CN116594082B - Balanced testing arrangement of hyperspectral remote sensing geological survey appearance - Google Patents

Abstract

The invention discloses a balance testing device of a hyperspectral remote sensing geological survey instrument, which relates to the field of balance testing and comprises a first fixed sleeve and a second fixed sleeve, wherein a guide rail installation rod is fixedly arranged between the first fixed sleeve and the second fixed sleeve, and a circulating belt is movably arranged on the inner side of the guide rail installation rod. According to the hyperspectral remote sensing geological survey balance test device, the simulation unmanned aerial vehicle is enabled to drive the geological survey to rapidly move, the movement balance test is conducted more accurately, the test accuracy is improved, the simulation unmanned aerial vehicle is enabled to drive the geological survey to move up and down, the movable jolt influence is simulated, the test effect is improved, the movement tests of different angles are achieved, the test effect is further improved, the real-time adjustment of the angle is conducted when the geological survey is moved, the use of the test is facilitated, the movement of different heights on the simulation unmanned aerial vehicle is simulated, and the balance of the unmanned aerial vehicle is measured more accurately.

Description

Balanced testing arrangement of hyperspectral remote sensing geological survey appearance

Technical Field

The invention relates to the field of balance test, in particular to a balance test device of a hyperspectral remote sensing geological survey instrument.

Background

The utility model provides a hyperspectral remote sensing geological survey appearance balanced testing arrangement is hyperspectral remote sensing geological survey appearance testing arrangement, because hyperspectral remote sensing geological survey appearance is installed when using, generally with unmanned aerial vehicle, adopt unmanned aerial vehicle overhead working's mode to carry out geological survey, therefore the balance when need carrying out the hyperspectral remote sensing geological survey appearance and remove, detect hyperspectral remote sensing geological survey appearance whether satisfy the standard that uses when removing, current hyperspectral remote sensing geological survey appearance balanced testing arrangement is when using, generally carry geological survey appearance through the flatbed that removes, realize the balanced test when removing, but through the mode that the flatbed removed, its travel speed is slow, and remove the precision difference, the precision that has led to the test is lower, and only can carry out single parallel movement, and unmanned aerial vehicle drives hyperspectral survey geological survey appearance overhead working, can produce from top to bottom when removing, and the test that can't carry out the test of jolt, consequently, the effect of test is reduced, the while also can't move the different angles and remove with the high degree of movement of the geological survey appearance, make the accurate balanced test of device.

Disclosure of Invention

The invention mainly aims to provide a balance testing device for a hyperspectral remote sensing geological survey instrument, which can effectively solve the technical problems of the background technology.

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

the utility model provides a hyperspectral remote sensing geological survey appearance balance test device, includes first fixed cover and second fixed cover, fixed mounting has the guide rail installation pole between first fixed cover and the second fixed cover, guide rail installation pole inboard movable mounting has circulation belt, the lower extreme fixed mounting of second fixed cover has driving motor, the inside movable mounting of second fixed cover has the belt pulley, the outside movable mounting of guide rail installation pole has the removal mount pad, the lower extreme movable mounting of removal mount pad has two sets of movable wheels, the upper end movable mounting of removal mount pad has rotatory mounting disc, lower extreme one side movable mounting of rotatory mounting disc has the linking arm, the rear end fixed mounting of linking arm has the slip cap, the upper end fixed mounting of rotatory mounting disc has the flexible bracing piece, the upper end fixed mounting of flexible bracing piece has the test mounting panel, the upper end fixed mounting of test mounting panel has four fixed posts, the upper end screw thread of fixed post installs lifting screw, lifting screw's upper end fixed mounting has the butt joint swivel, one side is kept away from mutually to the upper end of first fixed cover and second fixed cover and is equal fixed mounting have hydraulic support structure, hydraulic support structure's lower extreme fixed mounting has the bottom plate of placing, the rear end fixed mounting of first fixed cover has first alignment jig, the rear end fixed mounting of second fixed cover has the second alignment jig, the inner side slidable mounting of first alignment jig and second alignment jig has the regulation bracing piece, the upper end fixed mounting of regulation bracing piece has the lock sleeve, the inboard fixed mounting of lock sleeve has parallel sliding rod.

