eRedBook HalliburtonWelcome to eRedBookThank you for choosing to
install the Halliburton eRedBook. Halliburton eRedBook is an
essential information source for Halliburton services, products,
and API standards. With the inclusion of several oilfield
calculators, eRedBook will reduce time spent performing basic
calculations and searching for reference data. This online help
application will serve as a guide for using the application. This
guide will give the user an overview of the Halliburton eRedBook
application. Each section of the application will be identified and
its associated information will be presented. What is eRedbook? The
eRedBook application features an easy to use push button interface.
The sections are collapsible allowing the maximization of the
visible space. Information contained in the application has the
functionality to receive added features and product information, as
they are made available. Application SectionsInformation featured
in the application has been arranged in a intuitive manner to allow
the user to find information quickly. Information is sectioned in
the following manner. Reference Section Products Calculators
Technical Data Favorites Applications for eRedBook The Halliburton
eRedBook application can be used as a vital tool in planning and
operations situations. Tabular information allows the user to
quickly locate information. The interactive forms give the
functionality to perform calculations within the application.
Halliburton Energy Services products and services are featured to
help provide solutions to operational challenges. Accessing the
application Once installed the application can be accessed using
the following methods: Method 1: Start | Programs | Halliburton |
eRedbook Method 2: Select the eRedbook icon from the Windows
DesktopWhat information can be found in the application?The
following information is featured in the application. A digital
version of the industry recognized Halliburton Cement Tables i.e.
Halliburton Red Book Wellbore Geometry, an innovative tool that can
be used to create detailed down hole schematics Information on the
available Halliburton products and services API industry standard
technical data Useful oilfield calculatorsWhat's new with this
version of eRedBook?This release of eRedBook is the initial release
of the application. Listed below are highlights of the features and
information contained in the application. Please take a moment to
learn what the application has to offer. eRedBook Wellbore Geometry
is a new applet that is capable of creating detailed wellbore
schematics. Volumes are calculated for sections and user defined
interval segments. The appearance of the schematic can be
customized to give the best presentation. Content in the
application is capable of being updated on demand. As new products
and services are featured by Halliburton they will be made
available to eRedBook. The user has the ability to pick and choose
what product and service data is loaded in the application. New and
emerging services offered by Halliburton are updated right to the
desktop. Industry standard reference data products and services
Reference and product data All that is need to update the content
is an Calculators for common oilfield operations. System
Requirements Hardware The minimum recommended hardware requirements
are: CPU:1.0 Ghz Processor or faster
Memory:256 MB or greater
Video Card Memory32 MB
Hard Drive Available Space60 to 220 MB*
Software The minimum software requirements are: Operating
System:Windows XP SP2
Other software:Microsoft .Net v1.1
* Variability on the Hard Drive Available Space is based on the
installation content selected by the end user. The user has the
flexibility to select from all to certain product information.
Installing eRedbookInstallation OptionsThe eRedBook can be
installed from the commercially distributed Halliburton USB Drives
or from the Halliburton Intranet i.e. HALWORLD. Option #1:
Halliburton eRedBook USB drive: 1. Close all programs.2. Insert the
Halliburton USB drive into an available USB drive on the PC or
laptop.3. Select the View Files options from the Popup window.
Alternative Method: My Computer, locate the USB drive from the
listing, and double clickAn action performed with the computer
mouse where the left button is clicked twice in a rapid fashion. on
the item. This will open a window with the listing of files on the
drive. 4. Select the eRedbook.msi file from the listing. 5. Follow
the instructions on the screen. Option #2: CD Installation1. Close
all programs.2. Insert the Halliburton eRedBook CD in the units CD
or DVD drive. .3. Follow the installation instructions Should there
be a problem with installation please consult the Installation
Assistance section of this help file. The following options i.e. #3
and 4 are intended for Halliburton employees installing the
application. Option #3: Halliburton Intranet InstallationNote this
option is only available to Halliburton employees. 1. Close all
programs2. Open the Microsoft Internet Explorer and navigate to
http://halworld.corp.halliburton.com/ or (Click Here).3. Select the
Download eRedBook. 4. Follow the instructions on the screen . Note.
It is recommended that the installation file be downloaded to the
installation unit and then executed. This method will result in the
reduction in the probability of an error occurring due to bandwidth
quality. Accessing the RedbookLaunching eRedbookThe eRedbookThe
Halliburton eRedbook v1.0, represents the digitization of the
Halliburton CementingTables traditionally distributed in a hard
bound format. Tables have been convertedto a digital format
allowing the user to manipulated the information presented. Theuser
can enlarge information (zoom in or out) presented or even extract
it (copyand paste). eRedbook provides the user a technical resource
for API standard information. Inaddition, the unique interface for
the application allows the user to perform calculationsby inputting
information directly into its forms.eRedbook v1.0, represents the
digitization of the Halliburton CementingTables traditionally
distributed in a hard bound format. Tables have been convertedto a
digital format allowing the user to manipulated the information
presented. Theuser can enlarge information (zoom in or out)
presented or even extract it (copyand paste). eRedbook provides the
user a technical resource for API standard information. Inaddition,
the unique interface for the application allows the user to perform
calculationsby inputting information directly into its forms.
application can be launched two different ways, from the Microsoft
Windows Desktop or the Programs listing. Launching from the Windows
DesktopLocate the eRedbook icon on the desktop and double click the
icon. This launches the application. Note this method for launching
the application depends on the icon being present on the desktop.
The icon is placed on the desktop during the application
installation. Launching from the Windows Program Listing1.Select
the Start button from the Windows Taskbar. 2.Select All Programs |
Halliburton | eRedbook . This launches the application.
