CN111456711A

CN111456711A - Azimuth gamma test platform

Info

Publication number: CN111456711A
Application number: CN202010373290.XA
Authority: CN
Inventors: 薛让平; 倪华峰; 王万庆; 陶海君; 刘李宏; 贾武升; 陈琪; 罗军营; 李小鹏; 李阳; 陈联国; 李长远; 王岗; 王可仁; 王忠斌; 李富斌; 杨东良; 魏炜; 王辉
Original assignee: China Textile Industry Design Institute; CNPC Chuanqing Drilling Engineering Co Ltd
Current assignee: China Textile Industry Design Institute; China National Petroleum Corp; CNPC Chuanqing Drilling Engineering Co Ltd
Priority date: 2020-05-06
Filing date: 2020-05-06
Publication date: 2020-07-28

Abstract

The invention relates to an azimuth gamma test platform, which belongs to the field of drilling engineering in petroleum, coal mine and geological exploration, and comprises: the middle part of the stratum simulation part is provided with a drill hole; the diameter of the connecting rod part is smaller than the inner diameter of the drilled hole, and the middle part of the connecting rod part is used for mounting azimuth gamma; and the transmission system is arranged between the stratum simulation part and the connecting rod part, and the connecting rod part is driven by the transmission system to relatively rotate in the drilling hole of the stratum simulation part and relatively move along the axial direction of the through hole. The formation simulation part and the connecting rod part are controlled to move relatively by controlling the mutual movement between the formation simulation part and the connecting rod part provided with the orientation gamma, so that the drilling process is simulated, and the orientation gamma is simulated, tested and corrected by further simulating the real drilling process, so that the orientation gamma is close to the real environment during correction, and the test and correction result is more real.

Description

Azimuth gamma test platform

Technical Field

The invention belongs to the field of drilling engineering in petroleum, coal mine and geological exploration, and particularly relates to an azimuth gamma test platform.

Background

In recent years, with the increasing of directional wells and horizontal wells, the logging while drilling technology is rapidly developed, wherein the azimuth gamma logging while drilling is a necessary logging while drilling project. The measurement result has the azimuth characteristic, and the real-time transmission data can be used as important data of geosteering to better evaluate the stratum.

In the process of implementing the embodiment of the invention, the following defects in the background art are found:

at present, azimuth gamma is only used for calibrating a standard well and mutually calibrating instruments, and ground simulation test calibration cannot be realized.

Disclosure of Invention

The invention provides an azimuth gamma test platform, which aims to solve the problems that azimuth gamma only calibrates a standard well and mutually calibrates instruments and cannot realize ground simulation test calibration.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows:

an azimuth gamma test platform comprising:

the middle part of the stratum simulation part is provided with a drill hole;

the diameter of the connecting rod part is smaller than the inner diameter of the drilled hole, and the middle part of the connecting rod part is used for mounting azimuth gamma;

and the transmission system is arranged between the stratum simulation part and the connecting rod part, and the connecting rod part is driven by the transmission system to relatively rotate in the drilling hole of the stratum simulation part and relatively move along the axial direction of the through hole.

The wireless communication device is used for being in wireless communication connection with the outside; or

The signal transmission device is a slip ring, the slip ring end is used for being electrically connected with the azimuth gamma in the middle of the connecting rod part, and the slip ring end is used for being electrically connected with the outside.

Still include guide rail, bearing and base, transmission system includes servo motor and linear drive device, and linear drive device's transmission direction is parallel with the direction syntropy of guide rail, and linear drive device is connected with the slider transmission of guide rail, and stratum simulation portion fixes on the slider of guide rail, the axial direction of drilling is parallel with the direction of guide rail, and the middle part of connecting rod portion is located in the drilling, connecting rod portion with drilling is coaxial, and servo motor is connected with the coaxial transmission of connecting rod portion one end, and the main part of servo motor, linear drive device and guide rail is fixed respectively on the base, and connecting rod portion passes through the bearing and is connected with the base rotation.

Still include bearing and base, transmission system includes servo motor and linear transmission, and the middle part of connecting rod portion is located in the drilling, connecting rod portion with the drilling is coaxial, and servo motor is connected with the coaxial transmission of connecting rod portion one end, linear transmission be used for driving connecting rod portion with drilling is relative motion on the axial direction, and linear transmission's main part is fixed on the base, and connecting rod portion passes through the bearing and rotates for the base and connect.

