2013 Thermal Competion Products

Table of Contents Thermal Liner Hangers Running Tools Remedial Tools Reservoir Monitoring

Thermal Liner Hangers Pressure Tight System - TBL Thermal Liner Packer

Debris Seal System - CE Liner Top Packer - LRP Long Reach Liner Packer

Tailpipe Hanger - MH Thermal Liner Hanger Packer - LRP Long Reach Liner Packer

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Size Weight Range Packer O.D. in (mm) lb/ft (kg/m) in (mm)

4.500 x 7.000 (114.3 x 177.8) 23.0 (34.2) 6.200 (157.5)

5.500 x 8.625 (139.7 x 219.1) 36.0 (53.6) 7.635 (193.9)

7.000 x 9.625 (177.8 x 244.5) 40.0 - 43.5 (59.5 - 64.7) 8.535 (216.8)

TBL Thermal Liner Packer Specifications

DescriptionThe TBL Thermal Liner Packer is a hydraulically set liner hanger packer for use in thermal applications (injection or production). It is an engineered and tested product with a temperature rating of 343 C and pressure rating of 21 MPa. The TBL is designed with matching liner strength specifications, and is able to be rotated and circulated into position.

The design for this product includes no elastomers. It is engineered for harsh environments that exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds.

OperationThe TBL Thermal Liner Packer is designed to be run and set utilizing a hydraulic setting tool which is engineered for producing high setting forces, torque rates and axial loads. Surface setting pressures are adjustable by manipulating the initial setup for the setting tool.

The TBL Thermal Liner Packer isconveyed with a hydraulic setting tooland set by dropping a ball, or utilizing aplugging system, and pressuring up onthe work string. Once the thermal element is packed off, the setting tool hydraulically disconnects from the liner without work string manipulation, and is retrieved to surface.

ApplicationsThe TBL Thermal Liner Packer is designed for thermal applications when liner top pressure integrity is required throughout the life of the well, and the liner installation may require high torque and axial loads to position the liner into the wellbore. This packer is suitable for in-situ thermal environments such as SAGD, CSS and many other extreme temperature applications.

Features Large beveled upper seal bore One piece integral mandrel Integral clutch system Opposing 360 full circle slips Metal to metal seal with static element Matched liner strength NACE MR0175 compliant for environments containing H2S

Benefits Qualified to 343 C and 21 MPa Ability to rotate and circulate during deployment Beveled tieback sleeve with latching profile allows for: - Installation of a tieback packer with full bore access to the liner - Latching and anchoring of inner strings with pressure isolation - Attachment and retrieval of flow control at the liner top - Installation of warm up phase technology with open/closed positions and integral thermal expansion joint Fullbore access to liner Liner placement control (anchored liner top during thermal cycle loading) Adjustable surface setting pressures Tested and verified for well tractor transition from intermediate casing, through packer, and into liner without a slave string

TBL Thermal Liner Packer

TBL Thermal Liner Packer

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Size Weight Range Packer O.D. in (mm) lb/ft (kg/m) in (mm)

7.000 x 9.625 (177.8 x 244.5) 36.0 - 47.0 (53.6 - 69.9) 8.375 (212.7) 8.625 x 11.750 (219.1 x 298.5) 54.0 - 60.0 (80.3 - 89.2) 10.500 (266.7)

CE Liner Top Packer Specifications

DescriptionThe CE Liner Top Packer is a unique hydraulically set packer, for use in thermal injection or production applications. The CE Liner Top Packer utilizes the unique conditions of the SAGD environment to continuously supply energy to the dynamic sealing element system throughout the lifecycle of the well.

It is an engineered and tested product with temperature and pressure ratings in line with thermal in-situ environments. The CE Liner Top Packer is designed with matching liner strength specifications, and is able to be rotated and circulated into position.

OperationThe CE Liner Top Packer is designed to be run and set utilizing a hydraulic running tool which is engineered for high torque rates and axial loads. Surface setting pressures are adjustable by manipulating the initial setup for the running tool.

The CE Liner Top Packer is set by dropping a DPWP, and pressuring up on the work string. Once the element is packed off, the running tool hydraulically disconnects from the liner without work string manipulation. The running tool is retrieved by straight pick up.

ApplicationsThe CE Liner Top Packer is designed for thermal applications when liner top debris management is required throughout the life of the well.

This packer is suitable for in-situ thermal environments such as SAGD, and many others extreme temperature applications.

Features One piece integral mandrel Large bevelled upper seal bore Full tieback isolation capabilities External deployment clutch system Full bore access to liner Dynamically qualified sealing element Thermally activated port isolation technology (TAPIT) Manufactured from materials in compliance with NACE MR0175 for environments containing H2S

Benefits Full bore access to liner Able to rotate and circulate during deployment into the wellbore Low initial setting pressures, allows for rig pump setting TAPIT, isolates the pressure communication ports, eliminating the leak path from the tubing to annulus Fully contained deployment system, mitigates any interference with the setting sequence, due to circulating pressure

CE Liner Top Packer

CE Liner Top Packer

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Size Weight Range Packer O.D. in (mm) lb/ft (kg/m) in (mm)

2.875 x 4.500 (73.0 x 114.3) 9.5 - 12.6 (14.1 - 18.7) 3.771 (95.8)

3.500 x 5.500 (88.9 x 139.7) 15.5 - 17.0 (23.1 - 25.1) 4.625 (117.5)

5.000 x 7.000 (127.0 x 177.8) 23.0 - 29.0 (34.2 - 43.2) 5.900 (149.9)

6.625 x 8.625 (168.3 x 219.1) 28.0 - 40.0 (41.7 - 59.5) 7.500 (190.5)

7.000 x 9.625 (177.8 x 244.5) 36.0 - 47.0 (53.6 - 69.9) 8.375 (212.7)

8.625 x 11.750 (219.1 x 298.5) 38.0 - 60.0 (56.6 - 89.3) 10.375 (263.5)

MH Thermal Liner Hanger Packer Specifications

DescriptionThe MH Thermal Liner Hanger Packer is a hydraulically set liner hanger packer for use in thermal applications. With a temperature rating of 343 C, Schlumbergers metal to metal system in conjunction with the thermal element is capable of an initial pressure test to 21 MPa. This packer has both hanger slips as well as top hold down slips. The design for this product includes no elastomers. It is engineered for harsh environments which exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds.

OperationThe MH Thermal Liner Hanger Packer is designed to be run and set utilizing a hydraulic setting tool which is engineered for producing high setting forces and handling high axial loads. Surface setting pressures are adjustable by manipulating the initial setup for the setting tool. The MH Thermal Liner Hanger Packer is conveyed with a hydraulic setting tool and set by dropping a ball, or utilizing a plugging system, and pressuring up on the work string. Once the thermal element is packed off, the setting tool hydraulically disconnects from the liner packer without string manipulation, and is retrieved to surface. The MH Thermal Liner Hanger Packer can be retrieved if required, by utilizing standard retrieval equipment.

ApplicationsThe MH Thermal Liner Hanger Packer is designed for thermal applications. It is primarily used when it is necessary to have top and bottom anchoring slips, yet still be fully retrievable. This packer is utilized as a liner hanger, tailpipe hanger, bridge plug (with bullnose), and can be combined with the MH Patch Bottom to form a casing patch for remedial well bore repair.

