Difference between revisions of "Oil Well Casing"

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==Description==
 
==Description==
Oil well [[casings]] consist of a serie of methal tubes, which are installed in a drilled hole. Applied in the oil and gas industry. <br><br> The casing strengthens the side of the well-hole and ensures that no oil or gas can escape out of the well-hole as it is brought to the surface. The tubes are provided with threaded ends at either end for connection purposes. Threads on ends are particularly liable to damage by rough handling, even though thread protectors are fitted. <br><br>
+
Casing is large diameter pipe that is assembled and inserted into a recently drilled section of a borehole and typically held into place with [[cement]].<br><br>
Mostly shipped loose or in bundles. Damaged threaded ends may be cut and re-threaded in the oil-fields, where special machinery is usually available. Bends and dents, if not too severe, may also be straightened by special machinery in the larger oilfield centres, but, as oilwell casing is subject to high pressure, such repairs must be tested and inspected by technical processes, which are expensive.  
+
Casing that is cemented in place aids the drilling process in several ways:<br>
<br><br>
+
* Prevent contamination of fresh water well zones.
<b>Full information on this product is in the process of completion.</b>
+
* Prevent unstable upper formations from caving-in and sticking the drill string or forming large caverns.
 +
* Provides a strong upper foundation to use high-density drilling fluid to continue drilling deeper.
 +
* Isolates different zones, that may have different pressures or fluids - known as zonal isolation, in the drilled formations from one another.
 +
* Seals off high pressure zones from the surface, avoiding potential for a blowout
 +
* Prevents fluid loss into or contamination of production zones.
 +
* Provides a smooth internal bore for installing production equipment.<br><br>
 +
A slightly different metal string, called production tubing, is often used without cement in the smallest casing of a well completion to contain production fluids and convey them to the surface from an underground reservoir.<br><br>
 +
<b>Design</b><br>
 +
In the planning stages of a well a drilling engineer, usually with input from geologists and others, will pick strategic depths at which the hole will need to be cased in order for drilling to reach the desired total depth. This decision is often based on subsurface data such as formation pressures, strengths, and makeup, and is balanced against the cost objectives and desired drilling strategy.<br><br>
 +
With the casing set depths determined, hole sizes and casing sizes must follow. The hole drilled for each casing string must be large enough to easily fit the casing inside it, allowing room for cement between the outside of the casing and the hole. Also, the inside diameter of the first casing string must be large enough to fit the second bit that will continue drilling. Thus, each casing string will have a subsequently smaller diameter.<br><br>
 +
The inside diameter of the final casing string (or penultimate one in some instances of a liner completion) must accommodate the production tubing and associated hardware such as packers, gas lift mandrels and subsurface safety valves.<br><br>
 +
Casing design for each size is done by calculating the worst conditions that may be faced during drilling and production. Mechanical properties of designed pipes such as collapse resistance, burst pressure, and axial tensile strength must be sufficient for the worst conditions.<br><br>
 +
Casing strings are supported by casing hangers that are set in the wellhead, which later will be topped with the Christmas tree. The wellhead usually is installed on top of the first casing string after it has been cemented in place.<br><br>
 +
<b>Intervals</b><br>
 +
Typically, a well contains multiple intervals of casing successively placed within the previous casing run. The following casing intervals are typically used in an oil or gas well:<br>
 +
* Conductor casing
 +
* Surface casing
 +
* Intermediate casing (optional)
 +
* Production casing
 +
* Production liner<br><br>
 +
The conductor casing serves as a support during drilling operations, to flowback returns during drilling and cementing of the surface casing, and to prevent collapse of the loose soil near the surface. It can normally vary from sizes such as 18" to 30".<br><br>
 +
The purpose of surface casing is to isolate freshwater zones so that they are not contaminated during drilling and completion. Surface casing is the most strictly regulated due to these environmental concerns, which can include regulation of casing depth and cement quality. A typical size of surface casing is 13⅜ inches.<br><br>