The slip ring is electrically connected with the azimuth gamma in the middle of the connecting rod part through the lead, and the static end of the slip ring is electrically connected with the outside.

Still have transmission between servo motor and connecting rod portion, transmission includes support body, bearing and drive mechanism, the support body sets up in base upper end both sides, and the body of bearing is fixed the support body top, connecting rod portion pass through the bearing with the support body rotates to be connected, drive mechanism fixes on the support body, drive mechanism's one end and the coaxial transmission of connecting rod portion are connected, drive mechanism's the other end and servo motor transmission are connected.

The rotation end of bearing is fixed with the chuck, and connecting rod portion includes left extension bar, is used for installing position gamma's gamma drill collar and right extension bar under test, and left extension bar and right extension bar detachable connect at gamma drill collar both ends under test, and the tip of left extension bar and right extension bar is connected with the bearing through the chuck respectively.

The tail locking device is detachably connected to a bearing located at the tail of the connecting rod portion, and when the tail locking device is connected to the bearing, the tail locking device contacts one side of the end portion of the connecting rod portion.

One slide rail of the guide rail is a plane slide rail, the other slide rail of the guide rail is a V-shaped slide rail, the plane slide rail and the V-shaped slide rail are arranged in parallel, the guide rail is positioned at the tops of the plane slide rail and the V-shaped slide rail, and the guide rail is simultaneously connected with the plane slide rail and the V-shaped slide rail in a sliding manner.

The base is spliced by a plurality of frame bodies.

The invention has the advantages that the relative motion between the stratum simulation part and the connecting rod part is controlled by controlling the mutual motion between the stratum simulation part and the connecting rod part provided with the azimuth gamma, the drilling process is simulated, and the azimuth gamma is simulated, tested and corrected by further simulating the real drilling process, so that the azimuth gamma is close to the real environment during correction, and the test and correction result is more real.

Drawings

FIG. 1 is a perspective view of an overall structure of an azimuth gamma test platform according to the present invention;

FIG. 2 is a side view of FIG. 1;

FIG. 3 is an enlarged perspective view of FIG. 2 at B;

FIG. 4 is a schematic structural view of the platform and the guide rails and sliders of FIG. 2;

FIG. 5 is an enlarged perspective view taken at A in FIG. 2;

FIG. 6 is a schematic diagram of a rack gear assembly in an embodiment of an azimuthal gamma test platform according to the present invention;

FIG. 7 is a schematic structural diagram of a connecting rod portion of an orientation gamma test platform according to the present invention;

FIG. 8 is a schematic structural diagram of a joint between a planar slide rail and a V-shaped guide rail in an orientation gamma test platform according to the present invention.

Reference numerals: 1. a servo motor; 2. a bearing; 3. a motor driver control cabinet; 4. a control panel; 5. a V-shaped bracket; 6. a formation simulation unit; 7. a linear transmission; 8. a guide rail; 9. a link section; 10. a gamma-ray drill collar to be tested; 11. a tailstock adjusting screw rod; 12. a tail locking device; 13. a right extension bar; 14. a slider; 15. a needle bearing; 16. a planar slide rail; 17. a V-shaped guide wheel; 18. a V-shaped slide rail; 19. a chuck; 20. a cycloidal needle speed reducer; 21. a power take-off shaft; 22. an absolute value encoder; 23. a left extension bar; 24. a rack; 25. a turbine speed reducer; 26. a main gear; 27. a second-stage turbine reducer; 28. a drive motor; 29. a frame body; 30. a fixed seat; 31. the tailstock adjusts the lead screw.

Detailed Description

In the following, a detailed description will be given of an orientation gamma test platform scheme provided by an embodiment of the present invention through several specific embodiments.

Example 1

Referring to fig. 1 and fig. 2, which are schematic overall structural diagrams illustrating an embodiment of an orientation gamma test platform according to the present invention, the orientation gamma test platform is characterized by comprising:

the stratum simulation part 6 is provided with a drill hole in the middle of the stratum simulation part 6;

the diameter of the connecting rod part 9 is smaller than the inner diameter of the drilled hole, and the middle part of the connecting rod part 9 is used for installing azimuth gamma;

and the transmission system is arranged between the stratum simulation part 6 and the connecting rod part 9, and the connecting rod part 9 is driven by the transmission system to enable the connecting rod part 9 to relatively rotate in the drilling hole of the stratum simulation part 6 and relatively move along the axial direction of the through hole.