Accessing eRedbookAfter the eRedbook application has been
launched it can be minimized to work unobstructed on another
application. When the user is ready to utilize the application
again it can be maximized in from two locations. These locations
are the Windows Toolbar and Notification Area. Windows
ToolbarLocate the eRedbook icon on the desktop and double click the
icon. This launches the application. Note this method for launching
the application depends on the icon being present on the desktop.
The icon is placed on the desktop during the application
installation.Window Notification Area1.Locate the eRedbook icon in
the Windows Notification area and right click on it. Left click on
an application to launch Installation AssistanceShould installation
or usage issues arise pertaining to the eRedBook the Halliburton
Energy Services IT Service Desk should be contacted via one of the
following options: Technical SupportUnited
StatesPhone:1.866.425.1919
Phone: 1.713.839.4357
Email: [email protected] Address
ESG Service Center - AmericasHalliburton Address Book
Service Desk Hours:24-hour
Mail AddressP.O. Box 1675 Houston, TX 77251 United States
eRedbook: General User InterfaceThe General User Interfacerefers
to the visual interface of an application. Primarily comprised of
toolbars, icons, and controls. or GUI, as it is sometimes known,
refers to the visual interface portion of the application. The GUI
is any portion of the application that the user interacts with to
exchange input and output. The GUI will appear in two distinct
forms. These are the maximized application on the desktop and the
application icon in the windows notification areaidentified as the
area where the windows operating system clock appears. By default
this area is located in the lower right portion of the screeen..
The eRedbookThe Halliburton eRedbook v1.0, represents the
digitization of the Halliburton CementingTables traditionally
distributed in a hard bound format. Tables have been convertedto a
digital format allowing the user to manipulated the information
presented. Theuser can enlarge information (zoom in or out)
presented or even extract it (copyand paste). eRedbook provides the
user a technical resource for API standard information. Inaddition,
the unique interface for the application allows the user to perform
calculationsby inputting information directly into its
forms.eRedbook v1.0, represents the digitization of the Halliburton
CementingTables traditionally distributed in a hard bound format.
Tables have been convertedto a digital format allowing the user to
manipulated the information presented. Theuser can enlarge
information (zoom in or out) presented or even extract it (copyand
paste). eRedbook provides the user a technical resource for API
standard information. Inaddition, the unique interface for the
application allows the user to perform calculationsby inputting
information directly into its forms. GUI uses a very straight
forward point and click interface. Each section and its subsections
are accessible via one of the icons located in the GUI. Portions of
the subsection will require a "Leftan action performed with the
computer mouse where the left button is pressed to initate an
action. " or "Rightan action performed with the computer mouse
where the right button is pressed to initate an action. This action
can launch a popup window where additional options are displayed
and selected using a left mouse action. " click to access the
information. Icons and labels are used to convey what is contained
in each section. This section outlines the basics on accessing and
navigating the eRedbook applicationGetting Around a Digital
DocumentAccessing or moving around a section of eRedbookThe
Halliburton eRedbook v1.0, represents the digitization of the
Halliburton CementingTables traditionally distributed in a hard
bound format. Tables have been convertedto a digital format
allowing the user to manipulated the information presented. Theuser
can enlarge information (zoom in or out) presented or even extract
it (copyand paste). eRedbook provides the user a technical resource
for API standard information. Inaddition, the unique interface for
the application allows the user to perform calculationsby inputting
information directly into its forms.eRedbook v1.0, represents the
digitization of the Halliburton CementingTables traditionally
distributed in a hard bound format. Tables have been convertedto a
digital format allowing the user to manipulated the information
presented. Theuser can enlarge information (zoom in or out)
presented or even extract it (copyand paste). eRedbook provides the
user a technical resource for API standard information. Inaddition,
the unique interface for the application allows the user to perform
calculationsby inputting information directly into its forms. that
features data images, i.e. Adobe Acrobat, is a snap. eRedbook uses
the same navigational theme of an internet browser. This allows for
the shortest possible learning curve to get familiar with the
application. Navigating eRedbookThe eRedbookThe Halliburton
eRedbook v1.0, represents the digitization of the Halliburton
CementingTables traditionally distributed in a hard bound format.
Tables have been convertedto a digital format allowing the user to
manipulated the information presented. Theuser can enlarge
information (zoom in or out) presented or even extract it (copyand
paste). eRedbook provides the user a technical resource for API
standard information. Inaddition, the unique interface for the
application allows the user to perform calculationsby inputting
information directly into its forms.eRedbook v1.0, represents the
digitization of the Halliburton CementingTables traditionally
distributed in a hard bound format. Tables have been convertedto a
digital format allowing the user to manipulated the information
presented. Theuser can enlarge information (zoom in or out)
presented or even extract it (copyand paste). eRedbook provides the
user a technical resource for API standard information. Inaddition,
the unique interface for the application allows the user to perform
calculationsby inputting information directly into its forms.
application interface has been designed with the similar look and
feel of a remote control. Applications are accessed by selecting
buttons that are labeled with each application's name. Navigational
ControlseRedbook has several controls that it uses to perform
actions in the application. This section will present these
controls to familiarize the user with their function. Desktop
IconLaunches the application.
Application ToolbarThe application toolbar allows the user to
make application setting. Also, adds the functionality to minimize
or close the application.
Form ToolbarThe form toolbar allows the user to make settings to
the forms i.e. reference, product, or calculator sheets. These
settings are rippled to the other sheets in the application to
eliminate redundant settings.
HelpLaunches the main help application
HelpLaunches the help application for a specific section of the
application
ConfigurationMakes changes to the application default
settings.
MinimizeMinimizes the active window to the Windows Taskbararea
at the top of the eRedbook main interface consisting of the
Perferences, Minimize, and Close buttons.eRedbook main interface
consisting of the Perferences, Minimize, and Close buttons..
