CN221056374U - X-ray detection device for multi-split conductor - Google Patents

Abstract

The utility model discloses a multi-split conductor X-ray detection device, and mainly relates to the technical field of conductor X-ray detection. Including the electrical control box is installed to inner wall one side of bearing frame, the equal fixedly connected with suspension couple in upper surface both sides of bearing frame, the bottom of bearing frame is provided with the guide frame, the cross-section of guide frame is "V" shape, the both sides of bearing frame are provided with first mounting bracket and second mounting bracket respectively, the both ends of first mounting bracket and second mounting bracket all rotate with the lateral wall of guide frame and are connected, one side of bearing frame is provided with the installing frame, the both sides surface of installing frame all is provided with imaging plate. The utility model has the beneficial effects that: the problem of because the high-voltage cable of ordinary high tension is split more, will appear changing the condition of adjusting to imaging plate's position constantly, and then cause inconvenient to carrying out the flaw detection to the high tension cable of splitting more is solved.

Description

X-ray detection device for multi-split conductor

Technical Field

The utility model relates to the technical field of wire X-ray detection, in particular to a multi-split wire X-ray detection device.

Background

The X-ray flaw detector is used for detecting flaw of a single split cable, and in the running process of a power transmission line, line running accidents caused by the compression joint quality of a strain clamp or a splicing sleeve are caused, and the X-ray flaw detector is carried by an unmanned aerial vehicle for detection, so that the X-ray flaw detector is quite common in high-voltage cable construction operation.

Finding when carrying out X ray detection to high-voltage cable, whole wire X ray detection in-process, at first utilize large-scale unmanned aerial vehicle to hang whole imaging device to the position that high-voltage cable corresponds, the light transmitter of reuse unmanned aerial vehicle installation shines the imaging plate to carry out the X ray operation of detecting a flaw of high-voltage cable, and this in-process, because ordinary high-voltage cable splits more, the condition that need constantly change the position of adjusting the imaging plate will appear, and then cause inconvenient problem of detecting a flaw to the high-voltage cable of splitting more.

Disclosure of utility model

The utility model aims to solve the problems that in the prior art, when X-ray detection is carried out on a high-voltage cable, in the whole wire X-ray detection process, a large unmanned aerial vehicle is utilized to hang the whole imaging equipment to the position corresponding to the high-voltage cable, and then a light emitter arranged on a small unmanned aerial vehicle is utilized to irradiate an imaging plate, so that X-ray flaw detection operation of the high-voltage cable is carried out.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides a many split conductors X-ray detection device, includes the carriage, the electrical control box is installed to inner wall one side of carriage, the equal fixedly connected with suspension hook in upper surface both sides of carriage, the bottom of carriage is provided with the guide frame, the cross-section of guide frame is "V" shape, the both sides of carriage are provided with first mounting bracket and second mounting bracket respectively, the both ends of first mounting bracket and second mounting bracket all rotate with the lateral wall of guide frame and are connected, one side of carriage is provided with the installing frame, the both sides surface of installing frame all is provided with imaging plate, the position that the carriage bottom surface corresponds the guide frame inner wall is equipped with adjusting device, adjusting device includes lifting assembly and spacing subassembly.

The effects achieved by the components are as follows: in the X-ray detection process of the high-voltage cable, the whole imaging device is firstly hung to the corresponding position of the high-voltage cable by using a large unmanned aerial vehicle, the imaging plate is irradiated by using a light emitter installed by the small unmanned aerial vehicle through guiding and fixing between a guide frame at the bottom end of a bearing frame and the cable, so that the X-ray flaw detection operation of the high-voltage cable is carried out.

Preferably, the lifting assembly comprises a supporting frame, the upper surface of the supporting frame is fixedly connected with the lower surface of the bearing frame, a first servo motor is fixedly connected to one side of the bottom end of the supporting frame, the same rotating rod is rotationally connected to two ends of the inner wall of the supporting frame, the bottom end of the rotating rod is in transmission connection with the output end of the first servo motor, the arc surface of the rotating rod is in threaded connection with a sliding frame, one side, close to the imaging plate, of the sliding frame is fixedly connected with a supporting rod, one end, far away from the sliding frame, of the supporting rod is fixedly connected with the mounting frame, and the surface of the supporting rod is in sliding connection with the side wall of the guide frame.

