Downhole Jar
Item | JYQ178 | JYQ197 | JYQ203 | JYQ241 |
---|---|---|---|---|
O.D. (in) | 7 | 7 3/4 | 8 | 9 1/2 |
I.D. (in) | 2 3/4 | 3 | 2 3/4 | 3 |
Connection | API NC50 | 6 5/8REG | 6 5/8REG | 7 5/8REG |
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Downhole Jar / Drilling Jars (Mechanical / Hydraulic)
Downhole jars are critical mechanical tools used in drilling operations to deliver impact loads, especially when a downhole component becomes stuck. These tools come in two primary types: hydraulic and mechanical jars. Despite differences in design, both store energy in the drill string and release it suddenly, imparting a force to free the stuck component. This mechanism is similar to using a hammer, where kinetic energy is released with an impact. The jars can be designed to strike upward, downward, or both, depending on the application.
Types of Downhole Jars:
- Hydraulic Jars: Operate using fluid pressure to trigger the impact after a set delay.
- Mechanical Jars: Rely on mechanical mechanisms to store and release energy quickly.
- Fishing Jars: Specifically designed for fishing operations where stuck equipment needs to be freed.
These jars are designed to function in different operations, such as drilling, well completions, workovers, and interventions.
Features:
- Reset Mechanism: Jars can be reset and operated multiple times before retrieval.
- Up and Down Jarring: Capable of delivering impact loads in both upward and downward directions.
- Energy Storage: Energy stored in the drillstring is released with precision when the jar “fires.”
Applications:
- Drilling Operations: To free stuck bottom hole assemblies (BHA).
- Fishing Operations: Recover stuck tools or equipment in the well.
- Workover and Well Intervention: Efficiently dislodge stuck tool strings or operate downhole tools.
Jarring Loads of the Drilling Jar
Below is a summary of the jarring loads, hydraulic loads, and pulling forces for different models of drilling jars:
Model | Upward Jarring Load (KN) | Up Jarring Unlock Force (KN) | Ex-plant (KN) | Downward Jarring Load (KN) | Hydraulic Load (KN) | Testing Pulling Force (KN) | Time of Hydraulic Delay (Seconds) |
---|---|---|---|---|---|---|---|
JYQ121Ⅱ | 250 | 200±25 | 120±25 | 220±10 | 30~60 | – | – |
JYQ140 | 450 | 250±25 | 150±25 | 300±10 | 45~90 | – | – |
JYQ146 | 450 | 250±25 | 150±25 | 300±10 | 45~90 | – | – |
JYQ159 | 600 | 330±25 | 190±25 | 370±10 | 45~90 | – | – |
JYQ165 | 600 | 330±25 | 220±25 | 400±10 | 45~90 | – | – |
JYQ178 | 700 | 330±25 | 220±25 | 400±10 | 45~90 | – | – |
JYQ197 | 800 | 400±25 | 250±25 | 440±10 | 45~90 | – | – |
JYQ203 | 800 | 400±25 | 250±25 | 440±10 | 45~90 | – | – |
JYQ241 | 1400 | 460±25 | 260±25 | 480±10 | 60~120 | – | – |
Specifications of the Downhole Drilling Jar
The following table provides the detailed specifications for various models of downhole jars, including outer and inner diameter, connection types, and maximum loads:
Item | JYQ121 | JYQ140 | JYQ146 | JYQ159 | JYQ165 | JYQ178 | JYQ197 | JYQ203 | JYQ241 |
---|---|---|---|---|---|---|---|---|---|
O.D. (in) | 4 3/4 | 5 1/2 | 5 3/4 | 6 1/4 | 6 1/2 | 7 | 7 3/4 | 8 | 9 1/2 |
I.D. (in) | 2 | 2 1/4 | 2 1/4 | 2 1/4 | 2 1/4 | 2 3/4 | 3 | 2 3/4 | 3 |
Connection | API NC38 | NC38 | NC38 | NC46 | NC50 | NC50 | 6 5/8 REG | 6 5/8 REG | 7 5/8 REG |
Up Jar Stroke (in) | 9 | 9 | 9 | 9 | 9 | 9 | 9 | 9 | 9 |
Down Jar Stroke (in) | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 |
Working Torque (ft-lbs) | 22000 | 30000 | 36000 | 50000 | 50000 | 540000 | 670000 | 670000 | 1200000 |
Max. Tensile Load (lb) | 540000 | 670000 | 670000 | 670000 | 670000 | 670000 | 670000 | 1200000 | 1200000 |
Max. Up Jar Load (lb) | 180000 | 224000 | 224000 | 224000 | 224000 | 224000 | 224000 | 315000 | 315000 |
Max. Down Jar Load (lb) | 90000 | 100000 | 100000 | 100000 | 100000 | 100000 | 100000 | 112000 | 112000 |