CloseCloses the active window.
Application NotesAdds notes to the active section of the
application
Section ButtonsAccesses a section of the application.
SpinIncreases or decreases the value for the control.
Drop Down ArrowDisplays a list of values. Values can have
subsequent actions associated with each.
SearchLaunches a search of the currently selected document for
the user defined alpha or numeric characters.
Settings eRedBook PreferencesGeneral Click on the picture of the
eRedBook Preferences section to learn more about its
functionality
eRedBook Wellbore GeometryAdding an Open HoleOpen hole sections
of any diameter can be added to the wellbore canvas. A unique
feature in eRedBook Wellbore Geometry is ability to define "excess"
or washout as it is more commonly know. Assigning an excess
percentage allows for more accurate volume calculations where
washout has occurred. Steps Method 1:1. From the application main
menu, click on the Reference tab.2. Click on Wellbore Geometry. 3.
From the eRedbook Wellbore window that displays, click on the Pipes
section in the left window pane.4. Observe the icons listed in this
section: Casing, Coiled Tubing, Drill Pipe, Open Hole, and Tubing.
5. Locate the Open Hole icon.6. Click on the icon and drag-and-drop
it onto the wellbore canvas in the right window pane.7. From the
Hole Editor window that displays, enter values for Diameter, Bottom
(depth at which hole ends), and Washout.8. Click the OK button.The
user may opt to check inside the box to fill the open hole with
liquid.9. Observe the open hole added onto the wellbore canvas.The
user must first add either an open hole or casing to the wellbore
canvas prior to adding any other pipe from the list in Step
4.Method 2:1. Repeat Steps 1 and 2 above.2. Right click on the
wellbore canvas, scroll down to click on Add, and select Open
Hole.3. From the Hole Editor (or Casing Editor) window that
displays, enter values for Diameter, Bottom (depth at which hole
ends), and Washout.4. Observe the open hole added onto the wellbore
canvas.The user has the option of either editing or deleting the
open hole.Example Objective: Add 2 open holes to the wellbore
canvas with the following parameters:Hole size: average 8.75 to
8600, 8 from 8601 to 9924 ft. Solution
eRedBook Wellbore GeometryAdding a New IntervalUser defined
intervals can be defined under the Volume tab of wellbore geometry.
Each interval that is created allows for the volume in that
specific area to be highlighted.
4. Click OK to complete the new interval. Observe the new
interval.
Example Objective: Create a wellbore schematic from 0 to
3,000'MD and define a customized interval 0 to 800'MD. 1.Open Hole
20in (0 to 1,500' MD)
2.Casing 18in 105lb/ft (0 to 1,500' MD)
3.Open Hole 17.5in (1,500 to 3,000' MD)
4.Casing 16in 94.5lb/ft (1,500 to 3,000' MD)
Solution
Adding a FluidsA fluid type can be defined for any item that is
added to the wellbore canvas. The fluid type can be customized by
name, color, and depth range. This feature allows eRedBook to
handle multiple fluids in a single wellbore, as is the case for
cement or fluid displacement jobs. Steps 1. From the eRedbook
Wellbore window, add an open hole onto the wellbore canvas.2. Add
pipe into the open hole.3. Right click on either the newly added
pipe or the open hole, depending upon where fluid is to be added.4.
Place the cursor on Add, and scroll over to click on Fluid.5. From
the Fluid Editor window that displays, click the Add button beneath
the box designated Members. 6. Observe both the Members and
Properties boxes populated with data.7. Enter values for the data
listed in the Properties box. Click on the input box, Bottom. Once
highlighted in blue, enter a value. The input box will populate
with the data entered. Repeat for each property listed.8. Click the
OK button.9. Observe the addition of the fluid onto the desired
location on the wellbore canvas.The user has the option of either
editing or deleting a fluid.Example Objective: For a production
casing with the following parameters, add mud to the 8.75" open
hole from 876'-5548'3 pipes, 2 slurries, 1 spacer, 2 hole sizes
with the following parameters:4 1/2 11.6#/ft 0 1025 ft4 1/2
10.5#/ft 1026 - 7996 ft4 1/2 11.6#/ft 7997 - 9924 ftPrevious
Casing: 8 5/8 24#/ft set @ 876 ft.41 ft of shoe track.Hole size:
average 8.75 to 8600, 8 from 8601 to 9924 ft. Figure 500 tail, 2000
lead, 1000 ft of spacer.Solution
Adding EquipmentNumerous types of downhole equipment can be
added to the wellbore canvas. The addition of downhole equipment
gives the best possible graphical interpretation of wellbore
installations.Steps 1. From the eRedbook Wellbore Geometry window,
click the Add Items tab. 2. Select and add a tubular type to the
wellbore canvas. For more details on how to do this click here.
Equipment can only be added into tubular i.e. casing, drill pipe,
tubing, etc.3. Click on the Equipment tab.4. Locate the equipment
item of interest.5. Click on the equipment icon and drag-and-drop
the equipment onto the pipe.6. Enter a depth in the set depth
dialog box. This is the top set depth for the added equipment. The
heading for the dialog box will vary based on the type of equipment
being set. 7. Click the OK button. This closes the dialog box. 8.