In the above embodiment, the formation simulation part 6 is configured to simulate a structure of an underground formation, the formation simulation part 6 is provided with a borehole, the borehole drilled in a bottom layer under a real condition is simulated, the connecting rod part 9 is configured to bear azimuth gamma, and a working environment of the azimuth gamma under the real condition is simulated, the transmission system acts on the formation simulation part 6 or the connecting rod part 9, so that the connecting rod part 9 moves relative to the formation simulation part 6, the relative movement simulates a process of drilling in the bottom layer, and in the process, the connecting rod part 9 rotates at a certain rotation speed and moves in an axial direction of the borehole at a certain speed; in the movement process, the rotation speed and the axial direction movement of the drill hole can be set according to different rock strata, and the drilling situation of the drilling tool under different rock strata can be truly simulated.

The movement of the connecting rod part 9 drives the azimuth gamma installed on the connecting rod part to move, under the condition that other conditions are determined, the measurement data of the azimuth gamma are obtained again, the measurement data of the azimuth gamma are compared with preset data, and the azimuth gamma can be subjected to verification test.

The formation simulation part and the connecting rod part are controlled to move relatively by controlling the mutual movement between the formation simulation part and the connecting rod part provided with the orientation gamma, so that the drilling process is simulated, and the orientation gamma is simulated, tested and corrected by further simulating the real drilling process, so that the orientation gamma is close to the real environment during correction, and the test and correction result is more real.

Example 2

Furthermore, another embodiment of the azimuth gamma test platform of the present invention further comprises a signal transmission device, wherein the signal transmission device is a wireless transmission device, and the wireless transmission device is used for connecting with the outside in a wireless communication manner; or

The signal transmission device is a slip ring, the end of the slip ring is used for being electrically connected with the azimuth gamma in the middle of the connecting rod part 9, and the end of the slip ring is used for being electrically connected with the outside.

In the above embodiment, the power supply and the transmitter are disposed in the middle of the connecting rod portion 9 in a wireless manner for obtaining the azimuth gamma test data.

The test data of the azimuth gamma can also be acquired by adopting a wire connection mode, in this case, the stratum simulation part 6 can be directly rotated, or the connecting rod part 9 can be directly rotated, but the slip ring or the electric brush needs to be installed on the connecting rod part 9, so that the wire is prevented from being wound in a rotating process.

Example 3

Further, referring to fig. 1, another embodiment of the azimuth gamma test platform of the present invention further includes a guide rail 8, a bearing 2, and a base 12, the transmission system includes a servo motor 1 and a linear transmission device 7, a transmission direction of the linear transmission device 7 is the same as a guide direction of the guide rail 8, the linear transmission device 7 is in transmission connection with a slider of the guide rail 8, a formation simulation portion 6 is fixed on the slider of the guide rail 8, an axial direction of the drill hole is parallel to the guide direction of the guide rail 8, a middle portion of a connecting rod portion 9 is located in the drill hole, the connecting rod portion 9 is coaxial with the drill hole, the servo motor 1 is in coaxial transmission connection with one end of the connecting rod portion 9, bodies of the servo motor 1, the linear transmission device 7, and the guide rail 8 are respectively fixed on the base 12, and the connecting rod portion 9 is rotatably connected with the.

In the above embodiment, the base 12 plays a supporting role, the guide rail 8 is fixed on the base 12 to play a guiding role for the formation simulation part 6, the formation simulation part 6 can slide back and forth along the guiding direction of the guide rail 8 through the slider, the linear transmission device 7 is also fixed on the base 12, and the transmission end of the linear transmission device 7 is fixed with the formation simulation part 6, so that the linear transmission device 7 can drive the formation simulation part 6 to slide along the guide rail.

The link part 9 is fixed in position relative to the base 12, the link part 9 is rotatably connected with the base 12 through the bearing 2, and the link part 9 can be driven by the servo motor 1 to rotate.

Therefore, the servo motor 1 drives the connecting rod part 9 to simulate the rotating state during drilling, the linear transmission device 7 drives the stratum simulation part 6 to move along the guide direction of the guide rail 8 to relatively simulate the downward deep state of the connecting rod part 9 during drilling, through the structure of the embodiment, the rotating state and the downward deep state of the connecting rod part 9 are executed through two unconnected components, so that only one motion state needs to be completed by a single component, the device is more stable during operation, the measurement structure is more accurate due to the stability of the whole system during measurement, the structure of a transmission system is simplified, and the production cost is reduced.

