RU2491528C2 - Hydraulic jar test bench - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: test bench comprises structural frame formed by three rows of structural elements having transverse slots and transverse crossbars, hydraulic cylinder with piston, rod and seal, slider, first gripper arranged at said slider, sliding stop with second gripper secured at transverse slots of lengthwise structural elements, first and second threaded adapters to be connected to tested jar, electrically driven hydraulic pump, control valve, load metre, pressure gage and control board. Besides, it includes second hydraulic cylinder arranged parallel with the first one, lever module articulated with hydraulic cylinder rods. Said module is rigidly coupled with slider. Guide module with coaxial bushes is mounted at transverse wall. Slider is linked with said bushes. Every said row of lengthwise structural elements is composed of the row of stepped bars. The number of transverse cross-arms in every said row is larger than that of stepped bars by unity.

EFFECT: higher accuracy, reliability and safety.

8 cl, 9 dwg

Description

The invention relates to the field of petroleum engineering, and in particular to equipment for testing hydraulic jars: determining the time of hydraulic delay of double-acting hydraulic drill jars with set tensile and compression forces, as well as the release force of the latch of hydraulic drill jars.

A well-known test bench for hydraulic jars, consisting of a bed mounted on it with the possibility of axial movement of two carriages, rigidly fixed to the bed of a double-acting hydraulic cylinder and oil station, combined with a control panel, the bed contains two guide travers attached to each other with a number of vertical holes , one carriage is rigidly connected to the rod of the hydraulic cylinder, and the second is fixed on different sections of the bed using cylindrical clamps, while the tested hydraulic the avalanche jar is attached to the carriages with the help of adapters, the stand control panel is equipped with a regulator of fluid pressure supplied to the hydraulic cylinder, a switch of the direction of movement of the rod with a neutral position and a table for converting the pressure gauge pressure (MPa) to the load (tons) (www.sts-samara.ru )

The well-known stand is designed to test hydraulic jars up to 6 meters long with an outer diameter of up to 240 mm, a bed length of 7.5 meters, a maximum hydraulic cylinder pressure of 21 MPa, a maximum tensile force of 80 tons, a maximum compressive force of 95 tons, a reading indicator shows dynamic pressure gauge (MPa).

A disadvantage of the known design is the translation of the oil pressure in the hydraulic cylinder on the pressure gauge (MPa) to the axial load (in tons), which is performed using the table, which does not provide reliable tests of hydraulic jars due to the low accuracy of determining the oil pressure in the hydraulic cylinder on the pressure gauge and the rapid deviation of the arrow on the pressure gauge.

A disadvantage of the known stand is also the incomplete ability to reduce the cost, increase the reliability and safety of testing hydraulic jars, the lack of the ability to quickly set the range of tensile and compression forces controlled by a computer, the incomplete possibility of increasing the maximum force when stretching a hydraulic jar due to the fact that one of the carriages is rigidly connected to the rod of the hydraulic cylinder, while the rod area of the piston in the hydraulic cylinder has a smaller area and the generated tensile force vneny with the piston area and the force generated during compression.

A well-known test bench for hydraulic jars, consisting of a bed mounted on it with the possibility of axial movement of two carriages, rigidly fixed to the bed of a double-acting hydraulic cylinder and a hydraulic station combined with a control panel, the bed is two guide rails attached to each other with a row of vertical holes, one of the carriages is rigidly connected to the rod of the hydraulic cylinder, and the second is fixed on different sections of the bed, depending on the length of the test jar using cylindrical clamps, while the test jars are attached to the carriages with the help of adapters, the control panel of the stand is equipped with a regulator of the fluid pressure supplied to the hydraulic cylinder, a switch of the direction of movement of the rod with a neutral position and a table for transferring the pressure gauge to the load (www. Griffith • Vector Mini-Torque II Breakout Machine and Jar Testers) or (www. NATIONAL OIL WELL DOWNHOLE TOOLS CATALOG, US, 1998-99, p. 77).

The well-known stand (1786 series) is designed to test hydraulic jars up to 10 meters long with an outer diameter of up to 240 mm, the maximum tensile or compression force is 150 tons, the stroke length of the hydraulic cylinder rod is 810 mm, the stand bed length without a hydraulic station is 14 meters, an indicator for reading shows the applied dynamic load in tons.