Observe the equipment added to the inside of the pipe.The user has
the option of either editing or deleting equipment.Example Example
Objective: For a production casing with the following parameters,
add a float collar to the 4.5" 11.6lb/ft casing and set it to a
depth of 9924'.3 pipes, 2 slurries, 1 spacer, 2 hole sizes with the
following parameters:4 1/2 11.6#/ft 0 1025 ft4 1/2 10.5#/ft 1026 -
7996 ft4 1/2 11.6#/ft 7997 - 9924 ftPrevious Casing: 8 5/8 24#/ft
set @ 876 ft.41 ft of shoe track.Hole size: average 8.75 to 8600, 8
from 8601 to 9924 ft. Figure 500 tail, 2000 lead, 1000 ft of
spacer.Solution
Adding PipeAPI standard and user defined tubular types i.e.
drill pipe, casing, tubing, etc. can be added to the eRedBook
Wellbore Geometry canvas. The application does not restrict the
user to defining a supporting hole section when adding a pipe. This
is a unique time saving feature that allows a schematic to be
created without going through a defined order of installation.
Steps Method 1:1. From the eRedbook Wellbore window, add an open
hole to the wellbore canvas.2. Right click on the open hole, place
the cursor on Add, and scroll over to click on Pipes.3. Click on
the pipe of interest from the list displayed: Casing, Coiled
Tubing, Drill Pipe, Tubing.4. From the Pipe Editor window that
displays, click on the magnifying glass to select the parameters of
the pipe.5. From the Volume Lookup window that displays, enter
values for OD, Tors. Yld. Str., Grade, and Wall Thickness by
selecting from the list under each column.6. From the Pipe Editor
window that displays, enter values for Top (depth where pipe
begins) and Bottom (depth where pipe ends).7. Click the OK
button.8. Observe the pipe added to the open hole.The user has the
option of either editing or deleting pipe.Method 2:1. From the
eRedbook Wellbore window, add an open hole to the wellbore
canvas.2. Click on the Pipes section.3. Locate the pipe of
interest.4. Click on the pipe icon. 5. Drop-and-drag the pipe icon
onto the open hole.6. Repeat Steps 4-7 from Method 1.Example
Objective: Add three pipes to a wellbore with two hole sizes: 4 1/2
11.6#/ft 0 1025 ft4 1/2 10.5#/ft 1026 - 7996 ft4 1/2 11.6#/ft 7997
- 9924 ftPrevious Casing: 8 5/8 24#/ft set @ 876 ftHole size:
average 8.75 to 8600, 8 from 8601 to 9924 ft. Solution
Add LithologyThe eRedBook Wellbore Geometry canvas allows the
user to switch between different backgrounds. Currently, the canvas
can be displayed with a lithology or blank i.e. white background.
Additional backgrounds are currently in development and will be
available in the near future. Steps 1. From the eRedbook Wellbore
window, click on the Lithology section.2. Observe the Strata
wallpaper automatically displayed in the window.3. Click on the
wallpaper icon designated None.4. Drop-and-drag the icon onto the
wellbore canvas.5. Observe the wellbore canvas None displays in the
window.6. Click on the wallpaper icon designated Strata.7.
Drop-and-drag the icon onto the wellbore canvas.8. Observe the
wellbore canvas Strata displays in the window.Example Objective:
Change the wellbore canvas from Strata to None.Solution
Editing ItemsAny item that is added to the wellbore canvas can
be edited or deleted. By editing an item, small changes can be made
without having to reinstall underlying components. Steps 1. From
the eRedbook Wellbore window, right click on the open hole added to
the wellbore canvas. 2. Place the cursor on Edit, and scroll over
to click on Hole.3. From the Hole Editor window that displays, make
desired changes to the hole parameter data.4. Click the OK
button.5. The application will navigate back to the eRedbook
Wellbore window.6. Observe the edited open hole.Delete ItemsAny
item that is added to the wellbore canvas can be deleted or edited.
When an item is selected for deletion all subsequent items that
have been installed will also be removed. This feature saves
considerable time when making major changes to a schematic. Steps
1. From the eRedbook Wellbore window, right click on the open hole
added to the wellbore canvas. 2. Place the cursor on Edit, and
scroll over to click on Delete.3. Observe the open hole is deleted
from the wellbore canvas.Saving and Restoring Wellbore
FileseRedBook Wellbore Geometry allows wellbore schematics to be
save to a file and restored, at a later time. This feature allows a
user to create basic schematics that can be restored and updated as
needed. Steps Loading a Wellbore File:1. Select Wellbore Geometry
from the Reference section in the eRedbookThe Halliburton eRedbook
v1.0, represents the digitization of the Halliburton
CementingTables traditionally distributed in a hard bound format.
Tables have been convertedto a digital format allowing the user to
manipulated the information presented. Theuser can enlarge
information (zoom in or out) presented or even extract it (copyand
paste). eRedbook provides the user a technical resource for API
standard information. Inaddition, the unique interface for the
application allows the user to perform calculationsby inputting
information directly into its forms.eRedbook v1.0, represents the
digitization of the Halliburton CementingTables traditionally
distributed in a hard bound format. Tables have been convertedto a
digital format allowing the user to manipulated the information
presented. Theuser can enlarge information (zoom in or out)
presented or even extract it (copyand paste). eRedbook provides the
user a technical resource for API standard information. Inaddition,
the unique interface for the application allows the user to perform
calculationsby inputting information directly into its forms. main
interface. 2. Right clickan action performed with the computer
mouse where the right button is pressed to initate an action. This
action can launch a popup window where additional options are
displayed and selected using a left mouse action. on the canvas and
select File | Open. This opens the Open dialog box. 3. Locate and
double clickAn action performed with the computer mouse where the
left button is clicked twice in a rapid fashion. the wellbore file
(.wlb). This loads the previously created wellbore file. Saving a
Wellbore File:1. Create or load a wellbore schematic. 2. Right
clickan action performed with the computer mouse where the right
button is pressed to initate an action. This action can launch a
popup window where additional options are displayed and selected
using a left mouse action. on the wellbore schematic and select
File | Save. The default file location for the Wellbore Geometry
feature is C:\Program Files\Halliburton Energy Services\Wellbore
Simulator. The Halliburton eRedBook Wellbore Geometry applet is an
revolutionary graphics application that can be used to generate
detailed wellbore schematics. Common oilfield downhole tools and
equipment can be added to the wellbore canvas to create a highly
accurate schematic. Furthermore, the General Notes feature allows
the user to make notations on the schematic to call attention to
areas of interest. Output generated from Wellbore Geometry can be
exported to other instances of eRedBook or for graphical use in
Microsoft Office applications. Most common tubular items and
downhole equipment are available for use in creating a wellbore
schematic. As new Halliburton products and services are developed
the content will be made available in future application updates.