Features Large beveled re-entry sleeve Large through bore Top and bottom anchoring slips Metal to metal seal with static element NACE MR0175 compliant for environments containing H2S

Benefits Thermal element rated to 343 C No work string manipulation required to set packer Standard tools/spears used for retrieval Liner or tailpipe placement control (anchored during thermal cycling) Adjustable surface setting pressures Tested and verified for well tractor transition from intermediate casing, through packer, and into liner without a slave string

MH Thermal Liner Hanger Packer

MH Thermal Liner Hanger Packer

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Size Weight Range Packer O.D. in (mm) lb/ft (kg/m) in (mm)

4.500 x 7.000 (114.3 x 177.8 ) 20.0 - 26.0 (29.7 - 38.7) 5.930 (150.6)

5.000 x 7.000 (127.0 x 177.8 ) 20.0 - 26.0 (29.7 - 38.7) 5.930 (150.6)

5.500 x 8.625 (139.7 x 219.1 ) 24.0 - 32.0 (35.7 - 47.6) 7.440 (189.0)

7.000 x 9.625 (177.8 x 244.5) 40.0 - 47.0 (53.6 - 69.9) 8.375 (212.7)

7.000 x 9.625 (177.8 x 244.5) 43.5 - 53.5 (64.7 - 79.5) 8.250 (209.6)

9.625 x 11.750 (244.5 x 298.5) 42.0 - 54.0 (62.5 - 80.3) 10.560 (268.2)

9.625 x 13.375 (244.5 x 339.7) 48.0 - 61.0 (71.4 - 90.7) 12.130 (308.1)

LRP - Long Reach Liner Packer Specifications

DescriptionThe Long Reach Liner Packer (LRP) is an integral liner hanger packer that facilitates successful liner deployment in vertical and long-reach horizontal wellbores in thermal environments. Hydraulic-setting capability, combined with push, pull, and rotation capabilities, allows controlled deployment of the liner without excessive work string manipulation. The LRP features an optional internal circulating string for wellbore fluid displacement. Long Reach Packer elements are available with standard or thermal elastomers for use in steam-injection applications. The LRP is available in standard 80,000 psi (552 MPa) through 125,000 psi (862 MPa) yield materials. Other yield strengths and materials are available on request.

OperationThe LRP is deployed using the Long Reach Setting Tool (LRST). Surface setting pressures are adjustable by manipulating the initial setup for the setting tool. The LRP is conveyed with LRST and set by dropping a ball, dart, or utilizing another plugging system, and pressuring up on the work string. Once the element is packed off, the setting tool hydraulically disconnects from the liner packer without string manipulation, and is retrieved to surface. The LRP can be retrieved if required, by utilizing standard retrieval equipment.

Applications Un-cemented, horizontal wells Well applications requiring rotation when running in hole Operations requiring pushing and pulling the liner to reach target depth High-temperature environments Hanging of light liners Well applications requiring the liner to be held down Well applications requiring a hydraulic liner top packer

Features Integral liner hanger packer on single mandrel Hydraulic pusher mechanism to hang and packoff tool Secondary mechanical-release option Setting tool that accepts inner-string circulation string Optional hold-down slips Optional thermal elastomers

Benefits Minimizes completion time by rotating the liner when running in hole Prevents upward movement of the liner with hold-down slips for safe and secure liner installation Reduces trip time with large fluid bypass

LRP - Long Reach Liner Packer

LRP - Long Reach Liner Packer

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Running Tools MH MOST Setting Tool

CE Liner Running Tool

TBL HSPR Setting Tool - HR Splined Retrievable Bushing

MH Setting Tool - MH Setting Tool - running nut - MH Setting Tool - collet

LRST Long Reach Setting Tool

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Size O.D. in (mm) in (mm)

9.625 (244.5) 8.375 (212.7)

11.750 (298.5) 10.375 (263.5)

MH MOST Setting Tool Specifications

DescriptionThe MH MOST Setting Tool is engineered to generate high setting forces with low surface setting pressures, ideal for thermal liner packers. The rugged design allows for extreme axial loads to be transmitted from the work string through to the liner string.

The robust modular design allows for a wide range of configurations. The setting tool disengages from the liner string hydraulically, making this setting tool ideal for highly deviated well applications.

OperationThe liner packer is conveyed with the MH MOST Setting Tool. Utilizing a ball drop or plugging system, pressure is applied to the work string with the rig pump, the liner packer is hydraulically set, and hydraulically disconnected from the MH MOST Setting Tool.

A positive primary pressure indication is relayed on surface, and the setting tool is straight pulled from the liner packer, back to surface. No work string manipulation is required.

ApplicationsThe MH MOST Setting Tool is designed for running and setting packers when high setting force, and extreme torque and axial loads may be required for placement of liners in deviated wells.

Features Modular design Large internal thru bore Pressure port sand control Large setting piston area Hydraulic release mechanism Internal fluid by-pass release Pressure isolation packoff between the setting tool and the liner packer Incorporates a reliable secondary release mechanism

Benefits Simple run-set-release Rugged reliable design No need for pressure truck Ability to rotate and circulate during deployment Packer pressure test can be completed prior to disconnecting from the liner Adjustable surface setting pressures Positive primary pressure indication for downhole packer system release No work string manipulation required to disconnect from liner Generates high setting force at low surface pressures Able to transmit extreme axial loads Can be run in conjunction with a redundant hydraulic circulation string Incorporates a reliable secondary release mechanism

MH MOST Setting Tool

MH MOST Setting Tool

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Size Max. O.D. in (mm) in (mm)

7.000 x 9.625 (177.8 x 244.5) 8.375 (212.7)

8.625 x 11.750 (219.1 x 298.5) 10.375 (263.5)

CE Liner Running Tool Specifications

DescriptionThe CE Running Tool is a very compact tool, engineered to accept high torque and applied axial loads when required, in order to convey the CE Liner Top Packer and liner to the desired depth.

Circulation rates and differential pressure do not affect the CE Running Tool or CE Liner Top Packer. On the rig, the system can be circulated through at high rates and differential pressures without fear of pre-setting the liner top packer. Once on depth, a positive displacement dart is launched from surface. This dart shifts a sleeve that introduces setting pressures to the system.

The CE Liner Top Packer is set with very low pressures compared to other liner top packers. The robust design disconnects from the liner string hydraulically, making this setting tool ideal for highly deviated well applications.

OperationThe CE Packer is conveyed with the CE Running Tool. Utilizing a dart, a calculated volume is circulated to seat the dart at the running tool. Pressure is applied to the work string with the rig pump. The CE Packer is hydraulically set, and the CE Running Tool is hydraulically disconnected from CE Packer.

A positive primary pressure indication is relayed on surface. The CE Running Tool can be straight pulled from the CE Packer, or with the work string in compression, a pressure test of the CE Packer can be completed down the annulus. After which, the running tool can be retrieved to surface, as no work string manipulation is required to disconnect.

ApplicationsThe CE Liner Running Tool is designed for running and hydraulically setting liner packers where high torque and axial loads may be required. The compact length of this tool makes it ideal for placement of liners in highly deviated wells.

Benefits Compact length Pressure balanced dart activated primary release Integral secondary release Capable of handling high circulating rates and differential pressures

Features Simple run-set-release Rugged reliable design No need for pressure truck Ability to rotate and circulate during deployment Packer pressure test can be completed prior to disconnecting from the liner Adjustable surface setting pressures Positive primary pressure indication for downhole packer system release No work string manipulation required to disconnect from liner Incorporates a reliable secondary release mechanism

CE Liner Running Tool

CE Liner Running Tool

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Size Max. O.D. in (mm) in (mm)

7.000 (177.8) 5.875 (149.2)

8.625 (219.1) 7.500 (190.5)

9.625 (244.5) 8.438 (214.3)

HSPR Setting Tool Specifications

DescriptionThe HSPR Setting Tool is engineered to generate high setting forces with low surface setting pressures, ideal for thermal packers. The rugged design allows for torque and axial loads to be transmitted from the work string through to the liner packer, with the ability to circulate large volumes and rates.

