CN112665737A

CN112665737A - Photoelectron collision testing machine

Info

Publication number: CN112665737A
Application number: CN202011534836.1A
Authority: CN
Inventors: 范聪洁
Original assignee: Individual
Current assignee: Jiangsu Xiyi High Tech Materials Industry Technology Research Institute Co ltd
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-04-16
Anticipated expiration: 2040-12-22
Also published as: CN112665737B

Abstract

The invention discloses a photoelectron collision testing machine which comprises a collision testing device, a camera upwards moving device, a camera rotating device and a camera fine-adjustment device, wherein the camera upwards moving device inputs positive and negative electrons through other material input pipelines on the collision testing device to perform collision tests on the photons after the photoelectrons enter the middle of the interior of the device through a photon input pipeline on the collision testing device, meanwhile, the camera upwards moving device drives a high-speed camera to upwards move in an arc shape, a mechanical group in the camera rotating device operates to drive the high-speed camera to perform 360-degree rotary camera shooting so as to achieve full-range displacement camera shooting recording, and a mechanical group in the camera fine-adjustment device operates to focus the collided photoelectrons and other materials so as to ensure the definition of the camera.

Description

Photoelectron collision testing machine

Technical Field

The invention relates to the field of photoelectrons, in particular to a photoelectron impact testing machine.

Background

With the development and wide application of the photoelectronic technology, the photoelectronic industry has entered into many fields and has a very important position, which makes it a non-negligible high-tech industry, while the existing photoelectronic field has a very large development space, however, the research and development and test mode has obvious disadvantages, and in order to solve the problem, a photoelectronic collision test machine is especially disclosed.

Disclosure of Invention

A photoelectron collision test machine for the above technical problem comprises a collision test device, a camera shooting upward moving device, a camera shooting rotating device and a camera shooting fine adjustment device.

The collision test device comprises a photon input pipeline, a movable rack and a glass upper cover. The camera shooting upward moving device comprises a middle left driven straight gear, a middle right driven straight gear and a sliding block. The camera shooting rotating device comprises a connecting plate. The camera fine adjustment device comprises a rotating device connecting plate and a rotating driven helical gear.

Photon input pipeline fixed mounting is on the test bench, it carries out fixed connection with photon input pipeline to remove the rack, glass upper shield fixed mounting is on the test bench medium plate, the driven straight-teeth gear in centre left side rotates the left that is located the driven straight-teeth gear in centre right side on installing the middle driven shaft, the driven straight-teeth gear in right side rotates and installs on the driven shaft in right side, the driven straight-teeth gear in centre left side and the driven straight-teeth gear in right side form gear engagement with the removal rack, slider fixed mounting is on the middle right side surface of transmission storehouse board, the slider forms sliding fit with the removal rack, the connecting plate carries out fixed connection with the side surface of transmission storehouse board, rotary device connecting plate fixed mounting is on the glass upper shield, rotatory driven helical gear rotates and installs on the rotary device connecting plate, rotatory driven helical.

The collision test device further comprises a test bed bottom plate, a test bed connecting plate, a test bed middle plate, a test bed and other material input pipelines, the test bed middle plate is fixedly connected with the test bed bottom plate through the test bed connecting plate, the test bed is fixedly installed on the upper surface of the middle of the test bed bottom plate, and the other material input pipelines are fixedly connected with the side surfaces of the test bed.