A disadvantage of the known design is the display of pressure and axial load on the pressure gauge, which does not ensure the reliability of testing hydraulic jars due to the low accuracy of determining the oil pressure in the hydraulic cylinder and axial load on the manometer and the rapid deflection of the arrow on the pressure gauge, and also does not provide an economic advantage when operating the bench .

A disadvantage of the known stand is also the incomplete ability to reduce the cost, increase the reliability and safety of testing hydraulic jars, the lack of the ability to quickly set the range of tensile and compression forces controlled by a computer, the incomplete possibility of increasing the maximum force when stretching a hydraulic jar due to the fact that one of the carriages is rigidly connected to the rod of the hydraulic cylinder, while the rod area of the piston in the hydraulic cylinder has a smaller area and the generated tensile force vneny with the piston area and the force generated during compression.

Closest to the claimed design is a YOW type hydraulic hydraulic tester of the company BOWEN (US), comprising a power frame formed by three longitudinal power elements having transverse grooves and corresponding transverse traverses, a hydraulic cylinder with a piston, rod and seals, a movable slider interacting with a hydraulic cylinder rod, a first gripping device mounted on a movable slider, an emphasis stop with a second gripping device, mounted in the transverse grooves of the longitudinal power element c, the first and second threaded adapters designed to connect to the test jar, as well as an electric hydraulic pump, a control valve, a load regulator, a pressure gauge and a control panel (www. Bowen Type D Jar Tester) or (www. NATIONAL OIL WELL DOWNHOLE TOOLS CATALOG, 1998-99, p. 80).

The well-known hydraulic type tester D is designed to test jars up to 6 meters long with an outer diameter of up to 240 mm, the maximum tensile and compression force is 100 tons, the stroke length of the hydraulic cylinder rod is 500 mm, the frame can be equipped with an additional insert that extends it by 1,500 mm , the indicator for reading shows the applied load in tons.

A disadvantage of the known design is the display of pressure and axial load on the pressure gauge, which does not ensure the reliability of testing hydraulic jars due to the low accuracy of determining the oil pressure in the hydraulic cylinder and axial load on the manometer and the rapid deflection of the arrow on the pressure gauge, and also does not provide an economic advantage when operating the bench .

Another disadvantage of the known stand is the incomplete ability to reduce the cost, improve the accuracy, reliability and safety of testing hydraulic jars, the insufficient rigidity of the frame of the stand, the inability to quickly set the range of tensile and compression forces controlled by a computer, the incomplete possibility of increasing the maximum tensile force of a hydraulic jar due to that the first gripping device is mounted on a movable slider attached to the rod of the hydraulic cylinder, while the piston rod area in the hydraulic cylinder has a smaller area and the generated tensile force as compared with the piston area and the created compressive force, and also has a lesser rod seal life due to operation at increased pressure compared to the pressure of the working fluid in the piston cavity.

Another disadvantage of the well-known test bench is the lack of a system for measuring the tensile and compression forces, automatically converting the pressure values in the hydraulic cylinder to the tensile and compressive forces of the tested hydraulic jar, as well as the lack of a built-in stopwatch that displays the hydraulic delay time of the tested hydraulic drill jar in a given range of forces stretching and compression.

The technical problem to which the invention is directed is reducing the cost, improving the accuracy, reliability and safety of testing hydraulic jars, the ability to quickly set the range of tensile and compression forces controlled by a computer, increasing the accuracy of determining the time of hydraulic delay of a double-acting hydraulic drill jar in a given range of tensile forces and compression, as well as improving the accuracy of the release force of the latch of the hydraulic drill jar with a mechanical latch.

The essence of the technical solution lies in the fact that the stand for testing hydraulic jars, containing a power frame formed by three longitudinal power elements having transverse grooves and transverse traverses, a hydraulic cylinder with a piston, a rod and seals, a movable slider interacting with the hydraulic cylinder rod, is the first exciting a device mounted on a movable slider, an emphasis with a second gripping device, mounted in the transverse grooves of the longitudinal power elements, the first and second thread According to the invention, provided sub-assemblies for connecting to the test jar, as well as an electric hydraulic pump, a control valve, a load regulator, a pressure gauge and a control panel, are equipped with a second hydraulic cylinder parallel to the first, the hydraulic cylinder rods are directed opposite to the first gripping device, fixed on a movable slider, and is also equipped with a lever module pivotally connected to the rods of the hydraulic cylinders, and the lever module is rigidly fastened with a movable slider and located outside the power frame, while on the transverse wall located on the side of the lever module, there is a guide module with coaxially arranged bushes, and the movable slider is telescopically connected to the bushes of the guide module, each of the three rows of longitudinal power elements is made in the form a series of stepped rods with rows of annular grooves, each of the grooves is located in the same transverse plane with the corresponding annular grooves of two other stepped rods, m in each row of longitudinal power elements, the number of transverse traverses is one more than the number of stepped rods.

