OCTG - Well Casing for Oil Wells

Well casing is an integral part of the oil drilling and completion process.

In general, casing provides structure and strength to the walls of the well hole so that it doesn’t collapse on itself. It also ensures that there is no seepage of oil or natural gas out of the well hole as these are brought to the surface.

There are five different types of well casing. They include:

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

Careful planning is required so that the proper casing for each well is installed. Subsurface characteristics, the diameter of the well, and the pressures and temperatures experienced throughout the well, are all taken into account when planning the various casing strings.

Below is a list of standard API5CT specifications, all of which we supply.

We are also able to supply casing with non-API specifications for special situations, including those with semi-premium and premium connections.

Essentially, we are able to accommodate all your tubular requirements, many times with ready stock.

Please contact us to discuss your requirements.

Contact Us:

Email: chuckyan@gaslinepipe.com
Skype: chuck.yan1
Web: www.gaslinepipe.com

High Quality Drill Pipe

Application:Heavy weight drill pipe (HWDP) is usually run in between the drill collars and the drill pipe in order to prevent fatigue of the drill pipe in the vertical drilling industry. Heavy weight drill pipe is also utilized in the horizontal directional drilling (HDD) industry for added strength in high stress situations. Heavy weight drill pipe (HWDP) may be used to make the transition between the drill collars and drill pipe. The function of the HWDP is to provide a flexible transition between the drill collars and the drill pipe.

Introduction:

Heavy weight drill pipe has a “center upset”, also known as wear pad, that increases tube life by protecting the tube from wearing on the outer diameter by keeping the tube away from the hole wall. It also reduces hole drag and differential sticking problems. The walls of heavy weight drill pipe are thicker and have longer upsets compared to conventional drill pipe, as well as being stronger with high tensile strength.

Application:

Heavy weight drill pipe (HWDP) is usually run in between the drill collars and the drill pipe in order to prevent fatigue of the drill pipe in the vertical drilling industry. Heavy weight drill pipe is also utilized in the horizontal directional drilling (HDD) industry for added strength in high stress situations. Heavy weight drill pipe (HWDP) may be used to make the transition between the drill collars and drill pipe. The function of the HWDP is to provide a flexible transition between the drill collars and the drill pipe.

Quality Standard: API 7 and API 5DP

Steel Grade:

• Integral HWDP : AISI 4145HM
• Welded HWDP : AISI 1340 pipe body, AISI 4140HM tool joint

Sizes Range:

1. Outer Diameter: 2 7/8” – 6 5/8”
2. Weight Range: 6.27#/FT through 27.72#/FT
3. Lengths: Range 2 and Range 3
4. End Finishes: Internal Upset, External Upset, Plain End Upset, Non Upset
5. Tool Joint type：NC38、NC46、NC50、5-1/2 FH

Feature:

• A. High precision in size and shape
• B. Good low temperature toughness
• C. Excellent comprehensive mechanical properties
• D. High connection strength and sealability
• E. Large inside diameter of tool joint
• F. High torque resistance
• G. High fatigue strength and long fatigue life

Internal Coating Feature:

• A.High abrasion resistance and low friction factor
• B. Good adhesion and flexility
• C. High application temperature and pressure
• D. High hardness and impact resistance
• E. Good corrosion resistance

Hardbanding Feature:

• A. Good balance between antiwear and friction-reduction
• B. The wear rate is less than 6% of that of bare tool joint, which can prolong 3 times of the tool joint service life
• C. Good property of friction-reduction, which can reduce the casing wear to the least, and its wear to casing is less than 11% of that of bare tool joint
• D. Reduce the torque of drilling string
• E. Good weldablity with little splash and good rewelding preformance
• F. Friendly to environment

Options:

1. Internal Plastic Coating
2. Hardband Type especially on box and pin tool joint
3. Proprietary Connections
4. Make and Break Test

Mill Test Certificates:

1. Issued in accordance with API Spec 7/7-1 and API RP7G .
2. Third Party Inspection can be performed on request at buyer’s care and expense.

