CN211877815U - Gamma-ray flaw detection simulation equipment - Google Patents

Abstract

The utility model discloses a gamma ray flaw detection simulation equipment includes: the device comprises a workbench, a transmission device and a group of pillars, wherein the transmission device and the group of pillars are fixedly connected with the upper surface of the workbench; the transport subassembly sets up including the symmetry a set of support on the workstation is installed U template on the support, with U template fixed connection's transport motor sets up the rotation connecting rod of transport motor output is installed rotate the drive division on the connecting rod, with drive division fixed connection's perpendicular slide rail, and set up the clamping part of the perpendicular slide rail other end, and then when realizing device handling, can also reduce the device and measure the collision between the object, reduce artificial damage to measuring the object.

Description

Gamma-ray flaw detection simulation equipment

Technical Field

The utility model belongs to the technical field of the equipment of detecting a flaw, specifically a gamma ray flaw detection simulation equipment.

Background

With the wide use of gamma-ray flaw detection equipment, not only can welding seams in equipment pipelines be found in time, but also accident hazards caused by pipeline fracture are reduced, and the life health and safety of personnel are ensured. And the gamma-ray flaw detection equipment can not influence and damage the service performance of the pipeline when carrying out flaw detection on the interior of the pipeline, thereby realizing the nondestructive detection of the device on the pipeline.

However, the existing radiographic inspection equipment still has some problems, the existing radiographic inspection equipment mostly adopts a screw rod transmission mode to complete the conveying work of a pipeline, and then the pipeline is positioned at a correct flaw detection position to complete the flaw detection work, but in the actual working process, the screw rod transmission mode is too slow, so that the working efficiency of a flaw detection device is influenced, meanwhile, the height of the pipeline cannot be adjusted in the conveying process, and then the collision probability between a detected object and the flaw detection device is increased, and further the detected object is damaged manually.

Therefore, how to improve the carrying efficiency of the pipeline in the flaw detection process is a problem to be solved at present.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: the gamma-ray flaw detection simulation equipment is provided to solve the problems in the prior art.

The technical scheme is as follows: a gamma ray inspection simulation apparatus comprising:

the device comprises a workbench, a transmission device and a group of pillars, wherein the transmission device and the group of pillars are fixedly connected with the upper surface of the workbench;

the carrying assembly comprises a set of brackets symmetrically arranged on the workbench, a U-shaped plate arranged on the brackets, a carrying motor fixedly connected with the U-shaped plate, a rotating connecting rod arranged at the output end of the carrying motor, a driving part arranged on the rotating connecting rod, a vertical sliding rail fixedly connected with the driving part, and a clamping part arranged at the other end of the vertical sliding rail.

In a further embodiment, the U-shaped plate is further provided with a horizontal sliding rail and a horizontal sliding block in sliding connection with the horizontal sliding rail, and the horizontal sliding block is connected with the vertical sliding rail, so that the collision between the device and the measured object can be reduced, and the artificial damage can be reduced.

In a further embodiment, the U-shaped plate is provided with a U-shaped groove, and the driving part is positioned in the groove and can move in the groove, so that the device not only can complete the carrying work, but also can ensure the safety of the device in the carrying process.

In a further embodiment, the jacking subassembly is including setting up hydraulic stretching machine on the workstation, with the transmission shaft that the hydraulic stretching machine output is connected, the symmetry sets up a set of jacking gear at transmission shaft both ends, and set up be in drive chain on the jacking gear, and then accomplish the drive work of device, guarantee to be surveyed the smooth jacking of object.

In a further embodiment, the jacking subassembly still includes that the symmetry sets up a set of jacking pillar on the workstation, fixed mounting be in jacking slide rail on the jacking pillar, with jacking slide rail sliding connection's jacking slider, and fixed mounting be in jacking platform on the jacking slider, drive chain one end is connected with the workstation, and the other end then sets up on jacking platform to accomplish the jacking work of device, will be surveyed object jacking to assigned position, accomplish jacking work.

In a further embodiment, the centre gripping subassembly is including setting up flaw detection platform on the pillar sets up the connecting piece on the platform of detecting a flaw is installed connecting plate on the connecting piece, the symmetry is installed a set of connecting rod on the connecting plate sets up grip block on the connecting rod, with connecting plate fixed connection's driving medium, and set up a set of centre gripping motor on the driving medium, still be equipped with two sliding tray on the platform of detecting a flaw, and then can adjust the distance between two centre gripping arms, and then will be measured the object and press from both sides tightly, accomplish the tight work of clamp of device, guarantee that the device can not take place the skew at the in-process of detecting a flaw, and then improve the precision of detecting a flaw.