See Also...Adding PipeAdding EquipmentAdding FluidAdding Open
HoleDelete ItemsSections tabThe Halliburton eRedBook Wellbore
Geometry applet is an revolutionary graphics application that can
be used to generate detailed wellbore schematics. Common oilfield
downhole tools and equipment can be added to the wellbore canvas to
create a highly accurate schematic. The Sections tab of the
Wellbore Geometry applet provides a summary of the objects
(equipment, tubular types, and fluids) that have been added to the
schematic. When an item is selected in the Installed Objects viewer
it is highlighted on the drawing canvas. This makes identifying
installed items quick and easy.Steps 1. From the application main
menu, click on the Reference tab.2. Click on Wellbore Geometry.3.
From the eRedbook Wellbore window that displays, add an open
hole.4. Add pipe to the open hole.5. Add fluid inside of the
pipe.6. Click on the Sections tab at the bottom of the window.7.
Observe each added item to the wellbore canvas listed at the top of
the window.8. Click on an item of interest.9. Observe the item is
highlighted in blue.10. Observe data about the highlighted item in
the top of the window is displayed under the column headings
designated Misc. and Physical Properties located at the bottom of
the window.Example Objective: Observe the Misc. and Physical
Properties for a production casing (3 pipes, 2 slurries, 1 spacer,
2 hole sizes) with the following parameters:4 1/2 11.6#/ft 0 1025
ft4 1/2 10.5#/ft 1026 - 7996 ft4 1/2 11.6#/ft 7997 - 9924
ftPrevious Casing: 8 5/8 24#/ft set @ 876 ft.41 ft of shoe
track.Hole size: average 8.75 to 8600, 8 from 8601 to 9924 ft.
Figure 500 tail, 2000 lead, 1000 ft of spacer.Solution
Volume tabThe Halliburton eRedBook Wellbore Geometry applet is
an revolutionary graphics application that can be used to generate
detailed wellbore schematics. Common oilfield downhole tools and
equipment can be added to the wellbore canvas to create a highly
accurate schematic. The Volume tab of the Wellbore Geometry applet
provides a summary of the intervals in the wellbore schematic. By
default, an interval needs to be selected on the canvas for it to
be displayed in the volume summary viewer. Steps 1. From the
application main menu, click on the Reference tab.2. Click on
Wellbore Geometry.3. From the eRedbook Wellbore window that
displays, add an open hole.4. Add pipe to the open hole.5. Add
fluid inside of the pipe.6. Click on the Volume tab at the bottom
of the window.7. Enter a value for Percent Excess.8. Click on an
interval of the wellbore canvas where pipe, fluid, and/or an open
hole has been added.9. Observe the interval of interest is
highlighted in green.10. Observe the Total Volume of the interval
of interest is populated in the left side of the window.11. Click
in the empty white space beneath the Total Volume calculation.12.
Observe the calculated result for Total with Excess.13. Click on
the previously selected interval of interest on the wellbore canvas
to deselect the interval.14. Observe the interval is no longer
highlighted, and its corresponding volume calculation in the left
side of the window disappears.15. Repeat steps 8-14 to observe the
volume calculations for any interval of choice.Example Objective:
For a production casing with the following parameters, determine
the volume for the interval of 4.5" 10.5lb/ft casing with 10%
washout:3 pipes, 2 slurries, 1 spacer, 2 hole sizes 4 1/2 11.6#/ft
0 1025 ft4 1/2 10.5#/ft 1026 - 7996 ft4 1/2 11.6#/ft 7997 - 9924
ftPrevious Casing: 8 5/8 24#/ft set @ 876 ft.41 ft of shoe
track.Hole size: average 8.75 to 8600, 8 from 8601 to 9924 ft.
Figure 500 tail, 2000 lead, 1000 ft of spacer.Solution
Viewing Dimensions and Strengths DataTubingRelatively
small-diameter pipe that is run into a well to serve as a conduit
for the passage of oil and gas to the surface. is a small-diameter
pipe that is run inside a cased well. It allows the flow of oil and
gas into the casingA steel pipe placed in an oil or gas well to
prevent the wall of the hole from caving in, to prevent movement of
fluids from one formation to another, and to aid in well control.
or liner. Tubing is supplied in a varying array of sizes. Tubing
that meets API specifications has an outside diameter that ranges
from 1.050 in. to 4.5 in. Seven sizes in between the two extremes
are also available. Manufacturers provide joints of tubing in two
range lengths: range 1 tubing joints are 20-24 feet long; range 2
tubing joints are 28 to 32 feet long. Coiled tubing is also used in
a similar capacity as the tubing. It is a continuous length - it
does not have joints - of flexible steel pipe that comes rolled on
a large reel. Operators have completed wells over 20,000 feet deep
with coiled tubing. The main advantage of coiled tubing is that
crew members do not have to connect several single joints of tubing
when installing the string.Steps 1. From the application main menu,
click on the Reference tab.2. Click on Dimensions and Strengths.3.
