CN221145893U - Triaxial movable nondestructive testing equipment mounting bracket - Google Patents

Abstract

The utility model discloses a triaxial movable nondestructive testing equipment mounting bracket which comprises a movable trolley, a shearing fork structure, a driving structure, a supporting plate and a mounting plate, wherein the supporting plate is arranged above the movable trolley, the shearing fork structure is arranged between the supporting plate and the movable trolley and is respectively in rotary connection with the supporting plate and the movable trolley, the mounting plate is arranged above the supporting plate and is in rotary connection with the supporting plate through a rotary bearing, the driving structure is arranged on the movable trolley and is matched with the shearing fork structure for driving the shearing fork structure to ascend or descend, and the problems that the conventional mounting bracket is inconvenient to move and inconvenient to adjust in height when in use, so that the process of detecting workpieces by using the nondestructive testing equipment is complicated are solved.

Description

Triaxial movable nondestructive testing equipment mounting bracket

Technical Field

The utility model relates to the technical field of workpiece detection, in particular to a triaxial movable nondestructive detection equipment mounting bracket.

Background

Nondestructive testing is one of the most common means in the current testing industry, with many nondestructive testing devices being commonly used, such as: the portable X-ray machine can detect whether the workpiece is qualified under the condition that the workpiece is not damaged by the portable X-ray machine, but during detection, the workpiece is usually fixed and then can be detected, and the moving process is troublesome, so that different positions of the workpiece are detected by moving the portable X-ray machine in general.

At present, a portable X-ray machine is usually required to be matched with a mounting bracket, but most of the mounting brackets at present are manually carried to a designated position by the mounting bracket and the portable X-ray machine at present, and the height of the mounting bracket at present cannot be adjusted by adopting a fixed type, so that various gaskets are required to be added when the shape and the size of a workpiece are changed, the portable X-ray machine can be positioned at the designated detection position, and the mounting bracket at present has the problems of inconvenient movement and inconvenient height adjustment during use, thereby causing complicated detection process of the workpiece by using nondestructive detection equipment.

The application number is: 202220825022.1, publication number CN217766283U discloses a nondestructive test equipment installing support, including the installation component, the installation component includes mounting panel, mounting bracket, roll adjustment spare, connecting axle and detection piece, be fixed with the mounting bracket on the mounting panel, but it still exists the installing support when using, has to remove inconvenient and inconvenient height-adjusting to lead to the problem that the process that uses nondestructive test equipment to the work piece detects is loaded down with trivial details.

Disclosure of utility model

Based on the problems, the utility model provides the mounting bracket of the triaxial movable nondestructive testing equipment, which solves the problems that the existing mounting bracket is inconvenient to move and inconvenient to adjust in height when in use, so that the process of detecting a workpiece by using the nondestructive testing equipment is complicated.

The technical scheme of the utility model is as follows:

The mounting bracket comprises a movable trolley, a shearing fork structure, a driving structure, a supporting plate and a mounting plate, wherein the supporting plate is arranged above the movable trolley;

The shearing fork structure comprises a pair of shearing fork arms, each shearing fork arm comprises a first support arm and a second support arm, the middle parts of the first support arm and the second support arm are rotationally connected through a pin shaft, one end of each first support arm is provided with a first sliding block, the first support arm is rotationally connected with the first sliding block, the first sliding block is in sliding connection with the mobile cart, the other end of each first support arm is provided with a first connecting piece, the first support arm is rotationally connected with the first connecting piece, and the first connecting piece is arranged at the bottom of the supporting plate;

The second support arm one end is equipped with the second connecting piece, the second support arm rotates with the second connecting piece to be connected, the second connecting piece sets up on the removal shallow, the second support arm other end is equipped with the second sliding block, the second support arm rotates with the second sliding block to be connected, second sliding block and backup pad bottom sliding connection.