 +
Intermediate casing may be necessary on longer drilling intervals where necessary drilling mud weight to prevent blowouts may cause a hydrostatic pressure that can fracture shallower or deeper formations. Casing placement is selected so that the hydrostatic pressure of the drilling fluid remains between In order to reduce cost, a liner may be used which extends just above the shoe (bottom) of the previous casing interval and hung off downhole rather than at the surface. It may typically be 7", although many liners match the diameter of the production tubing.<br><br>
 +
Few wells actually produce through casing, since producing fluids can corrode steel or form deposits such as asphaltenes or [[paraffin]] waxes and the larger diameter can make flow unstable. Production tubing is therefore installed inside the last casing string and the tubing annulus is usually sealed at the bottom of the tubing by a packer. Tubing is easier to remove for maintenance, replacement, or for various types of workover operations. It is significantly lighter than casing and does not require a drilling rig to run in and out of hole; smaller "service rigs" are used for this purpose.<br><br>
 +
<b>Cementing</b><br>
 +
Cementing is performed by circulating a [[cement]] slurry through the inside of the casing and out into the annulus through the casing shoe at the bottom of the casing string. In order to precisely place the cement slurry at a required interval on the outside of the casing, a plug is pumped with a displacement fluid behind the cement slurry column, which "bumps" in the casing shoe and prevents further flow of fluid through the shoe. This bump can be seen at surface as a pressure spike at the cement pump. To prevent the cement from flowing back into the inside of the casing, a float collar above the casing shoe acts as a check valve and prevents fluid from flowing up through the shoe from the annulus.<br><br>
 +
Casing and tubing strings are the main parts of the well construction. All wells drilled for the purpose of oil or gas production (or injecting materials into underground formations) must be cased with material with sufficient strength and functionality.<br><br>
 +
<b>Casing</b><br>
 +
Casing is the major structural component of a well. Casing is needed to:<br>
 +
* Maintain borehole stability
 +
* Prevent contamination of water sands
 +
* Isolate water from producing formations
 +
* Control well pressures during drilling, production, and workover operations <br><br>
 +
Casing provides locations for the installation of:<br>
 +
* Blowout preventers
 +
* Wellhead equipment
 +
* Production packers
 +
* Production tubing <br><br>
 +
The cost of casing is a major part of the overall well cost, so selection of casing size, grade, connectors, and setting depth is a primary engineering and economic consideration.<br><br>
 +
<b>Casing strings</b><br>
 +
There are six basic types of casing strings:<br>
 +
* Conductor Casing
 +
* Surface Casing
 +
* Intermediate Casing
 +
* Production Casing
 +
* Liner <br><br>
 +
Conductor casing
 +
Conductor casing is the first string set below the structural casing (i.e., drive pipe or marine conductor run to protect loose near-surface formations and to enable circulation of drilling fluid). The conductor isolates unconsolidated formations and water sands and protects against shallow gas. This is usually the string onto which the casing head is installed. A diverter or a blowout prevention (BOP) stack may be installed onto this string. When cemented, this string is typically cemented to the surface or to the mudline in offshore wells.<br><br>
 +
<b>Surface casing</b><br>
 +
Surface casing is set to provide blowout protection, isolate water sands, and prevent lost circulation. It also often provides adequate shoe strength to drill into high-pressure transition zones. In deviated wells, the surface casing may cover the build section to prevent keyseating of the formation during deeper drilling. This string is typically cemented to the surface or to the mudline in offshore wells.<br><br>
 +
<b>Intermediate casing</b><br>
 +
Intermediate casing is set to isolate:<br>
 +
* Unstable hole sections
 +
* Lost-circulation zones
 +
* Low-pressure zones
 +
* Production zones <br><br>
 +
It is often set in the transition zone from normal to abnormal pressure. The casing cement top must isolate any hydrocarbon zones. Some wells require multiple intermediate strings. Some intermediate strings may also be production strings if a liner is run beneath them.<br><br>
 +
<b>Production casing</b><br>
 +
