CN216285056U - Pipeline magnetic particle inspection device capable of improving detection efficiency - Google Patents

Abstract

The application relates to the technical field of nondestructive testing, in particular to a pipeline magnetic particle inspection device capable of improving detection efficiency, which comprises supporting legs, a detection table, a mounting frame and a magnetic suspension spray head, wherein the detection table is arranged on the supporting legs, the mounting frame is arranged on the detection table, the magnetic suspension spray head is arranged on the mounting frame in a sliding manner, an adjusting mechanism is arranged on the mounting frame, and the adjusting mechanism comprises two supporting blocks, four supporting wheels for supporting a pipeline and a rotating assembly; the two supporting blocks are arranged on the detection table, two supporting wheels are arranged on each supporting block in a rotating mode, the rotating assembly is arranged on the detection table, and the rotating assembly is connected with the supporting wheels. This application runner assembly drives the pipeline and rotates, has saved the manpower and has removed the adjustment pipeline, has the effect that improves detection efficiency.

Description

Pipeline magnetic particle inspection device capable of improving detection efficiency

Technical Field

The application relates to the technical field of nondestructive testing, in particular to a pipeline magnetic particle inspection device capable of improving detection efficiency.

Background

At present, magnetic powder inspection utilizes the interaction between the leakage magnetic field and the magnetic powder at the defect position of a workpiece, and utilizes the difference between the magnetic conductivity of the surface and near-surface defects (such as cracks, slag inclusion, hairlines and the like) of a steel product and the magnetic conductivity of steel, after magnetization, the magnetic field at the discontinuous position of the materials generates a Kazaki deformation, a leakage magnetic field is generated on the surface of the workpiece at the position where partial magnetic flux leaks, thus magnetic powder is attracted to form magnetic powder accumulation-magnetic marks at the defect position, the defect position and the shape are shown under proper illumination conditions, and the magnetic powder accumulation is observed and explained, thus the magnetic powder inspection is realized.

Chinese patent application No. CN201610779720.1 discloses a clamping device for magnetic particle inspection. The movable guide rail type clamping device comprises a support, wherein two guide rails which are parallel to each other are arranged on the support, two clamping plates which can move on the movable guide rails are arranged on the guide rails, two clamping heads which can be vertically adjusted on the clamping plates are arranged on each clamping plate, and the clamping heads on the two clamping plates are oppositely arranged. And (3) placing the pipeline between the two clamping plates, and starting a magnetic powder flaw detector to perform flaw detection on the pipeline.

In the process of implementing the present application, the inventor finds that at least the following problem exists in the technology, and in order to enable the pipeline to carry out flaw detection in all directions during detection, the pipeline needs to be manually rotated and adjusted, so that the detection efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

In order to improve detection efficiency, this application provides a pipeline magnetic particle inspection device who improves detection efficiency.

The application provides a pair of pipeline magnetic particle inspection device who improves detection efficiency adopts following technical scheme:

a pipeline magnetic particle inspection device capable of improving detection efficiency comprises supporting legs, a detection table, a mounting frame and a magnetic suspension spray head, wherein the detection table is arranged on the supporting legs, the mounting frame is arranged on the detection table, the magnetic suspension spray head is arranged on the mounting frame in a sliding mode, an adjusting mechanism is arranged on the mounting frame and comprises two supporting blocks, four supporting wheels for supporting a pipeline and a rotating assembly; the two supporting blocks are arranged on the detection table, two supporting wheels are arranged on each supporting block in a rotating mode, the rotating assembly is arranged on the detection table, and the rotating assembly is connected with the supporting wheels.

By adopting the technical scheme, the pipeline is placed on the supporting wheel, the magnetic suspension spray head is used for spraying the magnetic suspension on the detected area of the pipeline, then the pipeline is subjected to magnetic flaw detection, after the flaw detection of the area is finished, the rotating assembly is used for driving the supporting wheel to rotate, the supporting wheel drives the pipeline to rotate and rotate to a new detection area, and the magnetic suspension spray head is used for spraying the magnetic suspension to perform the next round of detection; the rotating assembly drives the pipeline to rotate, so that manpower is saved for adjusting the pipeline, and the detection efficiency is improved.