The effects achieved by the components are as follows: the first servo motor is started firstly, the output end of the first servo motor drives the first transmission belt to rotate, and then the first transmission belt drives the rotating rod in the supporting frame to rotate, so that the rotating rod in the supporting frame drives the sliding frame on the surface to move up and down, one side of the sliding frame is fixed with the supporting rod, and the supporting rod is utilized to drive lifting adjustment of the position of the whole installation frame.

Preferably, the limiting component comprises a driving motor, one side of the driving motor is fixedly connected with the side face of the inner wall of the mounting frame, the output end of the driving motor is fixedly connected with a driving rod, one end of the driving rod, which is far away from the driving motor, is rotationally connected with the inner wall surface of the mounting frame, threads with opposite thread directions are arranged at two ends of the driving rod, the driving frame is penetrated by threads at two ends of the driving rod, two rotating plates are rotationally connected at two ends of the driving frame, four rotating plates are rotationally connected with connecting plates at one end, which is far away from the driving frame, of each connecting plate, the cross section of each connecting plate is L-shaped, each connecting plate is provided with a group, one side of each group of connecting plates is fixedly connected with the imaging plate, auxiliary rods are fixedly connected with two sides of the inner wall of the mounting frame, sliding through sliding blocks are respectively arranged at two ends of the auxiliary rods, and one side of each sliding block is fixedly connected with two ends of the driving frame.

The effects achieved by the components are as follows: for conveniently letting the imaging plate of installing frame both sides carry out the flexible removal of position, start driving motor in the installing frame inner wall this moment, let driving motor drive actuating lever rotate, thereby let the actuating lever drive the drive frame at both ends carry out the removal regulation of position, at this moment the drive frame drives the rotation board at both ends and carries out the deflection of position, thereby let two imaging plates remove towards the position of high voltage cable, the auxiliary rod that is fixed at this in-process installing frame both ends slides with the slider at drive frame both ends, can carry out spacing fixedly to the shift position of whole drive frame effectively, the deflection removal of imaging plate position has been avoided effectively.

Preferably, the inner wall of the sliding block is fixedly connected with a protective sleeve, and the inner wall of the protective sleeve is in sliding connection with the surface of the auxiliary rod.

The effects achieved by the components are as follows: in the process of sliding the sliding block and the auxiliary rod, the protecting sleeve fixed on the inner wall of the sliding block can be used for sliding protection with the auxiliary rod, so that abrasion of the auxiliary rod and the sliding block is avoided.

Preferably, the bottom surface both sides of bearing the frame are equipped with auxiliary device, auxiliary device includes direct current motor, one side and the bearing the frame fixed connection of direct current motor, direct current motor's output transmission is connected with the second drive belt, the one end transmission that direct current motor was kept away from to the second drive belt is connected with the transmission shaft, the inner wall fixedly connected with of transmission shaft rotates the post, it is flexible post to rotate the post, the arc surface of rotating the post is equipped with the damping, the equal fixedly connected with walking wheel in both ends of rotating the post, the equal fixedly connected with anti-skidding cover of arc surface of walking wheel, anti-skidding line has been seted up on the surface of anti-skidding cover.

The effects achieved by the components are as follows: after placing whole frame that bears on the wire surface, in order to conveniently remove spacingly to the position of whole frame that bears, through the direct current motor who bears the frame bottom surface this moment, let direct current motor drive the rotation of transmission shaft to let the transmission shaft drive the walking wheel at rotation post both ends slide along the wire, thereby conveniently regulate and control the position of whole frame that bears effectively.

Preferably, the positions of the two side surfaces of the guide frame corresponding to the travelling wheels are fixedly connected with motors, the output ends of the motors are fixedly connected with rotating frames, and one ends of the rotating frames are rotatably connected with holding wheels.

The effects achieved by the components are as follows: when the travelling wheels on two sides of the bearing frame slide with the travelling wires, the motor is started at the moment so as to prevent the travelling wires from falling off from the travelling wires, and the motor drives the rotating frame to rotate, so that the holding wheels rotating in the rotating frame and the travelling wires are close to each other, and can be locked and limited with the travelling wires.