The robust modular design allows for a wide range of configurations. The setting tool disengages from the liner string hydraulically, making this setting tool ideal for highly deviated well applications, with a reliable secondary mechanical release incorporated into the design of the setting tool.

OperationThe packer is conveyed with the HSPR Setting Tool. Utilizing a ball drop or plugging system, pressure is applied to the work; the liner packer is hydraulically set, and hydraulically disconnected from the HSPR Setting Tool.

A positive primary pressure indication is relayed on surface, and the setting tool is straight pulled from the liner packer, back to surface. No work string manipulation is required.

ApplicationsThe HSPR Setting Tool is designed for running and setting the TBL and LBL liner packers hydraulically on tubing and is capable of transmitting high torque and axial loads through to the packer. This tool is ideal for placement of liners in deviated wells.

Benefits Modular design Large internal thru bore Large setting piston area Primary hydraulic release mechanism Mechanical secondary release Integral clutch system Pressure isolation packoff between the setting tool and the liner packer

Features Simple run-set-release Rugged reliable design Ability to rotate and circulate during deployment Adjustable surface setting pressures Positive indication of primary pressure for liner release No work string manipulation required to disconnect from liner Generates high setting force Capable of large circulating volumes Able to transmit torque and axial loads Can run in conjunction with a redundant hydraulic circulation string

HSPR Setting Tool

HSPR Setting Tool

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Size Seal O.D. in (mm) in (mm)

7.000 (177.8) 5.900 (149.9)

8.625 (219.1) 8.375 (212.7)

9.625 (244.5) 10.375 (263.5)

HR Splined Retrievable Bushing Specifications

DescriptionThe HR Splined Retrievable Bushing is a reliable and versatile external seal system suitable for high pressure and high temperature applications.This bushing is designed to be run in conjunction with the HSPR Setting Tool enabling the transmission of torque through the HSPR Setting Tool to the Liner Hanger Packer.

OperationThe HR Splined Retrievable Bushing is connected to the bottom of the HSPR Setting Tool and the assembly is made up onto the liner packer.The torque transmitting mechanism of the bushing can be hydraulically disengaged. Once the torque mechanism has been disengaged, the HSPR Setting Tool can rotate independent of the liner hanger packer, allowing the setting tool to detach (back-off) from the liner hanger packer (liner string) through right hand rotation.

ApplicationsThe HR Splined Retrievable Bushing is designed for running and setting the TBL and LBL thermal liner hanger packers hydraulically on tubing where torque or circulation may be required.

Features Seals in the tieback receptacle of the liner hanger packer using self lubricating seals Transmits torque from the drill string to the liner through the HSPR setting tool and liner packer Adjustable torque mechanism release pressure Torque transmission mechanism locks in released position to prevent re-engaging Robust design

Benefits Torque transmitting mechanism of bushing is released hydraulically External seal enables a circulation string to be run through the liner No tubing manipulation required to set Retrieval with standard fishing tools

HR Splined Retrievable Bushing

HR Splined Retrievable Bushing

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Size O.D. in (mm) in (mm)

7.000 (177.8) 5.875 (149.2)

8.625 (219.1) 7.500 (190.5)

MH Setting Tool Specifications

DescriptionThe MH Setting Tool is hydraulic setting tool capable of generating high setting forces that are required for thermal element systems.

OperationThe MH Setting Tool is made up to the top of an MH thermal product and run into the well. Once on depth, the MH Setting Tool is pressured up in stages to engage the slips and thermal element of the MH Packer. Once the required final setting pressure has been achieved, the pressure is bled off and the running string weight is adjusted to neutral. Right hand rotation is applied through the running string to release the running nut on the MH Setting Tool from the MH Liner Packer allowing for the retrieval of the setting tool.

ApplicationsThe MH Setting Tool is utilized for the deployment and setting of the MH Thermal down hole products which include the MH Liner Hanger Packer, MH Bridge Plug and MH Casing Patch.

Features Hydraulic set No pipe manipulation required during setting Large setting piston area Modular Robust design

Benefits Simple to run and set Low surface setting pressure Ability to be set in highly deviated wells Cost effective Field proven Reliable

MH Setting Tool - with running nut

MH Setting Tool - with running nut

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Size O.D. in (mm) in (mm)

7.000 x 5.000 (177.8 x 127.0) 5.875 (149.2)

9.625 x 7.000 (244.5x 177.8) 8.250 (209.6)

MH Setting Tool Specifications

DescriptionThe MH Hydraulic Setting Tool is designed for generating high pack off forces required for setting the Dynaseal thermal element used on MH thermal products. These products include the MH Thermal Liner Hanger Packer, MH Thermal Casing Patch and the MH Thermal Step Casing Patch.

OperationThe MH Setting Tool is made up to the top of an MH thermal product and run into the well dry. For casing patches, the addition of the bottom collet assembly and spacer pipe is also required. Once on depth, the MH Setting Tool is pressured up hydraulically in stages to engage the slips and elements of the MH down hole tool. Once the final setting pressure has been achieved, straight pull at the running tool will release the MH Setting Tool from the down hole products. For deployment of long liners or a long patch section, the MH Setting Tool is made up to a running nut which requires right hand rotation for release.

ApplicationsThe MH Setting Tool is utilized for the deployment and setting of the MH family of thermal down hole products.

Benefits Ability to be set in highly deviated wells Cost effective Field proven

Features No rotation required for setting Hydraulic set Robust design

MH Setting Tool - with collet

MH Setting Tool - with collet

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Size in (mm)

4.500 x 7.000 (114.3 x 177.8 )

5.000 x 7.000 (127.0 x 177.8 )

5.500 x 8.625 (139.7 x 219.1 )

7.000 x 9.625 (177.8 x 244.5)

9.625 x 11.750 (244.5 x 298.5)

LRST - Long Reach Setting Tool Specifications

DescriptionThe Long Reach Setting Tool (LRST) is used exclusively to run liner systems that use the Long Reach Liner Packer (LRP). The setting tool includes a collet-type hydraulic-release liner deployment and release mechanism, as well as a pusher sleeve to pack off the LRP. No rotation is required to release the LRST from the liner, making it suitable for horizontal and high-inclination wells. The LRST allows the Long Reach Liner system to be pushed, pulled, and rotated to achieve target depth. An internal bypass feature reduces formation surge pressures and allows faster running speeds. The LRST also features a backup mechanical-release mechanism (option) that reduces the risk of not being able to release the LRST from the liner. The mechanical release is achieved by a one-quarter turn to the left.

OperationThe packer is conveyed with the LRST. Utilizing a ball drop, dart, or another plugging system, pressure is applied to the work string; the packer is hydraulically set, and hydraulically disconnects from the LRST. A positive pressure indication is relayed on surface, and the setting tool is straight pulled from the liner packer, back to surface. No work string manipulation is required.