Production casing is used to isolate production zones and contain formation pressures in the event of a tubing leak. It may also be exposed to:<br>
 +
* Injection pressures from fracture jobs
 +
* Downcasing, gas lift
 +
* The injection of inhibitor oil <br><br>
 +
A good primary cement job is very critical for this string.<br><br>
 +
<b>Liner</b><br>
 +
Liner is a casing string that does not extend back to the wellhead, but is hung from another casing string. Liners are used instead of full casing strings to:<br>
 +
* Reduce cost
 +
* Improve hydraulic performance when drilling deeper
 +
* Allow the use of larger tubing above the liner top
 +
* Not represent a tension limitation for a rig <br><br>
 +
Liners can be either an intermediate or a production string. Liners are typically cemented over their entire length.<br><br>
 +
<b>Tieback string</b><br>
 +
Tieback string is a casing string that provides additional pressure integrity from the liner top to the wellhead. An intermediate tieback is used to isolate a casing string that cannot withstand possible pressure loads if drilling is continued (usually because of excessive wear or higher than anticipated pressures). Similarly, a production tieback isolates an intermediate string from production loads. Tiebacks can be uncemented or partially cemented. An example of a typical casing program that illustrates each of the specified casing string types is shown in Fig. 1.<br><br>
 +
[[File:Typical_casing_program-1.png]]<br><br>
 +
<b>Tubing</b><br>
 +
Tubing is the conduit through which oil and gas are brought from the producing formations to the field surface facilities for processing. Tubing must be adequately strong to resist loads and deformations associated with production and workovers. Further, tubing must be sized to support the expected rates of production of oil and gas. Clearly, tubing  that is too small restricts production and subsequent economic performance of the well. Tubing that is too large, however, may have an economic impact beyond the cost of the tubing string itself, because the tubing size will influence the overall casing design of the well.<br><br>
 +
<b>Properties of casing and tubing</b><br>
 +
The American Petroleum Inst. (API) has formed standards for oil/gas casing that are accepted in most countries by oil and service companies. Casing is classified according to five properties:<br>
 +
* The manner of manufacture
 +
* Steel grade
 +
* Type of joints
 +
* Length range
 +
* The wall thickness (unit weight) <br><br>
 +
Almost without exception, casing is manufactured of mild (0.3 carbon) steel, normalized with small amounts of manganese. Strength can also be increased with quenching and tempering. API has adopted a casing "grade" designation to define the strength of casing steels. This designation consists of a grade letter followed by a number, which designates the minimum yield strength of the steel in ksi (103 psi). <br><br>
 +
<b>Pipe strength</b><br>
 +
To design a reliable casing string, it is necessary to know the strength of pipe under different load conditions. The most important mechanical properties of casing and tubing are:<br>
 +
* Burst strength
 +
* Collapse resistance
 +
* Tensile strength <br><br>
 +
API connection ratings<br><br>
 +
While a number of joint connections are available, the API recognizes three basic types:<br>
 +
* Coupling with rounded thread (long or short)
 +
* Coupling with asymmetrical trapezoidal thread buttress
 +
* Extreme-line casing with trapezoidal thread without coupling <br><br>
 +
Threads are used as mechanical means to hold the neighbouring joints together during axial tension or compression. For all casing sizes, the threads are not intended to be leak resistant when made up. API Spec. 5C2, Performance Properties of Casing, Tubing, and Drillpipe, provides information on casing and tubing threads dimensions.<br><br>
 +
In round threads, two small leak paths exist at the crest and root of each thread. Buttress threads have a much larger leak path along the stabbing flank and at the root of the coupling thread. API connections rely on thread compound to fill these gaps and provide leak resistance. The leak resistance provided by the thread compound is typically less than the API internal leak resistance value, particularly for buttress connections. The leak resistance can be improved by using API connections with smaller thread tolerances (and, hence, smaller gaps), but it typically will not exceed 5,000 psi with any long-term reliability. Applying tin or zinc plating to the coupling also results in smaller gaps and improves leak resistance.<br><br>
 +
Round-thread casing-joint strength.<br><br>
 +
<b>Proprietary connections</b><br>
 +
