CN217603797U - Nondestructive testing device for defects of bridge body - Google Patents

Abstract

The application provides a bridge body defect nondestructive test device belongs to detection device technical field. This bridge beam body defect nondestructive test device, including base subassembly and determine module, base subassembly top fixed mounting has lifting unit, determine module includes lifting block, two fixed blocks, pivot, electric telescopic handle, connecting rod, test rod and actuating mechanism. Through setting up the elevator, the elevator is installed on elevating unit, the pivot is passed through two fixed block settings on the elevator, actuating mechanism drives the pivot rotatory, it is rotatory to realize driving electric telescopic handle, thereby can be rotatory to the level with electric telescopic handle, then swivelling joint pole and gauge rod, angle of adjustment, promote base subassembly, make the gauge rod stretch out to bridge beam body one side, elevating unit can drive the elevator and go up and down, thereby realize driving the gauge rod and go up and down, be convenient for detect, can realize simultaneously that gauge rod and electric telescopic handle accomodate, convenient to use.

Description

Nondestructive testing device for defects of bridge body

Technical Field

The application relates to the field of detection devices, in particular to a nondestructive detection device for defects of a bridge body.

Background

The bridge generally refers to a construction erected on rivers, lakes and seas to enable vehicles, pedestrians and the like to smoothly pass through, and the nondestructive testing refers to a method for inspecting and testing structures, properties and the like inside and on the surface of a test piece on the premise of not damaging or influencing the service performance of a tested object and not damaging the internal tissue of the tested object.

In the related art, the bridge beam body needs to be regularly checked, an existing detection equipment probe needs to be close to the bridge body in the detection process, but the existing equipment probe cannot be stored, the probe is usually installed on a cross beam, then the cross beam extends out of one side of the bridge beam body, the side wall of the bridge beam body is detected through the probe, and the probe and the cross beam cannot be stored, so that the moving space of the whole device is easily limited, the position of the device on the bridge is not convenient to adjust, and inconvenience in use is caused.

SUMMERY OF THE UTILITY MODEL

In order to compensate for above not enough, this application provides a bridge beam body defect nondestructive test device, aims at improving the problem that current detection device probe can not be accomodate.

The embodiment of the application provides a bridge body of a beam defect nondestructive test device, including base subassembly and determine module.

Base subassembly top fixed mounting has a lifting unit, the detection subassembly includes elevator, two fixed blocks, pivot, electric telescopic handle, connecting rod, test bar and actuating mechanism, elevator fixed mounting in on the lifting unit, two the equal fixed mounting of fixed block in on the lateral wall of elevator, the pivot is rotated and is run through two the fixed block, electric telescopic handle's one end with pivot fixed connection, the test bar passes through the connecting rod with electric telescopic handle's the other end rotates to be connected, actuating mechanism fixed mounting in on the lateral wall of elevator, actuating mechanism with the pivot transmission is connected.

In the above-mentioned realization process, through setting up the elevator, the elevator is installed on lifting unit, the pivot is passed through two fixed block settings on the elevator, actuating mechanism drives the pivot rotation, it is rotatory to realize driving electric telescopic handle, thereby can be rotatory to the level with electric telescopic handle, then swivelling joint pole and gauge rod, angle of adjustment, promote base subassembly, make the gauge rod stretch out to bridge beam body one side, lifting unit can drive the elevator and go up and down, thereby realize driving the gauge rod and go up and down, be convenient for detect, can realize simultaneously that gauge rod and electric telescopic handle accomodate, convenient to use.

In a specific embodiment, the base assembly comprises a bottom plate and a plurality of rollers, the rollers are fixedly mounted at the bottom of the bottom plate, and the lifting assembly is fixedly mounted at the top of the bottom plate.

In the implementation process, the bottom of the bottom plate is provided with the roller, so that the bottom plate is convenient to push to move.

