Devices - Reduced PressurePrinciple and Double Check Valve Types," American Water WorksAssociation, New York, 1969.
[32] Springer, E. Kent "The Protection of Potable Water Systems fromContamination or Pollution by Backflow" A paper presented tothe Medford Water Commission, Medford, Oregon, Nov. 16, 1971.FCCCHR, University of Southern California, Los Angeles, Calif.
[33] "Oxygen Pressure Method for Accelerated Aging Tests of RubberCompounds" Bulletin of Research No. 16 June 1940. UnderwritersLaboratories , Chicago , 111.
73
[34] Angle, G . J. "Cross-Connections and Backflow Prevention" AWWASupplementary Reading Library Series, No. S106, AmericanWaterworks Association New York, N. Y. Dec 31, 1970.
[35] ANSI A112.26.1 "Water Hammer Arresters" American Society ofMechanical Engineers, New York, N. Y. 1969.
[36] Baird, J. N. ; Sanford, W. R. and Cristy, G. A.; "Reduced PressurePrinciple Backflow Preventer Evaluation and Use at Oak RidgeNational Laboratory" "Health Physics" Pergamon Press, 1965Vol. 11, pp. 743-757.
[37] Huddle, F. P.; Boesman, W. C, and Rothberg, P. F. "Science Policy:A Working Glossary", Science Policy Research Division, Libraryof Congress July 1973.
[38] National Standard Plumbing Code - 1975 Co-sponsored by NationalAssociation of Plumbing-Heating-Cooling Contractors and theAmerican Society of Plumbing Engineers, (National Associationof Plumbing Heating - Heating-Cooling Contractor, Washington,D. C. , June 1975)
.
74
9.0 ACKNOWLEDGMENT
The authors acknowledge the critical reviews of Roger D. Lee,
James A. Warren and Thomas N. Hushower in the Water Supply Divisionof the Environmental Protection Agency and the equally valuablework of William G. Street in the NBS Center for Building Technology.Also the informal contribution of Thomas P. Kruzic with NavalFacilities Engineering Command was appreciated.
The list of other individuals who contributed material forthe updating of this paper is long, including many sales engineers,plumbing officials, laboratory personnel and code writers. Theauthors are grateful for the cooperation of each person
.
75
10. APPENDIX
10.1 Vacuum Dissipation Calculations
Dawson and Kalinske present the following useful equations intheir report on "Plumbing Cross-Connections and Back-SiphonageResearch," pages 28 and 29 [3]. The introductory paragraph concerningthese equations is as follows:
"In order that some idea may be had of the time requiredto dissipate vacuums in different-size volumes, an analysiswill be made of this particular problem. It is to beremembered that the rate of air flow in pounds per secondthrough any given opening remains constant for any vacuumgreater than 14 inches of mercury. Therefore, the timerequired for a vacuum in a volume V to be reduced to thecritical pressure of 14 inches of mercury vacuum, can beobtained from the following expression :
Equation (11)
Where: t^ = seconds of time required.
W = weight of air per cubic foot at criticalpressure P . (lbs/ft 3
)c
P = 0.53P = 14 inches of mercury vacuum. Wc a, q
is ton>e determined by considering adiabaticexpansion from Pq to P . P = atmosphericpressure (lbs/ft*) °
a
= Unit weight of air at initial pressure andtemperature in the volume into which air isflowing, (lbs/ft 3 )"
Qa= pounds per second of air flow into the vacuum
for vacuums exceeding 14 inches of mercury.Q = 50CA, where C = the discharge coefficientor the opening through which air enters thevacuum. A = the area of the opening in squarefeet.
76
The unit weight of air after adiabatic expansion from atmosphericpressure to any pressure, P, can be determined from the followingformula:
W = W / P \3 rr)
3Where: W = unit weight of atmospheric air (lbs/ft )
k = 1.4 for air
The time to dissipate vacuums less than 14 inches mercury is given byDawson and Kalinske as follows:
t1
= 0.00086 V Equation (15)
CA
They give the following example:
"Taking an example where V is 10 gallons or 1 and 1/3 cubicfeet, find the time required to dissipate the vacuum from29 inches of mercury to atmospheric pressure if air flowsin through a 3/4-inch circular opening having a flow co-efficient of 1/2. From equation (11), the time requiredto reduce the vacuum from 29 inches to 14 inches is 0.8seconds. To reduce the vacuum from 14 inches of mercuryto atmospheric pressure required about another 0.8 seconds.Therefore, the total time for dissipation of the vacuum is
1.6 seconds. The persistence of a vacuum for such a shorttime would obviously prevent the maximum back-siphonageeffect. A 10 gallon volume is equivalent to about 100 feetof 1 1/2-inch pipe. The time required for vacuum dis-sipation in other volumes would be in proportion."
From Dawson and Kalinske's equation above, (11) and (15), a simplifiedequation for the dissipation of vacuum to atmospheric pressure can bedeveloped as follows for the total time t
fc
.
tt
= Cl
+ H
t = W - W.)V + 0.00086 Vt c i
CA
By substitution of the parameters of the above example into equation
11, it can be shown that (W - W.) = 0.0460 for Dawson and Kalinskeassumed conditions. Substituting this value into the above equationgives:
77
t 0.Q460 V 0.00086 V1 =
50x1/2x0.785 D+ 1/2x0.785 T)2
t 0.00234 V , 0.00219 V 0.00453 Vf-
«b» + —2 2 2
D D D
Where D = diameter in feet,
For a diameter d in inches
t _ 0.00453 V x 144 ^ 0.65232 Vt
2 2d d
For example in section 2.1 of this report, where V = seven and onethird gallons = 0.98 ft^ and d = 0.375 inches, the total time is as
follows
:
t 0.65232 x 0.98 4.547 seconds0.1406
78
10.2 The Navy Survey Form
The Navy survey form is reproduced here to aid in the
interpretation of the data gathered for table 2 on page 11.
BACKFLOW PREVENTION POLICYSURVEY FORM
NAVAL CIVIL ENGINEERING LABORATORYPort Hueneme, California 93043
Mechanical and Electrical Engineering Department
Work Unit: YF38.534.006.01.007, Backflow Prevention Devices
BACKFLOW PREVENTION SURVEY
The following questions concern policies and regulations governing
the protection of a potable water source which supplies a customer
having a known or potential cross-connection to a health hazard. Of
specific interest are the requirements for backflow preventers at
vessel watering points at piers and wharves.
Responding Agency
Name:
Address:
Phone:
Respondent: Name/Title
Please complete this questionnaire by checking (/) the appropriateanswer to each question that applies to your backflow preventionpolicies.
l.a. What is the minimum backflow prevention you require where a healthhazard exists?
( ) Air gap separation required (reduced pressure devices anddouble check valve devices not allowed).
( ) Reduced pressure principal backflow preventer required.
( ) Double check valve assembly required.
( ) Other protection.
( ) No protection specified.
79
l.b. What minimum protection do you require at vessel watering points
at piers and wharves? _____
2. If reduced pressure principal devices are used, what certificationor approval of the device do you require prior to its installation?
( ) Full approval by the Foundation for Cross-Connection ControlResearch at the University of Southern California.
( ) Provisional approval by the above Foundation.
( ) Laboratory test only by the above Foundation.
( ) Other certification or approval. (Please specify and listdevices approved.)
( ) No certification or approval required.
3. The Foundation for Cross-Connection Control Research has recentlychanged the field test requirement, before granting full approval, from
a three-year test to a one-year test with more frequent inspection. If
you currently require full or provisional approval will you:
t
( ) accept all devices approved under the new one year testprogram.
( ) accept only those devices previously approved under the
three-year test program.
( ) provide an alternate policy. (Please specify)
A. If devices now in service were previously approved by a certifyingauthority, and if they do not have their certification renewed, or if
it is rescinded by that authority, what will your policy be?
( ) Replace these devices at the earliest possibility with anapproved device.
( ) Replace these devices at the first sign of malfunction withan approved device.
( ) Accept the device as originally approved.
( ) Other policy. (Please specify)
5. The cost of purchasing and installing a backflow prevention deviceis borne by the:
( ) water utility.