Preferably, the inner wall surface of bearing frame is equipped with interval adjustment subassembly, interval adjustment subassembly includes second servo motor, one side and the bearing frame fixed connection of second servo motor, the output fixedly connected with lead screw of second servo motor, the one end rotation that second servo motor was kept away from to the lead screw is connected with the connecting block, the lower surface and the bearing frame fixed connection of connecting block, the opposite screw thread of screw thread direction has been seted up to the arc surface of lead screw, the equal threaded connection in both ends of lead screw has the movable frame, two the movable frame respectively with first mounting bracket and second mounting bracket fixed connection, the equal fixedly connected with slide rail in both ends inner wall of bearing frame, the equal sliding connection in both ends inner wall of slide rail has the sliding block, two the sliding block respectively with first mounting bracket and second mounting bracket fixed connection.

The effects achieved by the components are as follows: in the process that needs place the guide frame that the cross-section is "V" shape on high-voltage cable, because the interval between the cable of splitting more is different, thereby need adjust the walking wheel position in guide frame upper end first mounting bracket and the second mounting bracket, drive the rotation of lead screw through the second servo motor this moment, drive the fixed movable frame of lead screw both ends and first mounting bracket and second mounting bracket and remove, at this moment, will deflect between whole guide frame and first mounting bracket and the second mounting bracket, simultaneously, slide rail and the sliding block of frame inner wall will be born through bearing to first mounting bracket and second mounting bracket will slide spacing fixedly, thereby the position that lets first mounting bracket and second mounting bracket slide, can conveniently and effectively carry out the regulation and control of interval to the walking wheel on guide frame surface this moment.

In summary, the beneficial effects of the utility model are as follows:

In the utility model, in the process of carrying out X-ray detection on a high-voltage cable, firstly, a large unmanned aerial vehicle is utilized to hoist the whole imaging equipment to a position corresponding to the high-voltage cable, the guiding and fixing are carried out between a guiding frame at the bottom end of a bearing frame and the cable, then, a light emitter arranged on the small unmanned aerial vehicle is utilized to irradiate an imaging plate, so that the X-ray flaw detection operation of the high-voltage cable is carried out, in the process, the situation that the position of the imaging plate is required to be continuously replaced and regulated is caused because the common high-voltage cable is more in splitting, the flaw detection on the multi-split high-voltage cable is inconvenient, in the process, a lifting component and a limiting component in a universal regulating device can be carried out in an auxiliary operation mode, a first servo motor is started, the output end of the first servo motor drives a first driving belt to rotate, and then the first driving belt drives a rotating rod in the supporting frame to rotate, thereby the slide frame in the supporting frame drives the slide frame on the surface to move up and down, one side of the slide frame is fixed with the supporting rod, thereby the supporting rod is utilized to drive the lifting adjustment of the whole installation frame position, in order to facilitate the telescopic movement of the imaging plates on the two sides of the installation frame to carry out the position, thereby the imaging plates detect and image the multiple wires, at the moment, the driving motor in the inner wall of the installation frame is started, the driving motor drives the driving rod to rotate, thereby the driving rod drives the driving frames on the two ends to carry out the position movement adjustment, at the moment, the driving frame drives the rotating plates on the two ends to carry out the position deflection, thereby the two imaging plates move towards the position of the high-voltage cable, the auxiliary rods fixed on the two ends of the installation frame slide with the sliding blocks on the two ends of the driving frame in the process, the moving position of the whole driving frame can be effectively limited and fixed, the deflection movement of the imaging plate position is effectively avoided, and the lifting of the imaging plate position and the telescopic adjustment of the imaging plate position by using the rotating plates on two sides of the mounting frame are achieved through the operation of the adjusting device.

In the utility model, after the whole bearing frame is placed on the surface of the wire, in order to conveniently carry out movement limit on the position of the whole bearing frame, at the moment, the direct current motor drives the transmission shaft to rotate through the direct current motor on the bottom surface of the bearing frame, so that the transmission shaft drives the travelling wheels at the two ends of the rotating column to slide along the wire, thereby effectively and conveniently regulating and controlling the position of the whole bearing frame.