Example 4

Further, another embodiment of the azimuth gamma test platform of the present invention further includes a bearing 2 and a base 12, the transmission system includes a servo motor 1 and a linear transmission device 7, the middle part of the connecting rod portion 9 is located in the drill hole, the connecting rod portion 9 is coaxial with the drill hole, the servo motor 1 is coaxially connected with one end of the connecting rod portion 9 in a transmission manner, the linear transmission device 7 is used for driving the connecting rod portion 9 and the drill hole to move relatively in the axial direction, the main body of the linear transmission device 7 is fixed on the base 12, and the connecting rod portion 9 is rotatably connected with the base 12 through the bearing 2.

In the above embodiment, the servo motor 1 is coaxially and rotationally connected with the connecting rod portion 9, the servo motor 1 drives the connecting rod portion 9 to rotate for providing power, the linear transmission device 7 is used for driving the connecting rod portion 9 or the stratum simulation portion 6, the purpose is to move the connecting rod portion 9 relative to the length direction of the drilled hole of the stratum simulation portion 6, and the combined action of the servo motor 1 and the linear transmission device 7 enables the connecting rod portion 9 to simulate the working state of the drilled hole in the drilled hole so as to test the azimuth gamma in the connecting rod portion 9.

Example 5

Further, referring to fig. 1, another embodiment of the azimuth gamma test platform according to the present invention further includes a slip ring and a lead, wherein a rotation end of the slip ring is connected to the connecting rod portion 9, the slip ring is electrically connected to the azimuth gamma in the middle of the connecting rod portion 9 through the lead, and a static end of the slip ring is electrically connected to the outside.

In the above embodiment, since the azimuth gamma is installed inside the link part 9, and the link part 9 is in a rotating state during operation, in order to acquire the test data of the azimuth gamma inside the link part 9 during rotation, the slip ring is used to transmit the electrical signal to the outside.

Example 6

Further, referring to fig. 1, according to another embodiment of the azimuth gamma test platform of the present invention, a transmission device is further disposed between the servo motor 1 and the connecting rod portion 9, the transmission device includes a frame body, bearings 2 and a transmission mechanism, the frame body is disposed on two sides of the upper end of the base 12, a body of the bearings 2 is fixed on the top of the frame body, the connecting rod portion 9 is rotatably connected to the frame body through the bearings 2, the transmission mechanism is fixed on the frame body, one end of the transmission mechanism is coaxially connected to the connecting rod portion 9 in a transmission manner, and the other end of the transmission mechanism is connected to the servo motor 1 in a transmission manner.

In the above embodiment, the frame body is a supporting structure disposed at the upper end of the base 12 for supporting the connecting rod portion 9, and the connecting rod portion 9 is rotatably connected with respect to the frame body through the bearing 2.

Example 7

Further, referring to fig. 7, in another embodiment of the azimuth gamma test platform of the present invention, a chuck 19 is fixed at a rotation end of the bearing 2, the connecting rod portion 9 includes a left extension rod 23, a measured gamma drill collar 10 for mounting azimuth gamma, and a right extension rod 13, the left extension rod 23 and the right extension rod 13 are detachably connected to two ends of the measured gamma drill collar 10, and end portions of the left extension rod 23 and the right extension rod 13 are respectively connected to the bearing 2 through the chuck 19.

In the above embodiment, the chuck 19 is disposed at the rotating end of the bearing 2, and the connecting rod portion 9 is connected to the bearing 2 through the chuck 19, so that the connecting rod portion 9 can be conveniently detached during use.

Example 8

Further, referring to fig. 1, another embodiment of the azimuth gamma test platform of the present invention further includes a tail locking device 12, the tail locking device 12 is detachably connected to the bearing 2 located at the tail of the connecting rod portion 9, and when the tail locking device 12 is connected to the bearing 2, the tail locking device 12 contacts one side of the end of the connecting rod portion 9.

In the above embodiment, the purpose of the tail locking device 12 is to lock one end of the link portion 9, so that the link portion 9 is more stable during rotation, and further, the link portion 9 may extend into another bearing by passing through one bearing 2 to be installed, and then the link portion 9 is locked by the tail locking device 12, so as to facilitate the installation of the link portion 9.

Example 9

Further, referring to fig. 1, in another embodiment of the azimuth gamma test platform of the present invention, one slide rail of the guide rail 8 is a planar slide rail 16, the other slide rail of the guide rail 8 is a V-shaped slide rail 18, the planar slide rail 16 and the V-shaped slide rail 18 are arranged in parallel, the guide rail 8 is located on top of the planar slide rail 16 and the V-shaped slide rail 18, and the guide rail 8 is connected to the planar slide rail 16 and the V-shaped slide rail 18 in a sliding manner.