The camera shooting upward moving device also comprises a transmission cabin plate, a motor fixing plate, a motor, a driving bevel gear, a driven worm, a worm connecting bevel gear, a turbine driven shaft, a driven turbine, an upper driven belt pulley, a lower belt pulley driven shaft, a lower driven belt pulley, a driven belt, a driven bevel gear, a left driven shaft, a left driven bevel gear, a left driven spur gear, a middle driven shaft, a middle right driven spur gear and a right driven shaft, wherein the motor fixing plate is fixedly arranged on the upper surface of the inner side of the transmission cabin plate, the motor is fixedly arranged on the motor fixing plate, the driving bevel gear is rotatably arranged on the motor, the driven worm is rotatably arranged in an upper shaft hole and a lower shaft hole in the middle of the transmission cabin plate, the worm connecting bevel gear is rotatably arranged on the driven worm, the worm connecting bevel gear is meshed, the driven worm wheel is rotatably arranged on the worm connecting helical gear, the driven worm wheel is in gear engagement with the driven worm, the upper driven belt pulley is rotatably arranged on the turbine driven shaft and positioned at the right side of the driven worm wheel, the lower belt pulley driven shaft is rotatably arranged in a shaft hole below the right side of the transmission chamber plate, the lower driven belt pulley is rotatably arranged on the lower belt pulley driven shaft, the driven helical gear is rotatably arranged on the lower belt pulley driven shaft and positioned at the left side of the lower driven belt pulley, the left driven shaft is rotatably arranged in a shaft hole at the left side of the transmission chamber plate, the left driven helical gear is rotatably arranged on the left driven shaft, the left driven spur gear is rotatably arranged on the left driven shaft and positioned at the right side of the left driven helical gear, the middle driven shaft is rotatably arranged in a middle shaft hole of the transmission chamber plate, the middle right, the right driven shaft is rotatably arranged in a right shaft hole of the transmission cabin plate.

The camera rotating device also comprises a connecting plate, a servo motor, a driving straight gear, an intermediate driven connecting rod, an intermediate driven straight gear, an intermediate driven helical gear, a camera connecting plate, a left driven helical gear and a high-speed camera, wherein the servo motor is fixedly arranged on the lower side surface of the connecting plate, the driving straight gear is rotatably arranged on the servo motor, the intermediate driven connecting rod is rotatably arranged in a left side shaft hole of the connecting plate, the intermediate driven straight gear is rotatably arranged on the intermediate driven connecting rod, the intermediate driven straight gear and the driving straight gear form gear engagement, the intermediate driven helical gear is rotatably arranged on the intermediate driven connecting rod and is positioned above the intermediate driven straight gear, the camera connecting plate is fixedly connected with the upper left side surface of the connecting plate, the left driven helical gear is rotatably arranged at one end of a right side shaft of the camera connecting plate, the high-speed camera is fixedly arranged on the camera connecting plate.

The camera fine adjustment device also comprises a rotary motor fixing plate, a rotary motor, a right driving bevel gear, a right driven shaft, a right driven bevel gear, a right driven spur gear, an intermediate driven connecting shaft, an intermediate lower driven spur gear, a left driven shaft, a left driven spur gear, a driven pulley, a left belt pulley driven shaft, a left driven belt pulley, a belt, a lower driven bevel gear, a lower driven shaft, a lower right driven bevel gear and a lower left driven bevel gear, wherein the rotary motor fixing plate is fixedly arranged on the right side of the lower surface of the rotary driven bevel gear, the rotary motor is fixedly arranged on the rotary motor fixing plate, the right driving bevel gear is rotatably arranged on the rotary motor, the right driven shaft is rotatably arranged in a right shaft hole of the rotary driven bevel gear, the right driven bevel gear is rotatably arranged on the camera fine adjustment, the right driven spur gear is rotatably installed on a right driven shaft, the middle driven connecting shaft is rotatably installed in a middle shaft hole of the rotary driven helical gear, the middle lower driven spur gear is rotatably installed on the middle driven connecting shaft, the middle lower driven spur gear and the right driven spur gear form gear engagement, the left driven shaft is rotatably installed in a left shaft hole of the rotary driven helical gear, the left driven spur gear is rotatably installed on the left driven shaft, the driven pulley is rotatably installed on the left driven shaft below the left driven spur gear, the left pulley driven shaft is rotatably installed on the rotary driven helical gear on the left side of the left driven shaft, the left driven pulley is rotatably installed on the left pulley driven shaft, the belt is in belt transmission fit with the left driven pulley and the driven pulley, the lower driven helical gear is rotatably installed on the left pulley driven shaft below the left driven pulley, the lower side driven shaft is rotatably installed in a shaft hole of a lower surface supporting plate of the rotary driven helical gear, the lower side right driven helical gear is rotatably installed on the lower side driven shaft, the lower side right driven helical gear and the lower side driven helical gear form gear engagement, the lower side left driven helical gear is rotatably installed on the lower side driven shaft on the left side of the lower side right driven helical gear, and the lower side left driven helical gear and the rotary driven helical gear form gear engagement.