According to the utility model, in the process of placing the guide frame with the V-shaped section on the high-voltage cable, because the intervals among the split cables are different, the positions of the travelling wheels in the first installation frame and the second installation frame at the upper end of the guide frame are required to be adjusted, at the moment, the second servo motor drives the screw rod to rotate, the two ends of the screw rod are driven to move with the moving frames fixed by the first installation frame and the second installation frame, at the moment, the whole guide frame and the first installation frame and the second installation frame deflect, and meanwhile, the first installation frame and the second installation frame slide through the sliding rail and the sliding block on the inner wall of the bearing frame, so that the positions of the first installation frame and the second installation frame are subjected to sliding limiting fixation, at the moment, the intervals among the travelling wheels on the surface of the guide frame can be conveniently and effectively adjusted, and the distance between the first installation frame and the second installation frame is conveniently and effectively limited through the operation of the interval adjusting assembly, and the guide frame and the high-voltage cable can be conveniently and butted.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a partial schematic view of a three-dimensional structure of the present utility model;

FIG. 3 is a schematic structural view of the adjusting device of the present utility model;

FIG. 4 is a schematic view of the structure of the lift assembly of the present utility model;

FIG. 5 is a schematic view of the spacing assembly of the present utility model;

FIG. 6 is an enlarged schematic view of the structure of FIG. 5A in accordance with the present utility model;

FIG. 7 is a schematic view of the auxiliary device of the present utility model;

FIG. 8 is a schematic view of the auxiliary device of the present utility model in a disassembled configuration;

FIG. 9 is a schematic view of a split of the three-dimensional structure of the present utility model;

fig. 10 is a schematic view of the spacing adjustment assembly of the present utility model.

The reference numbers shown in the drawings: 1. a carrying frame; 2. an imaging plate; 3. a guide frame; 4. an adjusting device; 41. a lifting assembly; 411. a support frame; 412. a support rod; 413. a sliding frame; 414. a rotating lever; 415. a first servo motor; 416. a first belt; 42. a limit component; 421. a driving motor; 422. a driving rod; 423. a drive rack; 424. a slide block; 425. an auxiliary lever; 426. a rotating plate; 427. a splice plate; 428. a protective sleeve; 5. an auxiliary device; 51. a DC motor; 52. a transmission shaft; 53. a second belt; 54. rotating the column; 55. a walking wheel; 56. an anti-skid sleeve; 57. a motor; 58. a rotating frame; 59. a holding wheel; 6. a mounting frame; 7. a spacing adjustment assembly; 71. a second servo motor; 72. a screw rod; 73. a moving rack; 74. a connecting block; 75. a slide rail; 76. a sliding block; 8. an electrical control box; 9. a hanging hook; 10. a first mounting frame; 11. and a second mounting frame.

Detailed Description

The utility model will be further illustrated with reference to specific examples. It is to be understood that these examples are illustrative of the present utility model and are not intended to limit the scope of the present utility model. Furthermore, it should be understood that various changes and modifications can be made by one skilled in the art after reading the teachings of the present utility model, and such equivalents are intended to fall within the scope of the utility model as defined in the appended claims.

Referring to fig. 1 to 10, the present utility model provides a technical solution: the utility model provides a many split conductors X-ray detection device, including bearing frame 1, electric control box 8 is installed to inner wall one side of bearing frame 1, the equal fixedly connected with suspension hook 9 in upper surface both sides of bearing frame 1, the bottom of bearing frame 1 is provided with guide frame 3, the cross-section of guide frame 3 is "V" shape, the both sides of bearing frame 1 are provided with first mounting bracket 10 and second mounting bracket 11 respectively, the both ends of first mounting bracket 10 and second mounting bracket 11 all rotate with the lateral wall of guide frame 3 and are connected, one side of bearing frame 1 is provided with installing frame 6, the both sides surface of installing frame 6 all is provided with imaging plate 2, the position that the guide frame 3 inner wall was corresponded to the bottom surface of bearing frame 1 is equipped with adjusting device 4, the bottom surface both sides of bearing frame 1 are equipped with auxiliary device 5, the inner wall surface of bearing frame 1 is equipped with interval adjustment subassembly 7.

The specific arrangement and function of the adjusting device 4, the auxiliary device 5 and the distance adjusting assembly 7 will be described in detail below.