Recommendations for running heavy weight drill pipe:

When run in vertical holes for weight:
1. Run the necessary number of joints to provide the required weight plus enough more joints to ensure the transition point stays in the heavy weight pipe.
2.Do not run in compression where the hole size is more than 4″ larger than the heavy weight tool joint size.

When run in the transition zone between pipe and collars:
1. Run a minimum of 18 to 21 joints.
2. Utilize the manufacturer’s recommendations for the maximum drill collar size to be run below the heavy weight.

When run in directional holes for weight:
1. Run the necessary number of joints to achieve the desired weight on bit. (It is not uncommon to run as many as 60 joints in this application.)

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Standard Drill Collar

Drill collar are extra-heavy integral tools used to concentrate weight onto the drill bit so as to produce sufficient force for the drill bit to break rock efficiently while drilling. They are made of AISI 4145H modified steel and are connected between drill pipes and drill bits.

Introduction:

Drill Collar are one of the parts of a drill’s string. Drill for the Collars is meant to provide weight for drilling purposes. Drill collar has bars of solid steel that are drilled from one end to the other to provide a passage for pumping the drilling fluids through the collar.

Application:

Drill collar are extra-heavy integral tools used to concentrate weight onto the drill bit so as to produce sufficient force for the drill bit to break rock efficiently while drilling. They are made of AISI 4145H modified steel and are connected between drill pipes and drill bits.

Quality Standard: API Spec. 7/7-1, API RP7G

Size Range:

• OD 3 1/8″ – 11″
• Length: The standard drill collar length is 31′ 6″ . For outside diameters larger than 4″, slip or elevator recesses can be cut according to API-recommended practice RP7G. Connections are cut with standard API relief features, cold rolled and kemplated.

Features and Benefits:

• API Boreback Box Connection
• API stress relieve groove pin connection
• Cold Rolling Thread roots
• Phosphate coated connections
• A hardness range of 285 to 341 BHN and a Charpy impact value of 40 ft-lbs are guaranteed at evenly distributed 16 points in any sections at room temperature;
• Connections are completed（phosphate coated）to protect them from the elements after machining and to help prevent galling upon initial make-up;
• Thread roots are cold rolled on API and H-90 connections;
• Pressed steel thread protectors are supplied for all drill collar that are equipped with standard connections

Protection:

• Standard Pressed Steel Thread Protectors.
• Cast Steel Lifting Bail Thread Protectors upon request.

Mill Test Certificates:

• Issued in accordance with API 7/7-1 and API RP7G specifications.
• Third Party Inspection can be performed on request at buyer’s care and expense.

ORDERING INSTRUCTIONS:

When ordering or requesting quotations on drill collars, please specify:

1. Drill collar OD
2. Drill collar ID
3. Overall length
4. Connections required (size and type)
5. Indicate preference for pressed or cast steel thread protectors
6. Special features desired, for example:

• Slick or Spiral
• Stress Relief Features
• Slip and/or Elevator Recess
• Hardbanding

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API Spec 5CT - Specification for Casing and Tubing

API Spec 5CT – Specification 5CT/ISO 11960, Specification for Casing and Tubing, Eighth Edition, Petroleum and natural gas industries-Steel pipes for use as casing or tubing for wells.

Scope:

This Standard specifies the technical delivery conditions for steel pipes (casing, tubing and pup joints), coupling stock, coupling material and accessory material and establishes requirements for three Product Specification Levels (PSL-1, PSL-2, PSL-3).
The requirements for PSL-1 are the basis of this Standard.
The requirements that define different levels of standard technical requirements for PSL-2 and PSL-3, for all Grades except H-40, L-80 9Cr and C110, are contained in Annex H.
Peotroleum and natureal gas industies – Steel pipes for use as casing or tubing for wells.

Standard: API SPEC 5CT

API 5CT pipe Size (mm):

·  Outer Dimensions: 6.0mm – 219.0mm

·  Wall Thickness: 1.0mm – 30 mm

·  Length: max 12000mm

Application: gas, water and oil transportation in both oil and natural gas .

The main steel grade of API 5CT:

· API 5CT J55, API 5CT K55, API 5CT N80, API 5CT L80, API 5CT P110.