In the above embodiment, since the V-shaped slide rail 18 has a radial stabilizing function when the slide block slides, and the azimuth gamma test platform of the present invention requires more stable components for measurement, a slide rail with both stability and bearing property is formed by using a planar slide rail 16 and a V-shaped slide rail 18, so that the present invention is more stable in the test stage and the data is more accurate.

Example 10

Further, referring to fig. 1, in another embodiment of the azimuthal gamma test platform of the present invention, the base 12 is formed by splicing a plurality of frame bodies.

In the above embodiment, the base 12 adopts the splicing structure, so that the expandability is increased, and when the length of the connecting rod portion 9 needs to be increased during the simulation measurement of deeper drilling, the base 12 can be lengthened by increasing the middle part of the base 12 and extending the two ends of the base, without disassembling the two ends of the base 12 and replacing other bases, and the scheme can improve the number of the simulation environments measured by the invention.

Example 11

Further, referring to fig. 1 and 8, the motor driver control cabinet 3 in fig. 1 is mainly responsible for controlling the servo motor, and then the transmission connecting rod portion simulates drilling; the control panel 4 is a control assembly, and is a manual operation cabinet, the control panel 4 can recognize manual operation instructions, the components are in the prior art, and the V-shaped bracket 5 is an auxiliary mechanism of a connecting rod part and used for ensuring the stable operation of the whole machine. The tailstock adjusting screw rod 11 mainly controls the front-back transverse movement of the whole tailstock; the function of the slide 14 is to engage the rail 8 so that the stratigraphic simulation section 6 can slide along the rail 8.

Referring to fig. 1, 4 and 8, in an embodiment, the left and right rails of the guide rail 8 are a planar slide rail 16 and a V-shaped guide rail 17, respectively, the slider 14 is used for being slidably connected with the planar slide rail 16, the slider 14 and one side of the planar slide rail 16 are further connected with a needle bearing 15, the slider 14 and the planar slide rail 16 are used for bearing main weight, and the needle bearing 15 is used for tightly combining the slider 14 and the planar slide rail 16 to prevent the problems of the stratum simulation part 6 such as overturning and lane changing.

The V-shaped guide wheel 17 is used for being in rolling connection with the V-shaped slide rail 18, the V-shaped guide wheel 17 mainly bears the bearing and guiding of the stratum simulating part 6, the V-shaped slide rail 18 mainly bears the bearing and guiding of the stratum simulating part 6, effective flatness and straightness are provided, and friction is reduced.

Referring to fig. 5, the combined action of the cycloidal pin reducer 20, the power output shaft 21 and the absolute value encoder 22 in fig. 5 is the same as the principle of the conventional servo motor, and the combined power is higher than that of the conventional servo motor;

referring to fig. 6, a main gear 26 is engaged with the rack 24, the rotation of the main gear 26 drives the rack 24 to move back and forth, a turbine reducer 25, a secondary turbine reducer 27 and a driving motor 28 cooperate to provide power, and the power is transmitted to the main gear 26;

in fig. 3, the frame 29 is used for supporting the tailstock; the fixed seat 30 and the tailstock adjusting screw 31 are respectively a frame of the tailstock and a component for adjusting the position of the tailstock in the direction of the guide rail 8.

Further, the linear transmission device, the tail locking device, the signal transmission device, the wireless transmission device and the transmission device are all in the prior art.

It should be noted that all the directional indications (such as up, down, left, right, front, and rear … …) in the present embodiment are only used to explain the relative positional relationship between the components, the movement, and the like in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indication is changed accordingly.

In addition, descriptions related to "first", "second", and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature.

Technical solutions between various embodiments may be combined with each other, but must be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention. The components and structures of the present embodiments that are not described in detail are well known in the art and do not constitute essential structural elements or elements.

Claims

1. An azimuth gamma test platform, comprising:

the stratum simulation part (6), the middle part of the stratum simulation part (6) is provided with a drill hole;

the diameter of the connecting rod part (9) is smaller than the inner diameter of the drilled hole, and the middle part of the connecting rod part (9) is used for installing azimuth gamma;

and the transmission system is arranged between the stratum simulation part (6) and the connecting rod part (9), and the connecting rod part (9) is driven by the transmission system to enable the connecting rod part (9) to relatively rotate in a drilling hole of the stratum simulation part (6) and relatively move along the axial direction of the through hole.