Referring to fig. 3, 4, 5 and 6, in this embodiment: the adjusting device 4 comprises a lifting component 41 and a limiting component 42, the lifting component 41 comprises a supporting frame 411, the upper surface of the supporting frame 411 is fixedly connected with the lower surface of the bearing frame 1, one side of the bottom end of the supporting frame 411 is fixedly connected with a first servo motor 415, two ends of the inner wall of the supporting frame 411 are rotatably connected with a same rotating rod 414, the bottom end of the rotating rod 414 is in transmission connection with the output end of the first servo motor 415 with a same first transmission belt 416, the circular arc surface of the rotating rod 414 is in threaded connection with a sliding frame 413, one side of the sliding frame 413 close to the imaging plate 2 is fixedly connected with a supporting rod 412, one end of the supporting rod 412 away from the sliding frame 413 is fixedly connected with the mounting frame 6, the surface of the supporting rod 412 is in sliding connection with the side wall of the guide frame 3, the limiting component 42 comprises a driving motor 421, one side of the driving motor 421 is fixedly connected with the side surface of the inner wall of the mounting frame 6, the output end of the driving motor 421 is fixedly connected with a driving rod 422, one end of the driving rod 422 far away from the driving motor 421 is rotationally connected with the inner wall surface of the mounting frame 6, threads with opposite thread directions are arranged at two ends of the driving rod 422, driving frames 423 are penetrated through by threads at two ends of the driving rod 422, two rotating plates 426 are rotationally connected at two ends of the two driving frames 423, one end of the four rotating plates 426 far away from the driving frames 423 is rotationally connected with a connecting plate 427, the section of the connecting plate 427 is L-shaped, each two of the four connecting plates 427 is a group, one side of each group of connecting plates 427 is fixedly connected with the imaging plate 2, two sides of the inner wall of the mounting frame 6 are fixedly connected with auxiliary rods 425, two ends of the auxiliary rods 425 are respectively and slidably penetrated with sliding blocks 424, one side of each sliding block 424 is respectively fixedly connected with two ends of the driving frames 423, the inner wall of each sliding block 424 is fixedly connected with a protecting sleeve 428, the inner wall of the protective sleeve 428 is slidably coupled to the surface of the auxiliary rod 425.

Referring to fig. 4, 7 and 8, in this embodiment: the auxiliary device 5 comprises a direct current motor 51, one side of the direct current motor 51 is fixedly connected with a bearing frame 1, the output end of the direct current motor 51 is in transmission connection with a second transmission belt 53, one end of the second transmission belt 53, which is far away from the direct current motor 51, is in transmission connection with a transmission shaft 52, the inner wall of the transmission shaft 52 is fixedly connected with a rotating column 54, the rotating column 54 is a telescopic column, the arc surface of the rotating column 54 is provided with damping, both ends of the rotating column 54 are fixedly connected with travelling wheels 55, the arc surface of the travelling wheels 55 is fixedly connected with an anti-slip sleeve 56, anti-slip patterns are formed on the surfaces of the anti-slip sleeve 56, the positions, corresponding to the travelling wheels 55, of the surfaces of both sides of a guide frame 3 are fixedly connected with motors 57, the output ends of the motors 57 are fixedly connected with rotating frames 58, and one ends of the rotating frames 58 are rotationally connected with holding wheels 59.

Referring to fig. 9 and 10, in the present embodiment: the interval adjusting component 7 comprises a second servo motor 71, one side of the second servo motor 71 is fixedly connected with a bearing frame 1, the output end of the second servo motor 71 is fixedly connected with a screw rod 72, one end of the screw rod 72, which is far away from the second servo motor 71, is rotationally connected with a connecting block 74, the lower surface of the connecting block 74 is fixedly connected with the bearing frame 1, the circular arc surface of the screw rod 72 is provided with threads with opposite thread directions, both ends of the screw rod 72 are respectively and fixedly connected with a movable frame 73, the two movable frames 73 are respectively and fixedly connected with a first mounting frame 10 and a second mounting frame 11, both end inner walls of the bearing frame 1 are respectively and fixedly connected with sliding rails 75, both end inner walls of the sliding rails 75 are respectively and fixedly connected with sliding blocks 76, and the two sliding blocks 76 are respectively and fixedly connected with the first mounting frame 10 and the second mounting frame 11.