Special connections are used to achieve gas-tight sealing reliability and 100% connection efficiency (joint efficiency is defined as a ratio of joint tensile strength to pipe body tensile strength) under more severe well conditions. Severe conditions include:<br>
 +
* High pressure (typically > 5,000 psi)
 +
* High temperature (typically > 250°F)
 +
* A sour environment
 +
* Gas production
 +
* High-pressure gas lift
 +
* A steam well
 +
* A large dogleg (horizontal well) <br><br>
 +
Also, efficiency in flush joint, integral joint or other special clearance applications improves connections. A large diameter (> 16 in.) pipe improves the stab-in and makeup characteristics; galling should be reduced (particularly in CRA applications and tubing strings that will be re-used); and connection failure under high torsional loads (e.g., while rotating pipe) should be prevented.<br><br>
 +
The improved performance of many proprietary connections results from one or more of these features not found in API connections:<br>
 +
* More complex thread forms
 +
* Resilient seals
 +
* Torque shoulders
 +
* Metal-to-metal seals <br><br>
 +
The “premium” performance of most proprietary connections comes at a “premium” cost. Increased performance should always be weighed against the increased cost for a particular application. As a general rule, it is recommended to use proprietary connections only when the application requires them. “Premium” performance may also be achieved using API connections if certain conditions are met.<br><br>
 +
Those conditions are:<br>
 +
* Tighter dimensional tolerance
 +
* Plating applied to coupling
 +
* Use of appropriate thread compound
 +
* Performance verified with qualification testing <br><br>
 +
The performance of a proprietary connection can be reliably verified by performing three steps:<br>
 +
* Audit the manufacturer’s performance test data (sealability and tensile load capacity under combined loading)
 +
* Audit the manufacturer’s field history data
 +
* Require additional performance testing for the most critical applications <br><br>
 +
When requesting tensile performance data, make sure that the manufacturer indicates whether quoted tensile capacities are based on the ultimate tensile strength (i.e., the load at which the connection will fracture, commonly called the “parting load”) or the yield strength (commonly called the “joint elastic limit”). If possible, it is recommended to use the joint elastic limit values in the design so that consistent design factors for both pipe-body and connection analysis are maintained. If only parting load capacities are available, a higher design factor should be used for connection axial design.<br><br>
 +
<b>Connection failures</b><br>
 +
Most casing failures occur at connections. These failures can be attributed to:<br>
 +
* Improper design or exposure to loads exceeding the rated capacity
 +
* Failure to comply with makeup requirements
 +
* Failure to meet manufacturing tolerances
 +
* Damage during storage and handling
 +
* Damage during production operations (corrosion, wear, etc.) <br><br>
 +
Connection failure can be classified broadly as:<br>
 +
* Leakage
 +
* Structural failure
 +
* Galling during makeup
 +
* Yielding because of internal pressure
 +
* Jump-out under tensile load
 +
* Fracture under tensile load
 +
* Failure because of excessive torque during makeup or subsequent operations <br><br>
 +
Avoiding connection failure is not only dependent upon selection of the correct connection, but is strongly influenced by other factors, which include:<br>
 +
* Manufacturing tolerances
 +
* Storage (storage thread compound and thread protector)
 +
* Transportation (thread protector and handling procedures)
 +
* Running procedures (selection of thread compound, application of thread compound, and adherence to correct makeup specifications and procedures) <br><br>
 +
The overall mechanical integrity of a correctly designed casing string is dependent upon a quality assurance program that ensures damaged connections are not used and that operations personnel adhere to the appropriate running procedures.<br><br>
 +
<b>Connection design limits</b><br>
 +
The design limits of a connection are not only dependent upon its geometry and material properties, but are influenced by:<br>
 +
* Surface treatment
 +
* Phosphating
 +
* Metal plating (copper, tin, or zinc)
 +
* Bead blasting
 +
* Thread compound
 +
* Makeup torque
 +
* Use of a resilient seal ring (many companies do not recommend this practice)
 +
* Fluid to which connection is exposed (mud, clear [[brine]], or gas)
 +
* Temperature and pressure cycling
 +
* Large doglegs (e.g., medium- or short-radius horizontal wells)<br><br>
 +
 