In a further embodiment, the clamping plate is further provided with a clamping arm, and the clamping arm can move in the sliding groove, so that the distance between the two clamping arms can be conveniently adjusted, and the clamping arm can clamp the measured objects with different sizes.

Has the advantages that: the utility model discloses a gamma-ray flaw detection simulation device, which aims to improve the carrying speed of the device in the carrying process, further, a carrying component is provided, when the device starts to carry, the clamping part clamps the object to be measured, at the moment, the carrying motor starts to work, the moving carrying motor drives the rotating connecting rod to start working, and the moving rotating connecting rod drives the driving part to start working, the driving part starts to move in the U-shaped groove, so as to drive the vertical slide rail to start to move up and down on the horizontal slide block, meanwhile, the vertical slide rail can also apply a force to the horizontal slide block in a horizontal direction, thereby leading the horizontal slide block to start moving on the horizontal slide rail, further transporting the object to be measured to the appointed position, completing the transportation work, and then can also reduce the collision between device and the measurand when realizing device transport work, reduce artificial damage to the measurand.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic view of the jacking assembly of the present invention.

Fig. 3 is a schematic structural view of the carrying assembly of the present invention.

Fig. 4 is an exploded view of the clamping assembly of the present invention.

The reference signs are: the device comprises a workbench 1, a transmission device 2, a transportation table 3, a jacking assembly 4, a jacking support column 401, a jacking slide rail 402, a jacking slide block 403, a jacking platform 404, a hydraulic telescopic machine 405, a transmission shaft 406, a jacking gear 407, a transmission chain 408, a transmitting device 5, a receiving device 6, a conveying assembly 7, a conveying motor 701, a rotating connecting rod 702, a driving part 703, a vertical slide rail 704, a clamping part 705, a horizontal slide block 706, a horizontal slide rail 707, a U-shaped plate 708, a support column 8, a clamping assembly 9, a flaw detection platform 901, a connecting piece 902, a clamping motor 903, a transmission piece 904, a clamping plate 905, a clamping arm 906, a connecting plate 907, a connecting rod 908 and a support 10.

Detailed Description

Through the research and analysis of the applicant, the reason for the problem (too slow transportation, and the inability to adjust the height of the device during the transportation process, which increases the collision probability between the detected object and the flaw detection device, thereby causing the detected object to be damaged artificially) is that most of the existing radiographic inspection equipment adopts the screw transmission mode to complete the transportation work of the pipeline, so that the detected object is positioned at the correct flaw detection position, thereby completing the flaw detection work, but in the actual working process, the screw transmission mode is too slow, thereby affecting the working efficiency of the flaw detection device, the utility model discloses a transportation assembly for improving the transportation speed of the device during the transportation process, when the device starts the transportation work, the clamping part clamps the detected object, at the moment, the transportation motor starts to work, and the moving transportation motor drives the rotating connecting rod to start working, and then the pivoted connecting rod that moves drives drive division and begin work, and then the drive division that moves begins to move in U type inslot, and then drives vertical slide rail and begin the up-and-down motion at horizontal slider, and vertical slide rail still can give horizontal slider a horizontal direction's power simultaneously, and then makes horizontal slider begin the motion on horizontal slide rail to can transport the measured object to the assigned position, accomplish the transport work.

A gamma ray inspection simulation apparatus comprising: the device comprises a workbench 1, a transmission device 2, a transportation table 3, a jacking assembly 4, a jacking support column 401, a jacking slide rail 402, a jacking slide block 403, a jacking platform 404, a hydraulic telescopic machine 405, a transmission shaft 406, a jacking gear 407, a transmission chain 408, a transmitting device 5, a receiving device 6, a conveying assembly 7, a conveying motor 701, a rotating connecting rod 702, a driving part 703, a vertical slide rail 704, a clamping part 705, a horizontal slide block 706, a horizontal slide rail 707, a U-shaped plate 708, a support column 8, a clamping assembly 9, a flaw detection platform 901, a connecting piece 902, a clamping motor 903, a transmission piece 904, a clamping plate 905, a clamping arm 906, a connecting plate 907, a connecting rod 908 and a support 10.