As a further scheme of the invention, the output shaft of the driving motor penetrates into the second fixed sleeve and is fixedly connected with the belt pulley, the circulating belt penetrates into the second fixed sleeve and is matched and connected with the belt pulley, the movable mounting seat is positioned in front of and is fixedly connected with the circulating belt, and the two groups of movable wheels are embedded in front of and behind the guide rail mounting rod and are movably connected with the guide rail mounting rod.

As a further scheme of the invention, the lifting screw is screwed into the fixed upright posts, and the four fixed upright posts are arranged in a cross shape around the center of the test mounting plate.

As a further scheme of the invention, lifting motors are fixedly arranged at the upper ends of the rotary mounting plates and positioned at the two sides of the telescopic supporting rods, eccentric wheel discs are fixedly arranged on output shafts of the lifting motors, lifting connecting rods are movably arranged at the outer sides of the eccentric wheel discs, and the upper ends of the lifting connecting rods are movably connected with the test mounting plates.

As a further scheme of the invention, the hydraulic supporting structure comprises a supporting connecting plate, a mounting sliding sleeve, a supporting rotating shaft, a supporting ejector rod, a manual adjusting rod, a hydraulic telescopic rod and a hydraulic cylinder, wherein the two supporting connecting plates are respectively and fixedly arranged at the upper ends of the first fixing sleeve and the second fixing sleeve and far away from one side, the mounting sliding sleeve is sleeved on the outer side of the supporting connecting plate, the supporting rotating shaft is movably arranged on the inner side of the mounting sliding sleeve, the supporting ejector rod is fixedly arranged on the outer side of the supporting rotating shaft, the manual adjusting rod is movably arranged in front of the outer side of the supporting ejector rod, the hydraulic telescopic rod is fixedly arranged at the lower end of the supporting ejector rod, and the hydraulic cylinder is movably arranged at the lower end of the hydraulic telescopic rod.

As a further scheme of the invention, the mounting sliding sleeve slides left and right around the support connecting plate, the support rotating shaft rotates around the mounting sliding sleeve, and the lower end of the hydraulic telescopic rod is inserted into the hydraulic cylinder to perform telescopic movement.

As a further scheme of the invention, the placing bottom plate is fixedly arranged at the lower end of the hydraulic cylinder, the outer side of the placing bottom plate at one side is fixedly provided with the hydraulic control box, the butt joint rod is fixedly arranged between the hydraulic control box and the placing bottom plate at the other side, and the hydraulic pipeline is fixedly arranged between the hydraulic control box and the two hydraulic cylinders.

As a further scheme of the invention, the lower end of the first fixing sleeve is fixedly provided with the air cylinder mounting frame, the inner side of the air cylinder mounting frame is fixedly provided with the driving air cylinder, the rear end of the driving air cylinder is movably provided with the air cylinder telescopic rod, and the rear end of the air cylinder telescopic rod is fixedly provided with the pushing sleeve.

As a further scheme of the invention, the driving air cylinder and the air cylinder telescopic rod are positioned below the first adjusting frame, the pushing sleeve is sleeved on the outer side of the adjusting supporting rod and fixedly connected with the adjusting supporting rod, the sliding sleeve is sleeved on the outer side of the parallel sliding rod and is in sliding connection with the parallel sliding rod, and the parallel sliding rod is arranged between the two locking sleeves.