 +
==Shipment / Storage==
 +
See [[Pipes (steel)]]<br><br>
 +
==Risk factors==
 +
Threads on ends are particularly liable to damage by rough handling, even though thread protectors are fitted. Threaded ends so damaged may be cut and re-threaded in the oil-fields, where special [[machinery]] is usually available. Bends and dents, if not too severe, may also be straightened by special machinery in the larger oilfield centres, but, as oilwell casing is subject to high pressure, such repairs must be tested and inspected by technical processes, which are expensive.
 +
 
 +
 
 +
 
 +
 
 +
 
 +
[[Category:Products]]
 
[[Category:Metals and steel]]
 
[[Category:Metals and steel]]
[[Category:Products]]
 

Latest revision as of 14:50, 14 January 2021

Infobox on Oil Well Casing
Example of Oil Well Casing
Oil Well Casing-1.jpg
Facts
Origin -
Stowage factor (in m3/t) -
Humidity / moisture -
Ventilation -
Risk factors See text

Oil Well Casing

Description

Casing is large diameter pipe that is assembled and inserted into a recently drilled section of a borehole and typically held into place with cement.

Casing that is cemented in place aids the drilling process in several ways:

  • Prevent contamination of fresh water well zones.
  • Prevent unstable upper formations from caving-in and sticking the drill string or forming large caverns.
  • Provides a strong upper foundation to use high-density drilling fluid to continue drilling deeper.
  • Isolates different zones, that may have different pressures or fluids - known as zonal isolation, in the drilled formations from one another.
  • Seals off high pressure zones from the surface, avoiding potential for a blowout
  • Prevents fluid loss into or contamination of production zones.
  • Provides a smooth internal bore for installing production equipment.

A slightly different metal string, called production tubing, is often used without cement in the smallest casing of a well completion to contain production fluids and convey them to the surface from an underground reservoir.

Design
In the planning stages of a well a drilling engineer, usually with input from geologists and others, will pick strategic depths at which the hole will need to be cased in order for drilling to reach the desired total depth. This decision is often based on subsurface data such as formation pressures, strengths, and makeup, and is balanced against the cost objectives and desired drilling strategy.

With the casing set depths determined, hole sizes and casing sizes must follow. The hole drilled for each casing string must be large enough to easily fit the casing inside it, allowing room for cement between the outside of the casing and the hole. Also, the inside diameter of the first casing string must be large enough to fit the second bit that will continue drilling. Thus, each casing string will have a subsequently smaller diameter.

The inside diameter of the final casing string (or penultimate one in some instances of a liner completion) must accommodate the production tubing and associated hardware such as packers, gas lift mandrels and subsurface safety valves.

Casing design for each size is done by calculating the worst conditions that may be faced during drilling and production. Mechanical properties of designed pipes such as collapse resistance, burst pressure, and axial tensile strength must be sufficient for the worst conditions.

Casing strings are supported by casing hangers that are set in the wellhead, which later will be topped with the Christmas tree. The wellhead usually is installed on top of the first casing string after it has been cemented in place.