From the Dimensions and Strengths window that displays, click on
one of the tabs ( CasingA steel pipe placed in an oil or gas well
to prevent the wall of the hole from caving in, to prevent movement
of fluids from one formation to another, and to aid in well
control. , Drill PipeThe heavy seamless tubing used to rotate the
bit and circulate the drilling fluid. Joints of pipe are generally
approximately 30 feet long are coupled together by means of tool
joints.tubingRelatively small-diameter pipe that is run into a well
to serve as a conduit for the passage of oil and gas to the
surface. used to rotate the bit and circulate the drilling fluid.
Joints of pipe are generally approximately 30 feet long are coupled
together by means of tool joints. , TubingRelatively small-diameter
pipe that is run into a well to serve as a conduit for the passage
of oil and gas to the surface. , or Coil Tubing) along the top of
the screenA device used in sand control applications to support the
gravel pack. Screen is available in a range of sizes and
specifications, including outside diameter, material type and the
geometry and dimension of the screen slots. ScreeA device used in
sand control applications to support the gravel pack. Screen is
available in a range of sizes and specifications, including outside
diameter, material type and the geometry and dimension of the
screen slots. n is available in a range of sizes and
specifications, including outside diameter, material type and the
geometry and dimension of the screeA device used in sand control
applications to support the gravel pack. Screen is available in a
range of sizes and specifications, including outside diameter,
material type and the geometry and dimension of the screen slots. n
slots. to designate the type of tubular for which the dimension
data is needed.Select the User Defined tab to customize the
dimensions and specifications for a particular type of tubular. See
detailed steps below. 4. Locate the Size O.D. (outside diameter)
specification for the desired tubular. 5. Expand the entry for that
tubular by clicking on the plus button and locate the detailed
specifications. 6. Observe the dimension and strength data.
Customizing a Tubular:1. From the Dimensions and Strengths window,
click on the User Defined tab.2. Locate the heading "I would like
to add a custom pipe for" at the top of the screen.3. Select a pipe
from the available choices: Casing, Drill Pipe, Tubing, Coil Tubing
by clicking on the drop down button .4. Enter values for the
parameters applicable to the pipe of choice, using the tab key to
navigate between input boxes.5. Once all the desired parameter
values are entered, click the Add button located in the lower right
corner of the window.Click the Reset button (located below the Add
button) to zero-out all data previously entered. Re-enter data as
needed.6. Observe the Item Successfully Added popup box that
appears.7. Select Add Another to customize additional pipes, or
Finished if no further customization is needed. 8. The application
will navigate to the tab of the customized tubular where it has
been added to the bottom of the list. 9. Click on the plus button
to expand the selection and observe the user defined tubular
highlighted in green.Example Objective: Locate the specifications
for a 5" 19.5 lb/ft drill pipe.
Solution
Determining the Volume Between the Hole and Tubing, Casing or
Drill Pipe This calculator is used to determine the fluid volume
and column height for the space in between the open hole1. Any
wellboreA borehole; the hole drilled by the bit. A wellbore may
have casing in it or it may be open (uncased); or part of it may be
cased, and part of it may be open. Also called a borehole or hole.
in which casingA steel pipe placed in an oil or gas well to prevent
the wall of the hole from caving in, to prevent movement of fluids
from one formation to another, and to aid in well control. has not
been set. 2. Open or cased hole in which no drill pipeThe heavy
seamless tubing used to rotate the bit and circulate the drilling
fluid. Joints of pipe are generally approximately 30 feet long are
coupled together by means of tool joints. or tubingRelatively
small-diameter pipe that is run into a well to serve as a conduit
for the passage of oil and gas to the surface. is suspended. 3. The
portion of the wellbore that has no casing. and the tubing , casing
, or pipe for a given section length. A washoutAn enlarged region
of a wellbore. A washout in an openhole section is larger than the
original hole size or size of the drill bit. Washout enlargement
can be caused by excessive bit jet velocity, soft or unconsolidated
formations, in-situ rock stresses, mechanical damage by BHA
components, chemical attack and swelling or weakening of shale as
it contacts fresh water. Generally speaking, washouts become more
severe with time. Appropriate mud types, mud additives and
increased mud densityMass per unit of volume. Density is typically
reported in g/cm3 (for example, rocks) or pounds per barrel
(drilling mud) in the oil field. can minimize washouts. factor,
i.e. percentage, can be added to handle situations where the hole
is enlarged. Washout occurs when the open hole becomes larger than
the original hole size or size of the drill bit. Several operations
require that an amount of excess material be included in job
planning based on the washout factor. Steps 1. From the application
main menu, click on the Reference tab. 2. Click on Tub/Cas/ Pipe in
Hole.3. From the Tub/Cas/Pipe in Hole window that displays, enter
values for Hole Diameter and WashoutAn enlarged region of a
wellbore. A washout in an openhole section is larger than the
original hole size or size of the drill bit. Washout enlargement
can be caused by excessive bit jet velocity, soft or unconsolidated
formations, in-situ rock stresses, mechanical damage by BHA
components, chemical attack and swelling or weakening of shale as
it contacts fresh water. Generally speaking, washouts become more
severe with time. Appropriate mud types, mud additives and
increased mud density can minimize washouts. (%), using the tab key
to navigate between input boxes. 4. Select or enter a pipe.5. Enter
values for Total Length, Number of String(s), and Excess.6. Observe
the calculated results for volume and height. Example Objective:
Determine the volume and height for a 9.625" 53.5 lb/ft casing in a
10,000' 12.25" diameter hole.
Solution
Determining the Volume Between the Casing and Tubing, Casing or
Drill Pipe This calculator is used to determine the fluid volume
and column height that will fill the space in between the outer
casingA steel pipe placed in an oil or gas well to prevent the wall
of the hole from caving in, to prevent movement of fluids from one
formation to another, and to aid in well control. and the
tubingRelatively small-diameter pipe that is run into a well to
serve as a conduit for the passage of oil and gas to the surface.,
inner casing, or pipe that has been inserted into the outer casing.