Preferably, the mobile cart comprises a frame, a pushing handle, a connecting plate and a mobile assembly, wherein an opening which is communicated from top to bottom is formed in the frame, the connecting plate is arranged at two ends of the bottom of the frame, the mobile assembly is arranged on the connecting plate, a lug is arranged at one end of the frame, and the pushing handle is detachably connected with the lug through a bolt.

Preferably, the moving assembly comprises four sliding wheels, and two sliding wheels are arranged on each connecting plate.

Preferably, the sliding wheel adopts a universal brake wheel.

Preferably, a first sliding groove is formed in the inner wall of the frame, and the first sliding block is installed in the first sliding groove and is in sliding fit with the first sliding groove.

Preferably, a second sliding groove is formed in the inner wall side of the bottom of the supporting plate, and the second sliding block is installed in the second sliding groove and is in sliding connection with the second sliding groove.

Preferably, a connecting shaft and a rotating shaft are arranged between the two shearing fork arms, two ends of the connecting shaft are respectively connected with the second support arm in the two shearing fork arms, the second support arm is positioned on one side, close to the mobile cart, of the second support arm, and two ends of the rotating shaft are respectively connected with the pin shafts in the two shearing fork arms.

Preferably, the driving structure is a pedal hydraulic jack, and the pedal hydraulic jack comprises a jack main body, a first pedal arranged on the jack main body and used for increasing hydraulic pressure in the jack main body and a second pedal used for discharging hydraulic pressure in the jack main body, wherein the jack main body is arranged in a frame, the first pedal extends to one end of a push handle on the frame and is hinged with the frame through a first hinge, and the second pedal extends to one side of the frame and is hinged with the frame through a second hinge.

Preferably, the telescopic end of the jack body is hinged with the connecting shaft through a third hinge.

Compared with the prior art, the utility model has the beneficial effects that:

When the device is used, the driving structure drives the scissor structure to ascend or descend, so that the supporting plate hinged with the scissor structure ascends or descends, the mounting plate connected with the supporting plate through the rotating bearing is driven to ascend or descend, nondestructive testing equipment mounted on the mounting plate ascends or descends, and the height of the nondestructive testing equipment is adjusted.

The movable trolley is arranged, so that the nondestructive testing equipment can be moved to the specified detection position through the movable trolley when the detection position of the workpiece is required to be changed, the nondestructive testing equipment is not required to be manually carried, and the movement of the nondestructive testing equipment is facilitated.

Meanwhile, the mounting plate is rotationally connected with the supporting plate through the rotating bearing, and the angle of the nondestructive testing equipment can be adjusted by rotating the mounting plate, so that the device is suitable for the change of the position of a workpiece and the change of the shape of the workpiece to a certain extent.

The mounting bracket can realize triaxial movement, can adapt to the change of the size and the shape of a workpiece to a certain extent, has the advantages of simple structure, convenient operation and flexible adjustment, can effectively improve the efficiency of nondestructive detection, and is suitable for various nondestructive detection devices.

The problem of present installing support when using, have to remove inconvenient and inconvenient height-adjusting to lead to using nondestructive test equipment to the process of work piece detection loaded down with trivial details is solved.

Drawings

FIG. 1 is a schematic view of a three-axis movable nondestructive testing device mounting rack according to an embodiment of the present utility model;

FIG. 2 is a schematic view of a hidden mounting plate of a mounting bracket for a triaxial movable nondestructive testing device according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram showing a hidden mounting plate of a mounting bracket of a triaxial movable nondestructive testing device according to a second embodiment of the present utility model;

FIG. 4 is a schematic diagram II of a mounting bracket for a triaxial movable nondestructive testing device according to an embodiment of the present utility model;

FIG. 5 is a schematic diagram of a three-axis movable nondestructive testing device mounting bracket according to an embodiment of the present utility model;

FIG. 6 is a schematic diagram of a mounting bracket for a triaxial movable nondestructive testing device according to an embodiment of the present utility model;

FIG. 7 is a schematic diagram showing a three-axis movable nondestructive testing device mounting rack according to an embodiment of the present utility model;