Further, the driven belt forms a belt drive fit with the lower driven pulley and the upper driven pulley.

Further, the left driven helical gear and the driven helical gear form gear engagement.

Furthermore, the left driven spur gear and the middle lower driven spur gear form gear meshing.

Compared with the prior art, the invention has the beneficial effects that: (1) the invention can automatically move the high-speed camera upwards in an arc shape, and has high speed and stability. (2) The invention can automatically rotate the high-speed camera around the test bed and can record the collision test in all directions. (3) The invention can automatically focus the collision test so as to ensure the clarity of the camera shooting.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

FIG. 2 is a schematic structural diagram of a crash test apparatus according to the present invention.

Fig. 3 is a schematic structural diagram of the camera-shooting upward-moving device of the present invention.

Fig. 4 is a schematic view of the internal assembly structure of the camera upward-moving device of the present invention.

Fig. 5 is a schematic view of the internal assembly of the camera rotating device of the present invention.

Fig. 6 is a schematic view of an internal assembly structure of the fine adjustment device for camera shooting according to the present invention.

Fig. 7 is a schematic structural diagram of the camera fine adjustment device according to the present invention.

Reference numerals: 1-a crash test apparatus; 2-camera moving up device; 3-a camera rotation device; 4-camera fine adjustment device; 101-a test bed base plate; 102-a test bed connection plate; 103-test bed middle plate; 104-test stand; 105-other material input conduit; 106-photon input conduit; 107-moving the rack; 108-a glass upper cover; 201-a transmission cabin plate; 202-motor fixing plate; 203-a motor; 204-driving bevel gear; 205-a follower worm; 206-worm connected bevel gear; 207-turbine driven shaft; 208-a driven turbine; 209-an upper driven pulley; 210-lower pulley driven shaft; 211-lower driven pulley; 212-a driven belt; 213-driven bevel gear; 214-left driven shaft; 215-left driven bevel gear; 216-left driven spur gear; 217-intermediate driven shaft; 218-a middle right driven spur gear; 219-middle left driven spur gear; 220-right driven shaft; 221-right driven spur gear; 222-a slider; 301-connecting plate; 302-a servo motor; 303-a spur gear; 304-intermediate driven connecting rod; 305-intermediate driven spur gear; 306-intermediate driven bevel gear; 307-camera connection board; 308-left driven bevel gear; 309-high speed camera; 401-rotating means connection plate; 402-rotating the driven bevel gear; 403-rotating machine fixing plate; 404-a rotating electrical machine; 405-right drive bevel gear; 406-right driven shaft; 407-right driven bevel gear; 408-right driven spur gear; 409-middle driven connecting shaft; 410-middle lower driven spur gear; 411-left driven shaft; 412-left driven spur gear; 413-a driven pulley; 414-left pulley driven shaft; 415-left driven pulley; 416-a belt; 417-lower driven bevel gear; 418-lower driven shaft; 419-lower right driven bevel gear; 420-lower left driven helical gear.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

As shown in fig. 1, 2, 3, 4, 5, 6, and 7, the optoelectronic impact tester includes an impact tester 1, an image-pickup upward-moving device 2, an image-pickup rotating device 3, and an image-pickup fine-adjustment device 4.