In order to accurately calculate fluid levels, the user is required
to input detailed specifications for the outer casing, tubing,
inner casing, and pipe. Steps 1. From the application main menu,
click on the Reference tab.2. Click on Tub/Cas/Pipe in CasingA
steel pipe placed in an oil or gas well to prevent the wall of the
hole from caving in, to prevent movement of fluids from one
formation to another, and to aid in well control. .3. From the
Tub/Cas/Pipe in Casing window that displays, select or enter pipe
for both Outer Casing and Inner Casing/Tubing/Drill Pipe. 4. Enter
a value for Total Length. 5. Enter the Number of String(s) value
using the control . 6. Observe the calculated results for volume
and height. Example Objective: Determine the volume and height in a
casingA steel pipe placed in an oil or gas well to prevent the wall
of the hole from caving in, to prevent movement of fluids from one
formation to another, and to aid in well control. given the
following:Outer CasingA steel pipe placed in an oil or gas well to
prevent the wall of the hole from caving in, to prevent movement of
fluids from one formation to another, and to aid in well control. :
9.625" 53.5 lb/ft casingA steel pipe placed in an oil or gas well
to prevent the wall of the hole from caving in, to prevent movement
of fluids from one formation to another, and to aid in well
control. Number of String(s): 1Total Length: 2000'
Drill PipeThe heavy seamless tubing used to rotate the bit and
circulate the drilling fluid. Joints of pipe are generally
approximately 30 feet long are coupled together by means of tool
joints. : 5" @16.25 lb/ft
Solution
Viewing Coupling Displacement DataA coupling is a metal collar
with internal threads used to join two sections of threaded pipe.
In terms of coupling displacement, the coupling is involved in
removing one fluid (usually liquid) from a wellboreA borehole; the
hole drilled by the bit. A wellbore may have casing in it or it may
be open (uncased); or part of it may be cased, and part of it may
be open. Also called a borehole or hole. and replacing it with
another. This is accomplished by pumping a spacerA viscous fluid
used to aid removal of drilling fluids before a primary cementing
operation. The spacer is prepared with specific fluid
characteristics, such as viscosity and densitMass per unit of
volume. DensityMass per unit of volume. Density is typically
reported in g/cm3 (for example, rocks) or pounds per barrel
(drilling mud) in the oil field. is typically reported in g/cm3
(for example, rocks) or pounds per barrel (drilling mud) in the oil
field. y, that are engineered to displace the drilling fluid while
enabling placement of a complete cement sheath. fluid that is
benign to both the first and second fluid, followed by the new
fluid, down the drillstringThe combination of the drillpipe, the
bottomhole assembly and any other tools used to make the drill bit
turn at the bottom of the wellbore. and out the bottom of the
drillstring or bit. While the spacer and second fluid are pumped
into the top of the wellbore , the first fluid is forced out of the
annulusThe space between two concentric objects, such as between
the wellbore and casing or between casing and tubing, where fluid
can flow. Pipe may consist of drill collars, drillpipe, casing or
tubing. between the drillstring and the wellbore or casingA steel
pipe placed in an oil or gas well to prevent the wall of the hole
from caving in, to prevent movement of fluids from one formation to
another, and to aid in well control.. In some cases, this general
procedure may be reversed by pumping in the top of the annulus and
taking fluid back from the drillstring. Since this is the reverse
of the normal circulation path, this is referred to as "reversing
out" or "reverse circulation." Steps 1. From the application main
menu, click on the Reference tab.2. Click on Coupling
Displacement.3. From the Coupling Displacement window that
displays, click on one of the tabs (CasingA steel pipe placed in an
oil or gas well to prevent the wall of the hole from caving in, to
prevent movement of fluids from one formation to another, and to
aid in well control. , TubingRelatively small-diameter pipe that is
run into a well to serve as a conduit for the passage of oil and
gas to the surface. , or Drill PipeThe heavy seamless tubing used
to rotate the bit and circulate the drilling fluid. Joints of pipe
are generally approximately 30 feet long are coupled together by
means of tool joints.tubingRelatively small-diameter pipe that is
run into a well to serve as a conduit for the passage of oil and
gas to the surface. used to rotate the bit and circulate the
drilling fluid. Joints of pipe are generally approximately 30 feet
long are coupled together by means of tool joints. ) along the top
of the screenA device used in sand control applications to support
the gravel pack. Screen is available in a range of sizes and
specifications, including outside diameter, material type and the
geometry and dimension of the screen slots. ScreeA device used in
sand control applications to support the gravel pack. Screen is
available in a range of sizes and specifications, including outside
diameter, material type and the geometry and dimension of the
screen slots. n is available in a range of sizes and
specifications, including outside diameter, material type and the
geometry and dimension of the screeA device used in sand control
applications to support the gravel pack. Screen is available in a
range of sizes and specifications, including outside diameter,
material type and the geometry and dimension of the screen slots. n
slots. to designate the type of tubular for which the dimension
data is needed.4. Locate the Size O.D. (outside diameter)
specification for the desired tubular. 5. Expand the entry for that
tubular by clicking on the plus button and locate the detailed
specifications. 6. Observe the dimension and strength data. Example
Objective: Locate specifications for a 9 5/8" 40 lb/ft casingA
steel pipe placed in an oil or gas well to prevent the wall of the
hole from caving in, to prevent movement of fluids from one
formation to another, and to aid in well control. .