( ) customer.
80
6. Please list the manufacturer, model, and size of reduced pressureprincipal backflow preventers which have been installed in your watersystem. Reduced pressure devices have been used for how many years?
Manufacturer Model Size No. Installed
7. Please indicate your maintenance and inspection policy regardingreduced pressure principal devices.
i. Frequency of inspection
b. Frequency of scheduled testing
c. Frequency of scheduled maintenance
d. Work required during scheduled maintenance
e. Wh.o performs inspection
testing
maintenance
f. Who pays for inspection
testing
maintenance
8. Please describe any malfunctions, failures, or problems encounteredwith reduced pressure preventers, including the make, model, and sizeof unsatisfactory units, the date of installation, and length ofoperation before malfunction.
81
9. Repeat question 8 for double-check valve assemblies.
10. Is freezing a problem in your area?
How are these units protected from freezing?
What are the effects from freezing on reduced-pressure devices and
double-check valve assemblies?
11. Do you foresee any changes in your existing backflow prevention
policy in the near future?
12. Other comments. (Please attach a copy of any regulations
applicable to this survey.)
82
10.3 Procedures for a National Voluntary Laboratory AccreditationProgram.
The National Voluntary Laboratory Accreditation Program waspromulgated by the publication of procedures in the Federal Registeron February 25, 1976. It was stated that the goal of this programis to provide in cooperation with the private sector a nationalvoluntary system to examine upon request the professional and tech-nical competence of private and public testing laboratories thatserve regulatory and nonregulatory product and certification needs.The program is also intended to accredit those laboratories thatmeet the qualifications which will be established under theseprocedures
.
The program has been set up as Part 7 of Title 15 inCommerce and Foreign Trade. For this reason the document is
divided into eighteen sections numbered from 7.1 through 7.18.
Because some of the sections are quite lengthly and tedious to
read, a format with sidenotes has been chosen for the presentationof Part 7 in this paper. Also the format incorporated the follow-ing arrangements
:
1. The first line of the first sentence in a paragraph isindented
.
2. Subsequent sentences in the same paragraph are not indentedbut, after a line space, begin at the margin.
3. A small circle marks the location of each sentence and a
dash through a circle represents supporting statements orphrases for a previous sentence.
4. Where sentences are long, the ideas are separated bybreaking the line and continuing after a single line space.
83
7.1 Purpose
The purpose of this part is to establish proceduresunder which a National Voluntary Laboratory AccreditationProgram will function.
7.2 Description and goal of program
7.2(a)This system wouldexamine competenceof testing laboratories
This program establishes a national voluntary system thatwould examine the professional and technical competence oftesting laboratories that serve regulatory and non-regulatoryproduct evaluation and certification needs.
Laboratories that meetqualifications wouldbe accredited
o Laboratories that meet the qualifications established pursuantto the procedures set out below would be accredited.
Periodic checks andexaminations will berequired
This program will also require those laboratories that areaccredited to maintain their qualification status throughperiodic checks and examinations.
7.2(b)Program will makemaximum use of all
existing activities
o The program will seek through coordination and consul-tation, to maximize benefits derived from other laboratoryexamination and accreditation activities.
Would avoidduplication of
other programs
In this way, it is intended that the program will avoidduplication of other laboratory examination or accredi-tation programs conducted by the public and privatesectors.
Secretary will insureclose coordinationand consultation
To this end, the Secretary will insure that close andcontinuing coordination and consultation is undertakenand maintained with interested representatives of Federal,State and local governments and of the private sector,including those from professional and trade associationsand societies.
7.2(c)To serve needs of
industry, consumersand the Government
The intended goal of this program is to serve, on a
timely basis, the needs of industry, consumers, the Government,and others by accrediting this nation's testing laboratories.
To promote technicalcompetence
The achievement of this goal would be sought by fosteringand promoting a uniformly acceptable base of professionaland technical competence in testing laboratories
To establish a
background of
experience
and by establishing a background of experience necessaryto the orderly evolution of a laboratory accreditationsystem designed to serve national needs as they develop.
7.3 Definitions
7.3(a)Secretary
The term "Secretary" means the Secretary of Commerce or
his designee.
7.3(b)Product
The term "Product" includes the plural thereof and meansa type or a category of manufactured goods, constructions,installations and natural and processed materials or thoseassociated services whose characterization, classification orfunctional performance determination is specified by standards.
84
The term "Criteria Committee" means a National LaboratoryAccreditation Criteria Committee appointed by the Secretaryunder these procedures.
The term "person" means associations, companies, corpora-tions, educational institutions, firms, government agencies at
the Federal. State and local level, partnerships and societies,as well as divisions thereof, and individuals.
The term "testing laboratory" means any "person," asdefined above, whose functions include testing, analyzing or
inspecting "products," as defined above, and/or evaluating thedesigns or specifications of such "products" according to the
requirements of applicable standards.
The term "general criteria" means those characteristicsof a testing laboratory commonly found in, and generallyexpected of, such a laboratory serving the product underconsideration. See in this connection Sec. 7.7(a).
The term "specific criteria" means those detailedrequirements deemed essential to assuring an acceptableexamination and evaluation of the testing function performedby a testing laboratory in performing specific tests relatedto identified standards for the product under consideration.See in this connection Sec. 7.7(a).
.4 Finding of need to accredit testinglaboratories
.
Any person may request the Secretary to find that thereis a need to accredit testing laboratories which renderservices regarding a specific product so that it may beascertained whether such product meets the requirements of
applicable standards.
Such a request shall be in writing and will include thefollowing:
& (1) Identification of the product;
i (2) Text of an applicable standard;
& (3) Text of a test method, if not included in the
applicable standard identified in paragraph (b)(2)of this section; and
i (4) Basis of need for accrediting testing laboratoriesthat serve the product identified in paragraph (b) (1)
of this section.
<b The basis will provide information relative to the itemsset out in Sec. 7.5 and will include, where appropriate,documentary evidence on such items as:
(i) the number of testing laboratories that is believedwill want to be accredited to serve the productidentified in paragraph (b)(1) of this section; and
(ii) the number of users of testing laboratories thatis believed will desire services of testing laboratoriesaccredited to serve the product identified in paragraph(b)(1) of this section.
85
7.4(c)Secretary may ask
for more information
Secretary maydecline to act
upon the request
Secretary mustrespond in 10
working days
7.4(d)Should a request be
made that may affect
accreditation programof a Federal agency,
Secretary shall seek
views of such agency.
Should the affectedagency object in
writing within 30
days, the Secretaryshall cease further
actions
And the Secretaryshall notify the
requester of suchactions
o The Secretary may ask for more information to support
a request made under paragraph (a) of this section if he
feels it is necessary to do so.
o If on the basis of the information provided or because of the
lack of resources, the Secretary is unable to justify the
making of a preliminary finding of need, he will decline to
act further on the request.
o The Secretary shall in that event notify the requester in
writing within ten (10) working days after making a decisionand shall state the reasons for so declining.
o If a request received under this section is believed to
affect an existing or developing testing laboratory examination
or accreditation program of a Federal regulatory agency, the
Secretary shall seek from the head of such agency its views
relative to the Secretary's making a preliminary finding of
need.
o If within thirty (30) days after receipt of the Secretary's
solicitation of views, or such extension of time as may be
agreed to by the Secretary, the head of the affected Federal
regulatory agency explains, in writing, his objections to the
Secretary's making a preliminary finding of need, the
Secretary shall cease to act further on the making of such
finding.
o In that event, the Secretary shall notify the requestorof such objections and of his declination to act on the
request pursuant to paragraph (c) of this section.
7.4(e)Should Secretary find
that a need existshe will publicize in
the Federal Register
and provide at
least 30 daysfor written comments
o If, on the basis of the information provided to him, the
Secretary finds that a need exists to accredit testinglaboratories that serve a specific product, he shall publisha notice in the Federal Register indicating that such findingis a preliminary finding.
The notice shall include a statement as called for in Sec. 7.