The collision test device 1 comprises a photon input pipeline 106, a movable rack 107 and an upper glass cover 108. The camera upward-moving device 2 comprises a middle left driven spur gear 219, a right driven spur gear 221 and a slider 222. The imaging rotation device 3 includes a connection plate 301. The fine imaging adjustment device 4 includes a rotation device connection plate 401 and a rotation driven helical gear 402.

The photon input pipeline 106 is fixedly installed on the test bed 104, the movable rack 107 is fixedly connected with the photon input pipeline 106, the glass upper cover 108 is fixedly installed on the middle plate 103 of the test bed, the middle left driven spur gear 219 is rotatably installed on the middle driven shaft 217 and is positioned on the left side of the middle right driven spur gear 218, the right driven spur gear 221 is rotatably installed on the right driven shaft 220, the middle left driven spur gear 219 and the right driven spur gear 221 form gear engagement with the movable rack 107, the sliding block 222 is fixedly installed on the middle right side surface of the transmission cabin plate 201, the sliding block 222 forms sliding fit with the movable rack 107, the connecting plate 301 is fixedly connected with the side surface of the transmission cabin plate 201, the rotating device connecting plate 401 is fixedly installed on the glass upper cover 108, the rotating driven helical gear 402 is rotatably installed on the rotating device connecting plate 401, and the rotating driven helical gear 402 is fixedly connected with the end portion of.

The collision test device 1 further comprises a test bed bottom plate 101, a test bed connecting plate 102, a test bed middle plate 103, a test bed 104 and other substance input pipelines 105, wherein the test bed middle plate 103 is fixedly connected with the test bed bottom plate 101 through the test bed connecting plate 102, the test bed 104 is fixedly installed on the upper surface of the middle of the test bed bottom plate 101, and the other substance input pipelines 105 are fixedly connected with the side surfaces of the test bed 104.

The camera upward-moving device 2 further comprises a transmission cabin plate 201, a motor fixing plate 202, a motor 203, a driving bevel gear 204, a driven worm 205, a worm connecting bevel gear 206, a turbine driven shaft 207, a driven turbine 208, an upper driven pulley 209, a lower pulley driven shaft 210, a lower driven pulley 211, a driven belt 212, a driven bevel gear 213, a left driven shaft 214, a left driven bevel gear 215, a left driven spur gear 216, a middle driven shaft 217, a middle right driven spur gear 218 and a right driven shaft 220, wherein the motor fixing plate 202 is fixedly arranged on the upper surface of the inner side of the transmission cabin plate 201, the motor 203 is fixedly arranged on the motor fixing plate 202, the driving bevel gear 204 is rotatably arranged on the motor 203, the motor 203 is a power source and drives the driving bevel gear 204 to rotate when the motor 203 rotates, the driven worm 205 is rotatably arranged in two shaft holes at the upper part and the lower part of the middle of the, the worm connecting helical gear 206 forms gear engagement with the driving helical gear 204, when the driving helical gear 204 rotates, the worm connecting helical gear 206 and a driven worm 205 fixedly connected with the worm connecting helical gear are driven to synchronously rotate, the turbine driven shaft 207 is rotatably installed in a shaft hole at the upper right side of the transmission chamber plate 201, the driven turbine 208 is rotatably installed on the worm connecting helical gear 206, the driven turbine 208 and the driven worm 205 form gear engagement, the upper driven pulley 209 is rotatably installed on the turbine driven shaft 207 and positioned at the right side of the driven turbine 208, when the driven worm 205 rotates, the driven turbine 208 and an upper driven pulley 209 synchronously connected with the driven turbine are driven to rotate, the lower pulley driven shaft 210 is rotatably installed in a shaft hole at the lower right side of the transmission chamber plate 201, the lower driven pulley 211 is rotatably installed on the lower pulley driven shaft 210, the driven helical gear 213 is rotatably installed on the lower pulley driven shaft 210 and positioned, when the upper driven pulley 209 rotates, the lower driven pulley 211 and a driven bevel gear 213 synchronously connected with the lower driven pulley are driven by a driven belt 212 to synchronously rotate, a left driven shaft 214 is rotatably arranged in a left shaft hole of the transmission chamber plate 201, a left driven bevel gear 215 is rotatably arranged on the left driven shaft 214, a left driven spur gear 216 is rotatably arranged on the left driven shaft 214 and is positioned at the right side of the left driven bevel gear 215, when the driven bevel gear 213 rotates, the left driven bevel gear 215 and a left driven spur gear 216 synchronously connected with the left driven bevel gear are driven to synchronously rotate, an intermediate driven shaft 217 is rotatably arranged in a middle shaft hole of the transmission chamber plate 201, an intermediate right driven spur gear 218 is rotatably arranged on an intermediate driven shaft 217, the intermediate right driven spur gear 218 forms gear engagement with the left driven spur gear 216, when the left driven spur gear 216 rotates, the intermediate right driven spur gear 218 and an intermediate left driven spur gear 219 synchronously connected with, the right driven shaft 220 is rotatably installed in the right shaft hole of the transmission deck 201, and when the middle left driven spur gear 219 rotates, the right driven spur gear 221 is driven to rotate passively by the moving rack 107.