Reference numerals illustrate:

10-mobile cart, 100-frame, 101-push handle, 102-connecting plate, 103-mobile assembly, 104-bump, 105-first sliding groove, 20-scissor structure, 21-scissor arm, 200-first support arm, 201-second support arm, 202-first sliding block, 203-first connector, 204-second connector, 205-second sliding block, 206-connecting shaft, 207-rotating shaft, 30-driving structure, 300-jack main body, 301-first pedal, 302-second pedal, 303-first hinge, 304-second hinge, 305-third hinge, 40-support plate, 400-second sliding groove, 50-mounting plate, 51-rotating bearing, 60-clamping member, 600-mounting seat, 601-bi-directional counter screw, 602-sliding block, 603-rotating handle, 604-clamping portion, 605-fitting portion, 606-placing plate.

Detailed Description

Embodiments of the present utility model will be described in detail below with reference to the accompanying drawings.

Examples:

As shown in fig. 1 to 4, in order to solve the above problems, the present embodiment discloses a triaxial movable nondestructive inspection apparatus mounting bracket, which comprises a movable cart 10, a scissor structure 20, a driving structure 30, a support plate 40 and a mounting plate 50, wherein the support plate 40 is arranged above the movable cart 10, the scissor structure 20 is arranged between the support plate 40 and the movable cart 10 and is respectively in rotational connection with the support plate 40 and the movable cart 10, the mounting plate 50 is arranged above the support plate 40 and is in rotational connection with the support plate 40 through a rotary bearing 51, and the driving structure 30 is arranged on the movable cart 10 and is matched with the scissor structure 20 for driving the scissor structure 20 to ascend or descend;

The scissors structure 20 comprises a pair of scissors arms 21, the scissors arms 21 comprise a first support arm 200 and a second support arm 201, the middle parts of the first support arm 200 and the second support arm 201 are rotationally connected through a pin shaft, one end of the first support arm 200 is provided with a first sliding block 202, the first support arm 200 is rotationally connected with the first sliding block 202, the first sliding block 202 is slidingly connected with the mobile cart 10, the other end of the first support arm 200 is provided with a first connecting piece 203, the first support arm 200 is rotationally connected with the first connecting piece 203, and the first connecting piece 203 is arranged at the bottom of the supporting plate 40;

The second support arm 201 has a second connecting piece 204 at one end, the second support arm 201 is rotatably connected with the second connecting piece 204, the second connecting piece 204 is disposed on the mobile cart 10, a second sliding block 205 is disposed at the other end of the second support arm 201, the second support arm 201 is rotatably connected with the second sliding block 205, and the second sliding block 205 is slidably connected with the bottom of the support plate 40.

When in use, the driving structure 30 drives the scissor structure 20 to ascend or descend, so that the supporting plate 40 hinged with the scissor structure 20 ascends or descends, the mounting plate 50 connected with the supporting plate 40 through the rotating bearing 51 is driven to ascend or descend, and further the nondestructive testing equipment mounted on the mounting plate 50 ascends or descends, and the height of the nondestructive testing equipment is adjusted.

By arranging the movable trolley 10, the nondestructive testing equipment can be moved to the specified detection position by the movable trolley 10 when the detection position of the workpiece is required to be changed, the nondestructive testing equipment is not required to be manually carried, and the movement of the nondestructive testing equipment is facilitated.

Meanwhile, the mounting plate 50 is rotationally connected with the supporting plate 40 through the rotary bearing 51, and the angle of the nondestructive testing equipment can be adjusted by rotating the mounting plate 50 so as to adapt to the change of the position of the workpiece and the change of the shape of the workpiece to a certain extent.

The mounting bracket can realize triaxial movement, can adapt to the change of the size and the shape of a workpiece to a certain extent, has the advantages of simple structure, convenient operation and flexible adjustment, can effectively improve the efficiency of nondestructive detection, and is suitable for various nondestructive detection devices.