5
as to the basis for the Secretary's finding and shall provideat least a thirty (30) day period for the submission of writtencomments thereon.
Should a publichearing be held,time for writtencomments shall beextended to
hearing date
7.4(f)
Persons desiring to beheard shall notify the
Secretary in 15 days
If requested, informalhearings will be heldfor oral presentations
In the event that a public hearing or hearings are held onthis preliminary finding as authorized under paragraph (f)
of this section, the period allowed for the submission ofwritten comments shall be extended to the date on which suchhearing or hearings are held.
Interested persons wanting to express their views in aninformal hearing shall notify the Secretary of that desirewithin fifteen (15) days after the notice is published inthe Federal Register.
Upon receipt by the Secretary of such request, informalpublic hearings shall be held so as to give all interestedpersons an opportunity for the oral presentation of data,views, or arguments, in addition to the opportunity to makewritten submissions.
86
If appropriatehearings may be
held at two places
with notice publishedin Federal Register
All comments will
be on file in the
Commerce Building
o If deemed appropriate by the Secretary, such hearings may beheld at two locations, one of which shall be east of the
Mississippi River and the other west thereof.
o Notice of such hearings shall be published in the FederalRegister at least twenty (20) days in advance thereof.
o A transcript shall be kept of any oral presentation.
i (1) All written and oral comments will be filed in
the Central Reference and Records Inspection Facility,Room 7068, Commerce Building, 14th Street between E Streetand Constitution Avenue, N.W. , Washington, D.C. 20230,and will be available for public inspection at thatlocation.
7.4(g)By a notice in the
Federal Register theSecretary shall makea final finding of need
or shall withdraw hispreliminary finding
And shall state the
basis for such finding
After evaluating the comments received, the Secretaryshall publish a notice in the Federal Register making a
final finding of need or withdrawing his preliminary finding
of need to accredit testing laboratories that serve a
specific product.
The notice shall state the basis for the Secretary's finalfinding of need or for the withdrawal of his preliminaryfinding.
7.4(h)If notice sets out
the final finding of
need, it will include:
(1) identification of
product
(2) identification of
standards and test methods
(3) statement that
separate notice in FederalRegister will advise that
a NLACC will be formed or
else an existing criteriacommittee will be used
o The notice published under paragraph (g) of this section,if it sets out the Secretary's final finding of need, willalso include:
(1) Identification of the product for which testinglaboratories will be accredited to serve;
(2) The identification of applicable standards,including the test methods involved; and
(3) A statement that the Secretary is publishingsimultaneously with this notice,
a separate notice inthe Federal Register advising that pursuant to theprovisions of the Federal Advisory Committee Act (Pub.L. 92-463, dated October 6, 1972) the Secretary willform a National Laboratory Accreditation CriteriaCommittee pursuant to Sec. 7.6
or will utilize an existingCriteria Committee previously established under thatsection.
Such separate noticewill state duties of
Committee, its size andbasis for selection of
committee members.
Except where the Secretary utilizes an existing CriteriaCommittee such separate notice will outline the functionsand duties of the Committee, its size, and the basis forselection of the members thereof.
87
7.5 Statement of the basis for a pre-liminary finding of need.
Basis for preliminaryfinding of need are:
o The statement setting forth the basis for the preliminary findingof need referred to in Sec. 7.4(e) shall as a minimum addressthe following items:
7.5(a)The establishment of
criteria must benefitpublic interest
7.5(b)A National need extends
beyond that served byany existing program
7.5(c)An existing productstandard is deemedsuitable by the
Secretary
7.5(d)Existing testingmethodology is
determined by the
Secretary to bevalid
Whether the establishment of general or specific criteriaand other conditions for accrediting testing laboratoriesthat serve a specific product would benefit the public interest
Whether there is a national need to accredit testinglaboratories for the specific product involved beyond thatserved by any existing laboratory accreditation programs in
the public or private sector;
Whether for the specific product involved, there is in
existence a standard that is deemed by the Secretary as beingof importance to commerce, consumer well-being, or the publichealth and safety;
Whether there is in existence a valid testing methodologyas determined by the Secretary for ascertaining conformity to
to the standard of the specific product involved; and
7.5(e)Secretary determinesthat accreditationis feasible and
practical
o Whether it is feasible and practical to accredit testinglaboratories that serve the specific product involved.
7.6 Establishment and functions of a NationalLaboratory Accreditation Criteria Committee.
7.6(a)When the Secretaryestablishes a CriteriaCommittee he will:
o The Secretary will establish a Criteria Committee andappoint the Chairman and members thereto following:
(1) publish a noticein the Federal Registeraccording to Sec. 7.4(h)(3)
(2) and file a chartersetting forth purposeand nature
(1) Publication of the separate Federal Registernotice referred to in Sec. 7.4(h)(3) that announces the
Secretary's intention to form a Criteria Committee,as
distinguished from an announcement of intent to utilizean existing committee; and
(2) The filing of a charter setting forth the purposeand nature of the Criteria Committee.
7.6(b)Membership of CriteriaCommittee is chosenbroadly from interestedgroups
The membership of the Criteria Committee will be composedof employees of the Department of Commerce, other Federalagencies, and qualified representatives chosen from amongproducers, distributors, users, consumers, testing laboratoriesacademia, and general interest groups,
including State andlocal governmental bodies and agencies affected by theSecretary's finding of need to accredit testing laboratoriesserving a specific product.
88
Equitable balance of
members that representall interested groups
7.6(c)Criteria Committeeshall be governedby the Federal AdvisoryCommittee Act
The membership of each Criteria Committee shall be selectedso as to provide an equitable balance that represents theinterests affected by the Secretary's finding of need.
The establishment and functioning of each CriteriaCommittee formed and utilized by the Secretary under theseprocedures shall be governed by the applicable provisionsof the Federal Advisory Committee Act, cited earlier herein.
Committee members maybe paid per diem andtravel expenses
7.6(d)
Criteria Committee willdevelop and recommendcriteria to the Secretary
Secretary will definea time period fordevelopment of criteria
7.6(e)
Criteria Committee mayconsult with otherpublic and privateparties to developcriteria
Persons selected to serve on a Criteria Committee may be paidtravel expenses and per diem, provided authorized travel isinvolved.
Upon formation of the Criteria Committee, the Secretarywill request it to develop and recommend to him general andspecific criteria to accredit testing laboratories that servea specific product.
The Secretary, in a written communication to the Chairman of
the Committee, shall designate a time period for thedevelopment of general and specific criteria.
When developing general or specific criteria, the CriteriaCommittee may, where it deems such action to be appropriate,consult with other interested public and private parties,including Federal, State and local agencies and privatestandards bodies.
and evidence of suchconsultation will bemade a matter of publicrecord.
Exchanges of correspondence, memorandums and other evidenceof such consultation will be made a matter of public record.
7.7 Development and recommendation ofcriteria for accrediting testinglaboratories
.
7.7(a)Secretary and CriteriaCommittee will beguided in Criteriadevelopment by factorssuch as these:
o The Secretary, and the Criteria Committee acting at therequest of the Secretary, in developing general and specificcriteria to accredit testing laboratories that serve a specificproduct shall consider factors such as:
4 (1) For general criteria pertaining to testinglaboratories
:
for general criteria (i) Organization;(ii) Staff:
(iii) Physical plant;(iv) Operational processes;(v) Control procedures;
(vi) Quality assurance; and(vii) Professional and ethical business
practices, as appropriate.