Compared with the prior art, the invention has the following beneficial effects: the movable mounting seat is driven to move left and right on the outer side of the guide rail mounting rod through the circulating belt, so that the geological survey instrument above is driven to move left and right rapidly, the effect that the simulation unmanned aerial vehicle drives the geological survey instrument to move rapidly is achieved, the movement balance test is carried out more accurately, and the test accuracy is improved;

the test mounting plate is lifted up and down, the lifting motor is used for driving the test mounting plate to lift up and down continuously at the upper end of the telescopic support rod through the lifting connecting rod, so that the simulation unmanned aerial vehicle can lift up and down when driving the geological survey instrument to move, the movable jolt effect is simulated, and the test effect is improved;

through the sliding of the sliding sleeve around the parallel sliding rod, the sliding sleeve slides around the parallel sliding rod when the movable mounting seat moves left and right, and the movable mounting seat is matched with the angle inclination of the parallel sliding rod, so that the overhead geological survey instrument generates different angles when moving, the moving angle of the movable balance test is increased, the mounting angle of the parallel sliding rod can be adjusted through the front-back movement of the locking sleeve and the adjusting support rod, the movable test simulating different angles is realized, and the testing effect is further increased;

through synchronous driving of the driving air cylinders, when the movable mounting seat moves, the driving air cylinders are utilized to drive the telescopic jacking adjusting support rods of the air cylinders and the pushing sleeve and the locking sleeve to move forwards and backwards, so that the parallel sliding rods can adjust angles, and the angles can be adjusted in real time when the geological survey instrument moves for testing, so that the geological survey instrument is more convenient to use for testing;

through hydraulic support structure's multi-angle support, utilize the pneumatic cylinder with hydraulic telescoping rod jack-up or decline, come to jack-up first fixed cover and the fixed cover of second rise or descend, and then adjust the left and right angles of guide rail installation pole to when removing the mount pad and controlling the removal, make the removal test of geological survey appearance different angles, simulate the removal of not co-altitude on the unmanned aerial vehicle, more accurate measurement geological survey appearance equilibrium.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a balance testing device of a hyperspectral remote sensing geological survey according to the present invention;

FIG. 2 is a rear view of a balance testing device of the hyperspectral remote sensing geological survey according to the present invention;

FIG. 3 is a bottom view of a mobile mount in a hyperspectral telemetry device balance testing apparatus in accordance with the present invention;

FIG. 4 is a schematic diagram of a test mounting plate in a balance test apparatus for a hyperspectral remote sensing geological survey according to the present invention;

FIG. 5 is an enlarged view of a hydraulic support structure in a balance testing device of a hyperspectral remote sensing geological survey according to the present invention;

FIG. 6 is an enlarged view of a first tuning frame of a balance testing device of a hyperspectral remote sensing geological survey according to the present invention;

FIG. 7 is a schematic diagram of a second stationary sleeve of a balance testing device for a hyperspectral remote sensing geological survey according to the present invention.