Optionally, the rotating assembly comprises a rotating motor and a transmission shaft, the rotating motor is arranged on the detection table, the transmission shaft is arranged on an output shaft of the rotating motor, and one end, far away from the rotating motor, of the transmission shaft is connected with the supporting wheel.

Through adopting above-mentioned technical scheme, the start rotates the motor, rotates the motor and drives the transmission shaft rotation, and the transmission shaft drives the supporting wheel and rotates, and the supporting wheel drives the pipeline and rotates, and the runner assembly simple structure, the operation of being convenient for, and then improved work efficiency.

Optionally, a limiting mechanism is arranged on the detection table, the limiting mechanism comprises three sliding blocks, a limiting block, a sliding wheel and an adjusting assembly, and the limiting block is arranged on the detection table; the three sliding blocks slide on the limiting blocks, and included angles between every two adjacent sliding blocks are the same; the sliding wheel is rotatably arranged at one end of the sliding block, which is far away from the limiting block, and the sliding wheel is abutted against the inner wall of the pipeline; the adjusting component is arranged on the limiting block and connected with the sliding block.

Through adopting above-mentioned technical scheme, take the sliding block to slide on the stopper with adjusting part, the sliding block drives the movable pulley and slides towards the direction that is close to the pipeline inner wall, and the movable pulley is contradicted with the pipeline inner wall, and when pipeline pivoted in-process, the movable pulley can reduce the pipeline and fall the possibility of supporting wheel down, has the effect of firm pipeline.

Optionally, the limiting block is provided with a placing cavity, the adjusting assembly comprises a driving motor, a first bevel gear, three rotating shafts, three second bevel gears and three rotating screws, the driving motor is arranged on the side wall of the placing cavity, and the first bevel gear is in key connection with an output shaft of the driving motor; the rotating shaft is rotatably arranged on the side wall of the placing cavity; the three second bevel gears are respectively in key connection with the three rotating shafts, and the three second bevel gears are all meshed with the first bevel gear; the three rotating screws are respectively arranged at one end of the rotating shaft, which is far away from the second bevel gear.

By adopting the technical scheme, the driving motor is started, the driving motor drives the first bevel gear to rotate, the first bevel gear drives the second bevel gear to rotate, the second bevel gear drives the rotating shaft to rotate, the rotating shaft drives the rotating screw to rotate, the rotating screw drives the sliding block to slide on the limiting block, and the sliding block drives the sliding wheel to abut against the inner wall of the pipeline; the adjusting assembly is simple in structure and easy to operate, the adjusting assembly can adjust the position of the sliding block according to the thickness of the pipeline, and therefore the applicability of the limiting mechanism is improved.

Optionally, a connecting assembly is arranged on the limiting block, the connecting assembly comprises a fixed block, a clamping block, a connecting bolt and a connecting nut, the fixed block is arranged on the detection table, and a clamping groove is formed in the fixed block; the fixture block sets up on the stopper, the fixture block joint is in the draw-in groove, connecting bolt passes the fixed block with the fixture block, coupling nut with coupling bolt threaded connection, connecting bolt with coupling nut contradicts respectively two lateral walls of fixed block.

By adopting the technical scheme, when the diameter of the pipeline is larger or the limiting mechanism is damaged, the connecting bolt penetrates through the fixed block and the fixture block to be in threaded connection with the connecting nut, the fixture block on the limiting block can be pulled out of the clamping groove on the fixed block, a new limiting mechanism is replaced, and the effect of detachable replacement of the limiting mechanism is achieved; meanwhile, different limiting mechanisms can be replaced, the device is suitable for pipelines with more specifications, and the applicability of the device is improved.

Optionally, a connecting block is arranged on the detection table, a lifting mechanism is arranged on the detection table, and the lifting mechanism comprises a sliding block and a lifting piece; the sliding block is connected to the connecting block in a sliding mode, and the fixing block is arranged on the sliding block; the lifting piece is arranged on the mounting frame and connected with the sliding block.

By adopting the technical scheme, the diameters of the pipelines are different, the distance between the circle center position and the supporting block is different, the lifting piece is used for driving the sliding block to slide, the sliding block drives the limiting block to lift to the position which is as high as the circle center of the pipeline, and the lifting mechanism improves the applicability of the limiting mechanism.