The use method is as follows: in the X-ray detection process of the high-voltage cable, the whole imaging equipment is firstly lifted to the position corresponding to the high-voltage cable by using a large unmanned aerial vehicle, the imaging board 2 is irradiated by using a light emitter arranged on the small unmanned aerial vehicle through guiding and fixing between a guide frame 3 at the bottom end of a bearing frame 1 and the cable, so that X-ray flaw detection operation of the high-voltage cable is carried out, in the process, the situation that the position of the imaging board 2 is required to be continuously replaced and regulated is caused because the common high-voltage cable is more in splitting, so that flaw detection is inconvenient to be carried out on the multi-split high-voltage cable is caused, in the process, the lifting component 41 and the limiting component 42 in a universal regulating device 4 can be carried out in an auxiliary operation mode, a first servo motor 415 is started, the output end of the first servo motor 415 drives a first driving belt 416 to rotate, and then the first driving belt 416 drives a rotating rod 414 in a supporting frame 411 to rotate, so that the rotating rod 414 in the supporting frame 411 drives the sliding frame 413 on the surface to move up and down, one side of the sliding frame 413 is fixed with the supporting rod 412, so that the supporting rod 412 is used for driving the lifting adjustment of the position of the whole mounting frame 6, in order to facilitate the telescopic movement of the positions of the imaging plates 2 on two sides of the mounting frame 6, so that the imaging plates 2 perform detection imaging on multiple wires, at the moment, the driving motor 421 in the inner wall of the mounting frame 6 is started, the driving motor 421 drives the driving rod 422 to rotate, so that the driving rod 422 drives the driving frames 423 on two ends to perform the movement adjustment of the positions, at the moment, the driving frames 423 drive the rotating plates 426 on two ends to perform the position deflection, so that the two imaging plates 2 move towards the positions of the high-voltage cable, in the process, the auxiliary rods 425 fixed on two ends of the mounting frame 6 slide with the sliding blocks 424 on two ends of the driving frames 423, the moving position of the whole driving frame 423 can be effectively limited and fixed, and the deflection movement of the position of the imaging plate 2 can be effectively avoided.

After placing whole carriage 1 on the wire surface, in order to conveniently remove spacingly to the position of whole carriage 1, at this moment through the direct current motor 51 of carriage 1 bottom surface, let direct current motor 51 drive the rotation of transmission shaft 52, thereby let transmission shaft 52 drive the walking wheel 55 at the pivoted post 54 both ends slide along the wire, thereby effectively conveniently regulate and control the position of whole carriage 1, when carrying out the walking wheel 55 and the wire of carriage 1 both sides, in order to avoid wire and walking wheel 55 to take place to drop, start motor 57 this moment, let motor 57 drive rotating frame 58 and rotate, thereby let rotating in the rotating frame 58 hold and be close to each other between wheel 59 and the walking wheel 55, can lock spacingly with the wire.

In the process that the guide frame 3 with the cross section in the shape of V is required to be placed on a high-voltage cable, because the intervals between the split cables are different, the positions of the travelling wheels 55 in the first installation frame 10 and the second installation frame 11 at the upper end of the guide frame 3 are required to be adjusted, the second servo motor 71 drives the screw rod 72 to rotate at the moment, the moving frame 73, which is fixed with the first installation frame 10 and the second installation frame 11, at the two ends of the screw rod 72 is driven to move, the whole guide frame 3 deflects between the first installation frame 10 and the second installation frame 11, meanwhile, the first installation frame 10 and the second installation frame 11 slide through the sliding rail 75 and the sliding block 76 of the inner wall of the bearing frame 1, so that the positions of the first installation frame 10 and the second installation frame 11 are required to be limited and fixed in a sliding mode, and the intervals between the travelling wheels 55 on the surface of the guide frame 3 can be conveniently and effectively adjusted.

Claims (7)

1. The utility model provides a many split conductor X-ray detection device, includes loading frame (1), its characterized in that: the utility model discloses a portable electronic device is characterized in that an electric control box (8) is installed on one side of the inner wall of a bearing frame (1), hanging hooks (9) are fixedly connected to two sides of the upper surface of the bearing frame (1), a guide frame (3) is arranged at the bottom end of the bearing frame (1), the cross section of the guide frame (3) is in a V shape, a first installation frame (10) and a second installation frame (11) are respectively arranged on two sides of the bearing frame (1), two ends of the first installation frame (10) and the second installation frame (11) are respectively connected with the side wall of the guide frame (3) in a rotating mode, a mounting frame (6) is arranged on one side of the bearing frame (1), imaging plates (2) are respectively arranged on two side surfaces of the mounting frame (6), an adjusting device (4) is arranged at the position, corresponding to the inner wall of the guide frame (3), and the bottom surface of the bearing frame (1) is provided with an adjusting device (4) comprising a lifting assembly (41) and a limiting assembly (42).