The camera rotation device 3 further comprises a connection plate 301, a servo motor 302, a driving spur gear 303, an intermediate driven connection rod 304, an intermediate driven spur gear 305, an intermediate driven helical gear 306, a camera connection plate 307, a left driven helical gear 308 and a high-speed camera 309, wherein the servo motor 302 is fixedly installed on the lower side surface of the connection plate 301, the driving spur gear 303 is rotatably installed on the servo motor 302, the servo motor 302 is a power source and drives the driving spur gear 303 to rotate when the servo motor 302 rotates, the intermediate driven connection rod 304 is rotatably installed in a left side shaft hole of the connection plate 301, the intermediate driven spur gear 305 is rotatably installed on the intermediate driven connection rod 304, the intermediate driven spur gear 305 and the driving spur gear 303 form a gear engagement, the intermediate driven helical gear 306 is rotatably installed on the intermediate driven connection rod 304 above the intermediate driven spur gear 305, and when the driving spur gear 303 rotates, the intermediate driven spur gear 305 and the intermediate driven helical gear 306 synchronously connected with And when the camera connecting plate 307 rotates, the camera connecting plate 307 is fixedly connected with the upper left surface of the connecting plate 301, the left driven bevel gear 308 is rotatably installed at one end of a right shaft of the camera connecting plate 307, the middle driven bevel gear 306 rotates to drive the left driven bevel gear 308 to rotate, the left driven bevel gear 308 and the middle driven bevel gear 306 form gear engagement, and the high-speed camera 309 is fixedly installed on the camera connecting plate 307.