(2) For specific criteria pertaining to testinglaboratories
:
and for specific criteria (i) Personnel and equipment qualificationsrequired of the testing laboratory function;
(ii) Requirements applicable to proficiencysample programs;
89
7.7(b)Criteria in existingstandards will be used
when appropriate, but
where none are found
Criteria Committee will
undertake development of
criteria
7.7(c)Instructions for makingapplication shall be
included in criteriatogether with conditions
to be followed in the
program:
(1) examination and audit
(2) payment of fees
(3) limitation on
advertising
(iii) Application requirements;(iv) Initial and periodic examination and audit
procedures; and(v) Professional and technical qualifications of
personnel who examine testing laboratories.
o The general and specific criteria developed under thissection for accrediting testing laboratories will be basedupon criteria found in existing standards where such existingcriteria are deemed appropriate.
o Where appropriate existing criteria cannot be found, theCriteria Committee will, at the request of the Secretary,undertake to develop and recommend to him such appropriategeneral and specific criteria as may be needed.
o The criteria shall contain instructions for makingapplication by testing laboratories serving the productinvolved and
shall require that each testing laboratorythat desires to participate in this program must agreeto conditions that include but are not limited to the
following
:
& (1) Be examined and audited, initially and on a
continuing basis;
i> (2) Pay accreditation fees and charges; and
4 (3) Avoid reference by itself and forbid othersutilizing the services of an accredited testinglaboratory from referencing its accredited statusin consumer media and in product advertising or on
product labels, containers and packaging or thecontents therein.
7.7(d)Accreditation by thisprogram does not relievelaboratories fromobserving any existingstatutes, or regulations
7.7(e)
This section does not:
(1) prohibit accreditationsolely on basis of
organizational associationor for being a foreign firm
(2) provide for developmentof product standards or
test methods
The criteria shall contain a statement that complianceby testing laboratories with the general and specificcriteria and other conditions established by the Secretaryand which are accredited by him under these procedures
shall in no way relieve such laboratories from the necessityof also observing and being in compliance with any existingFederal, State and local statutes, ordinances, and regulationsthat may be applicable to the operation of such laboratories,including consumer protection and anti-trust laws.
In carrying out the activities authorized by thissection
:
6 (1) No action will be taken or criteria developedthat would prohibit the accreditation of a testinglaboratory solely on the basis of that laboratory'sassociation or nonassociation with manufacturing,distributing or vending organizations,
or because thetesting laboratory is a foreign firm;
4 (2) No action will be taken under this program to
develop a product standard or test method standard;
90
(3) establish proceduresto modify a product standardor a test method standard
(4) propose to promulgatecriteria considered to
be impractical or contraryto the public interest
(3) No action will be taken under this program to
modify a product standard or a test method standardwhere such a standard is in existence;
(4) No general or specific criteria will be promul-gated unless compliance with such criteria and itsimplementation has been determined by the Secretary tobe feasible and practical and not contrary to thepublic interest ; and
(5) want or accept businessdata, trade secrets, etc.
7.8(a)Criteria Committee shallforward its recommendationsto the Secretary
f> (5) The Secretary, under this program, will not askfor or accept confidential business data, trade secretsor other proprietary information.
7.8 Publication of proposed criteria.
Upon its development of the general and specificcriteria for accrediting testing laboratories under Sec. 7.7,the Criteria Committee shall forward its recommendations forsuch criteria to the Secretary for his consideration.
Secretary will publishit in Federal Register
TheSecretary, after consideration of such criteria will publishin the Federal Register a notice giving the complete text of
7.8(b)Request for a hearingcan be made byinterested personswithin 15 days
o and inviting any interested persons to submit writtencomments on such proposed criteria within forty-five (45)days after its publication in the Federal Register, unlessanother time limit is provided by the Secretary.
o Interested persons wanting to express their views in aninformal hearing shall notify the Secretary of that desirewithin fifteen (15) days after such proposed criteria arepublished in the Federal Register.
If requested, informalhearings will be heldfor oral presentation
Upon receipt by the Secretary of such request, informalpublic hearings shall be held so as to give all interestedpersons an opportunity for the oral presentation of data,views, or arguments, in addition to the opportunity tomake written submissions.
If appropriate,hearings may beheld at two places
with notice publishedin Federal Register
written and oralcomments will befiled and availablefor inspection
o If deemed appropriate by the Secretary, such hearings beheld at two locations, one of which shall be east of theMississippi River and the other west thereof.
o Notice of such hearings shall be published in the FederalRegister at least twenty (20) days in advance thereof.
o A transcript will be kept of any oral presentation.
i (1) All written and oral comments will be filed inthe Central Reference and Records Inspection Facility,Room 7068, Commerce Building, 14th Street between EStreet and Constitution Avenue NW. , Washington, D.C.20230,
and will be available for public inspectionat that location.
91
7.8(c)
Criteria Committeewill evaluate comments
and make recommendationsto the Secretary
Secretary will act
upon the CriteriaCommittee's recommen-dations in one of
three alternatives:
o The Secretary upon receipt of all written and oralcomments will request the Criteria Committee to conductand return to him in writing, within a time period specifiedby the Secretary, its evaluation and recommendations withrespect to such comments.
o After considering the Criteria committee's evaluationand recommendations, the Secretary will prepare his evaluationand publish in the Federal Register a notice;
(1) to announce the
final general and
specific criteria <
(1) Announcing the final general and specificcriteria that testing laboratories must meet in orderto be accredited and the date when such final criteriashall go into effect which shall not be less than thirty
(30) days after the date of publication of such notice;
(2) to postpone action
for further development(2) Stating that the proposed general and specific
criteria will be further developed before finalpublication; or
(3) to withdraw the
criteria fromconsideration
(3) Withdrawing the proposed general and specificcriteria from further consideration.
7.9 Coordination with Federal agencies,
7.9Secretary will consult
with interested Federal
agencies for meaningfulcooperation
As a means of assuring effective and meaningfulcooperation, input, and participation by those Federalagencies that have an interest in and may be impacted
by the laboratory accreditation program carried out underthese procedures,
the Secretary shall undertake to
communicate and consult with appropriate officials at
policy making levels within those agencies.
Opportunities for
Federal agencyrepresentatives to
serve on CriteriaCommittees
These coordination efforts will include opportunities forrepresentatives designated by those agencies to serve oneach Criteria Committee established by the Secretary inwhich those agencies have an interest.
7.10 Establishment of fees and charges.
7.10(a)Secretary shallestablish fees and
charges for examining,accrediting and
auditing
Fees shall be calcu-lated to maximize the
self-sufficiency of
the accrediting program
Notice in the FederalRegister will givecriteria of Sec. 7.8(a)
o The Secretary in conjunction with the use of theWorking Capital Fund of the National Bureau of Standards,as authorized by section 12 of the Act of March 3, 1901,as amended (15 U.S.C. 278b),
for this program shall establishfees and charges for examining, accrediting, and auditingtesting laboratories.
o The fees and charges established by the Secretary, which maybe revised by him when he deems it appropriate to do so,shall be in amounts calculated to maximize the self-sufficiency of this program.
o A separate notice will be published in the Federal Registersimultaneously with the notice of proposed general andspecific criteria referred to in Sec. 7.8(a).
92
and a tentativeschedule of fees
and charges
so that public mayevaluate criteriaagainst fees charged
7.10(b)Upon the announcementof final general andspecific criteriaa separate notice in
Federal Register willlist final scheduleof fees
o Such notice will set out a schedule of estimated fees and
charges the Secretary proposes to establish.
o The notice would be furnished for informational and guidancepurposes only in order that the public may evaluate theproposed criteria in light of the expected fees to be charged.
o At such time as the Secretary publishes the notjceannouncing the final general and specific criteria referredto in Sec. 7.8(c)(1),
he shall simultaneously publish a
separate notice in the Federal Register setting forth thefinal schedule of fees that will be charged testinglaboratories that serve a specific product.
to become effectiveon date criteriabecomes effective
o The effective date of such final schedule of fees shall bethe same as the date on which the final general and specificcriteria are to take effect.
7.10(c)Subsequent revisionsto be published inFederal Register -
to gecome effectivein not less than thirty
(30) days
o Revisions, if any, to the fees and charges establishedby the Secretary under paragraph (b) of this section shallbe published in subsequent Federal Register notices
and shalltake effect not less than thirty (30) days after the dateof publication of such notice.
o Mention of such revisions shall also be published in theappropriate quarterly reports referred to in Sec. 7.17(a).
7.11 Participation of testinglaboratories
.