Intervals
Typically, a well contains multiple intervals of casing successively placed within the previous casing run. The following casing intervals are typically used in an oil or gas well:

  • Conductor casing
  • Surface casing
  • Intermediate casing (optional)
  • Production casing
  • Production liner

The conductor casing serves as a support during drilling operations, to flowback returns during drilling and cementing of the surface casing, and to prevent collapse of the loose soil near the surface. It can normally vary from sizes such as 18" to 30".

The purpose of surface casing is to isolate freshwater zones so that they are not contaminated during drilling and completion. Surface casing is the most strictly regulated due to these environmental concerns, which can include regulation of casing depth and cement quality. A typical size of surface casing is 13⅜ inches.

Intermediate casing may be necessary on longer drilling intervals where necessary drilling mud weight to prevent blowouts may cause a hydrostatic pressure that can fracture shallower or deeper formations. Casing placement is selected so that the hydrostatic pressure of the drilling fluid remains between In order to reduce cost, a liner may be used which extends just above the shoe (bottom) of the previous casing interval and hung off downhole rather than at the surface. It may typically be 7", although many liners match the diameter of the production tubing.

Few wells actually produce through casing, since producing fluids can corrode steel or form deposits such as asphaltenes or paraffin waxes and the larger diameter can make flow unstable. Production tubing is therefore installed inside the last casing string and the tubing annulus is usually sealed at the bottom of the tubing by a packer. Tubing is easier to remove for maintenance, replacement, or for various types of workover operations. It is significantly lighter than casing and does not require a drilling rig to run in and out of hole; smaller "service rigs" are used for this purpose.

Cementing
Cementing is performed by circulating a cement slurry through the inside of the casing and out into the annulus through the casing shoe at the bottom of the casing string. In order to precisely place the cement slurry at a required interval on the outside of the casing, a plug is pumped with a displacement fluid behind the cement slurry column, which "bumps" in the casing shoe and prevents further flow of fluid through the shoe. This bump can be seen at surface as a pressure spike at the cement pump. To prevent the cement from flowing back into the inside of the casing, a float collar above the casing shoe acts as a check valve and prevents fluid from flowing up through the shoe from the annulus.

Casing and tubing strings are the main parts of the well construction. All wells drilled for the purpose of oil or gas production (or injecting materials into underground formations) must be cased with material with sufficient strength and functionality.

Casing
Casing is the major structural component of a well. Casing is needed to:

  • Maintain borehole stability
  • Prevent contamination of water sands
  • Isolate water from producing formations
  • Control well pressures during drilling, production, and workover operations

Casing provides locations for the installation of:

  • Blowout preventers
  • Wellhead equipment
  • Production packers
  • Production tubing

The cost of casing is a major part of the overall well cost, so selection of casing size, grade, connectors, and setting depth is a primary engineering and economic consideration.

Casing strings
There are six basic types of casing strings:

  • Conductor Casing
  • Surface Casing
  • Intermediate Casing
  • Production Casing
  • Liner

Conductor casing Conductor casing is the first string set below the structural casing (i.e., drive pipe or marine conductor run to protect loose near-surface formations and to enable circulation of drilling fluid). The conductor isolates unconsolidated formations and water sands and protects against shallow gas. This is usually the string onto which the casing head is installed. A diverter or a blowout prevention (BOP) stack may be installed onto this string. When cemented, this string is typically cemented to the surface or to the mudline in offshore wells.

Surface casing
Surface casing is set to provide blowout protection, isolate water sands, and prevent lost circulation. It also often provides adequate shoe strength to drill into high-pressure transition zones. In deviated wells, the surface casing may cover the build section to prevent keyseating of the formation during deeper drilling. This string is typically cemented to the surface or to the mudline in offshore wells.

Intermediate casing
Intermediate casing is set to isolate:

  • Unstable hole sections
  • Lost-circulation zones
  • Low-pressure zones
  • Production zones

It is often set in the transition zone from normal to abnormal pressure. The casing cement top must isolate any hydrocarbon zones. Some wells require multiple intermediate strings. Some intermediate strings may also be production strings if a liner is run beneath them.