Packing: Bare/bundles/crates/crate protection at the both sides of tubes or as per customers’ requirements .

This International Standard is applicable to the following connections in accordance with ISO 10422 or API Spec 5B:

·  short round thread casing (STC);

·  long round thread casing (LC);

·  buttress thread casing (BC);

·  extreme-line casing (XC);

·  non-upset tubing (NU);

·  external upset tubing (EU);

·  integral joint tubing (IJ).

For such connections, this International Standard specifies the technical delivery conditions for couplings and thread protection.

For pipes covered by this International Standard, the sizes, masses, wall thicknesses, grades and applicable end finishes are defined.

This International Standard may also be applied to tubulars with connections not covered by ISO/API standards.

Chemical Composition

Grade	C≤	Si≤	Mn≤	P≤	S≤	Cr≤	Ni≤	Cu≤	Mo≤	V≤	Als≤
API 5CT J55	0.34-0.39	0.20-0.35	1.25-1.50	0.020	0.015	0.15	0.20	0.20	/	/	0.020
API 5CT  K55	0.34-0.39	0.20-0.35	1.25-1.50	0.020	0.015	0.15	0.20	0.20	/	/	0.020
API 5CT N80	0.34-0.38	0.20-0.35	1.45-1.70	0.020	0.015	0.15	/	/	/	0.11-0.16	0.020
API 5CT  L80	0.15-0.22	1.00	0.25-1.00	0.020	0.010	12.0-14.0	0.20	0.20	/	/	0.020
API 5CT J P110	0.26-035	0.17-0.37	0.40-0.70	0.020	0.010	0.80-1.10	0.20	0.20	0.15-0.25	0.08	0.020

Mechanical Properties of API 5CT

Steel Grade	Yield Strength (Mpa)	Tensile Strength (Mpa)
API 5CT J55	379-552	≥517
API 5CT K55	≥655	≥517
API 5CT N80	552-758	≥689
API 5CT L80	552-655	≥655
API 5CT P110	758-965	≥862

API Spec 5CT standard replaced by:

· API Spec 5CT – Specification 5CT/ISO 11960, Specification for Casing and Tubing, Eighth Edition, Petroleum and natural gas industries-Steel pipes for use as casing or tubing for wells

· This product references:

· API Spec 5B – Specification for Threading, Gauging, and Thread Inspection of Casing, Tubing, and Line Pipe Threads (US Customary Units) (Includes March 2004 Addendum)

· ISO 10422:1993 – Petroleum and natural gas-industries; threading, gauging, and thread inspection of casing, tubing and line pipe threads; specification

· This product replaces:

· API 5CT – Specification for Casing and Tubing (U.S. Customary Units)

· ISO 11960 was prepared by Technical Committee ISO/TC 67, Materials, equipment and offshore structures for petroleum, petrochemical and natural gas industries, Subcommittee SC 5, Casing, tubing and drill pipe.

Well Casing

Once a natural gas or oil well is drilled, and it has been verified that commercially viable quantities of natural gas are present for extraction, the well must be 'completed' to allow for the flow of petroleum or natural gas out of the formation and up to the surface. This process includes strengthening the well hole with casing, evaluating the pressure and temperature of the formation, and then installing the proper equipment to ensure an efficient flow of natural gas out of the well.

There are two main types of conventional natural gas wells: natural gas wells and natural gas condensate wells. In addition, there are oil wells that contain “associated” natural gas. In an oil well with associated gas, the natural gas is often used to add pressure to the well and enhance the extraction of the well. Sometimes associated natural gas exists in large enough quantities to allow its extraction along with the oil. Natural gas specific wells are wells drilled exclusively for natural gas, and contain little or no oil. Shale-gas drilling is an example of wells being drilled for their natural gas resources.

Condensate wells are wells that contain natural gas, as well as a liquid condensate. This condensate is a liquid hydrocarbon mixture that is often separated from the natural gas either at the wellhead, or during the processing of the natural gas. It is important to remember that natural gas, being lighter than air, will naturally rise to the surface of a well. Because of this, in many natural gas and condensate wells, lifting equipment and well treatment are not necessary.