7.11(a)Each laboratory mayinitiate an applicationfor accreditation
7.11(b)Secretary will notifyapplicant and NBS of
requirements and fees
Each testing laboratory serving a product for whichfinal general and specific criteria have been promulgatedunder Sec. 7.8(c)(1),
and desiring to be accredited underthis program, will notify the Secretary of its desire pur-suant to the provisions of such criteria.
After receipt and evaluation of the testing laboratory'sapplication and information contained therein,
the Secretaryshall, upon the acceptance thereof, notify the applicanttesting laboratory
and the National Bureau of Standards inwriting of the specific applicable examination requirementsfor accreditation and
the fees and charges for suchexamination and accreditation.
Rejected applicant mayreapply after he hascorrected deficiences
Rejected applicant mayrequest a hearing
If the application is not accepted, the Secretary shallnotify the applicant testing laboratory of the reasons forrejection of its application,
and such testing laboratorymay reapply under Sec. 7.13(d) after correcting thedeficiencies set out in the Secretary's notification ofrejection.
Alternatively, the applicant testing laboratory shall havethirty (30) days to request a hearing pursuant to 5 U.S.C.556.
93
Secretary's rejectionwould be stayed until
the hearing
7.11(c)Applicant laboratoriesmust meet general and
specific criteria
7.11(d)National Bureau of
<
Standards, on behalfof Secretary, willarrange for examinationof applicant laboratory
National Bureau of
Standards will assurethat examiners possessqualification of Sec.
7.8(c)(1)
If NBS conducts exam-
ination, the resultingreport will be sent to
the Secretary
If testing is preparedby contractor, NBS willreview it before sendingto Secretary
In the event, however, that the applicant testing laboratoryrequests a hearing within that thirty (30) day period theSecretary's rejection shall be stayed until the hearing heldpursuant to 5 U.S.C. 556.
A testing laboratory desiring to be accredited underthis program to serve the product identified by the Secretaryin his final finding of need under Sec. 7.4(g) in accordancewith the standards and test methods identified by theSecretary in that finding must meet the general and specificcriteria promulgated by him.
Upon receipt by the National Bureau of Standards of the
applicant testing laboratory's written request for examinationand of the fees and charges specified in paragraph (b) of
this section,the National Bureau of Standards on behalf of
the Secretary, will arrange for by contract or will itselfconduct, the examination requirements of the Secretary.
In all cases where testing laboratories are examined, the
National Bureau of Standards will assure that the personnelused by the contractor
or by the National Bureau of Standardspossess the professional and technical qualifications set out
in the specific criteria promulgated under Sec. 7.8(c)(1).
If the National Bureau of Standards conducts the examination,the resultant examination report will be forwarded to the
Secretary.
In cases where the examination report was prepared by a
contractor, the National Bureau of Standards, before makingpayment thereunder
or forwarding the report to the Secretary,will review the report to assure that the contract termshave been fulfilled.
7.11(e)Secretary will grant
or propose to denyaccreditation within20 working days afterreceiving report.
or will notifyapplicant in writingwith reason for delay
Secretary's determinationof status will be givenin writing
and if he proposes to
deny the accreditationhe will state reasons
The Secretary, after reviewing the examination reportfurnished under paragraph (d) of this section, will make a
determination granting orproposing to deny accreditation
to the applicant testing laboratory, not later than twenty(20) working days following the date on which the reportis received by him.
If the determination is not made within such time limit, theSecretary shall notify the applicant testing laboratory in
writing of the reasons for the delay.
Upon making his determination, the Secretary will notifythe testing laboratory in writing of its accreditationstatus
.
If the Secretary proposes to deny accreditation to anapplicant testing laboratory, the notification will statethe reasons for such proposed denial.
94
7.11(f)and the applicantshall have thirty
(30) days fromreceipt of noticeto request a hearing
If appeal is not
made in requiredperiod the Secretary'sproposed denial will be
made final in a writtennotification
o If an applicant testing laboratory is notified by the
Secretary that he proposes to deny accreditation, the testinglaboratory shall have thirty (30) days from the date ofreceipt of such notification to request a hearing under theprovisions of 5 U.S.C. 556.
o The Secretary's proposed denial shall become final throughthe issuance of a written decision to the applicant in theevent that the applicant does not appeal such notificationby the end of that thirty (30) day period.
However, if hearingis requested, proposeddenial shall be stayeduntil hearing
o In the event, however, that the applicant testing laboratoryrequests a hearing within that thirty (30) day period, theSecretary's proposed denial shall be stayed until the hearingheld pursuant to 5 U.S.C. 556.
7.12Advertising by the
accredited laboratoryis limited in scope
7.13(a)Secretary may findcause to revoke theaccreditation of a
laboratory
7.13(b)If so notified bythe Secretary suchlaboratory mayrequest a hearing
Revocation wouldbecome final shouldhearing not berequested in 30 days
Should a hearing beproperly requestedthe proposed revocationshall be stayed
7.12 Reference to accredited status.
o Except as limited under Sec. 7.7(c)(3), a testinglaboratory accredited under this program may use the followingstatement on its letterheads and in professional, technicaland trade publications:
i> "Accredited by the Department of Commerce, NationalLaboratory Accreditation Program for (appropriatewording as authorized by the Secretary's notificationunder Sec. 7.11(e))."
7.13 Revocation or termination of
accreditation of a testing laboratory.
o If the Secretary finds that a testing laboratory whichhe has previously accredited has violated the terms of itsaccreditation
or the provisions of these procedures, he may,after consultation with such testing laboratory, notify thattesting laboratory that he proposes to revoke its accreditation.
o Upon receipt of a notice from the Secretary of theproposed revocation, which notice shall set forth the reasonsfor such proposed revocation,
the accredited testinglaboratory shall have thirty (30) days from the date ofreceipt of such notification to request a hearing under theprovisions of 5 U.S.C. 556.
o The Secretary's proposed revocation shall become final throughthe issuance of a written decision to the testing laboratoryin the event that such testing laboratory does not appealthe proposed revocation within that thirty (30) day period.
o In the event, however, that the accredited testing laboratoryrequests a hearing within that thirty (30) day period, theSecretary's proposed revocation shall be stayed until thehearing held pursuant to 5 U.S.C. 556.
95
7.13(c)A laboratory may end
participation with a
written notice to
the Secretary
Receipt of noticewould terminateprocessing of
application
or terminatethe accreditation
when acknowledgedby the Secretary
7.13(d)
A laboratory mayreapply shouldaccreditation be
denied, revoked
or terminated
7.14(a)
Secretary may ceaselaboratory accreditationfor a specific product
Notice of preliminaryfinding in FederalRegister
Shall address thoseitems of Sec. 7.5
covered by originalfinding.
7.14(b)Minimum period of
60 days to submitwritten comments
Should publichearings be heldwritten commentsaccepted up to
hearing date
7.14(c)Twenty (20) daysallowed for therequest for hearing
o A testing laboratory may at any time terminate itsparticipation and responsibilities under this program orwithdraw its application for accreditation by giving writtennotice to the Secretary.
o Upon receipt by the Secretary of such notice, he shall
terminate further processing of the testing laboratory'sapplication for accreditation.
o If such testing laboratory has been accredited, the
Secretary shall terminate that testing laboratory'saccreditation.
o The Secretary shall notify the testing laboratory that its
accreditation has been terminated pursuant to its request.
o A testing laboratory whose application has been rejected orwhose accreditation has been denied, revoked or terminated orwhich has withdrawn its application prior to being accreditedmay reapply for and be accredited if it meets the applicablegeneral and specific criteria promulgated by the Secretaryunder Sec. 7.8(c)(1) and
agrees also to meet the conditions set out under Sec. 7.7(c)
and the provisions of Sec. 7.12.