Applications Horizontal wells Well applications requiring rotation when running in hole Operations requiring pushing and pulling the liner to reach target depth Well applications requiring a hydraulic setting and release mechanism

Features Clutch design to transmit torque to the liner Hydraulic pusher sleeve to hang and pack off tool Setting tool that accepts inner circulation string Backup mechanical release to ensure liner release (1/4 left-hand turn)

Benefits Minimize completion time by rotating the liner when running in hole Reduces risk of pulling liner out of well and saves associated time and costs with secondary-release option

LRST - Long Reach Setting Tool

LRST - Long Reach Setting Tool

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Remedial Tools Mechanical Packers - Cup Type Test Tool

Bridge Plugs - Thermal Permanent Bridge Plug - MH Thermal Retrievable Bridge Plug

Casing Patches - MH Thermal Casing Patch - MH Thermal Patch Bottom

Scrapers & Drift Subs - Model A Casing Scraper - Drift Lock Casing Scraper - FD Drift Sub

Tubing Accessories - Thermal Sliding Sleeve - Burst Joint - Thermal Expansion Joint - Thermal Pumpout Float Valve - Thermal Latch Down Plug

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Casing Size Casing Weight Range Gauge O.D. in (mm) lb/ft (kg/m) in (mm)

8.625 (219.1) 28.0 - 36.0 (41.7 - 53.6) 7.700 (195.6)

9.625 (244.5) 47.0 - 58.4 (59.5 - 69.9) 8.281 (210.3)

Cup Type Test Tool Specifications

DescriptionThe Cup Type Test Tool is designed for locating casing leaks, with the ability for downward movement under pressure for determining exact point of leak off.

OperationThe Cup Type Test Tool is typically made up with a bypass valve above it, and lowered into the wellbore. The test tool is run to depth with the bypass valve closed. With the pack-off head or the pipe rams closed at surface, pressure is applied on the annulus and charted to determine whether there is a leak off. If a pack-off head is used, connections may be made up and the work string lowered into the well until a bleed off point is found. Once the leak point has been determined, the test tool is retrieved by; bleeding off the annulus pressure, opening the bypass valve, and pulling the assembly from the wellbore.

Applications Pressure testing of BOPs Pressure tesing for casing leaks

Features Packer cup type element system Can be run in conjunction with a Model A Bypass Valve Tested via annular pressure Standard configuration utilizes redundant cups

Benefits Setting tool not required Ability to maintain pressure on tool while lowering tubing through a pack-off, to determine the exact point of bleed off

Cup Type Test Tool

Cup Type Test Tool

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Casing Size Casing Weight Range Plug O.D. in (mm) lb/ft (kg/m) in (mm)

4.500 (114.3) 9.5 - 15.1 (14.1 - 22.5) 3.562 (90.5)

5.000 (127.0) 11.5 - 20.8 (17.1 - 31.0) 3.937 (100.0)

5.500 (139.7) 13.0 - 23.0 (19.4 - 34.3) 4.312 (109.5)

6.625 (168.3) 17.0 - 32.0 (25.3 - 47.6) 5.375 (136.5)

7.000 (177.8) 17.0 - 35.0 (25.3 - 52.1) 5.687 (144.4)

7.625 (193.7) 20.0 - 39.0 (29.8 - 58.0) 6.312 (160.3)

8.625 (219.1) 24.0 - 49.0 (35.7 - 72.9) 7.125 (181.0)

9.625 (244.5) 29.3 - 58.4 (43.6 - 86.9) 8.125 (206.4)

Thermal Permanent Bridge Plug Specifications

DescriptionThe Thermal Permanent Bridge Plug (TPBP) is the thermal version of the reliable HM-1B and DB bridge plug. The thermal permanent bridge plugs are an economical way to suspend or abandon a well bore while maintaining the ability to drill out the bridge plug and re-enter the hole.

OperationThe TPBP is run and set utilizing the compact hydraulic setting tool. The TPBP is run to depth on the hydraulic setting tool and work string. The work string is filled and pressured up to initiate a set. The work string is pulled into tension aiding in the pack off, and locking the setting force into the element. It is a best practice to hold hydraulic pressure and pull tension into the bridge plug, and repeat. Once the element is packed off, right hand rotation will release the setting tool from the bridge plug.

Applications Thermal applications requiring a permanent bridge plug Abandonments requiring a thermal bridge plug

Features Field proven Simple design Compact design allows greater casing access No elastomers eliminate leak paths

Benefits Full circle, one piece slips Hydraulic set with retrievable setting tool Compact Tapered nose Thermal element rated to 350 C No elastomers

Thermal Permanent Bridge Plug

Thermal Permanent Bridge Plug

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Size Weight Range Packer O.D. in (mm) lb/ft (kg/m) in (mm)

7.000 (177.8) 23.0 - 29.0 (34.2 - 43.2) 5.900 (149.9)

9.625 (244.5) 36.0 - 47.0 (53.6 - 69.9) 8.375 (212.7)

11.750 (298.5) 38.0 - 60.0 (56.6 -89.3) 10.375 (263.5)

MH Thermal Bridge Plug Specifications

DescriptionThe MH Thermal Bridge Plug is part of the MH family of thermal completion technology. It is a hydraulically set bridge plug for use in thermal applications. It has a temperature rating of 343 C, and utilizes Schlumbergers metal to metal system in conjunction with a thermal element.

The design for this product includes no elastomers. It is engineered for harsh environments that exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds.

OperationThe MH Thermal Bridge Plug is designed to be run and set utilizing a hydraulic setting tool which is engineered for producing high setting forces and handling high axial loads. Surface setting pressures are adjustable by manipulating the initial setup for the setting tool.

The MH Thermal Bridge Plug is conveyed with a hydraulic setting tool and set by dropping a ball, or utilizing a plugging system, and pressuring up on the work string. Once the thermal element is packed off, the setting tool hydraulically disconnects for the liner packer without string manipulation, and is retrieved to surface.

The MH Thermal Bridge Plug can be retrieved if required, by utilizing standard fishing equipment.

ApplicationsThe MH Thermal Bridge Plug is designed for thermal applications. It is designed specifically for temporary well bore suspension in thermal applications, or utilized for zonal isolation.

Features Large beveled re-entry sleeve Top and bottom anchoring slips MH Bridge Plug has top and bottom slips Metal to metal seal with static element NACE MR0175 compliant for environments containing H2S

Benefits Thermal element rated to 343 C No work string manipulation required to set Standard tools/spears used for retrieval Adjustable surface setting pressures

MH Thermal Bridge Plug

MH Thermal Bridge Plug

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DescriptionThe MH Thermal Casing Patch incorporates the benefits of both MH Thermal Liner Hanger packer and the MH Thermal Patch Bottom. The system is hydraulically set, mechanically retrievable, and used for patching casing integrity issues or utilized as a sand management system at the liner top.With a temperature rating of 343 C, Schlumbergers metal to metal system in conjunction with the thermal element is capable of an initial pressure test to 21 MPa. The casing patch incorporates anchoring slips at the top of the assembly, with a high temperature slip-less system at the bottom end. This compensates for temperature induced expansion and contraction of the tubulars in thermal applications. The design for this product includes no elastomers. It is engineered for harsh environments which exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds.

OperationThe MH Thermal Casing Patch is designed to be run and set utilizing a hydraulic setting tool which is engineered for producing high setting forces and handling high axial loads. Surface setting pressures are adjustable by manipulating the initial setup for the setting tool. The MH Thermal Casing Patch is conveyed utilizing a hydraulic setting tool with the MH Collet Setting assembly in place. The patch is set by dropping a ball, or utilizing a plugging system, and pressuring up on the work string. Once the thermal elements are packed off, the setting tool hydraulically disconnects from the Casing Patch without string manipulation, and is retrieved to surface. The MH Thermal Casing Patch can be retrieved if required, by utilizing standard retrieval equipment.