The problem of present installing support when using, have to remove inconvenient and inconvenient height-adjusting to lead to using nondestructive test equipment to the process of work piece detection loaded down with trivial details is solved.

The swivel bearing 51 includes a swivel bearing and a swivel shaft, and the bottom of the swivel shaft is inserted into the swivel bearing, so that relative rotation between the swivel shaft and the swivel bearing can be achieved.

As shown in fig. 1 to 4, in order to facilitate the fixing of the nondestructive testing device, this embodiment is modified based on the above embodiment, and is different from the above embodiment in that the mobile cart 10 includes a frame 100, a pushing handle 101, a connecting plate 102, and a moving assembly 103, where the frame 100 is provided with an opening penetrating from top to bottom, the connecting plate 102 is disposed at two ends of the bottom of the frame 100, the moving assembly 103 is disposed on the connecting plate 102, one end of the frame 100 is provided with a bump 104, and the pushing handle 101 is detachably connected with the bump 104 through a bolt.

Preferably, the moving assembly 103 includes four pulleys, and two pulleys are provided on each connecting plate 102.

Preferably, the sliding wheel adopts a universal brake wheel.

When the nondestructive testing device is used, the movable trolley 10 can be pushed manually, after the movable trolley 10 moves to a designated position with nondestructive testing equipment, the universal brake wheel is fixed through the brake on the universal brake wheel, and then the movable trolley 10 and the whole mounting bracket in the nondestructive testing device are fixed, so that the nondestructive testing device can conveniently detect a workpiece.

In order to facilitate the lifting and the falling of the scissors structure 20 to be more stable, this embodiment is modified on the basis of the above embodiment, and is different from the above embodiment in that a first sliding groove 105 is provided on an inner wall of the frame 100, and the first sliding block 202 is installed in the first sliding groove 105 and is slidably engaged with the first sliding groove 105.

Preferably, a second sliding groove 400 is provided on the bottom inner wall side of the support plate 40, and the second sliding block 205 is installed in the second sliding groove 400 and slidably connected to the second sliding groove 400.

Preferably, a connecting shaft 206 and a rotating shaft 207 are arranged between the two scissor arms 21, two ends of the connecting shaft 206 are respectively connected with the second support arm 201 in the two scissor arms 21, the second support arm 201 is positioned at one side close to the mobile cart 10, and two ends of the rotating shaft 207 are respectively connected with the pin shafts in the two scissor arms 21.

When in use, the scissor structure 20 is driven by the driving structure 30, so that the first sliding block 202 slides in the first sliding groove 105, and the second sliding block 205 slides in the second sliding groove 400, so that the scissor can be lifted or lowered, and the lifting or lowering of the scissor structure 20 is more stable due to the cooperation of the sliding blocks and the sliding grooves.

As shown in fig. 5 to 6, in order to better drive the scissor structure 20 to ascend or descend, this embodiment is modified based on the above embodiment, and is different from the above embodiment in that the driving structure 30 adopts an electro-hydraulic telescopic rod, and a telescopic end of the electro-hydraulic telescopic rod is rotatably connected with the connecting shaft 206, so that the electro-hydraulic telescopic rod drives the scissor structure 20 to ascend or descend when driving the connecting shaft 206 to move.

As shown in fig. 1 to 4, in order to enable the raising or lowering of the scissors structure 20 without inserting electricity, and solve the problem of the interference detection process caused by the power outage or the winding of the power transmission line, the present embodiment is modified on the basis of the above-described embodiment, and is different from the above-described embodiment in that the driving structure 30 is a foot-operated hydraulic jack, including a jack body 300, a first foot 301 for increasing the hydraulic pressure in the jack body 300 and a second foot 302 for releasing the hydraulic pressure in the jack body 300, which are provided on the jack body 300, are provided in the frame 100, the first foot 301 extends to one end of the push handle 101 of the frame 100 and is hinged with the frame 100 through a first hinge 303, and the second foot 302 extends to one side of the frame 100 and is hinged with the frame 100 through a second hinge 304.