In the figure: 1. a first fixing sleeve; 2. a second fixing sleeve; 3. a guide rail mounting bar; 4. a circulating belt; 5. a driving motor; 6. a belt pulley; 7. moving the mounting base; 8. a moving wheel; 9. rotating the mounting plate; 10. a connecting arm; 11. a sliding sleeve; 12. a telescopic support rod; 13. a test mounting plate; 14. fixing the upright post; 15. lifting screw rods; 16. butt joint rotary head; 17. a lifting motor; 18. an eccentric wheel disc; 19. lifting the connecting rod; 20. a hydraulic support structure; 21. a support connection plate; 22. installing a sliding sleeve; 23. supporting a rotating shaft; 24. supporting the ejector rod; 25. a manual adjusting lever; 26. a hydraulic telescopic rod; 27. a hydraulic cylinder; 28. a hydraulic conduit; 29. placing a bottom plate; 30. a hydraulic control box; 31. a butt joint rod; 32. a first adjusting frame; 33. a second adjusting frame; 34. adjusting the supporting rod; 35. locking the sleeve; 36. parallel sliding rods; 37. a cylinder mounting rack; 38. a driving cylinder; 39. a cylinder telescopic rod; 40. pushing the sleeve.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1-7, a balancing test device for a hyperspectral remote sensing geological survey instrument comprises a first fixed sleeve 1 and a second fixed sleeve 2, wherein a guide rail mounting rod 3 is fixedly mounted between the first fixed sleeve 1 and the second fixed sleeve 2, a circulating belt 4 is movably mounted on the inner side of the guide rail mounting rod 3, a driving motor 5 is fixedly mounted on the lower end of the second fixed sleeve 2, a belt pulley 6 is movably mounted in the second fixed sleeve 2, a movable mounting seat 7 is movably mounted on the outer side of the guide rail mounting rod 3, two groups of movable wheels 8 are movably mounted on the lower end of the movable mounting seat 7, a rotary mounting disc 9 is movably mounted on the upper end of the movable mounting seat 7, a connecting arm 10 is movably mounted on one side of the lower end of the rotary mounting disc 9, a sliding sleeve 11 is fixedly mounted on the rear end of the connecting arm 10, four fixed uprights 14 are fixedly mounted on the upper end of the telescopic supporting rod 12, a lifting screw 15 is mounted on the upper end of the lifting screw 15, a rotary joint 16 is fixedly mounted on the upper end of the testing mounting plate 13, a second fixed upright post 14 is fixedly mounted on the upper end of the second fixed sleeve 20, a second fixed support rod 33 is fixedly mounted on the inner side of the second fixed support frame 20, a hydraulic support rod 33 is fixedly mounted on the upper end of the second fixed support frame 20 is fixedly mounted on the second fixed on the second side of the second fixed support frame 20, and is fixedly mounted on the second fixed support frame 33 is fixedly mounted on the second side of the second fixed support frame 20, and is fixed on the second fixed support frame 33 is fixed and far from the upper end of the second fixed support frame 20.

In this embodiment, the output shaft of the driving motor 5 penetrates into the second fixed sleeve 2 and is fixedly connected with the belt pulley 6, the circulating belt 4 penetrates into the second fixed sleeve 2 and is connected with the belt pulley 6 in a matched manner, the movable mounting seat 7 is positioned in front of the circulating belt 4 and is fixedly connected with the circulating belt 4, the two groups of movable wheels 8 are embedded in front of and behind the guide rail mounting rod 3 and are movably connected with the guide rail mounting rod, and the circulating belt 4 is driven to move circularly inside the guide rail mounting rod 3 by the operation of the driving motor 5.

In this embodiment, the lifting screw 15 is screwed into the fixed upright posts 14, the four fixed upright posts 14 are arranged in a cross shape around the center of the test mounting plate 13, and the lifting screw 15 is used for adjusting the height of the butt joint rotary head 16 through threaded lifting.

In this embodiment, the upper end of the rotary mounting plate 9 is located at two sides of the telescopic supporting rod 12 and is fixedly provided with a lifting motor 17, an output shaft of the lifting motor 17 is fixedly provided with an eccentric wheel disc 18, the outer side of the eccentric wheel disc 18 is movably provided with a lifting connecting rod 19, the upper end of the lifting connecting rod 19 is movably connected with the test mounting plate 13, and the lifting motor 17 drives the lifting connecting rod 19 to move up and down by driving the eccentric wheel disc 18 to rotate and then finally drives the test mounting plate 13 to move up and down.

In this embodiment, the hydraulic support structure 20 includes a support connection plate 21, a mounting sliding sleeve 22, a support rotating shaft 23, a support push rod 24, a manual adjustment rod 25, a hydraulic telescopic rod 26 and a hydraulic cylinder 27, where the two support connection plates 21 are respectively and fixedly installed on the upper ends of the first and second fixed sleeves 1 and 2 and far away from each other, the mounting sliding sleeve 22 is sleeved on the outer side of the support connection plate 21, the support rotating shaft 23 is movably installed on the inner side of the mounting sliding sleeve 22, the support push rod 24 is fixedly installed on the outer side of the support rotating shaft 23, the manual adjustment rod 25 is movably installed on the front of the outer side of the support push rod 24, the hydraulic telescopic rod 26 is fixedly installed on the lower end of the support push rod 24, the hydraulic cylinder 27 is movably installed on the lower end of the hydraulic telescopic rod 26, and the hydraulic support structure 20 plays a role in supporting the first and second fixed sleeves 1 and 2.