The stepped rods are made, each with centering belts at the edges, in the transverse traverses made centering holes directed to the stepped rods, while the centering belts of each stepped bar are telescopically connected to the centering holes of the transverse traverses, and they are fastened to the power frame by threaded rods mounted inside the stepped rods and transverse traverse, and threaded elements.

Three rows of longitudinal power elements, made in the form of a series of stepped rods with rows of annular grooves, are uniformly distributed in the circumferential direction relative to the inner diameters of the coaxially located bushings of the guide module for the movable slide.

The test bench for hydraulic jars contains a system for measuring tensile and compression forces, automatically converting pressure values in hydraulic cylinders into values of tensile and compression forces of the tested hydraulic jar, as well as an integrated stopwatch that displays the hydraulic delay time of the tested hydraulic jar, while the system for measuring tensile and compression forces the tested hydraulic jar is made in the form of a panel computer, including a touch screen, processor, RAM and a real watch th time.

The first gripping device, mounted on a movable slider, is equipped with an adjustable roller support that moves along the power frame along the longitudinal axis of the bushings of the guide module.

The test bench for hydraulic jars contains a frame fence for the movement zone of the lever module pivotally connected to the rods of parallel hydraulic cylinders, and also contains an armored fence for the movement zone of the movable slide and the first gripping device mounted on it.

The implementation of the bench for testing hydraulic jars in such a way that it is equipped with a second hydraulic cylinder parallel to the first, the cylinder rods are directed to the side opposite to the first gripping device mounted on a movable slider, and also equipped with a lever module pivotally connected to the cylinder rods, and the lever module is rigidly fastened with a movable slider and located outside the power frame, while on the transverse wall located on the side of the lever module is installed on a guide module with coaxially arranged bushings, and a movable slider telescopically connected to the guide module bushings, each of three rows of longitudinal power elements is made in the form of a series of stepped rods with rows of ring grooves, each of the ring grooves is located in one transverse plane with the corresponding ring grooves of the other two step rods, and in each row of longitudinal power elements the number of transverse traverses is one more than the number of step rods, reduces cost, increases accurately The reliability, reliability and safety of testing hydraulic jars provides the ability to quickly set the range of tensile and compression forces controlled by a computer, increases the accuracy of determining the hydraulic delay time of a double-acting hydraulic drill jar in a given range of tensile and compression forces, and also increases the accuracy of the release force of the hydraulic drill latch mechanical catch latch.

The implementation of the bench for testing hydraulic jars so that the stepped rods are made, each with centering belts at the edges, centering holes are made in the transverse traverses directed to the stepped rods, while the centering belts of each stepped rod are telescopically connected to the centering holes of the transverse traverses, and fastened with a power frame by threaded rods installed inside stepped rods and transverse traverses, and threaded elements, with three rows of longitudinal forces new elements, made in the form of a series of stepped rods with rows of annular grooves, are evenly distributed in the circumferential direction relative to the inner diameters of the coaxially located bushes of the guide module for the movable slide, increases the accuracy of the arrangement of three rows of longitudinal power elements, reduces bending stresses in the power frame at maximum tensile forces and compression of test jars, increases the reliability and safety of testing hydraulic jars.

The implementation of the bench for testing hydraulic jars in such a way that it contains a system for measuring the tensile and compression forces, automatically converting the pressure values in the hydraulic cylinders into the tensile and compressive forces of the tested hydraulic jar, as well as a built-in stopwatch that displays the hydraulic delay time of the tested hydraulic jar, while the system for measuring the tensile and compressive forces of the tested hydraulic jar is made in the form of a panel computer, including a touch screen, the process , Memory and real time clock, provides the ability to quickly configure the range of tensile and compressive forces, controlled by computer, as well as improving the accuracy of the time delay of the hydraulic drilling jar hydraulic double-acting with the required force expansion and contraction.