Optionally, the lifting piece is a hydraulic cylinder, a cylinder body of the hydraulic cylinder is arranged on the connecting block, and a piston rod of the hydraulic cylinder is connected with the sliding block.

Through adopting above-mentioned technical scheme, start the pneumatic cylinder, the piston rod of pneumatic cylinder drives the sliding block and goes up and down, and pneumatic cylinder simple structure is convenient for operate to work efficiency has been improved.

Optionally, the connecting block slides detect the bench, it is provided with the subassembly that slides to detect the bench, the subassembly that slides includes the motor that slides, driving gear and rack, the motor that slides sets up on the connecting block, the driving gear sets up on the output shaft of the motor that slides, the rack sets up detect the bench, the driving gear with rack toothing.

Through adopting above-mentioned technical scheme, start the motor that slides, the motor that slides drives the driving gear and rotates, and relative slip takes place for driving gear and rack, and the motor that slides drives the connecting block and slides for stop gear can be applicable to the pipeline of different length, makes stop gear's application scope widen.

To sum up, the application comprises the following beneficial technical effects:

1. the rotating assembly is used for driving the supporting wheel to rotate, the supporting wheel drives the pipeline to rotate, the pipeline rotates to a new detection area, and the next round of detection is carried out; the rotating assembly drives the pipeline to rotate, so that manpower is saved for adjusting the pipeline, and the detection efficiency is improved;

2. when the pipeline rotates, the sliding wheel can reduce the possibility that the pipeline falls off the supporting wheel, and the pipeline stabilizing device has the effect of stabilizing the pipeline;

3. the sliding motor drives the connecting block to slide, so that the limiting mechanism can be suitable for pipelines with different lengths, and the application range of the limiting mechanism is widened.

Drawings

FIG. 1 is a schematic structural diagram of a pipeline magnetic particle inspection device for improving inspection efficiency in an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a rotating assembly in an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a lifting mechanism in an embodiment of the present application;

fig. 4 is a schematic structural diagram of a limiting mechanism in the embodiment of the present application.

Reference numerals: 11. a support leg; 12. a detection table; 121. a chute; 122. a slider; 13. a mounting frame; 131. a fixing plate; 132. mounting blocks; 133. connecting blocks; 14. a magnetic suspension spray header; 15. placing the blocks; 2. an adjustment mechanism; 21. a support block; 22. a support wheel; 23. a rotating assembly; 231. rotating the motor; 232. a drive shaft; 3. a limiting mechanism; 31. a limiting block; 32. a slider; 33. a sliding wheel; 34. an adjustment assembly; 341. a drive motor; 342. a first bevel gear; 343. a rotating shaft; 344. a second bevel gear; 345. rotating the screw; 4. a connecting assembly; 41. a fixed block; 42. a clamping block; 43. a connecting bolt; 44. a connecting nut; 5. a lifting mechanism; 51. a sliding block; 52. a hydraulic cylinder; 6. a slipping component; 61. a slip motor; 62. a driving gear; 63. a rack.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses pipeline magnetic particle inspection device capable of improving detection efficiency.

Referring to fig. 1, the pipeline magnetic particle inspection device for improving the detection efficiency includes a supporting leg 11, a detection table 12 is fixedly connected to the supporting leg 11, an installation frame 13 is arranged on the detection table 12, a magnetic suspension spray header 14 is connected to the installation frame 13 in a sliding manner, and an adjusting mechanism 2 for adjusting a pipeline is arranged on the detection table 12.

An operator places the pipeline on the detection table 12, sprays magnetic suspension on the pipeline by using the magnetic suspension spray head 14, and then carries out magnetic flaw detection on the pipeline; when the position of the pipeline needs to be adjusted, the position of the pipeline is adjusted by the adjusting mechanism 2, and the pipeline is subjected to flaw detection by continuing the operation.

Referring to fig. 1, the mounting frame 13 includes a fixing plate 131, the fixing plate 131 is vertically and fixedly connected to the testing table 12, and the fixing plate 131 is located at one end of the testing table 12; the end of the fixing plate 131 far away from the detection table 12 is vertically and fixedly connected with a mounting block 132, and the magnetic suspension spray header 14 is connected to the mounting block 132 close to the side wall of the detection table 12 in a sliding manner.