Production casing
Production casing is used to isolate production zones and contain formation pressures in the event of a tubing leak. It may also be exposed to:

  • Injection pressures from fracture jobs
  • Downcasing, gas lift
  • The injection of inhibitor oil

A good primary cement job is very critical for this string.

Liner
Liner is a casing string that does not extend back to the wellhead, but is hung from another casing string. Liners are used instead of full casing strings to:

  • Reduce cost
  • Improve hydraulic performance when drilling deeper
  • Allow the use of larger tubing above the liner top
  • Not represent a tension limitation for a rig

Liners can be either an intermediate or a production string. Liners are typically cemented over their entire length.

Tieback string
Tieback string is a casing string that provides additional pressure integrity from the liner top to the wellhead. An intermediate tieback is used to isolate a casing string that cannot withstand possible pressure loads if drilling is continued (usually because of excessive wear or higher than anticipated pressures). Similarly, a production tieback isolates an intermediate string from production loads. Tiebacks can be uncemented or partially cemented. An example of a typical casing program that illustrates each of the specified casing string types is shown in Fig. 1.

Typical casing program-1.png

Tubing
Tubing is the conduit through which oil and gas are brought from the producing formations to the field surface facilities for processing. Tubing must be adequately strong to resist loads and deformations associated with production and workovers. Further, tubing must be sized to support the expected rates of production of oil and gas. Clearly, tubing that is too small restricts production and subsequent economic performance of the well. Tubing that is too large, however, may have an economic impact beyond the cost of the tubing string itself, because the tubing size will influence the overall casing design of the well.

Properties of casing and tubing
The American Petroleum Inst. (API) has formed standards for oil/gas casing that are accepted in most countries by oil and service companies. Casing is classified according to five properties:

  • The manner of manufacture
  • Steel grade
  • Type of joints
  • Length range
  • The wall thickness (unit weight)

Almost without exception, casing is manufactured of mild (0.3 carbon) steel, normalized with small amounts of manganese. Strength can also be increased with quenching and tempering. API has adopted a casing "grade" designation to define the strength of casing steels. This designation consists of a grade letter followed by a number, which designates the minimum yield strength of the steel in ksi (103 psi).

Pipe strength
To design a reliable casing string, it is necessary to know the strength of pipe under different load conditions. The most important mechanical properties of casing and tubing are:

  • Burst strength
  • Collapse resistance
  • Tensile strength

API connection ratings

While a number of joint connections are available, the API recognizes three basic types:

  • Coupling with rounded thread (long or short)
  • Coupling with asymmetrical trapezoidal thread buttress
  • Extreme-line casing with trapezoidal thread without coupling

Threads are used as mechanical means to hold the neighbouring joints together during axial tension or compression. For all casing sizes, the threads are not intended to be leak resistant when made up. API Spec. 5C2, Performance Properties of Casing, Tubing, and Drillpipe, provides information on casing and tubing threads dimensions.

In round threads, two small leak paths exist at the crest and root of each thread. Buttress threads have a much larger leak path along the stabbing flank and at the root of the coupling thread. API connections rely on thread compound to fill these gaps and provide leak resistance. The leak resistance provided by the thread compound is typically less than the API internal leak resistance value, particularly for buttress connections. The leak resistance can be improved by using API connections with smaller thread tolerances (and, hence, smaller gaps), but it typically will not exceed 5,000 psi with any long-term reliability. Applying tin or zinc plating to the coupling also results in smaller gaps and improves leak resistance.

Round-thread casing-joint strength.