In addition, the implementation of the bench for testing hydraulic jars in this way provides increased test safety due to the fact that it prevents unexpected activation and spontaneous impact of a hydraulic jar of double-acting (with rapid compression or tension) by increasing the accuracy of the hydraulic delay time of a hydraulic drill jar.

The implementation of the bench for testing hydraulic jars in such a way that the first gripping device mounted on a movable slide is equipped with an adjustable roller support that moves along the longitudinal axis along the longitudinal axis of the bushes of the guide module, provides an increase in the life and reliability of the movable slide, lever module and parallel cylinders, and also provides the ability to quickly set the range of tensile and compression forces controlled by a computer, due to the fact that the adjustable roller The new support accepts bending loads from the weight of the movable slide with the first gripping device fixed on it, the weight of the threaded sub connected to the test box, and also from the part of the weight of the test box.

In addition, this embodiment of the test bench for hydraulic jars increases the resource and reliability of the movable slide, the lever module and parallel hydraulic cylinders, and also provides the ability to quickly set the range of tensile and compression forces controlled by the computer, also due to the fact that when applying pressure to the piston cavities hydraulic cylinders, hydraulic cylinder rods through a lever module, a movable slider, a first gripping device, a first threaded sub transmit a force p tension to the hydraulic jar, and when pressure is applied to the rod cavity of each of the hydraulic cylinders, the hydraulic cylinder rods through the lever module, the movable slide, the first gripping device, the first threaded sub transmit the compressive force to the hydraulic jar, which makes it possible to quickly set the range of tensile and compression forces controlled by computer, improves the accuracy of determining the hydraulic delay time of a double-acting hydraulic drill string with installed power In addition to tension and compression, it also increases the accuracy of the release force of the latch of the hydromechanical box.

The implementation of the bench for testing hydraulic jars in such a way that it contains a frame guard of the movement zone of the lever module pivotally connected to the rods of parallel hydraulic cylinders, and also contains an armored fence of the movement zone of the movable slide and the first gripping device mounted on it, increases the safety of dynamic tests of hydraulic jars, for example, in case of unexpected activation and spontaneous striking with a double-acting hydraulic jar i.

Below is the best version of the SGI-75RS test bench for testing hydraulic jars.

Figure 1 shows a General view of the test bench for hydraulic jars.

Figure 2 shows a top view of a bench for testing hydraulic jars.

Figure 3 shows the load part of the stand (hydraulic cylinder and lever module).

Figure 4 shows a top view of the loading part of the stand (two hydraulic cylinders, a movable slider, a lever module, a first gripping device, a first threaded sub connected to the jar).

Figure 5 shows a section aa in figure 4 along a movable slider installed in the bushings of the guide module, a lever module fastened to the movable slider, a first gripping device fastened to the movable slider and a first threaded sub connected to the jar.

In Fig.6 shows a section bB in Fig.4 along the hydraulic cylinder, its mounting elements on the transverse traverse and its mounting elements with a lever module.

In Fig.7 shows a section bb In Fig.1 along a series of stepped rods fastened with transverse traverses, as well as a second gripping device, a second threaded sub connected to the jar.

On Fig shows a section GG in figure 1 across the longitudinal power elements of the stand, the first gripping device for the first threaded sub.

In Fig.9 shows a section DD in Fig.1 across the longitudinal power elements of the stand, the emphasis with the second gripping device for the second threaded sub, mounted in the transverse grooves of the longitudinal power elements.

The test bench for hydraulic jars contains a power frame 1 formed by three longitudinal power elements 2, 3, 4, having transverse grooves 5, and corresponding transverse traverses 6, 7, a hydraulic cylinder 8 with a piston 9, a rod 10 and seals 11, 12, a movable slider 13, interacting with the rod 10 of the hydraulic cylinder 8, the first gripping device 14, mounted on a movable slider 13, the movable stop 15 with the second gripping device 16, mounted in the transverse grooves 5 of the longitudinal power elements 2, 3, 4, the first and second threaded adapters 17, 18, respectively, designed to connect with the test box 19, as well as a hydraulic pump 20 with an electric actuator 21, a distribution valve 22, a load value regulator 23, a pressure gauge 24 and a control panel 25, are shown in FIGS. 1, 2, 3, 4, 5, 6, 7.