7.14 Cessation of accreditations.
o The Secretary may cease the accreditation of testinglaboratories that serve a specific product if he finds thatthere is no longer a need to accredit such laboratories.
o An action to cease such accreditations shall commence withthe issuance of a preliminary finding which shall bepublished in the Federal Register.
o Such notice shall set forth the Secretary's reasons for hispreliminary finding and shall,
as a minimum, address thoserelevant items listed in Sec. 7.5 which formed the basis for
his original finding of need to accredit testing laboratoriesserving a specific product.
o The notice published under paragraph (a) of this sectionshall provide at least a sixty (60) day period for the sub-mission of written comments on the Secretary's preliminaryfinding.
o In the event that a public hearing or hearings are held onthis preliminary finding as authorized under paragraph (c) of
this section,
the period allowed for the submission of writtencomments shall be extended to the date on which such hearingor hearings are held.
o Interested persons wanting to express their views in aninformal hearing shall notify the secretary of that desirewithin twenty (20) days after the notice is published in theFederal Register.
96
Public hearingsmay be held to
get views of all
concerned
Hearings may beheld east and westof the Mississippi
Twenty (20) days
advance notice in
Federal Register
o Upon receipt by the Secretary of such request, informal publichearings shall be held so as to give all interested personsan opportunity for the oral presentation of data, views, orarguments, in addition to the opportunity to make writtensubmissions.
o If deemed appropriate by the Secretary, such hearings may be
held at two locations, one of which shall be east of the
Mississippi River and the other west thereof.
o Notice of such hearings shall be published in the FederalRegister at least twenty (20) days in advance thereof.
A transcript shall be kept of any oral presentation.
all records of
hearings will beavailable at
Commerce Building
(1) All written and oral comments will be filed inthe Central Reference and Records Inspection Facility,Room 7068, Commerce Building, 14th Street between E
Street and Constitution Avenue N.W., Washington, D.C.
20230,and will be available for public inspection at
that location.
7.14(d)Notice of Secretary'sdecision shall be in
Federal Register
After evaluating the comments received, the Secretaryshall publish a notice in the Federal Register making a
final finding,or withdrawing his preliminary finding, that
there is no longer a need to accredit testing laboratoriesthat serve a specific product.
together with basisfor his decision
Cessation date shall
be not less than 60
days after publicationof notice
o The notice shall state the basis for the Secretary's finalfinding or for the withdrawal of his preliminary finding.
o If the notice sets forth the Secretary's final finding thatthere is no longer a need to accredit testing laboratoriesthat serve a specific product,
such notice shall also statethe effective date of such final finding which shall not beless that sixty (60) days after the publication of the notice.
7.14(e)
Cessation of accred-itation affects allthose previouslyaccredited for a
product.
If the Secretary ceases the accreditation of testinglaboratories that serve a specific product as provided forin this section, ,
he shall withdraw the accreditationpreviously issued to all those testing laboratories servingthe same specific product.
Such accreditedlaboratory may seekto serve anotherproduct
o Any testing laboratory whose accreditation to serve a specificproduct has been withdrawn by the Secretary under this sub-section may seek to be accredited to serve a different specificproduct under these procedures,
and may be accreditedby meeting provisionsof Sees. 7.7(c), 7.8(c)land 7.12
o and may be so accredited if it meets the general and specificcriteria promulgated by the Secretary under Sec. 7.8(c)(1) thatare applicable to that different specific product
and if itagrees also to meet the conditions set out under Sec. 7.7(c)and the provisions of Sec. 7.12.
7.14(f)Accreditation may bereinstituted by pro-cedures of Sec. 7.4
o The Secretary may reinstitute the accreditation of testinglaboratories that serve a specific product which he previouslyceased accrediting under this section.
97
o In that event he shall follow the same procedures set out
under Sec. 7.4 relative to the finding of need to accredittesting laboratories that serve a specific product.
If the accreditation of a testing laboratory is revoked bythe Secretary under Sec. 7.13, no part of the fees and chargespaid by the testing laboratory will be refunded.
7.15(d)Some fees will be
refunded when theaccreditation ceasesas in Sec. 7.14
If the Secretary ceases the accreditation of testinglaboratories that serve a specific product under Sec. 7.14
and withdraws the accreditation of a testing laboratory to
test a specific product under that section,such testing
laboratory will be refunded the unexpended part of the
examination fees or charges paid by such testing laboratoryto maintain its accredited status under this program:
PROVIDED, HOWEVER, That no such testing laboratory will berefunded its original application fee, if any, to beaccredited to serve a specific product.
7.16 Amendment or revision of criteria.
7.16Provisions are madefor amendments or
revisions to
previously promul-gated criteria
The Secretary, or a Criteria Committee acting at therequest of the Secretary, may undertake the development of
amendments or revisions of any applicable general orspecific criteria previously promulgated by the Secretaryby following the same procedures pertaining to the originaldevelopment of such criteria.
98
7.17 User education and reports.
7.17(a)Secretary will publisha quarterly report of
actions involving eachspecific product
For each specific product for which the Secretary hasmade a final finding under these procedures that a need existsto accredit testing laboratories that serve such product,
hewill publish a quarterly report noting all action taken by himregarding such matters as accreditations, revocations, theestablishment of fees and charges, the promulgation of generaland specific criteria and any amendments or revisions to suchcriteria.
Such report to state
clearly that accredi-tation does not relieve
the laboratories from
any legal responsibilities
Such publications shall clearly state that testing laboratoriesaccredited by the Secretary under these procedures are in nomanner immune from the necessity of being in compliance
withall legal obligations and responsibilities imposed by existingFederal, State, and local laws, ordinances, and regulations,including those related to consumer protection and antitrustprohibitions
.
7.17(b)
Secretary's annualreport shall listall laboratoriesaccredited duringthe year
7.17(c)Secretary shall reportmonthly in the
Federal Register
all actions involvingstatus change
The Secretary will also prepare an annual reportsummarizing all activities carried out under these procedureswhich shall include a listing of all testing laboratoriesaccredited by the Secretary during the year to which theannual report relates.
As a means of giving prompt notice to the public of
accreditation actions taken by the Secretary, he shall, in
addition to the reports called for under this section,publish
in the Federal Register all actions taken by him during thepreceding month which grant, revoke, terminate or result inthe withdrawal of the accreditation of a testing laboratory.
with name and addressof laboratoriesconcerned
Such notice shall include the name and address of the testinglaboratory concerned, and a brief explanation of the actiontaken by the Secretary with respect to that laboratory.
7.18 Support function.
Secretary shallprovide necessarysupport
o The Secretary shall make provisions for administrativeand technical support and staff services as may be needed tocarry out this program.
99
10.4 Hose Connection Vacuum Breaker Tests at NBS
A test was conducted to see how the HCVB would respond tosimultaneous back-siphonage and back pressure (due to garden hoseelevation) when the check valve was fouled with a wire in the mannerpresented in ASSE standard No. 1011 for the back-siphonage testmethod
.
10.4.1 Test Procedure and Results
The basic test procedure was as follows and as depicted in
figure 5
:
(a) Fill Pail "A" to some level (measured from the floor)
as shown in setup #1, figure 5. (Pail "A" simulatesa contaminated source - swimming pool)
.
(b) Weigh Pail "B" (tare weight) on weighing platform shownin figure 6, Appendix 10.5 (Water flows out of the ventports down the outside of the hose and into Pail "B")
.
(c) Open spring loaded hose nozzle submerged to bottom ofPail "A".
(d) Open vacuum valve "C" (make sure Pail "B" is dry) . Thepurpose of Pail "B" is to collect vent port discharge.
(e) Simultaneously open quick-closing valve "D" and start
time interval recorder
.
(f) Read vacuum manometer and record vacuum (absolute value)
(g) When the sight glass is half full with water, shut valve"D" and simultaneously stop time interval recorder.(Water collected in the sight glass is backflow)
.
(h) Weigh Pail "B" to get weight of water plus weight ofbucket
.
(i) Remove the hose from HCVB and blow water (compressed airfrom sight glass through HCVB into a graduated cylinder(milliliters) . Record the volume of water as milliliterof back-siphonage
.
For each setup shown in figure 5, make triplicate runs.
100
101
The average results are presented in Table 12 . The averagevacuum was 11.7 centimeters of mercury, absolute. The above averagerate results were quite repeatable even though vacuum fluctuations ofabout + 2 cm of mercury occurred sporadically throughout each run.The last observed vacuum reading before closing valve "D" was recordedas the running vacuum and these values were averaged. This variationis judged to be normally caused by water movement through the atmo-spheric vents of the HCVB. Water movement being somewhat variablesince air is attempting to enter the vents simultaneously as watertends to escape.