Completing a well consists of a number of steps: installing the well casing, completing the well, installing the wellhead, and installing lifting equipment or treating the formation should that be required. Click on the links below to learn about these aspects of the well completion process:

• Well Casing
• Completion
• The Wellhead
• Lifting and Well Treatment

Well Casing

Installing well casing is an important part of the drilling and completion process. Well casing consists of a series of metal tubes installed in the freshly drilled hole. Casing strengthens the sides of the well hole, ensures that no oil or natural gas seeps out of the well hole as it is brought to the surface, and keeps other fluids or gases from seeping into the formation through the well. A good deal of planning is necessary to ensure that the proper casing for each well is installed. The type of casing used depends on the subsurface characteristics of the well, including the diameter of the well and the pressures and temperatures experienced throughout the well. The diameter of the well hole depends on the size of the drill bit used. In most wells, the diameter of the well hole decreases the deeper it is drilled, leading to a type of conical shape that must be taken into account when installing casing. To review the drilling of a natural gas well and the history of drilling practices, including casing, click here.

There are five different types of well casing. They include:

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

Conductor Casing

Conductor casing is installed first, usually prior to the arrival of the drilling rig. The hole for conductor casing is often drilled with a small auger drill, mounted on the back of a truck. Conductor casing is usually no more than 20 to 50 feet long. It is installed to prevent the top of the well from caving in and to help in the process of circulating the drilling fluid up from the bottom of the well. Onshore, this casing is usually 16 to 20 inches in diameter, while offshore casing usually measures 30 to 42 inches. The conductor casing is cemented into place before drilling begins.

Surface casing is the next type of casing to be installed. It can be anywhere from a few hundred to 2,000 feet long, and is smaller in diameter than the conductor casing. When installed, the surface casing fits inside the top of the conductor casing. The primary purpose of surface casing is to protect fresh water deposits near the surface of the well from being contaminated by leaking hydrocarbons or salt water from deeper underground. It also serves as a conduit for drilling mud returning to the surface, and helps protect the drill hole from being damaged during drilling. Surface casing, like conductor casing, is cemented into place. Regulations often dictate the thickness of the cement to be used to ensure that there is little possibility of freshwater contamination.

Intermediate Casing

Intermediate casing is usually the longest section of casing found in a well. The primary purpose of intermediate casing is to minimize the hazards that come along with subsurface formations that may affect the well. These include abnormal underground pressure zones, underground shale, and formations that might otherwise contaminate the well, such as underground salt-water deposits. In many instances, even though there may be no evidence of an unusual underground formation, intermediate casing is run as insurance against the possibility of such a formation affecting the well. These intermediate casing areas may also be cemented into place for added protection.

Liner Strings

Liner strings are sometimes used instead of intermediate casing. Liner strings are commonly run from the bottom of another type of casing to the open well area. However, liner strings are usually attached to the previous casing with 'hangers', instead of being cemented into place. This type of casing is thus less permanent than intermediate casing.

Production Casing

Production casing, alternatively called the 'oil string' or 'long string,’ is installed last and is the deepest section of casing in a well. This is the casing that provides a conduit from the surface of the well to the petroleum-producing formation. The size of the production casing depends on a number of considerations, including the lifting equipment to be used, the number of completions required, and the possibility of deepening the well at a later time. For example, if it is expected that the well will be deepened at a later date, then the production casing must be wide enough to allow the passage of a drill bit later on.

Well casing is a very important part of the completed well. In addition to strengthening the well hole, it provides a conduit to allow hydrocarbons to be extracted without intermingling with other fluids and formations found underground. It is also instrumental in preventing blowouts, allowing the formation to be 'sealed' from the top should dangerous pressure levels be reached. For more technical information on blowouts and their prevention, click here. Once the casing has been set, and in most cases cemented into place, proper lifting equipment is installed to bring the hydrocarbons from the formation to the surface. After the casing is installed, tubing is inserted inside the casing, running from the opening well at the top to the formation at the bottom. The hydrocarbons that are extracted go up this tubing to the surface. This tubing may also be attached to pumping systems for more efficient extraction, should that be necessary.