In this embodiment, the installation sliding sleeve 22 slides left and right around the support connection plate 21, the support rotating shaft 23 rotates around the installation sliding sleeve 22, the lower end of the hydraulic telescopic rod 26 is inserted into the hydraulic cylinder 27 to perform telescopic movement, and the hydraulic cylinder 27 drives the hydraulic telescopic rod 26 to perform lifting movement.

In this embodiment, the placement base plate 29 is fixedly installed at the lower end of the hydraulic cylinder 27, the outer side of the placement base plate 29 on one side is fixedly installed with the hydraulic control box 30, the docking rod 31 is fixedly installed between the hydraulic control box 30 and the placement base plate 29 on the other side, the hydraulic pipeline 28 is fixedly installed between the hydraulic control box 30 and the two hydraulic cylinders 27, and the hydraulic control box 30 plays a role in hydraulic control.

In this embodiment, the lower end of the first fixing sleeve 1 is fixedly provided with a cylinder mounting frame 37, the inner side of the cylinder mounting frame 37 is fixedly provided with a driving cylinder 38, the rear end of the driving cylinder 38 is movably provided with a cylinder telescopic rod 39, the rear end of the cylinder telescopic rod 39 is fixedly provided with a pushing sleeve 40, and the driving cylinder 38 is used for driving the cylinder telescopic rod 39 to move in a telescopic manner.

In this embodiment, the driving cylinder 38 and the cylinder telescopic rod 39 are located below the first adjusting bracket 32, the pushing sleeve 40 is sleeved on the outer side of the adjusting supporting rod 34 and is fixedly connected with the same, the sliding sleeve 11 is sleeved on the outer side of the parallel sliding rod 36 and is slidably connected with the same, the parallel sliding rod 36 is installed between the two locking sleeves 35, and the driving cylinder 38 can drive the adjusting supporting rod 34 to move back and forth through the cylinder telescopic rod 39 during operation.

It should be noted that, the invention is a hyperspectral remote sensing geological survey instrument balance testing device, when in use, the geological survey instrument is installed on four butt joint rotary heads 16, and the rotation of the butt joint rotary heads 16 drives the lifting screw 15 and the fixed upright column 14 to lift and balance and adjust, so as to simulate the installation of the geological survey instrument and an unmanned aerial vehicle, after the installation, the geological survey instrument drives the belt pulley 6 to rotate by utilizing the operation of the driving motor 5, the belt pulley 6 drives the circulating belt 4 to move on the inner side of the guide rail installation rod 3, so that the circulating belt 4 drives the movable installation seat 7 to move left and right on the outer side of the guide rail installation rod 3, and meanwhile, the movable installation seat 7 moves left and right on the outer side of the guide rail installation rod 3, so as to drive the geological survey instrument above to move left and right quickly, so as to simulate the unmanned aerial vehicle to drive the geological survey instrument to move quickly, and after the movement is finished, the working data and structural integrity of the geological survey instrument are checked, and whether balance requirements are met is evaluated, so as to complete the balance test;

when the movable mounting seat 7 moves left and right through the up-and-down lifting of the test mounting plate 13, the eccentric wheel disc 18 is driven to rotate by the operation of the lifting motor 17, and the eccentric wheel disc 18 drives the lifting connecting rod 19 to rotate up and down for circular movement, so that the test mounting plate 13 is driven to continuously lift and move at the upper end of the telescopic supporting rod 12 through the lifting connecting rod 19, and the simulated unmanned aerial vehicle drives the geological survey instrument to move in a lifting manner;