10.4.2 Discussion of Results
Even though vacuum varied somewhat, the back-siphonage ratetended to remain quite constant. The volumes collected generallywere several hundred milliliters and these volumes tended to be repeat-able within + 20 milliliters during any set of three runs for a givensetup. Out of fifteen runs only one run was off by + 50 milliliters.The back-siphonage rate did not vary appreciably with increasing backpressure condition. The device is designed to relieve back-pressurethrough the ports and data shows that it does this quite effectively.Although back-siphonage rate remained relatively constant with in-
creasing back pressure, the vent discharge increased considerably as
back pressure head was increased. A constant back-siphonage rateindicated that back pressure at the HCVB must be relatively constantregardless of the back pressure head potential imposed by the elevatedhose
.
102
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103
10.5 Reduced-Pressure Backflow Prevention Device Tests at NBS
A test was conducted to determine if the RPBD would allow back-siphonage, when checks were fouled with wires in the manner used for
testing vacuum breakers.
10.5.1 Test Procedure and Results
The basic test procedure was as follows:
(a) Mount the device in its normal operating position as
recommended by the manufacturer, using test setup shown in
Figure 6.
(b) Apply water pressure to the device and conduct the three
tests described in AWWA publication No. S106, pages 21 and22 [34] to determine that the checks are tight and that therelief valve is functioning according to specifications.
(c) With check valve seats fouled with 0.042 inch diameter wire,
apply vacuum to the inlet and back-pressure to the outletof the device simultaneously. (Down stream check appearsto be open more than 0.042 inches because of its design).
(d) Measure zone pressure in inches of water column and record.
(e) Read back pressure at pressure gage P and record reading.
(f) With start of the run referenced to the initial applicationof vacuum, time the run for an interval of 60 to 70 secondsand close inlet and outlet valves simultaneously.
(g) Measure the volume of backflow (back-siphonage) collectedduring the time interval and also the weight of water inthe zone discharge. Calculate flow rates in gpm.
(h) Tabulate results as follows:
RUN VOLUME OF
# BACK-SIPHONAGECOLLECTED - ml
130
125
110
TIME TO
COLLECT- Sec.
60
70
70
BACK-SIPHONAGERATE
- gpm
0.034
0.028
0.025
104
rOPEN TO ATMOSPHERE
INCHESSCALE
,PIEZOMETER TUBEFOR MEASURINGZONE PRESSURE
FOR CONNECTIONTO DRY COMPRESSED ^^z£><]=AIR FOR FORCE DRAINAGEOF SIGHT GLASS
MILLILITER GRADUATEDCYLINDER TO MEASURE /VOLUME OF BACKFLOW /COLLECTED /
UPSTREAM SIDE OF RPBDUPSTREAM CHECK FOULED WITHA 0.042 IN. DIA. WIRE (paper clip)
UNDER SEATS
DISCHARGE FROM ZONEVIA PIPE ELBOW
WEIGHTING TANKANDWEIGHING PLATFORM
I I I I I
777777777777DIGITAL READOUT OFWEIGHT COLLECTED
VENTURI FORMEASURING RATE
OF WATER FLOWINTO THE RPBD
+777777?ELECTRIC TIMER FORDETERMINING RATE OFBACKFLOW AND ZONEDISCHARGE RATE
Figure 6. A Diagram of Apparatus Used in the Testing of the Reduced-
Pressure Backflow Prevention Device.
105
The average of three (3) runs of data are as follows:
(a) 1.85 gpm backflow rate (also zone discharge rate for allpractical purposes). Well below the rate specified in thestandards for a 3/4" safe RPBD.
(b) 0.029 gpm back-siphonage rate (rate into inlet of thedevice)
.
(c) Zone pressure one (1) inch of water column.
(d) Backpressure 1.31 psig (36 1/4" head).
(e) Vacuum, 11 centimeters of mercury absolute (at inlet duringback-siphonage)
.
10.5.2 Discussion of Results
The relatively low backflow rate appeared close to the cutoffcondition when backflow would not occur (not exactly defined since suchinformation would serve no useful purpose at this time because the pur-pose was merely to test at some reasonable condition). The rubbercheck material tended to seal itself around the fouling wire and back-siphonage rate decreased with time. Unfortunately, it was beyond thescope of this effort to investigate this phenomenon. It was noticedthat backflow rate tended to fall off with time after initial instal-lation of the fouling wires. The preceding backflow data illustratesa slight change and trend during the runs. The three runs were takenin about one hour (approximately 20 min./run).
After the device had been idle for several weeks with foulingwires in place, it was noticed that only about 10 ml was collectedduring a one minute period. The short term effect (one hour) appearsto be the seating of the soft rubber upstream check valve materialaround the wire (self repairing, sealing tendency). The long termeffect (several weeks) appears to be the self repairing tendency plusthe effect of wire diameter reduction caused by corrosion. Afterseveral weeks the wire diameter was reduced to about 0.020 inchdiameter in that portion under the seat of the upstream check. It wasnot determined if complete sealing would result in time due to theseating effect. Some reduction in backflow rate must have occurreddue to reduction in wire diameter.
106
The flow rates imposed on the zone were well below the value set
in the RPBD standards (five gpm^. Zone pressure with or without back-siphonage were well below the 1.5 psig maximum allowed by the RPBDstandards (appeared to be the same with or without vacuum at inlet to
the RPBD). Zone pressures and flow rates were checked as follows:
ZONE FLOW RATE
1.85 gpm4.27
4.88
BACK PRESSURE
1.3 j>sig
2.55.0 '
ZONE PRESSURE
1" of water2.5" of water4.0" of water
At the end of the test, the fouling wires were removed and thedevice tested in the usual field test manner using a differentialgage .8/ The test was conducted with 60 psig of water pressure. Theopening differential pressure of the relief valve was 6.5 psig whichwas the same as that obtained at the beginning of the test. This test
and zone pressure tests demonstrated that the device was operating ina satisfactory manner.
The reason why backf^ow took place is simply that the zone wasfull of water at a pressure superior to that at the inlet, and theinlet was separated from £he zone by the leaking check which allowedwater to flow from the high pressure zone into the low pressure inlet.One of the basic problems is that water flowing from the relief valveport blocks air that tends to enter the zone to vent the vacuum in theinlet. In other words, this RPBD acts like a submerged vacuum breaker.If it had adequate zone shape and configuration with independent zoneventing and drainage such that the air inlet was not submerged and theupstream check were exposed only to the entering air during back-siphonage
, backflow of the liquid would be prevented.
8/
The differential gage was a special manufactured kit especiallydesigned and sold for use with RPBD.
107
10.6 Analysis of Test Methods in ASSE Standards for BackflowPrevention Devices
While seeking a means of evaluating the tests methods thatapply to existing standards for backflow protection devices, it wasnoted that the recent ASSE Standards could be analyzed into
:
(a) Test requirement
(b) Test Setup and Preparation for Testing
(c) Test Procedure
(d) Observations , Records , and Computations
(e) Basis for Rejection of Device
The results of such analyses to the ASSE Standards 1001,
1002, 1011, 1012, 1013, 1015 and 1020 are documented herewith ontables 13 through 19. A uniformity of style has become establishedwith the more recent output. The uniformity of style or format is
sharply defined in table 20 wherein the numerical sequence ofparagraph of ASSE 1013 were matched with comparable subject matter(where possible) to be found in ASSE 1001, 1011, 1012, and 1015. Suchanalysis is expected to be helpful in the development of criteria.
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133
Table 20 Descriptive Cataloging of Five Backflow Prevention Devices Indexed
to Comparable Paragraphs of the Respective A.S.S.E. Standards
A.S.S.E. No. 1001
October, 1970
2.6Claused in this group of
devices ere only those
that perforin the single
function of back-3lphona».;e
preventlon;not included
are the atmospheric types
ueed In conjunction with
other controls(such as on
antl-slphon ballcocf.) or
vacuum relief valve6.