The test bench for hydraulic jars is equipped with a second hydraulic cylinder 26, parallel to the first hydraulic cylinder 8, and the rods 10, 27 of the hydraulic cylinders, respectively, 8, 26 are directed towards the edge 28 of the power frame 1, opposite the first gripping device 14, mounted on a movable slider 13, shown in figure 1, 2, 3, 4, 5, 6.

The test bench for hydraulic jars is equipped with a lever module 29, pivotally connected by the axles 30 with the rods 10, 27 of the hydraulic cylinders, respectively 8, 26, and the lever module 29 is rigidly fastened by a bolt 31 with a movable slider 13 and is located outside the edge 28 of the power frame 1, while on the transverse wall 32, located on the side of the lever module 29, a guide module 33 is mounted with coaxially located bushings 34, 35, and the movable slider 13 is telescopically connected to the bushes 34, 35 of the guide module 33, shown in Figs. 2, 3, 4, 5 , 6, 7.

In addition, figure 6 shows: pos. 36 - threaded earring for fastening on one side with a bolt 37 with a transverse wall 38, as well as for fastening on the other side of the housing of the hydraulic cylinder 8 using the axis 30, the second earring 36 with the transverse the wall 38, and also fastened to the housing of the hydraulic cylinder 26 using the second axis 30; pos.39 - a threaded earring for fastening the lever module 29 with the axis 30 of the rod 10 of the hydraulic cylinder 8, the rod 27 of the hydraulic cylinder 26 is secured in a similar manner to the second threaded rod 39 using the axis 30, shown in Figs. 3, 4, 6.

Each of the three rows of longitudinal power elements 2, 3, 4 is made in the form of a series of identical stepped rods 40 of length L, 41 with rows of annular grooves 42, each of the annular grooves 42, for example, in a series of longitudinal power elements 2, is located in one transverse plane P, 43 with corresponding annular grooves 44 of two other stepped rods 40 of two other rows of longitudinal power elements 3 and 4, and in each row of longitudinal power elements 2, 3, and 4, essentially along the length H, 45 of the power frame 1, the number ( 9) transverse traverse 6 and 7 one more the number (8) of the stepped rods 40, shown in figures 1, 2, 3, 4.

The stepped rods 40 (identical) are made, each with centering belts 46 at the edges 47, 48, in the transverse traverses 6, 7 there are made centering holes 49 directed to the stepped rods 40, while the centering belts 47, 48 of each stepped rod 40 are telescopically connected to centering holes 49 of the transverse traverse 6, 7, and also fastened to the power frame 1 by threaded rods 50 mounted inside the stepped rods 40 and transverse traverses 6, 7, and threaded elements 51, shown in Fig.2, 4, 7.

Three rows of longitudinal power elements 2, 3, 4, made in the form of a series of identical stepped rods 40 with rows of annular grooves 42, are uniformly distributed in the circumferential direction relative to the inner diameters D, 52 of the coaxially located bushings 34, 35 of the guide module 33 for the movable slide 13, shown in figures 1, 2, 5, 8.

The hydraulic jar test bench includes a system 53 for measuring tensile and compression forces, automatically converting the pressure values in the hydraulic cylinders 8, 26 into the values of the tensile and compression forces of the tested hydraulic jar 19, as well as a built-in stopwatch 54 that displays the hydraulic delay time of the tested hydraulic jar 19, this system 53 measuring the tensile and compression forces of the test hydraulic jar 19 is made in the form of a panel computer 55, including a touch screen 56, processor 57, operational knead 58 and 59 real-time clock is shown in Figures 1, 2.

The first gripping device 14, mounted on a movable slider 13, is equipped with an adjustable roller support 60, which is moved along the power frame 1, on the surface 61 along the longitudinal 62 axis of the bushings 34, 35 of the guide module 33, shown in Fig.5, 6.

The test bench for hydraulic jars contains a frame fence 63 of the movement zone of the lever module 29, pivotally connected by the axes 30 to the rods 10, 27 of the parallel-mounted hydraulic cylinders 8, 26, and also contains an armored fence 64 of the movement zone of the movable slide 13 and the first gripping device 14 mounted on it shown in figures 1, 2, 3, 4, 5, 6, 8.