through the sliding of the sliding sleeve 11 around the parallel sliding rod 36, the sliding sleeve 11 is driven to slide around the parallel sliding rod 36 by the connecting arm 10 when the movable mounting seat 7 moves left and right, and the angle of the parallel sliding rod 36 is different from that of the guide rail mounting rod 3, so that the connecting arm 10 pushes the rotary mounting disc 9 to rotate at different left and right positions, further, different angles are generated when the upper geological survey instrument moves, the locking sleeve 35 fixed on the parallel sliding rod 36 can also move back and forth in the first adjusting frame 32 and the second adjusting frame 33 through the adjusting support rod 34, so as to adjust the mounting angle of the parallel sliding rod 36, and simultaneously, the driving cylinder 38 can also be used for driving the telescopic cylinder 39 to stretch, so that the pushing sleeve 40 pushes the adjusting support rod 34 and the locking sleeve 35 in the first adjusting frame 32 to move back and forth, so as to adjust the angle of the parallel sliding rod 36 in real time when the movable mounting seat 7 moves left and right;

through the multi-angle support of the hydraulic support structure 20, the hydraulic cylinders 27 and the hydraulic telescopic rods 26 on two sides play a role in supporting the first fixed sleeve 1 and the second fixed sleeve 2, hydraulic control boxes 30 are utilized to convey and discharge hydraulic pressure to the hydraulic cylinders 27 through hydraulic pipelines 28, the hydraulic cylinders 27 jack up or lower the hydraulic telescopic rods 26, then the first fixed sleeve 1 and the second fixed sleeve 2 are jacked up or lowered through the rotary movement of the support rotary shafts 23 on the support jacking rods 24 in the installation sliding sleeves 22, the installation sliding sleeves 22 can move left and right around the support connecting plates 21 at the same time, the left and right movement amount is counteracted, and then the left and right angles of the guide rail installation rods 3 are adjusted, so that when the movable installation seat 7 moves left and right, the geological survey instrument can be subjected to movement tests of different angles.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. A hyperspectral remote sensing geological survey appearance balance test device, its characterized in that: including first fixed cover (1) and second fixed cover (2), fixed mounting has guide rail installation pole (3) between first fixed cover (1) and the second fixed cover (2), guide rail installation pole (3) inboard movable mounting has circulation belt (4), the lower extreme fixed mounting of second fixed cover (2) has driving motor (5), the inside movable mounting of second fixed cover (2) has belt pulley (6), the outside sliding of guide rail installation pole (3) has movable mount pad (7), the lower extreme movable mounting of movable mount pad (7) has two sets of movable wheels (8), the upper end movable mounting of movable mount pad (7) has rotary mounting dish (9), lower extreme one side movable mounting of rotary mounting dish (9) has linking arm (10), the rear end fixed mounting of linking arm (10) has sliding sleeve (11), the upper end fixed mounting of rotary mounting dish (9) has flexible bracing piece (12), the upper end fixed mounting of flexible bracing piece (12) has test mounting plate (13), the lower extreme movable mounting of movable mounting has two sets of movable wheels (8), the upper end movable mounting of movable mounting arm (10) has screw rod (15) fixed mounting of screw rod (15), the hydraulic support structure (20) is fixedly installed on the upper ends of the first fixing sleeve (1) and the second fixing sleeve (2) far away from each other, the lower end of the hydraulic support structure (20) is fixedly provided with the placing bottom plate (29), the rear end of the first fixing sleeve (1) is fixedly provided with the first adjusting frame (32), the rear end of the second fixing sleeve (2) is fixedly provided with the second adjusting frame (33), the inner sliding of the first adjusting frame (32) and the second adjusting frame (33) is provided with the adjusting support rod (34), the upper end of the adjusting support rod (34) is fixedly provided with the locking sleeve (35), and the inner side of the locking sleeve (35) is fixedly provided with the parallel sliding rod (36).

2. The balance testing device of a hyperspectral remote sensing geological survey according to claim 1, wherein: the output shaft of driving motor (5) runs through to the inside of second fixed cover (2) and with belt pulley (6) fixed connection, circulation belt (4) penetrate in to second fixed cover (2) with belt pulley (6) cooperation connection, remove mount pad (7) and be located the place ahead of circulation belt (4) and rather than fixed connection, two sets of removal wheels (8) imbeds to the place ahead and the rear of guide rail installation pole (3) and rather than swing joint.