Calculating CapacityCapacity refers to the maximum volume that a
defined space is capable of containing. The capacity calculator
measures the maximum amount of material and/or fluid that can be
contained within and object. In the case of casingA steel pipe
placed in an oil or gas well to prevent the wall of the hole from
caving in, to prevent movement of fluids from one formation to
another, and to aid in well control., the calculator could
potentially be used to determine the amount of cement, mud, or
water that it can hold. The calculator can also determine the
maximum amount of tubingRelatively small-diameter pipe that is run
into a well to serve as a conduit for the passage of oil and gas to
the surface. it could hold. For tubing, a calculation would be used
to determine the amount of oil and/or gas it could contain.
Similarly, for pipe, the calculator would be used to determine the
amount of fluid it could hold.Casing/Tubing/PipeHoleDrill
Collars
Drill CollarsA drill collar is a component of a drillstring that
provides weight on bit for drilling. Drill collars are thick-walled
tubular pieces machined from solid bars of steel, usually plain
carbon steel but sometimes of nonmagnetic nickel-copper alloy or
other nonmagnetic premium alloys. The bars of steel are drilled
from end to end to provide a passage to pumping drilling fluids
through the collars. The outside diameter of the steel bars may be
machined slightly to ensure roundness, and in some cases may be
machined with helical grooves ("spiral collars"). Last, threaded
connections, male on one end and female on the other, are cut so
multiple collars can be screwed together along with other downhole
tools to make a bottomhole assembly (BHA). Gravity acts on the
large mass of the collars to provide the downward force needed for
the bits to efficiently break rock. To accurately control the
amount of force applied to the bit, the driller carefully monitors
the surface weight measured while the bit is just off the bottom of
the wellbore. Next, the drillstring (and the drill bit), is slowly
and carefully lowered until it touches bottom. After that point, as
the driller continues to lower the top of the drillstring, more and
more weight is applied to the bit, and correspondingly less weight
is measured as hanging at the surface. If the surface measurement
shows 20,000 pounds [9080 kg] less weight than with the bit off
bottom, then there should be 20,000 pounds force on the bit (in a
vertical hole). Downhole MWD sensors measure weight-on-bit more
accurately and transmit the data to the surface. Steps 1. From the
application main menu, click on the Reference tab.2. Click on
Capacity. 3. From the Capacity window that displays, click on the
Drill Collars tab.4. Locate a drill collar number of interest from
the list provided.5. Click on the grayed-out field to the left of
the desired data row to highlight the row for easier viewing.6.
Observe the parameters of the drill collar of interest. Clicking in
the grayed-out area of a header column will sort its data in
ascending/descending order.Example Objective: Determine the OD and
Bevel Diameter for drill collar number NC23-31.
Solution
Calculating Capacity for a Hole SectionCapacity refers to the
maximum volume that a defined space is capable of containing. The
capacity calculator for a hole section measures the maximum amount
of material and/or fluid that can be contained within an open hole.
Steps 1. From the application main menu, click on the Reference
tab.2. Click on Capacity.3. From the Capacity window that displays,
click on the Hole tab.4. Select a unit for Diameter and enter a
value. 5. Tab over and select a unit for Length and enter a value.
6. Observe the calculated results for capacity. ExampleObjective:
Determine the capacity for 10,000' of 12 1/4" hole.
Calculating Capacity for a TubularCapacity refers to the maximum
volume that a defined space is capable of containing. The capacity
calculator measures the maximum amount of material and/or fluid
that can be contained within and object. For tubing, a calculation
would be used to determine the amount of oil and/or gas it could
contain. Steps 1. From the application main menu, click on the
Reference tab.2. Click on Capacity.3. From the Capacity window that
displays, click on the Casing/Tubing/Pipe tab. 4. Select or enter a
pipe. 5. Enter a value for Length.6. Observe the calculated results
for capacity.Example Objective: Determine the capacity for 12,000'
of 13 3/8" 77 lb/ft casing.
Cement Product InformationIn petroleum well construction,
cementing is the process used to bond casingA steel pipe placed in
an oil or gas well to prevent the wall of the hole from caving in,
to prevent movement of fluids from one formation to another, and to
aid in well control. to the exposed wellboreA borehole; the hole
drilled by the bit. A wellbore may have casing in it or it may be
open (uncased); or part of it may be cased, and part of it may be
open. Also called a borehole or hole. to help ensure optimum
reservoir access. While the majority of wells drilled can be
cemented with standard slurries and equipment, Halliburton has also
distinguished itself as a reliable provider of cementing solutions
to meet challenging downhole and environmental conditions. This
section provides information on the various cementing products and
additives Halliburton employs.Steps 1. From the application main
menu, click on the Products tab.2. Place the cursor over Fluid
Systems, then Cementing, and scroll over to click on Product
Information.3. From the Product Information window that displays,
locate the product type of interest under the Product column
heading. 4. Click on the plus button to the left of the product
type to expand a listing of a subset of product types.Notice that a
minus button appears to the left of the product type for the
expanded selection. Clicking it will collapse the selection. 5.
From the subset list, click on the plus button to expand a list of
items in that particular subset.6. Observe the selected
products.Example Objective: Observe the Cementing Equipment product
types.
Solution
Objective: For a production casing with the following
parameters, add a float collar to the 4.5" 11.6lb/ft casing and set
it to a depth of 9924'.3 pipes, 2 slurries, 1 spacer, 2 hole sizes
with the following parameters:4 1/2 11.6#/ft 0 1025 ft4 1/2
10.5#/ft 1026 - 7996 ft4 1/2 11.6#/ft 7997 - 9924 ftPrevious
Casing: 8 5/8 24#/ft set @ 876 ft.41 ft of shoe track.Hole size:
average 8.75 to 8600, 8 from 8601 to 9924 ft. Figure 500 tail, 2000
lead, 1000 ft of spacer.Solution