In addition, Fig.6 shows: pos.65 - the piston cavity of the hydraulic cylinders 8, 26; pos.66 - rod cavity of hydraulic cylinders 8, 26.

The stand contains an automated control system (ACS) designed to manage the stand systems, protect process equipment and its units in case of an accident threat, provide personnel with sufficient, reliable and timely information about the test process, including emergency and warning alarms, output and storage of test results. Specifications of the stand are shown in table 1.

Table 1 1.1 The maximum diameter of the tested products, mm 240 1.2 Maximum tensile force, kgf 95000 1.3 Maximum compression force, kgf 78500 1.4 Maximum distance between captures, mm 9990 1.5 Minimum distance between captures, mm 2200 1.6 Fixation step of a fixed capture, mm 140 1.7 Movable gripping stroke, mm 650 1.8 The maximum working pressure in the hydraulic system, kgf / cm ² 250 1.9 Overall dimensions (L × B × H), mm 12750 × 730 × 740 1.10 Stand weight without pump, kg 4235 1.11 Electric motor 380V 50 Hz power, kW, eleven rotational speed, rpm 960 1.12 Pump axial piston adjustable displacement of the pump, cm ³ / rev; 32 pressure control range, kgf / cm ² 10 ... 250 1.13 Hydraulic tank capacity, l 112 1.14 Working fluid Mobil DTE 25 1.15 Overall dimensions (L × B × H), mm 1016 × 914 × 1074 1.16 Pump mass without working fluid, kg 400

Double-acting hydraulic drill jar, for example, RDT-2H with a diameter of 203 mm (8 ") and a length of 7 meters (in a compressed state) is screwed with the first and second threaded sub, respectively 17, 18 and installed in the first gripping device 14, mounted on a movable slider 13, and in the interchange stop 15 with a second gripping device 16, mounted in three rows of longitudinal power elements 2, 3, 4, made in the form of a series of identical stepped rods 40 with rows of annular grooves 42.

After introducing the test start teams into the automated control system, the axial piston adjustable pump is started and brought to its minimum operating mode. The working fluid (Mobil DTE 25) is first supplied to the piston cavities 65 of the hydraulic cylinders 8, 26.

When applying a given pressure of the working fluid to the piston cavities 65 of the hydraulic cylinders 8, 26, the rods 10, 27 of the hydraulic cylinders, respectively, 8, 26 through the axes 30, the lever module 29, the bolt 31, the movable slider 13, the first gripping device 14, the first threaded adapter 17 transmit tensile force to the hydraulic jar 19.

When applying the specified pressure of the working fluid to the rod cavities 66 of the hydraulic cylinders 8, 26, the rods 10, 27 of the hydraulic cylinders, respectively, 8, 26 through the axis 30, the lever module 29, the bolt 31, the movable slider 13, the first gripping device 14, the first threaded adapter 17 transmit the compression force to the hydraulic box 19.

The system 53 measuring the tensile and compression forces automatically converts the pressure values in the hydraulic cylinders 8, 26 into the tensile and compressive forces of the tested hydraulic jar 19, and the built-in stopwatch 54 displays the hydraulic delay time of the tested hydraulic jar 19 ("delay" or throttling of the working fluid of the hydraulic jar through jets), while the system 53 measuring the tensile and compressive forces of the test hydraulic jar 19 displays the performance of tests on the panel computer 55, including a touch screen 56, a processor 57, RAM 58 and a real-time clock 59, and also records the progress of the tests and is processed by the computer 55.

Improving the accuracy of the delay time created by hydraulics for striking, with the optimal ratio between the shock load and the shock pulse, allows the operator at the rig to change the permissible tensile force of the drill string, and then apply the winch brake. As a result of this, the force when releasing the stick is easily controlled, damage to the lifting equipment is prevented.

When testing hydraulic drill jars with a mechanical latch, the tensile and compression force measuring system 53 automatically translates the pressure values in the hydraulic cylinders 8, 26 into the unlocking forces of the mechanical latch during tension and compression.

Hydraulic drill jar works by moving the drill string up or down. The magnitude of the upward impact force is directly proportional to the applied tensile force. In the stretching mode, as the applied tensile force begins to exceed the latch setting parameter (upon impact as part of the drill string up), the mechanical latch is sharply released from blocking and a hydraulic delay occurs. After a short period of time, the mandrel of the jar 19 is sharply released and accelerated to the position of full extension.