ApplicationsThe MH Thermal Casing Patch is designed for remedial wellbore repair thermal applications. It is primarily used to isolate damaged casing, and isolate leaking liner tops, and yet it is still fully retrievable.

Features Large beveled upper re-entry sleeve Large through bore Upper anchoring slips with a slip-less bottom end design Half-muled and beveled lower re-entry guide Metal to metal seals with static element NACE MR0175 compliant for environments containing H2S

Benefits Thermal element rated to 343 C No work string manipulation required to set Standard tools/spears used for retrieval Allows for expansion and contraction independent of the casing Spacer pipe lengths from 1.0 meter to 200+ meters Anchored during thermal cycling Adjustable surface setting pressures

MH Thermal Casing Patch

MH Thermal Casing Patch

Rev. 00 Page 18

Size Weight Range in (mm) lb/ft (kg/m)

3.500 x 4.500 (88.9 x 114.3) 11.6- 12.6 (17.3 - 18.8)

4.000 x 5.500 (101.6 x 139.7) 15.5- 20.0 (23.1 - 29.8)

5.000 x 7.000 (127.0 x 177.8) 23.0 - 29.0 (34.2 - 43.2)

5.500 x 7.000 (139.7 x 177.8) 20.0 - 26.0 (29.8 - 38.7)

7.000 x 9.625 (177.8 x 244.5) 36.0 - 47.0 (53.6 - 69.9)

8.625 x 11.750 (219.1 x 298.5) 38.0 - 60.0 (56.6 - 89.3)

MH Patch Bottom Specifications

DescriptionThe MH Thermal Patch Bottom is a high temperature packer assembly which allows for temperature induced expansion and contraction of tubulars in thermal applications. It is designed to be run with the MH Thermal Liner Hanger Packer, creating a reliable retrievable casing patch solution for thermal applications. The MH Thermal Patch Bottom can also be run with other thermal upper completion packers, permanent or retrievable. With a temperature rating of 343 C, Schlumbergers metal to metal system in conjunction with the thermal element is capable of an initial pressure test to 21 MPa. The design for this product includes no elastomers. It is engineered for harsh environments which exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds.

OperationThe MH Thermal Patch Bottom is typically conveyed with an upper packer, or on the bottom end of the patch pipe. It is set utilizing the MH Collet Setting Assembly, and can be set in conjunction with the upper packer, or can also be set independent of the upper packer. The setting assembly can be mechanically actuated by straight pickup of the work string, or it can be actuated by hydraulically pressuring up on hydraulic setting tool, which will induce upwards force into the work string. The applied upward force in the work string packs off the thermal element and releases the setting collet from the MH Thermal Patch Bottom, when the required setting force has been achieved. The setting assembly is retrieved by simple pick-up of the work string, and retrieval to surface.

ApplicationsThe MH Thermal Patch Bottom is designed for thermal applications. It is primarily used as the lower seal in a retrievable casing patch type application in conjunction with an upper packer. When used in tandem with another packer, the MH Thermal Patch Bottom can isolate damaged casing, isolate leaking liner tops, or serve as a tieback seal assembly.

Features Large through bore Slipless design Muled, beveled re-entry guide Metal to metal seal with static element NACE MR0175 compliant for environments containing H2S

Benefits Thermal element rated to 343 C Packoff can be re-energized Standard tools/spears used for retrieval Hydraulic setting tool or mechanically set Allows for expansion and contraction independent of the casing

MH Thermal Patch Bottom

MH Thermal Patch Bottom

Rev. 00 Page 19

Model A Casing Scraper Specifications

Casing Size Weight Range Thread Connection in (mm) ppf (kg/m) in (mm)

4.500 (114.3) 9.5 - 13.5 (14.1 - 20.1) 2.375 (60.3) API Regular

5.000 (127.0) 11.5 - 21.4 (17.1 - 34.8) 2.375 (60.3) API Regular

5.500 (139.7) 13.0 - 26.0 (19.4 - 38.7) 2.875 (73.0) API Regular

6.625 (168.3) 23.2 - 32.0 (34.5 - 47.6) 3.500 (88.9) API Regular

7.000 (177.8) 17.0 - 32.0 (25.3 - 47.6) 3.500 (88.9) API Regular

8.628 (219.1) 28.0 - 49.0 (41.7 - 72.9) 3.500 (88.9) API Regular

9.625 (244.5) 32.3 - 47.0 (48.1 - 69.9) 4.500 (114.3) API Regular

10.750 (273.1) 32.8 - 65.7 (48.7 - 97.8) 4.500 (114.3) API Regular

11.750 (298.5) 38.0 - 71.0 (56.6 - 105.7) 4.500 (114.3) API Regular

13.375 (339.7) 48.0 - 80.7 (71.4 - 120.1) 4.500 (114.3) API Regular

DescriptionThe Model A Casing Scraper is used to remove cement sheath, perforating burrs, scale, and other foreign matter from the inside walls of the casing by providing full 360 coverage with blade blocks.

OperationThe Model A Casing Scraper should be run pin thread up and box thread down. This scraper operates equally well when reciprocated vertically or rotated. In areas of the casing where sheath or burrs may exist, he casing scraper should be worked up and down through the area several times. This is especially important in areas of perforations or where a packer is to be set. If desired, the casing scraper may be rotated (always clockwise) while reciprocating.

ApplicationsDesigned to utilized prior to running packers, bridge plugs and other equipment employing pack-offs, slips, cups, etc. These packers etc, are manufactured to close tolerances and require that the casing I.D. be smooth and free from obstructions. An obstruction or a sheath of foreign matter in the casing I.D. may damage or interfere with the proper setting of slips or seals and may result in tool failure.

Features Large bypass area between blades to allow for circulation Self-sharpening blades provide full 360 coverage of casing I.D. All thrust and rotational loads are carried by the scraper body, not by the retaining screws Robust design Built for use with common pipe connections

Benefits Rugged, one-piece alloy steel body Tough alloy blades are designed for extra long wear Blades are individually locked into the scraper body for ease of repair

Model A Casing Scraper

Model A Casing Scraper

Rev. 00 Page 20

Drift Lock Casing Scraper Specifications

Casing Size Thread Connection in (mm) in (mm)

4.500 (114.3) 2.375 (60.3) EUE

5.500 (139.7) 2.875 (73.0) EUE

7.000 (177.8) 3.500 (88.9) EUE

8.625 (219.1) 3.500 (88.9) EUE

9.625 (244.5) 4.500 (114.3) EUE

DescriptionThe Drift Lock Casing Scraper was designed and built with Heavy Oil applications in mind. With the high instance of casing anomalies due to thermal stresses or strains, the Drift Lock Casing Scraper combines the features of both a casing scraper and drift gauge in one design. Each Drift Lock Casing Scraper is designed to lock the blades extended to the drift I.D. of the specific casing weight of a particular casing size.

OperationMake up Drift Lock Casing Scraper to the work string and run in hole. Reciprocate up and down, and/or rotate clockwise, to clean areas where obstructions were detected or where the packer is to be set.

As the Drift Lock Casing Scraper is lowered into the well bore, the angled scraper blades automatically rotate into the drift-locked position against the casing wall. The scraper blades rotate back to the standard non-drift (fully collapsible) position as the Drift Lock is retrieved from the well bore.