Referring to fig. 1 and 2, the adjusting mechanism 2 includes two supporting blocks 21, the two supporting blocks 21 are respectively located at two ends of the detection table 12 in the length direction, and the supporting blocks 21 are fixedly connected with the detection table 12; each supporting block 21 is rotatably connected with two supporting wheels 22 for supporting pipelines; the supporting wheel 22 is located at one end of the supporting block 21 far away from the detection table 12, the supporting block 21 far away from the fixing plate 131 is fixedly connected with a placing block 15, and the placing block 15 is located between the two supporting blocks 21.

Place and be provided with runner assembly 23 on the piece 15, runner assembly 23 includes rotating electrical machines 231, and rotating electrical machines 231 fixed connection is in the one end of placing piece 15 and keeping away from detecting platform 12, is connected with transmission shaft 232 on rotating electrical machines 231's the output shaft, and one end and the supporting wheel 22 fixed connection of rotating electrical machines 231 are kept away from to transmission shaft 232.

The rotating motor 231 is started, the rotating motor 231 drives the transmission shaft 232 to rotate, the transmission shaft 232 drives the supporting wheel 22 to rotate, and the supporting wheel 22 drives the pipeline to rotate.

Referring to fig. 1 and 3, one end of the detection table 12, which is far away from the fixing plate 131, is provided with a connecting block 133, one end of the connecting block 133, which is far away from the detection table 12, is provided with a sliding cavity, the connecting block 133 is provided with a lifting mechanism 5, the lifting mechanism 5 comprises a sliding block 51, and the sliding block 51 is connected in the sliding cavity in a sliding manner.

A mounting cavity is formed in the connecting block 133 and communicated with the sliding cavity; be provided with the lifting unit in the installation cavity, the lifting unit is pneumatic cylinder 52, and the cylinder body fixed connection of pneumatic cylinder 52 is on the installation cavity is close to the lateral wall that detects platform 12, and the piston rod of pneumatic cylinder 52 is located the one end fixed connection in the chamber that slides with sliding block 51.

The hydraulic cylinder 52 is started, and the piston rod of the hydraulic cylinder 52 drives the sliding block 51 to ascend.

Referring to fig. 1 and 3, two sliding grooves 121 are formed in the detection table 12, a sliding block 122 is connected in each sliding groove 121 in a sliding manner, two ends of a connecting block 133 are fixedly connected with the two sliding blocks 122 respectively, a sliding assembly 6 is arranged on the connecting block 133, the sliding assembly 6 comprises a sliding motor 61, the sliding motor 61 is fixedly connected to the side wall of the connecting block 133 far away from the supporting block 21, and the sliding motor 61 is located at one end of the connecting block 133 close to the detection table 12; the output shaft of the sliding motor 61 is connected with a driving gear 62 by a key; a sliding groove parallel to the sliding grooves 121 is formed in the detection table 12, the sliding groove is located between the two sliding grooves 121, and a rack 63 is fixedly connected in the sliding groove; the rack gear 63 is engaged with the pinion gear 62.

The sliding motor 61 is started, the sliding motor 61 drives the driving gear 62 to rotate, the driving gear 62 and the rack 63 generate relative displacement, and the sliding motor 61 drives the connecting block 133 to slide on the detection table 12.

Referring to fig. 1 and 3, a limiting mechanism 3 is arranged at one end of the sliding block 51, which is far away from the connecting block 133, the limiting mechanism 3 includes a limiting block 31, a connecting assembly 4 connected with the sliding block 51 is arranged on the limiting block 31, the connecting assembly 4 includes a fixing block 41, the fixing block 41 is fixedly connected to a side wall of the sliding block 51, which is close to the supporting block 21, and a clamping groove is formed in a side wall of the fixing block 41, which is far away from the sliding block 51; one end of the limiting block 31 close to the fixed block 41 is fixedly connected with a clamping block 42, the clamping block 42 is clamped in the clamping groove, two side walls of the clamping groove are respectively provided with a first connecting hole and a second connecting hole, and the axis of the first connecting hole is overlapped with the axis of the second connecting hole; the fixture block 42 is provided with a third connecting hole, the fixture block 41 is provided with a connecting bolt 43, the connecting bolt 43 sequentially penetrates through the first connecting hole, the third connecting hole and the second connecting hole, and one end of the connecting bolt 43 penetrating through the second connecting hole is in threaded connection with a connecting nut 44.