2. The multi-split wire X-ray inspection apparatus of claim 1, wherein: lifting component (41) are including carriage (411), the upper surface of carriage (411) is connected with the lower fixed surface who bears frame (1), the first servo motor (415) of bottom one side fixedly connected with of carriage (411), the inner wall both ends rotation of carriage (411) are connected with same dwang (414), the bottom of dwang (414) is connected with same first drive belt (416) with the output transmission of first servo motor (415), the arc surface threaded connection of dwang (414) has carriage (413), one side fixedly connected with bracing piece (412) that carriage (413) are close to imaging plate (2), the one end and the installation frame (6) fixed connection of carriage (413) are kept away from to bracing piece (412), the surface and the lateral wall sliding connection of guide frame (3) of bracing piece (412).

3. The multi-split wire X-ray inspection apparatus of claim 1, wherein: limiting component (42) are including driving motor (421), one side of driving motor (421) and the inner wall side fixed connection of installing frame (6), the output fixedly connected with actuating lever (422) of driving motor (421), the one end that actuating lever (422) kept away from driving motor (421) is rotated with the inner wall surface of installing frame (6) and is connected, the screw thread opposite in direction has been seted up at the both ends of actuating lever (422), the equal screw thread in both ends of actuating lever (422) runs through there is actuating frame (423), two the both ends of actuating frame (423) all rotate and are connected with two dwang (426), four the one end that dwang (426) kept away from actuating frame (423) is all rotated and is connected with link up board (427), the cross-section of link up board (427) is "L" shape, four every two are a set of link up board (427) one side of linking board (427) all with imaging plate (2) fixed connection, the equal fixedly connected with in both sides of the inner wall of installing frame (6) is connected with auxiliary rod (424), both ends of two slider (425) are connected with both ends of auxiliary rod (424) respectively.

4. A multi-split wire X-ray inspection apparatus according to claim 3, wherein: the inner wall of the sliding block (424) is fixedly connected with a protective sleeve (428), and the inner wall of the protective sleeve (428) is in sliding connection with the surface of the auxiliary rod (425).

5. The multi-split wire X-ray inspection apparatus of claim 1, wherein: the utility model discloses a motor vehicle, including frame (1) and bearing frame, the bottom surface both sides of bearing frame (1) are equipped with auxiliary device (5), auxiliary device (5) include direct current motor (51), one side and the bearing frame (1) fixed connection of direct current motor (51), the output transmission of direct current motor (51) is connected with second drive belt (53), the one end transmission that direct current motor (51) was kept away from to second drive belt (53) is connected with transmission shaft (52), the inner wall fixedly connected with of transmission shaft (52) rotates post (54), rotate post (54) and be the telescopic column, the arc surface of rotating post (54) is equipped with the damping, the equal fixedly connected with walking wheel (55) in both ends of rotating post (54), the equal fixedly connected with anti-skidding cover (56) of arc surface of walking wheel (55), anti-skidding line has been seted up on the surface of anti-skidding cover (56).

6. The multi-split wire X-ray inspection apparatus according to claim 5, wherein: the two sides of the guiding frame (3) are fixedly connected with motors (57) corresponding to the positions of the travelling wheels (55), the output ends of the motors (57) are fixedly connected with rotating frames (58), and one ends of the rotating frames (58) are rotatably connected with holding wheels (59).

7. The multi-split wire X-ray inspection apparatus according to claim 5, wherein: the inner wall surface of bearing frame (1) is equipped with interval adjustment subassembly (7), interval adjustment subassembly (7) include second servo motor (71), one side and bearing frame (1) fixed connection of second servo motor (71), the output fixedly connected with lead screw (72) of second servo motor (71), the one end rotation that second servo motor (71) was kept away from to lead screw (72) is connected with connecting block (74), the lower surface and the bearing frame (1) fixed connection of connecting block (74), the screw thread opposite in screw thread direction has been seted up to the arc surface of lead screw (72), the equal threaded connection in both ends of lead screw (72) has movable frame (73), two respectively with first mounting bracket (10) and second mounting bracket (11) fixed connection, the equal sliding connection in both ends inner wall of bearing frame (1) has sliding block (76), two sliding block (76) respectively with first (10) and second mounting bracket (11) fixed connection.