If any casing anomalies are encountered while running into the well bore, pick up the Drift Lock Casing Scraper above the anomaly, rotate turn to the left to unlock the scraper blades from drift, and reciprocate through the anomaly.

ApplicationsThe Drift Lock Casing Scraper is utilized to remove scale, cement sheath, perforating burrs, and other foreign matter from the casing walls. In the locked position, the scraping blades cannot collapse below drift size of the casing. This will ensure the casing I.D. is smooth and free from obstructions, prior to running any completions. If any obstruction is detected, the Drift Lock Casing Scraper can be switched to the unlocked position and reciprocated until the anomaly drifts, or is removed.

Features Automatically locks blades extended to drift I.D. while running Self-sharpening blades provide full 360 coverage to casing drift I.D. Large bypass channels around and between blades Built for use with common pipe connections Full bore I.D.

Benefits Confirms full drift I.D. of casing More efficient than conventional casing scrapers The scraper blades lock to drift size automatically when reciprocating down hole Can be adjusted while running, allowing the scraper to pass through restrictions Robust design

Drift Lock Casing Scraper

Drift Lock Casing Scraper

Rev. 00 Page 21

Casing Size Casing Weight Drift Sub O.D. in (mm) ppf (kg/m) in (mm)

8.628 (219.1) 36.0 (53.6) 7.700 (195.6) 9.625 (244.5) 40.0 (59.5) 8.679 (220.5) 9.625 (244.5) 43.5 (64.7) 8.599 (218.4) 11.750 (298.5) 47.0 (69.9) 10.844 (275.4) 13.375 (339.7) 61.0 (90.8) 12.359 (313.9)

FD Drift Sub Specifications

DescriptionThe FD Drift Sub is an economical means of confirming down hole tool casing bore when running liner hangers and/or packers in deviated well bores prior to running the liner.

OperationThe fluted FD Drift Sub is typically run along with a casing scraper and tubing. Deploying this bottom hole assembly confirms torque and drag values as well as confirming the ability to land the final bottom hole assembly at the desired depth. This assembly is run-in-hole to the first deviated section of the well and then slowly run through deviated sections of the intermediate casing while monitoring and recording torque and drag. Once the bottom hole assembly has reached the desired depth (end of the casing string), the drill pipe drift can be dropped from surface to land in the Totco ring. A successful drift confirms that the deployment string has a internal diameter that will allow an OD specific phenolic ball, used for setting hydraulic liners and/or packers, to reach the liner and/or packer setting tool.

Applications Used to ensure casing is open to full drift ID For thermal and non-thermal applications to ensure full drift ID of casing prior to running down hole equipment

Features Spiral fluted bypass incorporated to allow for circulation while maintaining full circumference drift diameter Built for use with common pipe connections Robust design Bottom hole assembly can be run in variable lengths

Benefits Confirms passage of future liner hangers and packer assemblies Torque and drag values are validated

FD Drift Sub

FD Drift Sub

Rev. 00 Page 22

DescriptionThe CS(X)-3U-0 Thermal Sliding Sleeve is a communication device with a ported inner sleeve. Sizeable chokes are available as options for adjusting the opening to the tubing annulus.

The simplicity of the sliding sleeve design provides a long operating life. Equalizing slots in the inner sleeve permit gradual equalization between the tubing and casing annulus. The sleeves may be ordered with Otis-style X-type and Baker-style F- and R-type landing profiles.

OperationThe CS(X)-3U-O Thermal Sliding Sleeve can be opened or closed using a shifting tool and standard wireline and coiled tubing methods. The CS(X)-3U-O Thermal Sliding Sleeve shifts up to open, and down to close. The sliding sleeve is assembled to, and forms part of the tubing string.

Equalizing pressure between the tubing and casing annulus is normally accomplished by applying pressure or filling the tubing or casing with fluid. The sliding sleeve can also be opened even if facilities for equalizing pressures are not available beforehand. This requires careful monitoring of tubing and annulus pressures while slowly opening the sleeve until equalization.

ApplicationsThe CS(X)-3U-O Thermal Sliding Sleeve is designed for steam injection / heavy oil production applications. There are two operating positions for the sleeve, fully open and fully closed.

For injection applications, the number of sliding sleeves and orifice sizes can be setup to balance steam injection, ensuring that steam is being placed in each interval / segment of the wellbore.

For production applications, the sliding sleeve can be setup to ensure production from each zone based on the number and size of orifices required.

Each Thermal Sliding Sleeve is available with various orifice sizes and installed quantity. Depending on the desired injection / production rate, the orifices are selected.

Features NACE MR0175 compliant for environments containing H2S Includes sizeable orifices in the tubing to-annulus communication ports Non-elastomeric seals Available with landing nipple profiles

Benefits Compact and simple design Replaceable chokes Choice of nipple profiles Qualified to: 2,000 psi @ 580 F (13.8 MPa @ 304 C) 1,000 psi @ 600 F (6.9 MPa @ 316 C)

CS(X)-3U-O Thermal Sliding Sleeve

CS(X)-3U-O Thermal Sliding Sleeve

Rev. 00 Page 23

Size Standard Thread Burst Pressure in (mm) Configuration psi (kPa)

2.375 (60.3) EUE box x pin 3,000 (20,684) 2.875 (73.0) EUE box x pin 3,000 (20,684) 3.500 (88.9) EUE box x pin 3,000 (20,684) 4.500 (114.3) LTC pin x pin 3,000 (20,684) 5.500 (139.7) LTC pin x pin 3,000 (20,684)

Internal Cut Window Burst Joint Specifications

* Other thread configurations and burst pressures are available upon request

DescriptionThe Internal Cut Window Burst Joint is designed for thermal applications where an elastomeric type tubing drain is not feasible.

OperationThe burst joint is made up in the tubing string immediately above the pump seating nipple, and run in the well as part of the tubing string. In the event the rod string parts, pressuring up on the tubing string in excess of the burst pressure will burst out the window of the burst joint, providing a large drainage area. This will allow for a dry trip while retrieving the tubing, rods, and pump.

Applications Thermal installations in place of a standard elastomeric tubing drain

Features Rated for temperatures to 350 C and above +/- 5% burst accuracy Various burst pressures available

Benefits Internally cut profile reduces the potential of rod wear affecting the burst value of the burst joint Large drainage window

Internal Cut Window Burst Joint

Intermal Cut Window Burst Joint

Rev. 00 Page 24

Size Stroke Length O.D. in (mm) feet (meters) in (mm)

7.000 x 5.500 (177.8 x 139.7) 13.17 (4.01) 7.656 (194.5)

Thermal Expansion Joint

DescriptionThe Thermal Expansion Joint is a high temperature expansion device which compensates for temperature induced expansion and contraction of tubulars in thermal applications.

When in the fully extended position, a robust clutch system allows for torque and axial loads to be transmitted through the expansion joint.

The design for this product includes no elastomers. It is engineered for harsh environments which exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds

With a temperature rating of 650 F (343 C), Schlumbergers metal to metal seal system in conjunction with a thermal seal is capable of holding 3,000 psi (21.7 MPa) of differential pressure.

The thermal expansion joint can be manufactured to any length to suit customer requirements and allows safe installation and retrieval of the tubing string and completion components.

ApplicationsThe Thermal Expansion Joint is designed for use in thermal cycling applications to reduce liner stresses. Commonly used where compensation is required for expansion or contraction of tubulars during enhanced oil recovery operations. It is primarily used in the liner system below a thermal liner hanger packer.