Referring to fig. 3 and 4, the limiting block 31 is slidably connected with three sliding blocks 32, and the included angles between two adjacent sliding blocks 32 are the same; one end of the sliding block 32, which is far away from the limiting block 31, is rotatably connected with a sliding wheel 33, and the sliding wheel 33 is abutted against the inner side wall of one end of the pipeline, which is far away from the fixing plate 131.

A placing cavity is formed in one end, away from the fixture block 42, of the limiting block 31, an adjusting assembly 34 is arranged in the placing cavity, the adjusting assembly 34 comprises a driving motor 341, the driving motor 341 is fixedly connected to the side wall of the placing cavity, and an output shaft of the driving motor 341 is in keyed connection with a first bevel gear 342; the placing cavity is rotatably connected with three rotating shafts 343, and included angles between every two adjacent rotating shafts 343 are the same; one end of each rotating shaft 343 is keyed with a second bevel gear 344, and the three second bevel gears 344 are meshed with the first bevel gear 342; one end of the sliding block 32, which is far away from the sliding wheel 33, is provided with a threaded hole, and a rotating screw 345 is connected with the internal thread of the threaded hole; the end of the rotating screw 345 remote from the sliding block 32 is fixedly connected to the end of the rotating shaft 343 remote from the second bevel gear 344.

The implementation principle of the pipeline magnetic particle inspection device for improving the detection efficiency is as follows: placing the pipe on four support wheels 22; the hydraulic cylinder 52 is started, the piston rod of the hydraulic cylinder 52 drives the sliding block 51 to ascend, and the sliding block 51 drives the limiting block 31 on the fixing block 41 to ascend until the axis of the limiting block 31 coincides with the axis of the pipeline.

According to the position of the pipeline, the sliding motor 61 is started, the sliding motor 61 drives the driving gear 62 to rotate, the driving gear 62 and the rack 63 slide relatively, the sliding motor 61 drives the connecting block 133 to slide, and the connecting block 133 drives the sliding block 51 to slide towards the direction close to the pipeline; the sliding block 51 drives the limiting block 31 on the fixed block 41 to slide towards the direction close to the pipeline, and one end of the limiting block 31 far away from the sliding block 51 enters the pipeline.

The driving motor 341 is started, the driving motor 341 drives the first bevel gear 342 to rotate, the first bevel gear 342 drives the three second bevel gears 344 to rotate, the second bevel gears 344 drive the rotating shafts 343 to rotate, the rotating shafts 343 drive the rotating screws 345 to rotate, the rotating screws 345 drive the sliding blocks 32 to slide on the limiting blocks 31, the sliding blocks 32 drive the sliding wheels 33 to slide towards the direction close to the inner wall of the pipeline, and the three sliding wheels 33 are all abutted against the inner wall of the pipeline.

Starting the magnetic suspension spray header 14, spraying the magnetic suspension on the pipeline, carrying out magnetic flaw detection on the pipeline, after flaw detection is finished, starting the rotating motor 231, driving the transmission shaft 232 to rotate by the rotating motor 231, driving the support wheel 22 to rotate by the transmission shaft 232, driving the pipeline to rotate at a non-detection position by the support wheel 22, starting the magnetic suspension spray header 14 again, spraying the magnetic suspension on the pipeline, and carrying out next flaw detection; the pipeline rotates to drive the sliding wheel 33 to rotate, the sliding wheel 33 has a limiting effect on the pipeline, and the phenomenon that the supporting wheel 22 falls down from the pipeline is reduced.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The pipeline magnetic particle inspection device capable of improving the detection efficiency comprises supporting legs (11), an inspection table (12), an installation frame (13) and a magnetic suspension spray header (14), wherein the inspection table (12) is arranged on the supporting legs (11), the installation frame (13) is arranged on the inspection table (12), and the magnetic suspension spray header (14) is arranged on the installation frame (13) in a sliding manner, and is characterized in that an adjusting mechanism (2) is arranged on the installation frame (13), and the adjusting mechanism (2) comprises two supporting blocks (21), four supporting wheels (22) for supporting a pipeline and a rotating assembly (23); the two supporting blocks (21) are arranged on the detection table (12), two supporting wheels (22) are arranged on each supporting block (21) in a rotating mode, the rotating assembly (23) is arranged on the detection table (12), and the rotating assembly (23) is connected with the supporting wheels (22).