Wherein, the carrying component 7 comprises a vertical slide rail 704 arranged on the clamping part 705, a driving part 703 fixedly arranged on the vertical slide rail 704, a rotating connecting rod 702 arranged on the driving part 703, a carrying motor 701 arranged on the rotating connecting rod 702, a UU template 708 fixedly arranged on the carrying motor 701, a group of supports 10 arranged on the UU template 708, the supports 10 are fixedly arranged on the worktable 1, a transmission device 2 and a group of pillars 8 fixedly arranged on the worktable 1, a jacking component 4 positioned at the tail end of the transmission device 2 and fixedly connected with the worktable 1, a conveying table 3 arranged on the transmission device 2, a transmitting device 5 and a receiving device 6 fixedly arranged on the worktable 1, and a clamping component 9 arranged at the top of the pillars 8, when the device starts carrying work, the clamping part 705 clamps the object to be measured, at this moment, the carrying motor 701 starts to work, and then the moving carrying motor 701 drives the rotating connecting rod 702 to start to work, and then the moving rotating connecting rod 702 drives the driving part 703 to start to work, and then the moving driving part 703 starts to move in the U-shaped groove, and then the vertical sliding rail 704 is driven to start to move up and down at the horizontal sliding block 706, and meanwhile, the vertical sliding rail 704 can also supply a horizontal force to the horizontal sliding block 706, so that the horizontal sliding block 706 starts to move on the horizontal sliding rail 707, thereby the object to be measured can be transported to a designated position, and the carrying work is completed.

The UU-shaped plate 708 is further provided with a horizontal sliding rail 707 and a horizontal sliding block 706 connected with the horizontal sliding rail 707 in a sliding mode, the horizontal sliding block 706 is connected with the vertical sliding rail 704, and therefore the fact that the horizontal sliding rail 707 moves in the vertical direction and the horizontal direction in the year can be brought when the connecting rod 702 rotates is guaranteed, and therefore when the device is carried, collision between the device and a measured object can be reduced, and artificial damage is reduced.

The UU-shaped plate 708 is provided with a U-shaped groove, the driving part 703 is positioned in the groove and can move in the groove, and the driving part 703 can move in a specified area through the U-shaped groove, so that the device can not only complete the carrying work, but also ensure the safety of the device in the carrying process.

The jacking assembly 4 comprises a hydraulic compressor 405 arranged on the workbench 1, a transmission shaft 406 connected with the output end of the hydraulic compressor 405, a group of jacking gears 407 symmetrically arranged at two ends of the transmission shaft 406, and a transmission chain 408 arranged on the jacking gears 407, when the transmission device 2 transports the tested object to a specified position, the hydraulic compressor 405 starts to work, the moving hydraulic compressor 405 drives the transmission shaft 406 to move upwards, the moving transmission shaft 406 drives the jacking gears 407 at two sides to start to work, and the moving jacking gears 407 drive the transmission chain 408 to start to work, so that the driving work of the device is completed, and the tested object is guaranteed to be jacked smoothly.

Jacking subassembly 4 still includes the symmetry and sets up a set of jacking pillar 401 on the workstation 1, fixed mounting is in jacking slide rail 402 on the jacking pillar 401, with jacking slide rail 402 sliding connection's jacking slider 403, and fixed mounting is in jacking platform 404 on the jacking slider 403, drive chain 408 one end is connected with workstation 1, and the other end then sets up on jacking platform 404, starts work when drive chain 408, and then the drive chain 408 of motion drives jacking platform 404 and begins the upward movement, and then drives jacking slider 403 and move on jacking pillar 401 to accomplish the jacking work of device, will be surveyed the object jacking to the assigned position, accomplish jacking work.

The clamping assembly 9 comprises a flaw detection platform 901 arranged on the pillar 8, a connecting piece 902 arranged on the flaw detection platform 901, a connecting plate 907 arranged on the connecting piece 902, a group of connecting rods 908 symmetrically arranged on the connecting plate 907, a clamping plate 905 arranged on the connecting rods 908, a transmission piece 904 fixedly connected with the connecting plate 907, and a group of clamping motors 903 arranged on the transmission piece 904, wherein the flaw detection platform 901 is further provided with two sliding grooves, when the carrying assembly 7 carries a measured object to the flaw detection platform 901, the clamping motors 903 start to work, the working clamping motors 903 drive the transmission piece 904 to start to work, the moving transmission piece 904 drives the clamping plate 905 to start to work, the moving clamping plate 905 drives the connecting rods 908 to start to work, and the connecting plate 907 is enabled to deflect, and then can adjust the distance between two centre gripping arms 906, and then will be surveyed the object and press from both sides tightly, accomplish the tight work of clamp of device, guarantee that the device can not take place the skew at the in-process of detecting a flaw, and then improve the device the precision of detecting a flaw.

Still be equipped with centre gripping arm 906 on the grip block 905, centre gripping arm 906 can the sliding tray internal motion is convenient for adjust the distance between two grip arms 906, makes it can grasp the measurand of equidimension not.