Features NACE MR0175 compliant for environments containing H2S Non-elastomeric seals Integral clutch system Can be setup for any length

Benefits Thermal seals rated to 650F (343C) Able to rotate and circulate during deployment Fullbore access to liner Adjustable shear system

Thermal Expansion Joint

Thermal Expansion Joint

Rev. 00 Page 25

Size / Connection O.D. in (mm) in (mm) 2.875 (73.0) EUE 3.668 (93.2) 5.000 (127.0) Buttress 5.563 (141.3)

Thermal Pumpout Float Valve Specifications

DescriptionThe Thermal Pump-out Float Valve (TPFV) is a float valve, for use in thermal applications. The TPFV is designed to allow steam injection into the reservoir while stopping the reservoir from flowing back. After steam injection is complete, reservoir production is initiated by dropping a ball and pumping off the float valve.

The design for this product includes no elastomers. It is engineered for harsh environments which exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds With a temperature rating of 650 F (343 C), Schlumbergers metal to metal seal system in conjunction with a thermal seal is capable of holding 3,000 psi (21.7 MPa) of differential pressure.

OperationInstall the TPFV into the completion design and run to depth. Perform the steam injection program for the wellbore. Once completed the steam program, and production is required, drop the appropriate size of ball and seat in the valve. At the predetermine pressure, the valve will release, and production through the TPFV is possible.

ApplicationsUsually installed on the bottom of a MH Thermal Liner Hanger Packer, the TPFV is utilized in thermal wells, for temporary suspension of reservoir production.

Features Rugged, reliable design NACE MR0175 compliant for environments containing H2S Non-elastomeric seals Adjustable pump out pressure

Benefits Thermal seals rated to 650 F (343 C) Temporary wellbore suspension is achievable without intervention Operates in highly deviated wells, negating the need for CT operations to set plugs

Thermal Pumpout Float Valve

Thermal Pumpout Float Valve

Rev. 00 Page 26

Tubing Size Profile - Type / Size in (mm) in (mm)

3.500 (88.9) 2.312 (58.7) X

Thermal Latch Down Plug Specifications

DescriptionThe Thermal Latch Down Plug has been designed for thermal applications where liners are circulated into place, and isolation of the flow port is required. The plug will seal and isolate flow out through the toe of the liner, or at any position in the string, where the landing sub or profile is placed.

It is engineered for harsh environments which exceed the temperature and pressure limits for elastomers, such as o-rings, packing and rubber compounds With a temperature rating of 650 F (343 C), Schlumbergers metal to metal seal system in conjunction with a thermal seal is capable of holding 3,000 psi (21.7 MPa) of differential pressure.

OperationInstall the landing sub into the liner, or workstring, and deploy to desired depth. Once all completion operations or stimulation operations have been completed, pick up the Thermal Latch Down Plug with the running tool, and run the assembly. Once on depth, pick up to set the thermal seals, and shear off the running tool to POOH.

ApplicationsThe Thermal Latch Down Plug is used for thermal applications where a latch down plug is required.

Features Mechanical deployment and retrieval NACE MR0175 compliant for environments containing H2S Adjustable release loads

Benefits Thermal seals rated to 650 F (343 C) Positive shutoff for the liner shoe Lands in standard size profile sub Pressure testable for tubular isolation Straight pull retrieval

Thermal Latch Down Plug

Thermal Latch Down Plug

Rev. 00 Page 27

Reservoir Monitoring Distributed Temperature Systems - WellWatcher BriteBlue HT

Acquisition Systems - WellWatcher Ultra - WellWatcher Ultra ASE

Monitoring Accessories - Turn Around Sub - Bullnose Pressure Port - Thermal Disconnect - Shower Head - Wellhead Outlet

Rev. 00 Page 28

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ApplicAtions Heavyoilthermalrecoverymonitoring Distributedtemperature

measurements Controlofproductionrates

anddrawdown Productionallocation

Benefits Longerfiberloggingandincreasedsys-

temlifeduetoimprovedinterrogation Reductionofsystemcoststhrough

reducedfiberlength Long-term,reliable,permanentin-well

reservoirmonitoring Enhancedrecoveryandproduction

managementthroughimprovedreservoirsurveillance

Fastidentificationofproductionprob-lemsthroughbest-in-classtemperaturemeasurements

Minimizedserviceinterventions

feAtures Multiplelaserinterrogation Dynamicfiberlosscorrectionalong

everymeteroffiberforeveryacquiredtemperatureprofile

CompatibilitywithWellWatcherBriteBlue*multimodefiber,formaximumsystemlife

Nodownholeelectronics Simple-to-usesurfacesoftwarewith

autosetupandoptimization

Reliability,robustness,andextendedsystemlife

Range:6km[3.73mi] 12single-endedchannels

Inharshenvironments,suchasthermalrecoveryandhigh-pressure,high-temperatureapplications,measuringfromonlyoneendofafibercanleadtoadeteriorationinaccuracywhenthefiberbeginsshowingsignsofhydro-gendegradation.TheextremelyversatileWellWatcherUltraASE*distributedtemperaturesensing(DTS)systemdynamicallycorrectsforsuchfiberlossalongtheentirelengthofthesensingmultimodefiber.Thissystemprovidesanaccuratesingle-endedfiber-loss-correctedtemperatureprofileforreservoirmonitoring.Itmeasuresupto6km[3.73mi]offiberatametersresolution,updatesdatainjustafewseconds,andinterrogatesnumerousfibersfromonesurfacesystem.Asaresult,theWellWatcherUltraASElastslongerandallowssimplifiedcompletiondesigns,comparedwithstandardDTSsystems.

Thedataobtainedareavailableassoonasthemeasurementistaken.Theyarecommunicatedviavariousindustry-standardprotocolsorthosecustomizedbySchlumbergersengineeringteamtothespecificsofaparticularinstallation.The

dataarecombinablewithdataobtainedbyotherSchlumbergersensors,andexpertsareavailabletohelpderivethebestsolutionfromthedatatoallowoperatorstomakekeydecisionswithconfidence.

Acquisition resultsTheWellWatcherUltraASEacquisitionsys-temcanrevitalizewellsinwhichtheopticalfiberhasdegraded.Accuratetemperatureprofilescanbeobtainedwithouttheexpenseoffiberreplacement.

Toenhancesystemlifeintheharshestwell-boreconditions,acustom-designedfiber-op-ticsolutioncanbeobtainedbycombiningtheASEsystemwiththeWellWatcherBriteBluemultimodefiber.

The graph shows distributed temperature measurements in a typical heavy-oil thermal recovery well. The surface fiber connects to the wellhead at 150 m, after which the fiber goes downhole, carried by a control line clamped to the completion. The temperature variation at 400 m indicates a change in the wellbore fluid level. The con-ventional DTS system temperature plot is affected by fiber degradation, and a temperature error is induced. The WellWatcher Ultra ASE system, on the other hand, accounts for this degradation; the graph clearly shows how the system has corrected for an error of >45 degC.

WellWatcher Ultra ASEAccuratesingle-endeddistributedtemperaturesystem

The WellWatcher Ultra ASE system is designed for challenging field conditions. It incorporates rugged design, portability, and ease of use for field personnel.