The camera fine adjustment device 4 further comprises a rotary motor fixing plate 403, a rotary motor 404, a right driving helical gear 405, a right driven shaft 406, a right driven helical gear 407, a right driven spur gear 408, an intermediate driven connecting shaft 409, an intermediate lower driven spur gear 410, a left driven shaft 411, a left driven spur gear 412, a driven pulley 413, a left pulley driven shaft 414, a left driven pulley 415, a belt 416, a lower driven helical gear 417, a lower driven shaft 418, a lower right driven helical gear 419 and a lower left driven helical gear 420, wherein the rotary motor fixing plate 403 is fixedly arranged on the right side of the lower surface of the rotary driven helical gear 402, the rotary motor 404 is fixedly arranged on the rotary motor fixing plate 403, the right driving helical gear 405 is rotatably arranged on the rotary motor 404, the rotary motor 404 is a power source, and the rotary motor 404 drives the right driving helical gear, a right driven shaft 406 is rotatably installed in a right shaft hole of the rotary driven helical gear 402, a right driven helical gear 407 is rotatably installed on the camera fine adjustment device 46, the right driven helical gear 407 is in gear engagement with the right driving helical gear 405, a right driven spur gear 408 is rotatably installed on the right driven shaft 406, the right driving helical gear 405 rotates to drive the right driven helical gear 407 and a right driven spur gear 408 synchronously connected therewith to rotate synchronously, an intermediate driven connecting shaft 409 is rotatably installed in an intermediate shaft hole of the rotary driven helical gear 402, an intermediate lower driven spur gear 410 is rotatably installed on the intermediate driven connecting shaft 409, the intermediate lower driven spur gear 410 is driven to rotate when the right driven spur gear 408 rotates, the intermediate lower driven spur gear 410 is in gear engagement with the right driven spur gear 408, and a left driven shaft 411 is rotatably installed in a left shaft hole of the rotary driven helical gear 402, a left driven spur gear 412 is rotatably mounted on the left driven shaft 411, a driven pulley 413 is rotatably mounted on the left driven shaft 411 below the left driven spur gear 412, the left driven spur gear 412 and the driven pulley 413 synchronously connected therewith are driven to rotate when the intermediate lower driven spur gear 410 rotates, the left pulley driven shaft 414 is rotatably mounted on the rotary driven helical gear 402 on the left side of the left driven shaft 411, a left driven pulley 415 is rotatably mounted on the left pulley driven shaft 414, a belt 416 is in belt transmission engagement with the left driven pulley 415 and the driven pulley 413, a lower driven helical gear 417 is rotatably mounted on the left pulley driven shaft 414 below the left driven pulley 415, the lower driven shaft 418 is rotatably mounted in a shaft hole of a lower surface supporting plate of the rotary driven helical gear 402, and a lower right driven helical gear 419 is rotatably mounted on the lower driven shaft 418, the lower right driven bevel gear 419 and the lower driven bevel gear 417 form a gear engagement, when the driven pulley 413 rotates, the left driven pulley 415 and the lower driven bevel gear 417 synchronously connected with the left driven pulley are driven to rotate by the belt 416, the lower left driven bevel gear 420 is rotatably installed on the lower driven shaft 418 and is positioned on the left side of the lower right driven bevel gear 419, when the lower driven bevel gear 417 rotates, the lower right driven bevel gear 419 and the lower left driven bevel gear 420 synchronously connected with the lower right driven bevel gear are driven to rotate synchronously, the lower left driven bevel gear 420 and the rotary driven bevel gear 402 form a gear engagement, and when the lower left driven bevel gear 420 rotates, the rotary driven bevel gear 402 is driven to rotate.

The driven belt 212 is in belt driving engagement with the lower driven pulley 211 and the upper driven pulley 209. The left driven helical gear 215 is in gear engagement with the driven helical gear 213. The left driven spur gear 412 is in gear engagement with the middle lower driven spur gear 410.

Claims

1. The utility model provides a photoelectron collision test machine, includes collision test device (1), makes a video recording and shifts up device (2), makes a video recording rotary device (3) and fine setting device (4) of making a video recording, its characterized in that:

the collision test device (1) comprises a photon input pipeline (106), a movable rack (107) and an upper glass cover (108);

the camera shooting upward moving device (2) comprises a middle left driven straight gear (219), a middle right driven straight gear (221) and a sliding block (222);

the camera shooting rotating device (3) comprises a connecting plate (301);

the camera fine adjustment device (4) comprises a rotating device connecting plate (401) and a rotating driven bevel gear (402);

photon input pipeline 106 fixed mounting on test bench (104), removal rack (107) and photon input pipeline (106) carry out fixed connection, glass upper shield (108) fixed mounting on test bench medium plate (103), driven spur gear (219) in the middle of the left side rotate and install the left that lies in driven spur gear (218) in the middle of right side on middle driven shaft (217), driven spur gear (221) in the right side rotate and install on right driven shaft (220), driven spur gear (219) in middle of the left side and driven spur gear (221) in the right side form gear engagement with removal rack (107), slider (222) fixed mounting on the middle right side surface of transmission storehouse board (201), slider (222) and removal rack (107) form sliding fit, connecting plate (301) and the side surface of transmission storehouse board (201) carry out fixed connection, the rotating device connecting plate (401) is fixedly arranged on the glass upper cover (108), the rotating driven bevel gear (402) is rotatably arranged on the rotating device connecting plate (401), and the rotating driven bevel gear (402) is fixedly connected with the end part of the photon input pipeline (106).