Completion

Well completion commonly refers to the process of finishing a well so that it is ready to produce oil or natural gas. In essence, completion consists of deciding on the characteristics of the intake portion of the well in the targeted hydrocarbon formation. There are a number of types of completions, including:

• Open Hole Completion
• Conventional Perforated Completion
• Sand Exclusion Completion
• Permanent Completion
• Multiple Zone Completion
• Drainhole Completion

The use of any type of completion depends on the characteristics and location of the hydrocarbon formation to be mined.

Open Hole Completion

Open hole completions are the most basic type and are used in formations that are unlikely to cave in. An open hole completion consists of simply running the casing directly down into the formation, leaving the end of the piping open without any other protective filter. Very often, this type of completion is used on formations that have been ‘acidized’ or ‘fractured.’

Conventional Perforated Completion

Conventional perforated completions consist of production casing being run through the formation. The sides of this casing are perforated, with tiny holes along the sides facing the formation, which allows for the flow of hydrocarbons into the well hole, but still provides a suitable amount of support and protection for the well hole. The process of perforating the casing involves the use of specialized equipment designed to make tiny holes through the casing, cementing, and any other barrier between the formation and the open well. In the past, 'bullet perforators' were used, which were essentially small guns lowered into the well. The guns, when fired from the surface, sent off small bullets that penetrated the casing and cement. Today, 'jet perforating' is preferred. This consists of small, electrically-ignited charges, lowered into the well. When ignited, these charges poke tiny holes through to the formation, in the same manner as bullet perforating.

Sand Exclusion Completion

Sand exclusion completions are designed for production in an area that contains a large amount of loose sand. These completions are designed to allow for the flow of natural gas and oil into the well, but at the same time prevent sand from entering the well. Sand inside the well hole can cause many complications, including erosion of casing and other equipment. The most common methods of keeping sand out of the well hole are screening or filtering systems. These include analyzing the sand experienced in the formation and installing a screen or filter to keep sand particles out. The filter may be either a type of screen hung inside the casing, or a layer of specially-sized gravel outside the casing to filter out the sand. Both types of sand barriers can be used in open holes and perforated completions.

Permanent Completion

Permanent completions are those in which the components are assembled and installed only once. Installing the casing, cementing, perforating, and other completion work is done with small diameter tools to ensure the permanent nature of the completion. Completing a well in this manner can lead to significant cost savings compared to other types.

Multiple Zone Completion

Multiple zone completion is the practice of completing a well so that hydrocarbons from two or more formations may be produced simultaneously, yet separately. For example, a well may be drilled that passes through a number of formations as it descends; alternately, it may be more effective in a horizontal well to add multiple completions to drain the formation efficiently. Although it is common to separate multiple completions so that the fluids from the different formations do not intermingle, the complexity of achieving complete separation can present a barrier. In some instances, the different formations being drilled are close enough to allow fluids to intermingle in the well hole. When it is necessary to prevent this intermingling, hard rubber 'packing' instruments are used to maintain separation among different completions.

Drainhole Completion

Drainhole completions are a form of horizontal or slant drilling. This type of completion consists of drilling out horizontally into the formation from a vertical well, providing a 'drain' for the hydrocarbons to empty into the well. In certain formations, drilling a drainhole completion may allow for more efficient and balanced extraction of the targeted hydrocarbons. Drainhole completions are more commonly associated with oil wells than with natural gas wells.

The Wellhead

The wellhead consists of the pieces of equipment mounted at the opening of the well to manage the extraction of hydrocarbons from the underground formation. It prevents leaking of oil or natural gas out of the well, and also prevents blowouts caused by high pressure. Formations that are under high pressure typically require wellheads that can withstand a great deal of upward pressure from the escaping gases and liquids. These wellheads must be able to withstand pressures of up to 20,000 pounds per square inch (psi). The wellhead consists of three components: the casing head, the tubing head, and the 'christmas tree.’

The casing head consists of heavy fittings that provide a seal between the casing and the surface. The casing head also serves to support the entire length of casing that is run all the way down the well. This piece of equipment typically contains a gripping mechanism that ensures a tight seal between the head and the casing itself.