Description of the working principle: when the transmission device 2 transports the object to be tested to a designated position, the hydraulic expansion machine 405 starts working, the moving hydraulic expansion machine 405 drives the transmission shaft 406 to move upwards, the moving transmission shaft 406 drives the jacking gears 407 on both sides to start working, the moving jacking gears 407 drive the transmission chains 408 to start working, and the driving work of the device is completed, so as to ensure the smooth jacking of the object to be tested, when the transmission chains 408 start working, the moving transmission chains 408 drive the jacking platform 404 to start moving upwards, and further drive the jacking slider 403 to move on the jacking strut 401, thereby completing the jacking work of the device, jacking the object to the designated position, completing the jacking work, when the device starts the carrying work, the clamping part 705 clamps the object to be tested, at this moment, the carrying motor 701 starts working, and further the moving carrying motor 701 drives the rotating connecting rod 702 to start working, then the moving rotating connecting rod 702 drives the driving part 703 to start working, and then the moving driving part 703 starts moving in the U-shaped groove, and then drives the vertical sliding rail 704 to start moving up and down on the horizontal sliding block 706, and simultaneously the vertical sliding rail 704 also can apply a horizontal force to the horizontal sliding block 706, so that the horizontal sliding block 706 starts moving on the horizontal sliding rail 707, and thus the object to be measured can be transported to a designated position, and the transportation work is completed, when the transportation component 7 transports the object to be measured to the flaw detection platform 901, the clamping motor 903 starts working at this moment, and then the operating clamping motor 903 drives the transmission part 904 to start working, and then the moving transmission part 904 drives the clamping plate 905 to start working, and then the moving clamping plate 905 drives the connecting rod 908 to start working, so that the connecting plate 907 starts working, and then the connecting plate 907 shifts, and then the distance between the two clamping arms 906 can, and then will be surveyed the object and press from both sides tightly, accomplish the tight work of clamp of device, guarantee that the device can not take place the skew at the in-process of detecting a flaw, and then improve the flaw detection precision of device, emitter 5 and receiving arrangement 6 begin work this moment, and then accomplish the detection work to the measurand, then transport subassembly 7 transports the measurand after detecting to the assigned position to accomplish the work of detecting a flaw.

The preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, however, the present invention is not limited to the details of the above embodiments, and the technical concept of the present invention can be modified to perform various equivalent transformations, which all belong to the protection scope of the present invention.

Claims (7)

1. A gamma ray flaw detection simulation device is characterized by comprising:

the device comprises a workbench, a transmission device and a group of pillars, wherein the transmission device and the group of pillars are fixedly connected with the upper surface of the workbench;

the carrying assembly comprises a set of brackets symmetrically arranged on the workbench, a U-shaped plate arranged on the brackets, a carrying motor fixedly connected with the U-shaped plate, a rotating connecting rod arranged at the output end of the carrying motor, a driving part arranged on the rotating connecting rod, a vertical sliding rail fixedly connected with the driving part, and a clamping part arranged at the other end of the vertical sliding rail.

2. The gamma ray inspection simulation equipment of claim 1, wherein: the U-shaped plate is further provided with a horizontal sliding rail and a horizontal sliding block in sliding connection with the horizontal sliding rail, and the horizontal sliding block is connected with the vertical sliding rail.

3. The gamma ray inspection simulation equipment of claim 1, wherein: the U-shaped plate is provided with a U-shaped groove, and the driving part is positioned in the groove and can move in the groove.

4. The gamma ray inspection simulation equipment of claim 1, wherein: the jacking assembly comprises a hydraulic telescopic machine arranged on the workbench, a transmission shaft connected with the output end of the hydraulic telescopic machine, a group of jacking gears arranged at two ends of the transmission shaft, and a transmission chain arranged on the jacking gears.

5. The gamma ray inspection simulation equipment of claim 4, wherein: jacking subassembly still sets up including the symmetry a set of jacking pillar on the workstation, fixed mounting is in jacking slide rail on the jacking pillar, with jacking slide rail sliding connection's jacking slider, and fixed mounting be in jacking platform on the jacking slider, drive chain one end is connected with the workstation, and the other end then sets up on jacking platform.

6. The gamma ray inspection simulation equipment of claim 1, wherein: the centre gripping subassembly is including setting up flaw detection platform on the pillar sets up connecting piece on the flaw detection platform is installed connecting plate on the connecting piece, the symmetry is installed a set of connecting rod on the connecting plate sets up grip block on the connecting rod, with connecting plate fixed connection's driving medium, and set up a set of centre gripping motor on the driving medium, still be equipped with two sliding trays on the flaw detection platform.

7. The gamma ray inspection simulation equipment of claim 6, wherein: the clamping plate is further provided with a clamping arm, and the clamping arm can move in the sliding groove.

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