Overall Length (mm) | 5256 | 5096 | 5095 | 5300 | 5300 | 5300 | 5300 | 5300 | 5300 |
Piston Area (mm²) | 5102 | 8796 | 9170 | 17192 | 17192 | 17192 | 17192 | 17192 | 17192 |
item | JYQ178 | JYQ197 | JYQ203 | JYQ241 |
O.D. in | 7 | 7 3/4 | 8 | 9 1/2 |
I.D in | 2 3/4 | 3 | 23/4 | 3 |
Connection API | NC50 | 6 5/8REG | 65/8REG | 7 5/8REG |
up jar stroke in | 9 | 9 | 9 | 9 |
down jar stroke in | 6 | 6 | 6 | 6 |
working torque ft-Ibs | 22000 | 30000 | 36000 | 50000 |
max. tensile load lb | 540000 | 670000 | 670000 | 1200000 |
Max. up jar load Ib | 180000 | 224000 | 224000 | 315000 |
Max. down jar load Ib | 90000 | 100000 | 100000 | 112000 |
overall length mm | 5256 | 5096 | 5095 | 5300 |
piston area mm2 | 5102 | 8796 | 9170 | 17192 |
Conclusion
Downhole jars, both hydraulic and mechanical, are essential tools in drilling, workover, and intervention operations. With customizable designs and robust features, they are vital for addressing stuck components or delivering precise impact loads downhole. Our comprehensive range of products ensures that we can meet the specific needs of any drilling project.
1. [Drilling]
A mechanical device used downhole to deliver an impact load to another downhole component, especially when that component is stuck. There are two primary types, hydraulic and mechanical jars. While their respective designs are quite different, their operation is similar. Energy is stored in the drillstring and suddenly released by the jar when it fires. The principle is similar to that of a carpenter using a hammer. Kinetic energy is stored in the hammer as it is swung, and suddenly released to the nail and board when the hammer strikes the nail. Jars can be designed to strike up, down, or both. In the case of jarring up above a stuck bottomhole assembly, the driller slowly pulls up on the drillstring but the BHA does not move. Since the top of the drillstring is moving up, this means that the drillstring itself is stretching and storing energy. When the jars reach their firing point, they suddenly allow one section of the jar to move axially relative to a second, being pulled up rapidly in much the same way that one end of a stretched spring moves when released. After a few inches of movement, this moving section slams into a steel shoulder, imparting an impact load. In addition to the mechanical and hydraulic versions, jars are classified as drilling jars or fishing jars. The operation of the two types is similar, and both deliver approximately the same impact blow, but the drilling jar is built such that it can better withstand the rotary and vibrational loading associated with drilling.
2. [Well Completions]
A downhole tool that is used to impart a heavy blow or impact load to a downhole tool assembly. Commonly used in fishing operations to free stuck objects, jars are available in a range of sizes and capacities to deliver upward or downward impact loads. Some slickline tool assemblies use jars to operate tools that contain shear pins or spring profiles in their operating method.
3. [Well Workover and Intervention]
A downhole tool used to deliver an impact force to the tool string, usually to operate downhole tools or to dislodge a stuck tool string. Jars of different designs and operating principles are commonly included on slickline, coiled tubing and workover tool strings. Simple slickline jars incorporate an assembly that allows some free travel within the tool to gain momentum for the impact that occurs at the end of the stroke. Larger, more complex jars for coiled tubing or workover strings incorporate a trip or firing mechanism that prevents the jar from operating until the desired tension is applied to the string, thus optimizing the impact delivered. Jars are designed to be reset by simple string manipulation and are capable of repeated operation or firing before being recovered from the well