The tubing head is much like the casing head. It provides a seal between the tubing, which is run inside the casing, and the surface. Like the casing head, the tubing head is designed to support the entire length of the casing, as well as provide connections at the surface, which allow the flow of fluids out of the well to be controlled.

The 'christmas tree' is the piece of equipment that fits on top of the casing and tubing heads, and contains tubes and valves that control the flow of hydrocarbons and other fluids out of the well. It commonly contains many branches and is shaped somewhat like a tree, thus its name, ‘christmas tree.’ The christmas tree is the most visible part of a producing well, and allows for the surface monitoring and regulation of the production of hydrocarbons from a producing well. A typical Christmas tree is about six feet tall.

Lifting and Well Treatment

Once the well is completed, it may begin to produce natural gas. In some instances, the hydrocarbons that exist in pressurized formations will naturally rise up through the well to the surface. This is most commonly the case with natural gas. Since natural gas is lighter than air, once a path to the surface is opened, the pressurized gas will rise to the surface with little or no interference. This is most common for formations containing natural gas alone, or with only a light condensate. In these scenarios, once the christmas tree is installed, the natural gas will flow to the surface without assistance.

In order to more fully understand the nature of the well, a potential test is typically run in the early days of production. This test allows well engineers to determine the maximum amount of natural gas that the well can produce in a 24-hour period. From this and other knowledge of the formation, the engineer may make an estimation on what the 'most efficient recovery rate', or MER will be. The MER is the rate at which the greatest amount of natural gas may be extracted without harming the formation itself.

Another important aspect of producing wells is the 'decline rate'. When a well is first drilled, the formation is under pressure and produces natural gas at a very high rate. However, as more and more natural gas is extracted from the formation, the production rate of the well decreases. This is known as the decline rate. Certain techniques, including lifting and well stimulation, can increase the production rate of a well.

In some natural gas wells, and oil wells that have associated natural gas, it is more difficult to ensure an efficient flow of hydrocarbons up the well. The underground formation may be very 'tight', making the movement of petroleum through the formation and up the well a very slow and inefficient process. In these cases, lifting equipment or well treatment is required.

Lifting equipment consists of a variety of specialized equipment used to help 'lift' petroleum out of a formation. This is most commonly used to extract oil from a formation. Because oil is found as a viscous liquid, it takes some coaxing to extract it from underground. Various types of lifting equipment are available, but the most common lifting method is known as 'rod pumping'. Rod pumping is powered by a surface pump that moves a cable and rod up and down in the well, providing the lifting pressure required to bring the oil to the surface. The most common type of cable rod lifting equipment is the 'horse head' or conventional beam pump. These pumps are recognizable by the distinctive shape of the cable feeding fixture, which resembles a horse's head.

Well Treatment

Well treatment is another method of ensuring the efficient flow of hydrocarbons out of a formation. Essentially, this type of well stimulation consists of injecting acid, water, or gases into the well to open up the formation and allow the petroleum to flow through the formation more easily. Acidizing a well consists of injecting acid (usually hydrochloric acid) into the well. In limestone or carbonate formations, the acid dissolves portions of the rock in the formation, opening up existing spaces to allow for the flow of petroleum. Fracturing consists of injecting a fluid into the well, the pressure of which 'cracks' or opens up fractures already present in the formation. In addition to the fluid being injected, 'propping agents' are also used. These propping agents can consist of sand, glass beads, epoxy, or silica sand, and serve to prop open the newly widened fissures in the formation. Hydraulic fracturing involves the injection of water into the formation, while CO2 fracturing uses gaseous carbon dioxide. Fracturing, acidizing, and lifting equipment may all be used on the same well to increase permeability, widening the pores of the formation.

These techniques have been more common to oil wells, but are increasingly being applied to increase the extraction rate for gas wells, particularly hydraulic fracturing. As deeper and less conventional natural gas wells are drilled, it is becoming more common to use stimulation techniques on gas wells.

Click on the following links to learn more: hydraulic fracturing and shale gas.

The next step in the process of producing natural gas is processing. This involves taking the 'raw' natural gas obtained from underground, removing impurities, and ensuring that the gas is ready for use prior to being transported to its destination.