2. The azimuth gamma test platform as claimed in claim 1, further comprising a signal transmission device, wherein the signal transmission device is a wireless transmission device, and the wireless transmission device is used for connecting with the outside in a wireless communication manner; or

The signal transmission device is a slip ring, the end of the slip ring is used for being electrically connected with the azimuth gamma in the middle of the connecting rod part (9), and the end of the slip ring is used for being electrically connected with the outside.

3. The azimuth gamma test platform as claimed in claim 1, further comprising a guide rail (8), a bearing (2) and a base (12), wherein the transmission system comprises a servo motor (1) and a linear transmission device (7), the transmission direction of the linear transmission device (7) is the same direction as the guide direction of the guide rail (8), the linear transmission device (7) is in transmission connection with a slide block of the guide rail (8), the stratum simulation part (6) is fixed on the slide block of the guide rail (8), the axial direction of the drill hole is parallel to the guide direction of the guide rail (8), the middle part of the connecting rod part (9) is located in the drill hole, the connecting rod part (9) is coaxial with the drill hole, the servo motor (1) is in coaxial transmission connection with one end of the connecting rod part (9), the servo motor (1), the linear transmission device (7) and the main body of the guide rail (8) are respectively fixed on the base (12), the connecting rod part (9) is rotationally connected with the base (12) through a bearing (2).

4. The orientation gamma test platform as claimed in claim 1, further comprising a bearing (2) and a base (12), wherein the transmission system comprises a servo motor (1) and a linear transmission device (7), the middle part of the connecting rod part (9) is located in the drill hole, the connecting rod part (9) is coaxial with the drill hole, the servo motor (1) is in coaxial transmission connection with one end of the connecting rod part (9), the linear transmission device (7) is used for driving the connecting rod part (9) and the drill hole to move relatively in the axial direction, the main body of the linear transmission device (7) is fixed on the base (12), and the connecting rod part (9) is rotatably connected with the base (12) through the bearing (2).

5. An azimuth gamma test platform as claimed in claim 3 or 4, further comprising a slip ring and a lead wire, wherein the rotating end of the slip ring is connected with the connecting rod part (9), the slip ring is electrically connected with the azimuth gamma in the middle of the connecting rod part (9) through the lead wire, and the static end of the slip ring is electrically connected with the outside.

6. The azimuth gamma test platform as claimed in claim 5, wherein a transmission device is further arranged between the servo motor (1) and the connecting rod part (9), the transmission device comprises a frame body, bearings (2) and a transmission mechanism, the frame body is arranged on two sides of the upper end of the base (12), a body of each bearing (2) is fixed to the top of the frame body, the connecting rod part (9) is rotatably connected with the frame body through the bearing (2), the transmission mechanism is fixed to the frame body, one end of the transmission mechanism is coaxially connected with the connecting rod part (9) in a transmission manner, and the other end of the transmission mechanism is connected with the servo motor (1) in a transmission manner.

7. The azimuth gamma test platform as claimed in claim 6, wherein a chuck (19) is fixed at the rotating end of the bearing (2), the connecting rod part (9) comprises a left extension rod (23), a tested gamma drill collar (10) for installing azimuth gamma and a right extension rod (13), the left extension rod (23) and the right extension rod (13) are detachably connected at two ends of the tested gamma drill collar (10), and the ends of the left extension rod (23) and the right extension rod (13) are respectively connected with the bearing (2) through the chuck (19).

8. The azimuth gamma test platform as claimed in claim 6, further comprising a tail locking device (12), wherein the tail locking device (12) is detachably connected to the bearing (2) at the tail of the link portion (9), and when the tail locking device (12) is connected to the bearing (2), the tail locking device (12) contacts one side of the end of the link portion (9).

9. The orientation gamma test platform of claim 3, wherein one rail of the guide rail (8) is a flat rail (16), the other rail of the guide rail (8) is a V-shaped rail (18), the flat rail (16) and the V-shaped rail (18) are arranged in parallel, the guide rail (8) is located on the top of the flat rail (16) and the V-shaped rail (18), and the guide rail (8) is connected with the flat rail (16) and the V-shaped rail (18) in a sliding manner.

10. An azimuth gamma test platform as claimed in claim 3 or 4 wherein the base (12) is made up of a plurality of shelves.