U.lt
The basic function of the
device is accomplished by
ans of a check valve
and an air relief valve.
2-3It is designed to operate
only on the discharge side
of a control valve.
3.7.5It must not leak or spill
water even under condi-
tions of minimum flow and/
or flow pressure.
1.2It must be Installed with
the C-I-L point at least6" above the flood level
rim of the receptacleserved.
Pine Api-lted Atn.iSK.erK
Type Vacuum Srenxers
llor.o ConnectionVacuum Hreaxera
U.5 and Fig. 2
Sites 'are 1/6" , l/V ,1/2"
,
3/V,l",l-l/V, 1-1/2",
2", 2-1/2", 3" and V.
3.2.1 and 3-2-2Devices for cold water
supply lines only have a
working temperature range
from 32*F to 110°F. For
use with either hot or
cold water the temperature
range Is from 32*F to 212
*F.
3.2 and U.2
The hydrostatic workingpressure is 125 pel
.
3-1The entire assembly shall
be certified by the manu-
facturer to be of nontoxlmaterials, when used withpotable water.
3.2.1. and U.2
Must withstand 3 ten-min-ute hydrostatic teats at
3C*F and also 3 ten-min-ute tests at 110'F for
cold water service at 1^5
pel.
A.3.3.B. No. 1011
June, 1970
1.1.1The desl-'n ami-races a
check valve na.-D.ijer foroe-
louded.or biased, to a
closed position and an
atmospheric vent valve,
or means, force-loaded to
an open position when the
device is not under
pressure.
1.1.2The device is intended for
the protection of the po
.able water supply against
contaminants which could
otherwise enter the water
system by back-slphonage
cr bock-pressure backflow
through the hose-threadedoutlets.
1.1.1It is designed to be in-
stalled on the discharge
side of the control valve
ForewordTo be effective it must be
so Installed that the air
ports connot be submerged
1.2.2The two sizes have 3/Vand i" hose connection
threads.
1.2.1 and 2.1.10
It must be suitable for
both he. and cold water
service. The working temp-
erature range is i2°F to
190°F.
1.2.3The ™-iri-iinini working pres-
sure is 125 psl.
1.3.1All material in contactwith t!.e water flowing
through the device whichcan, in any way, contami-
nate the water so that it
may be Injurious to per-
sons consuming It, are
prohibited
L'OCkl'low Preventer j
wi tii Interaetllata
A.3.3.E. No. 1012
May, 1972
1.1.1.1Such devices r.ave two in-
dependently cieratiivcneck valves separate.: by
an lntercediate chaxcerwitli a means :'or eutcr.a-
tlcally ventliug it tc the
atmosphere. The checkvalves are force loadei to
a normally-clcsed positionand the venting means Is
force loaded to a norr-al-
ly-open position.
1.1.2Should not be used fcr
building Isolation, but
may be used back-pressurebackflow and/or back-si-phonage involves contam-inants of low hazard.
1.1.1.1The device can operate un-
der continuous :>r inter-mittent pressu-j condl-tlons.
1.7-1It must not be '. stalled
In a concealed i • inacces-
sible location whereventing of watt! would be
objectionable, t
1.1.1.2Inlet and cutlet
;lpe
sizes are l/V,\(?",
1/2", and 3/V-
1.1.1. It
The temperatureU0*F to 220*F.
2.1.1Must withstand for a 5-
mlnute period a hydrosta-tic test of ^ tlacs therated working pressure.
1.1.1.1Tne device consists of twolndeper iently actim; checkvalves Internally force-loaded to a normallyclosed position and sepa-rated by an lntercediatechamber or zone In whichthere is an automatic re-lief means for venting toatmosphere. Such means isinternally force-loaded to
a normally-open position.
Foreword and 1.1.1.1It is designed primarilyfor the prevention ofbackflow due to back pres-
sure and to operate undercontinuous pressure condi-
tions.
Foreword of A.S.S.E. 1012The device is consideredto be the best availablefor building isolationor for high health hazardconditions
1.3-7The design must incorpo-rate provision for bleed-ing trapped air from thedevice.
mlnute period, two timesthe rated working pressureon the downstream sidewith atmospheric on up-stream side.
2.4 and 2.5Each check valve must be
drip tight when not lessthan 1 psi is applied to
upstream side and atmos-spherlc pressure to down-stream side.
2.10At rated flow (gpm fromtable 4) the pressure lossshall not exceed 25 psl.
2.6There must be no leakagefrom the vent port whenthe supply valve Is openedregardless of the rate atwhicli it is opened, norany leakage at any flowrate up to the 'capacityrating of the device.
lie-iueed PressurePrinciple bacK Frc^ure
Backflow Pre-. enters
A.S.S.E. No. 1013
June, 1971
:.2
The outlet checu valvemust with3tai.d for 10 min-utes, two tires the ratedworking pressure on thedownstream side with atmo6pheric pressure In the in-
let and Intermediate cham-bers.
2.3The outlet check valvemust be drip ti-Tht whenthe intermediate pressureis 1 psl and the outletpressure is atmospheric.
2.4
At rated flow (-ri and pslfrom table 2; the pressureloss must not exceed themaximum allowable.
2.5Under either static orflow conditions the Inter-mediate zone pressure mustbe at least 2 psi lowerthan the Inlet.
2.6During static operatingcondition, s:.ouid supplypressure fall tc 2 psithen pressure in the zonemust become atmospheric.
2.7aDuring backflow conditionwith supply pressure 2 pslor more, the zone must dis-charge to at=ospi.ere at
rate shown In taile 3 andzone pressure must be atleast 0.5 psi below thesupply pressure.
2.7bDuring backflow conditionwith supply pressure lessthan 2 psl, the zone mustdischarge to atrx sphere at
rate shown In table 3 andthe zone pressure must notexceed 1.5 psl.
i.aThe atmospheric vent valvemust start tc open whenpressure In zone is atleast 2 psi lower thanpressure in Inlet. It mustopen and close positively.
2.9The relief valve must notdischarge water jidersupply pressure fluctua-tions of l-i/2 psl maximumvariation.
A.S.S.E. No. 1015
May, 1972
2.2Each check valve mustwithstand two times therated working pressure ondownstream side and atmos-pheric on upstream sidefor a 5-mlnute period.
2.3Each check valve must bedrip tight when not lessthan 1 psi is applied toupstream side and atmos-pheric to downstream side.
2.4At rated flow (gpm fromtable 2) the pressure lossmust not exceed 10 psi.
16. ABSTRACT (A 200-word or less (actual summary of most significant information. If document includes a significant
bibliography or literature survey, mention it here.)
A significant potential for potable water supply contamination exists within all
water supply systems due to backflow and cross connections. Surveillance of the watersupplies to protect from such hazards requires continuing vigilance by the administra-tors of cross-connection control programs, and continuing upgrading of technicalcriteria and methods of evaluation.
The Environmental Protection Agency assists local (usually municipal) authorities,through the State water supply agency, in establishing and operating cross-connectioncontrol programs. Essential to these programs are (1) information on the suitabilityof commercially available devices for use in potentially high-hazard locations, and
(2) practical and effective standardized test methods for evaluation of devices. TheNational Bureau of Standards investigation reported herein addresses the two needsidentified.
This study includes a systematic review of the literature, together with consulta-tions and visits with water purveyors, plumbing officials, laboratory officials andresearchers in this field. Emphasis has been placed on those devices, test methods, anc
laboratory practices considered most essential to an effective assessment of the state-of-the-art. Also, test development needs were identified in a few areas of greatestconcern.
17. KEY WORDS (six to twelve entries; alphabetical order; capitalize only the first letter of me first key word unless a proper
name; separated by semicolons)
Backflow; backflow preventers; back pressure; back-siphonage; cross connections;health hazard; potable water; vacuum breaker; water supply.
18. AVAILABILITY [* Unlimited
|
' For Official Distribution. Do Not Release to NTIS
|' Order From Sup. of Doc, U.S. Government Printing Office
Washington, D.C. 20402, SD Cat. No. C13
|X IOrder From National Technical Information Service (NTIS)