Proprietary connections
Special connections are used to achieve gas-tight sealing reliability and 100% connection efficiency (joint efficiency is defined as a ratio of joint tensile strength to pipe body tensile strength) under more severe well conditions. Severe conditions include:

  • High pressure (typically > 5,000 psi)
  • High temperature (typically > 250°F)
  • A sour environment
  • Gas production
  • High-pressure gas lift
  • A steam well
  • A large dogleg (horizontal well)

Also, efficiency in flush joint, integral joint or other special clearance applications improves connections. A large diameter (> 16 in.) pipe improves the stab-in and makeup characteristics; galling should be reduced (particularly in CRA applications and tubing strings that will be re-used); and connection failure under high torsional loads (e.g., while rotating pipe) should be prevented.

The improved performance of many proprietary connections results from one or more of these features not found in API connections:

  • More complex thread forms
  • Resilient seals
  • Torque shoulders
  • Metal-to-metal seals

The “premium” performance of most proprietary connections comes at a “premium” cost. Increased performance should always be weighed against the increased cost for a particular application. As a general rule, it is recommended to use proprietary connections only when the application requires them. “Premium” performance may also be achieved using API connections if certain conditions are met.

Those conditions are:

  • Tighter dimensional tolerance
  • Plating applied to coupling
  • Use of appropriate thread compound
  • Performance verified with qualification testing

The performance of a proprietary connection can be reliably verified by performing three steps:

  • Audit the manufacturer’s performance test data (sealability and tensile load capacity under combined loading)
  • Audit the manufacturer’s field history data
  • Require additional performance testing for the most critical applications

When requesting tensile performance data, make sure that the manufacturer indicates whether quoted tensile capacities are based on the ultimate tensile strength (i.e., the load at which the connection will fracture, commonly called the “parting load”) or the yield strength (commonly called the “joint elastic limit”). If possible, it is recommended to use the joint elastic limit values in the design so that consistent design factors for both pipe-body and connection analysis are maintained. If only parting load capacities are available, a higher design factor should be used for connection axial design.

Connection failures
Most casing failures occur at connections. These failures can be attributed to:

  • Improper design or exposure to loads exceeding the rated capacity
  • Failure to comply with makeup requirements
  • Failure to meet manufacturing tolerances
  • Damage during storage and handling
  • Damage during production operations (corrosion, wear, etc.)

Connection failure can be classified broadly as:

  • Leakage
  • Structural failure
  • Galling during makeup
  • Yielding because of internal pressure
  • Jump-out under tensile load
  • Fracture under tensile load
  • Failure because of excessive torque during makeup or subsequent operations

Avoiding connection failure is not only dependent upon selection of the correct connection, but is strongly influenced by other factors, which include:

  • Manufacturing tolerances
  • Storage (storage thread compound and thread protector)
  • Transportation (thread protector and handling procedures)
  • Running procedures (selection of thread compound, application of thread compound, and adherence to correct makeup specifications and procedures)

The overall mechanical integrity of a correctly designed casing string is dependent upon a quality assurance program that ensures damaged connections are not used and that operations personnel adhere to the appropriate running procedures.

Connection design limits
The design limits of a connection are not only dependent upon its geometry and material properties, but are influenced by:

  • Surface treatment
  • Phosphating
  • Metal plating (copper, tin, or zinc)
  • Bead blasting
  • Thread compound
  • Makeup torque
  • Use of a resilient seal ring (many companies do not recommend this practice)
  • Fluid to which connection is exposed (mud, clear brine, or gas)
  • Temperature and pressure cycling
  • Large doglegs (e.g., medium- or short-radius horizontal wells)

Shipment / Storage

See Pipes (steel)

Risk factors

Threads on ends are particularly liable to damage by rough handling, even though thread protectors are fitted. Threaded ends so damaged may be cut and re-threaded in the oil-fields, where special machinery is usually available. Bends and dents, if not too severe, may also be straightened by special machinery in the larger oilfield centres, but, as oilwell casing is subject to high pressure, such repairs must be tested and inspected by technical processes, which are expensive.