Preferably, the telescopic end of the jack body 300 is hinged to the connection shaft 206 by a third hinge 305.

When the jack is used, the jack main body 300 can be driven to the third connecting shaft 206 by continuously treading the first pedal 301 by manpower, the scissor structure 20 is driven to ascend, the second pedal 302 is manually treaded, the jack main body 300 is driven to the third connecting shaft 206, the scissor structure 20 is driven to descend, and the height adjustment of the nondestructive testing tool is realized.

The driving structure 30 is a pedal hydraulic jack, and the pedal hydraulic jack adopts a pedal hydraulic jack or a pedal hydraulic jack in the prior art.

As shown in fig. 7, when a workpiece is inspected, a part of nondestructive inspection equipment needs to be fixed, in order to facilitate fixing of the nondestructive inspection tool, this embodiment is modified based on the above embodiment, and is different from the above embodiment in that a clamping piece 60 for clamping the nondestructive inspection tool is provided at the top of the mounting plate 50, the clamping piece 60 includes a mounting seat 600 provided at the top of the mounting plate 50, a bidirectional counter screw 601 is provided in the mounting seat 600, a positive thread and a counter thread are provided on the bidirectional counter screw 601, a pair of sliders 602 are provided on the bidirectional counter screw 601, one of the sliders 602 is in threaded engagement with the positive thread, the other slider 602 is in threaded engagement with the counter thread, two ends of the bidirectional counter screw 601 penetrate the mounting seat 600 respectively and are in rotational connection with the mounting seat 600, a rotating handle 603 is provided at one end of the bidirectional counter screw 601, a clamping portion 604 is provided on the clamping portion 604, a pair of placing plates 606 are provided on the mounting seat 600 in engagement with the clamping portion 604, and the two placing plates 604 are located between the two placing plates 606 in threaded engagement with the sliding engagement.

Preferably, the mounting base 600 is detachably connected to the mounting plate 50 by bolts.

Preferably, the fitting portion 605 is a sponge.

When the nondestructive testing device is used, the rotating handle 603 can be rotated to drive the bidirectional inverted wire screw 601 to rotate, so that two sliding blocks 602 on the bidirectional inverted wire screw 601 move at the middle part or two ends of the bidirectional inverted wire screw 601 at the same time, and the clamping part 604 can clamp or loosen the nondestructive testing device.

The working principle of the utility model is as follows:

When in use, the driving structure 30 drives the scissor structure 20 to ascend or descend, so that the supporting plate 40 hinged with the scissor structure 20 ascends or descends, the mounting plate 50 connected with the supporting plate 40 through the rotating bearing 51 is driven to ascend or descend, and further the nondestructive testing equipment mounted on the mounting plate 50 ascends or descends, and the height of the nondestructive testing equipment is adjusted.

By arranging the movable trolley 10, the nondestructive testing equipment can be moved to the specified detection position by the movable trolley 10 when the detection position of the workpiece is required to be changed, the nondestructive testing equipment is not required to be manually carried, and the movement of the nondestructive testing equipment is facilitated.

Meanwhile, the mounting plate 50 is rotationally connected with the supporting plate 40 through the rotary bearing 51, and the angle of the nondestructive testing equipment can be adjusted by rotating the mounting plate 50 so as to adapt to the change of the position of the workpiece and the change of the shape of the workpiece to a certain extent.

The foregoing examples merely illustrate specific embodiments of the utility model, which are described in greater detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model.