In the compression mode of the hydraulic jar 19 (directed downward in the drill string), as the compressive force acting on the jar begins to exceed the latch setting when it strikes down, the mechanical latch of the jar 19 is sharply released from the lock, allowing the mandrel 19 to return to the fully closed position.

The system 53 measuring the tensile and compression forces automatically converts the pressure values in the hydraulic cylinders 8, 26 into the parameter (force) of the latch when stretching and compressing the test hydraulic jar 19, and the built-in stopwatch 54 displays the hydraulic delay time of the tested hydraulic jar 19 ("delay" or throttling the working fluid of the hydraulic jar through the nozzles), while the system 53 measuring the tensile and compression forces of the tested hydraulic jar 19 displays the execution of tests on the panel computer 55, including a touch screen 56, a processor 57, a RAM 58 and a clock 59 real-time, and also records the progress of the tests and is processed by the computer 55.

The test bench for hydraulic jars improves the accuracy, reliability and safety of testing hydraulic jars, provides the ability to quickly set the range of tensile and compression forces controlled by a computer, increases the accuracy of determining the hydraulic delay time of a double-acting hydraulic drill string in a given range of tensile and compression forces, and also increases accuracy of the release force of the latch of a hydraulic drill jar with a mechanical latch.

Claims (8)

1. A test bench for hydraulic jars containing a power frame formed by three rows of longitudinal power elements having transverse grooves and transverse traverses located between these longitudinal power elements, a hydraulic cylinder with a piston, rod and seals, a movable slider interacting with the hydraulic cylinder rod, a first gripping device mounted on a movable slider, an emphasis with a second gripping device, mounted in the transverse grooves of the longitudinal power elements, first th and second threaded sub, designed to be connected to the test jar, as well as an electric hydraulic pump, a control valve, a load regulator, a pressure gauge and a control panel, characterized in that it is equipped with a second hydraulic cylinder parallel to the first, the hydraulic cylinder rods are directed to the side, opposite to the first gripping device mounted on a movable slider, and also equipped with a lever module pivotally connected to the rods of the hydraulic cylinders, and the lever mode l is rigidly fixed to the movable slider and located outside the power frame, while on the transverse wall located on the side of the lever module, a guide module with coaxially arranged bushings is installed, and the movable slider is telescopically connected to the bushes of the guide module, each of three rows of longitudinal power elements made in the form of a series of stepped rods with rows of annular grooves, each of the annular grooves is located in the same transverse plane with the corresponding annular grooves of two other stupas chatyh rods, wherein in each row of longitudinal power elements of the number of transverse traverse one more than the number of stepped rod. 2. A test bench for hydraulic jars according to claim 1, characterized in that the stepped rods are each made with centering belts at the edges, centering holes are made in the transverse traverses directed to the stepped rods, while the centering belts of each stepped bar are telescopically connected to the centering holes transverse traverses, as well as fastened with a power frame by threaded rods installed inside the stepped rods and transverse traverses, and threaded elements. 3. A test bench for hydraulic jars according to claim 1, characterized in that three rows of longitudinal power elements, made in the form of a series of stepped rods with rows of annular grooves, are uniformly distributed in the circumferential direction relative to the inner diameters of the coaxially located bushings of the guide module for the movable slide. 4. The test bench for hydraulic jars according to claim 1, characterized in that it contains a system for measuring tensile and compression forces, automatically converting the pressure values in the hydraulic cylinders into the values of the tensile and compression forces of the tested hydraulic jar, as well as an integrated stopwatch that displays the time of the hydraulic delay of the tested hydraulic jar. 5. The test bench for hydraulic jars according to claim 4, characterized in that the system for measuring the tensile and compressive forces of the tested hydraulic jar is made in the form of a panel computer, including a touch screen, processor, RAM and a real-time clock. 6. The test bench for hydraulic jars according to claim 1, characterized in that the first gripping device mounted on a movable slide is equipped with an adjustable roller support that moves along the power frame along the longitudinal axis of the bushes of the guide module. 7. The test bench for hydraulic jars according to claim 1, characterized in that it comprises a frame guard for the movement zone of the lever module pivotally connected to the rods of parallel hydraulic cylinders. 8. The test bench for hydraulic jars according to claim 1, characterized in that it contains an armored enclosure of the moving zone of the movable slider and the first gripping device mounted on it.

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