3. The balance testing device of a hyperspectral remote sensing geological survey according to claim 1, wherein: the lifting screw rods (15) are screwed into the fixed upright posts (14), and the four fixed upright posts (14) are arranged in a cross shape around the center of the test mounting plate (13).

4. The balance testing device of a hyperspectral remote sensing geological survey according to claim 1, wherein: lifting motors (17) are fixedly mounted on the upper ends of the rotary mounting plates (9) located on the two sides of the telescopic supporting rods (12), eccentric wheel discs (18) are fixedly mounted on output shafts of the lifting motors (17), lifting connecting rods (19) are movably mounted on the outer sides of the eccentric wheel discs (18), and the upper ends of the lifting connecting rods (19) are movably connected with the test mounting plates (13).

5. The balance testing device of a hyperspectral remote sensing geological survey according to claim 1, wherein: the hydraulic support structure (20) comprises a support connecting plate (21), a mounting sliding sleeve (22), a support rotating shaft (23), a support ejector rod (24), a manual adjusting rod (25), a hydraulic telescopic rod (26) and a hydraulic cylinder (27), wherein the two support connecting plates (21) are respectively fixedly arranged at the upper ends of the first fixing sleeve (1) and the second fixing sleeve (2) and away from one side, the mounting sliding sleeve (22) is sleeved on the outer side of the support connecting plate (21), the support rotating shaft (23) is movably arranged on the inner side of the mounting sliding sleeve (22), the support ejector rod (24) is fixedly arranged on the outer side of the support rotating shaft (23), the manual adjusting rod (25) is movably arranged in front of the outer side of the support ejector rod (24), the hydraulic telescopic rod (26) is fixedly arranged at the lower end of the support ejector rod (24), and the hydraulic cylinder (27) is movably arranged at the lower end of the hydraulic telescopic rod (26).

6. The balance testing device of the hyperspectral remote sensing geological survey according to claim 5, wherein: the installation sliding sleeve (22) slides left and right around the support connecting plate (21), the support rotating shaft (23) rotates around the installation sliding sleeve (22), and the lower end of the hydraulic telescopic rod (26) is inserted into the hydraulic cylinder (27) to stretch and retract.

7. The balance testing device of the hyperspectral remote sensing geological survey according to claim 5, wherein: the hydraulic control device is characterized in that the placing bottom plate (29) is fixedly arranged at the lower end of the hydraulic cylinder (27), a hydraulic control box (30) is fixedly arranged on the outer side of the one side placing bottom plate (29), a docking rod (31) is fixedly arranged between the hydraulic control box (30) and the other side placing bottom plate (29), and a hydraulic pipeline (28) is fixedly arranged between the hydraulic control box (30) and the two hydraulic cylinders (27).

8. The balance testing device of a hyperspectral remote sensing geological survey according to claim 1, wherein: the lower extreme fixed bolster (1) is fixed with cylinder mounting bracket (37), and the inboard fixed mounting of cylinder mounting bracket (37) has drive cylinder (38), and the rear end movable mounting of drive cylinder (38) has cylinder telescopic link (39), and the rear end fixed mounting of cylinder telescopic link (39) has promotion cover (40).

9. The balance testing device of the hyperspectral remote sensing geological survey according to claim 8, wherein: the driving cylinder (38) and the cylinder telescopic rod (39) are positioned below the first adjusting frame (32), the pushing sleeve (40) is sleeved on the outer side of the adjusting supporting rod (34) and fixedly connected with the adjusting supporting rod, the sliding sleeve (11) is sleeved on the outer side of the parallel sliding rod (36) and is in sliding connection with the parallel sliding rod, and the parallel sliding rod (36) is arranged between the two locking sleeves (35).