2. An optoelectronic impact tester according to claim 1, characterized in that: the collision test device (1) further comprises a test bed bottom plate (101), a test bed connecting plate (102), a test bed middle plate (103), a test bed (104) and other substance input pipelines (105), wherein the test bed middle plate (103) is fixedly connected with the test bed bottom plate (101) through the test bed connecting plate (102), the test bed (104) is fixedly installed on the upper surface of the middle part of the test bed bottom plate (101), and the other substance input pipelines (105) are fixedly connected with the side surfaces of the test bed (104).

3. An optoelectronic impact tester according to claim 1, characterized in that: the camera shooting upward moving device (2) further comprises a transmission cabin plate (201), a motor fixing plate (202), a motor (203), a driving bevel gear (204), a driven worm (205), a worm connecting bevel gear (206), a turbine driven shaft (207), a driven turbine (208), an upper driven pulley (209), a lower pulley driven shaft (210), a lower driven pulley (211), a driven belt (212), a driven bevel gear (213), a left driven shaft (214), a left driven bevel gear (215), a left driven spur gear (216), a middle driven shaft (217), a middle right driven spur gear (218) and a right driven shaft (220), wherein the motor fixing plate (202) is fixedly installed on the upper surface of the inner side of the transmission cabin plate (201), the motor (203) is fixedly installed on the motor fixing plate (202), the driving bevel gear (204) is rotatably installed on the motor (203), the driven worm (205) rotate and install in two shaft holes about the centre of transmission storehouse board (201), worm connect helical gear (206) rotate and install on driven worm (205), worm connect helical gear (206) and form gear engagement with initiative helical gear (204), turbine driven shaft (207) rotate and install in the right side top shaft hole of transmission storehouse board (201), driven turbine (208) rotate and install on worm connect helical gear (206), driven turbine (208) and driven worm (205) form gear engagement, last driven pulley (209) rotate and install on turbine driven shaft (207) and lie in the right side of driven turbine (208), lower pulley driven shaft (210) rotate and install in the right side below shaft hole of transmission storehouse board (201), lower driven pulley (211) rotate and install on lower pulley driven shaft (210), the driven bevel gear (213) is rotatably arranged on the lower driven pulley shaft (210) and is positioned at the left side of the lower driven pulley (211), the left driven shaft (214) is rotatably arranged in a left shaft hole of the transmission cabin plate (201), the left driven helical gear (215) is rotationally arranged on a left driven shaft (214), the left driven spur gear (216) is rotationally arranged on the left driven shaft (214) and is positioned at the right side of the left driven helical gear (215), the middle driven shaft (217) is rotatably arranged in a middle shaft hole of the transmission cabin plate (201), the middle right driven spur gear (218) is rotationally arranged on a middle driven shaft (217), the middle right driven spur gear (218) and the left driven spur gear (216) form gear meshing, the right driven shaft (220) is rotatably arranged in a right shaft hole of the transmission cabin plate (201).