Claims (9)

1. The utility model provides a but triaxial removes nondestructive test equipment installing support, its characterized in that, including removal shallow (10), cut fork structure (20), drive structure (30), backup pad (40) and mounting panel (50), backup pad (40) set up in removal shallow (10) top, cut fork structure (20) set up between backup pad (40) and removal shallow (10), and respectively with backup pad (40) and removal shallow (10) rotate to be connected, mounting panel (50) set up in backup pad (40) top, and rotate to be connected with backup pad (40) through swivel bearing (51), drive structure (30) set up on removal shallow (10), and with cut fork structure (20) cooperation setting for drive cut fork structure (20) rise or decline;

The scissors structure (20) comprises a pair of scissors arms (21), the scissors arms (21) comprise a first support arm (200) and a second support arm (201), the middle parts of the first support arm (200) and the second support arm (201) are rotationally connected through a pin shaft, a first sliding block (202) is arranged at one end of the first support arm (200), the first support arm (200) is rotationally connected with the first sliding block (202), the first sliding block (202) is in sliding connection with the mobile cart (10), a first connecting piece (203) is arranged at the other end of the first support arm (200), the first support arm (200) is rotationally connected with the first connecting piece (203), and the first connecting piece (203) is arranged at the bottom of the supporting plate (40);

second support arm (201) one end is equipped with second connecting piece (204), second support arm (201) and second connecting piece (204) rotate to be connected, second connecting piece (204) set up on removal shallow (10), second support arm (201) other end is equipped with second sliding block (205), second support arm (201) and second sliding block (205) rotate to be connected, second sliding block (205) and backup pad (40) bottom sliding connection.

2. The triaxial mobile nondestructive testing equipment mounting bracket according to claim 1, wherein the mobile trolley (10) comprises a frame (100), a push handle (101), a connecting plate (102) and a mobile assembly (103), wherein an opening which is arranged in a penetrating manner from top to bottom is formed in the frame (100), the connecting plate (102) is arranged at two ends of the bottom of the frame (100), the mobile assembly (103) is arranged on the connecting plate (102), a bump (104) is arranged at one end of the frame (100), and the push handle (101) is detachably connected with the bump (104) through bolts.

3. A triaxial mobile nondestructive inspection apparatus mounting according to claim 2, wherein the mobile assembly (103) includes four pulleys, two on each web (102).

4. A triaxial movable nondestructive testing equipment mounting bracket according to claim 3, wherein the sliding wheels are universal brake wheels.

5. The triaxial movable nondestructive inspection equipment mounting bracket according to claim 4, wherein a first sliding groove (105) is formed in the inner wall of the frame (100), and the first sliding block (202) is mounted in the first sliding groove (105) and is in sliding fit with the first sliding groove (105).

6. The triaxial movable nondestructive inspection apparatus mounting bracket according to claim 5, wherein a second sliding groove (400) is provided on the bottom inner wall side of the support plate (40), and the second sliding block (205) is mounted in the second sliding groove (400) and is slidably connected to the second sliding groove (400).

7. The triaxial movable nondestructive testing equipment mounting bracket according to claim 2, wherein a connecting shaft (206) and a rotating shaft (207) are arranged between the two shearing arms (21), two ends of the connecting shaft (206) are respectively connected with the second support arm (201) in the two shearing arms (21), the second support arm (201) is positioned at one side close to the movable cart (10), and two ends of the rotating shaft (207) are respectively connected with pin shafts in the two shearing arms (21).

8. The triaxial movable nondestructive inspection equipment mounting bracket according to claim 7, wherein the driving structure (30) is a pedal hydraulic jack, and comprises a jack main body (300), a first pedal (301) arranged on the jack main body (300) and used for increasing hydraulic pressure in the jack main body (300), and a second pedal (302) used for discharging hydraulic pressure in the jack main body (300), wherein the jack main body (300) is arranged in the frame (100), the first pedal (301) extends to one end of a push handle (101) on the frame (100) and is hinged with the frame (100) through a first hinge (303), and the second pedal (302) extends to one side of the frame (100) and is hinged with the frame (100) through a second hinge (304).

9. The triaxial movable nondestructive inspection apparatus mounting bracket according to claim 8, wherein the telescopic end of the jack main body (300) is hinged to the connecting shaft (206) by a third hinge (305).