Fiber length, m

Tempe

rature, deg

C

250

200

150

100

50

0100 200 300 400 500 600 700 800

New downhole thermocouples

WellWatcher Ultra ASE system

Conventional DTS system

Errorcorrection

Rev. 00 Page 33

www.slb.com/wellwatcher

WellWatcher Ultra ASE

WellWatcher ultra Ase specificationsRange, km [mi] 6 [3.73] Spatial resolution, m [ft] 12 [3.36.6] Sample interval, m [ft] 0.51 [1.643.3] Calibration accuracy, degC [degF] 2 [3.6] at (06 km on Schlumberger fibers) Number of loops or fibers 12 single-endedFiber type 50 um, multimodeDTS physical dimensions 3U 19-in, rack mounted or mobileOperating temperature, degC [degF] 0 to 40 [32 to 104]Storage temperature, degC [degF] 20 to 65 [4 to 149] Relative humidity, % 585 (noncondensing) Power AC, 90253 V (optional DC, 24 V); typical steady state: 50 W; maximum: 150 WDTS communications

DTS to PC Ethernet 100/1,000 Base T DTS to Modbus PLC Ethernet 10/100 Base T Laser classification Class 1m (IEC/EN 60825-1 [2001])

*MarkofSchlumbergerCopyright2010Schlumberger.Allrightsreserved.10-CO-0148

Invisible laser radiationDo not view directly

with optical instrumentsClass 1M laser product

INVISIBLE LASER RADIATIONDO NOT VIEW DIRECTLY

WITH OPTICAL INSTRUMENTSCLASS 1M LASER PRODUCT

This product is affixed with the above label.

100 450 500 550 600

200

195

190

185

180

175

WellWatcher Ultra ASE system

New downhole thermocouples

Fiber length, m

Tempe

rature, deg

C

This temperature profile, acquired with the WellWatcher Ultra ASE DTS system, shows that after the system corrected for the error induced from a degraded fiber, its measurements agreed with two independent reference points obtained from newly installed downhole thermocouples.

Rev. 00 Page 34

DescriptionThe Turn Around Sub is a completion accessory tool used to provide a downhole connection between two control lines in order to facilitate hydraulic communication. It comprises of a tubing sized sub which has a protection sleeve that covers the control line termination.

OperationThe Turn Around Sub is made up to the tubing string. The control lines are terminated to an internal mini loop to provide a hydraulic connection between the control lines. The radius of the mini loop is sufficient to ensure successful deployment of double ended fiber optic systems. The protection sleeve is then slid up to cover the mini loop and hydraulic connections. The sleeve is held in place with set screws. The Turn Around Sub is then run in hole as part of the completion string.

ApplicationsDouble Ended Fiber Optic Systems

Benefits Fully protected hydraulic connections Full tubing bore I.D. Optimized O.D.

Features Large bend radius for fiber Wide range of metallurgy options available Threaded as per customer requirements Available in 2-3/8 to 7 sizes

Turn Around Sub

Turn Around SubStandard - Hydraulic

Rev. 00 Page 35

DescriptionThe Bullnose Pressure Port is designed for use in Coil Tubing deployed pressure monitoring systems. It provides a termination of the coil tubing that allows wellbore pressure to be transferred to a pressure monitoring gauge installed in the string whilst maintaining the coil tubings pressure integrity.

OperationThis bullnose is made up of a welded coil tubing connector and control line pressure transfer connector. A short length of control line is terminated to the pressure port on the pressure monitoring gauge. The bullnose then slides back into the coil and is welded onto the coil tubing.

The bullnose portion of the tool has holes which allow well bore pressure to be transferred to the pressure gauge via the control line.

ApplicationsCoil Tubing deployed pressure monitoring systems

Benefits Low profile bullnose

Features Proven Coil Tubing connector Welded pressure barrier

Bullnose Pressure Port

Bullnose Pressure Port

Rev. 00 Page 36

DescriptionThe Thermal Disconnect tool is utilized to allow the deployment of coil tubing monitoring strings alongside conventional tubing strings. Due to differing thermal expansion rates, the Thermal Disconnect tool ensures that the coil tubing string will separate from the tubing sting in a controlled manner as thermal expansion takes place.

OperationThis Thermal Disconnect is connected to the lower portion of the coil tubing string being deployed via conventional dimple connector. The tool is then welded onto the tubing string allowing the tubing to drag the coil string into the well. Once the string is deployed, as the wellbore temperature increases, the Thermal Disconnected tool will part the coil string from the tubing string at a specific temperature range. Thus the coil string will be free from the tubing string.

ApplicationsCoil Tubing deployed monitoring systems

Benefits Adjustable shear temperature Controlled disconnect

Features Available for all Coil Tubing sizes Allows rotation via knuckle joint Standard dimple connector used Ratchet system

Thermal Disconnect

Thermal Disconnect

Rev. 00 Page 37

DescriptionThe Shower Head provides control line feed through for monitoring systems deployed via coil tubing. Up to four control lines can be managed.

OperationThe control lines exiting the coil tubing are fed through the shower head. The shower head is then terminated onto the coil tubing via a swagelok connector. Each control line passing through the shower head is sealed to the shower head utilizing NPT connections, thus providing a pressure barrier between the control lines and the coil tubing.

ApplicationsCoil tubing deployed monitoring systems

Benefits Maintains pressure integrity of coil tubing

Features Wide range of sizes to suit coil tubing Multiple control line configurations Simple installation at wellhead

Shower Head

Shower Head

Rev. 00 Page 38

DescriptionThe Wellhead Outlet provides a pressure barrier between the instrumentation control line and the wellhead.

OperationMultiple options are available to suit the required Wellhead sealing configuration including threaded and flanged profiles. The instrumentation control line is passed through the wellhead, the flanged or threaded profile sealing between the wellhead and wellhead outlet. Inside the wellhead outlet, the control lines are terminated to feed-throughs that are pressure contained. Therefore the potential for pressure to be transmitted from the control line to surface is contained with the wellhead outlet.

ApplicationsReservoir Monitoring and Control installations.

Benefits Maximizes well control

Features Multiple sealing configurations to suit wellhead design High pressure and temperature rating available Electrical / Optical feed-throughs

Wellhead Outlet

Wellhead Outlet

Rev. 00 Page 39

Thermal Completions CatalogTable of ContentsThermal Liner HangersPressure Tight SystemTBL - Thermal Liner Hanger Packer

Debris Seal SystemCE Liner Top PackerLRP Long Reach Liner Packer

Tailpipe HangerMH Thermal Liner Hanger PackerLRP Long Reach Liner Packer

Running ToolsMOST - MHCE Liner Running ToolHSPR - TBLHydraulic Release Packoff Bushing

MH Setting Tool - Running NutMH Setting Tool - ColletLRST Long Reach Setting Tool

Remedial ToolsMechanical PackersCup Type Test Tool

Bridge PlugsThermal Permanent Bridge PlugMH Retrievable Thermal Bridge Plug

Thermal Casing PatchMH Thermal Casing PatchMH Thermal Patch Bottom

Scrapers and Drift SubsModel A Casing ScraperDrift Lock Casing ScraperFD Drift Sub

Tubing AccessoriesThermal Sliding SleeveInternal Cut Window Burst JointThermal Expansion JointThermal Pump Out Float ValveThermal Latch Down Plug

Reservoir MonitoringDistributed Temperature SystemsWellWatcher Brite Blue HT

Acquisition SystemsWellWatcher UltraWellWatcher Ultra ASE

Monitoring AccessoriesTurn Around SubBullnose Pressure PortThermal DisconnectShower HeadWelhead Outlet