4. An optoelectronic impact tester according to claim 1, characterized in that: the camera rotation device (3) further comprises a connecting plate (301), a servo motor (302), a driving spur gear (303), a middle driven connecting rod (304), a middle driven spur gear (305), a middle driven helical gear (306), a camera connecting plate (307), a left driven helical gear (308) and a high-speed camera (309), wherein the servo motor (302) is fixedly installed on the lower side surface of the connecting plate (301), the driving spur gear (303) is rotatably installed on the servo motor (302), the middle driven connecting rod (304) is rotatably installed in a left shaft hole of the connecting plate (301), the middle driven spur gear (305) is rotatably installed on the middle driven connecting rod (304), the middle driven spur gear (305) and the driving spur gear (303) form gear engagement, the middle driven helical gear (306) is rotatably installed on the middle driven connecting rod (304) and is positioned above the middle driven spur gear (305), the camera connecting plate (307) is fixedly connected with the upper surface of the left side of the connecting plate (301), the left driven helical gear (308) is rotatably installed at one end of a right shaft of the camera connecting plate (307), the left driven helical gear (308) and the middle driven helical gear (306) form gear engagement, and the high-speed camera (309) is fixedly installed on the camera connecting plate (307).

5. An optoelectronic impact tester according to claim 1, characterized in that: the camera fine adjustment device (4) further comprises a rotary motor fixing plate (403), a rotary motor (404), a right driving bevel gear (405), a right driven shaft (406), a right driven bevel gear (407), a right driven spur gear (408), a middle driven connecting shaft (409), a middle lower driven spur gear (410), a left driven shaft (411), a left driven spur gear (412), a driven pulley (413), a left pulley driven shaft (414), a left driven pulley (415), a belt (416), a lower driven bevel gear (417), a lower driven shaft (418), a lower right driven bevel gear (419) and a lower left driven bevel gear (420), wherein the rotary motor fixing plate (403) is fixedly installed on the right side of the lower surface of the rotary driven bevel gear (402), and the rotary motor (404) is fixedly installed on the rotary motor fixing plate (403), the right side initiative helical gear (405) rotate and install on rotating electrical machines (404), right side driven shaft (406) rotate and install in the right side shaft hole of rotatory driven helical gear (402), right side driven helical gear (407) rotate and install on fine setting device (4) of making a video recording, right side driven helical gear (407) and right side initiative helical gear (405) form gear engagement, right side driven spur gear (408) rotate and install on right side driven shaft (406), middle driven connecting axle (409) rotate and install in the middle shaft hole of rotatory driven helical gear (402), middle driven spur gear (410) down rotate and install on middle driven connecting axle (409), middle driven spur gear (410) down form gear engagement with right side driven spur gear (408), left side driven shaft (411) rotate and install in the left side shaft hole of rotatory driven helical gear (402), the left driven spur gear (412) is rotatably installed on a left driven shaft (411), the driven pulley (413) is rotatably installed on the left driven shaft (411) below the left driven spur gear (412), the left driven pulley (414) is rotatably installed on the left side of the left driven shaft (411) on the rotary driven helical gear (402), the left driven pulley (415) is rotatably installed on the left driven pulley (414), the belt (416) is in belt transmission fit with the left driven pulley (415) and the driven pulley (413), the lower driven helical gear (417) is rotatably installed on the left driven pulley (414) below the left driven pulley (415), and the lower driven shaft (418) is rotatably installed in a shaft hole of a lower surface supporting plate of the rotary driven helical gear (402), the lower right driven helical gear (419) is rotatably installed on the lower driven shaft (418), the lower right driven helical gear (419) is in gear engagement with the lower driven helical gear (417), the lower left driven helical gear (420) is rotatably installed on the lower driven shaft (418) and positioned on the left side of the lower right driven helical gear (419), and the lower left driven helical gear (420) is in gear engagement with the rotary driven helical gear (402).

6. An optoelectronic impact tester according to claim 3, characterized in that: the driven belt (212) is in belt transmission fit with the lower driven pulley (211) and the upper driven pulley (209).

7. An optoelectronic impact tester according to claim 3, characterized in that: the left driven helical gear (215) and the driven helical gear (213) form gear engagement.

8. An optoelectronic impact tester according to claim 5, wherein: the left driven spur gear (412) is in gear engagement with the middle lower driven spur gear (41).