2. The pipeline magnetic particle inspection device for improving the inspection efficiency according to claim 1, wherein the rotating assembly (23) comprises a rotating motor (231) and a transmission shaft (232), the rotating motor (231) is arranged on the inspection table (12), the transmission shaft (232) is arranged on an output shaft of the rotating motor (231), and one end of the transmission shaft (232) far away from the rotating motor (231) is connected with the supporting wheel (22).

3. The pipeline magnetic particle inspection device for improving the inspection efficiency is characterized in that a limiting mechanism (3) is arranged on the inspection table (12), the limiting mechanism (3) comprises three sliding blocks (32), a limiting block (31), a sliding wheel (33) and an adjusting assembly (34), and the limiting block (31) is arranged on the inspection table (12); the three sliding blocks (32) slide on the limiting blocks (31), and included angles between every two adjacent sliding blocks (32) are the same; the sliding wheel (33) is rotatably arranged at one end, away from the limiting block (31), of the sliding block (32), and the sliding wheel (33) is abutted against the inner wall of the pipeline; the adjusting component (34) is arranged on the limiting block (31), and the adjusting component (34) is connected with the sliding block (32).

4. The pipeline magnetic particle inspection device for improving the detection efficiency according to claim 3, wherein the limiting block (31) is provided with a placing cavity, the adjusting assembly (34) comprises a driving motor (341), a first bevel gear (342), three rotating shafts (343), three second bevel gears (344) and three rotating screws (345), the driving motor (341) is arranged on the side wall of the placing cavity, and the first bevel gear (342) is connected to an output shaft of the driving motor (341) in a key manner; the rotating shaft (343) is rotatably arranged on the side wall of the placing cavity; three second bevel gears (344) are respectively keyed on the three rotating shafts (343), and the three second bevel gears (344) are meshed with the first bevel gear (342); the three rotating screws (345) are respectively arranged at one end of the rotating shaft (343) far away from the second bevel gear (344).

5. The pipeline magnetic particle inspection device for improving the inspection efficiency according to claim 4, wherein the limiting block (31) is provided with a connecting assembly (4), the connecting assembly (4) comprises a fixing block (41), a clamping block (42), a connecting bolt (43) and a connecting nut (44), the fixing block (41) is arranged on the inspection table (12), and the fixing block (41) is provided with a clamping groove; fixture block (42) set up on stopper (31), fixture block (42) joint is in the draw-in groove, connecting bolt (43) pass fixed block (41) with fixture block (42), coupling nut (44) with connecting bolt (43) threaded connection, connecting bolt (43) with coupling nut (44) contradict respectively two lateral walls of fixed block (41).

6. The pipeline magnetic particle inspection device for improving the inspection efficiency according to claim 5, wherein a connecting block (133) is arranged on the inspection table (12), a lifting mechanism (5) is arranged on the inspection table (12), and the lifting mechanism (5) comprises a sliding block (51) and a lifting piece; the sliding block (51) is connected to the connecting block (133) in a sliding mode, and the fixing block (41) is arranged on the sliding block (51); the lifting piece is arranged on the mounting frame (13), and the lifting piece is connected with the sliding block (51).

7. The pipeline magnetic particle inspection device for improving the inspection efficiency according to claim 6, wherein the lifting member is a hydraulic cylinder (52), a cylinder body of the hydraulic cylinder (52) is arranged on the connecting block (133), and a piston rod of the hydraulic cylinder (52) is connected with the sliding block (51).

8. The pipeline magnetic particle inspection device for improving the inspection efficiency according to claim 7, wherein the connecting block (133) slides on the inspection table (12), a sliding assembly (6) is arranged on the inspection table (12), the sliding assembly (6) comprises a sliding motor (61), a driving gear (62) and a rack (63), the sliding motor (61) is arranged on the connecting block (133), the driving gear (62) is arranged on an output shaft of the sliding motor (61), the rack (63) is arranged on the inspection table (12), and the driving gear (62) is meshed with the rack (63).

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