In a specific embodiment, the lifting assembly comprises a vertical plate and a lifting mechanism, the vertical plate is fixedly installed on the bottom plate, the lifting mechanism is fixedly installed on the vertical plate, the lifting block is in sliding contact with the vertical plate, a through hole is formed in the vertical plate, and one end of the lifting mechanism penetrates through the through hole and is fixedly connected with the lifting block.

In a specific embodiment, elevating system includes first motor, threaded rod and interior screw block, first motor fixed mounting in on the lateral wall of riser, the threaded rod with the drive shaft fixed connection of first motor, interior screw block thread bush is located on the threaded rod, interior screw block pass through the through-hole with elevator fixed connection.

In a specific embodiment, the lifting mechanism further comprises a mounting block, the mounting block is fixedly mounted on the side wall of the vertical plate, and one end of the threaded rod is rotatably connected with the mounting block.

In the implementation process, the first motor drives the threaded rod to rotate, so that the inner thread block is driven to move on the threaded rod, and the lifting block can be driven to lift.

In a specific embodiment, the driving mechanism comprises a supporting plate, a second motor and a connecting shaft, the second motor is fixedly installed on the side wall of the lifting block through the supporting plate, and the connecting shaft is fixedly connected with a driving shaft of the second motor.

In a specific embodiment, the driving mechanism further comprises a transmission shaft, and the transmission shaft is in transmission connection with both the connection shaft and the rotation shaft.

In a specific embodiment, a sleeve block is fixedly sleeved on the rotating shaft, and one end of the electric telescopic rod is fixedly connected with the sleeve block.

In the implementation process, the second motor drives the rotating shaft to rotate through the connecting shaft and the transmission rod, so that the electric telescopic rod is driven to rotate through the sleeve block.

In a specific embodiment, the connecting shaft and the transmission shaft are respectively fixedly sleeved with a first belt pulley and a second belt pulley, and the first belt pulley is in transmission connection with the second belt pulley.

In a specific embodiment, a first flat gear and a second flat gear are fixedly sleeved on the rotating shaft and the transmission shaft respectively, and the first flat gear is meshed with the second flat gear.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some examples of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also derive other related drawings based on these drawings without inventive effort.

FIG. 1 is a schematic front structural view of a nondestructive testing device for bridge beam defects provided by an embodiment of the present application;

FIG. 2 is a schematic structural view of a partial cross-sectional view of the front side of a nondestructive testing device for detecting defects of a bridge beam body provided in the embodiment of the present application;

FIG. 3 is a schematic side view of a driving mechanism in the nondestructive testing apparatus for bridge beam defects according to the embodiment of the present disclosure;

fig. 4 is a schematic structural view of a lifting mechanism in the nondestructive testing device for bridge beam defects provided by the embodiment of the application;

fig. 5 is a schematic view of a connecting structure of a connecting rod and a detection rod in the nondestructive testing device for defects of a bridge body provided by the embodiment of the application.

In the figure: 10-a base assembly; 100-a base plate; 200-a roller; 110-a lifting assembly; 1110-a riser; 1120-a lifting mechanism; 1121 — a first electric machine; 1122-threaded rod; 1123-internal thread block; 1124-mounting block; 1130-through port; 20-a detection component; 210-a lifting block; 220-fixed block; 230-a rotating shaft; 240-electric telescopic rod; 250-a connecting rod; 260-a detection rod; 270-a drive mechanism; 2710-support plate; 2720-a second motor; 2730-connecting shaft; 2740-drive shaft; 30-a set of blocks.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

To make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments obtained by a person of ordinary skill in the art without any inventive work based on the embodiments in the present application are within the scope of protection of the present application.

Referring to fig. 1-5, the present application provides a nondestructive testing apparatus for bridge beam defects, which includes a base assembly 10 and a testing assembly 20.

Base subassembly 10 top fixed mounting has lifting unit 110, determine module 20 includes elevator 210, two fixed blocks 220, pivot 230, electric telescopic handle 240, connecting rod 250, detection pole 260 and actuating mechanism 270, elevator 210 fixed mounting is on lifting unit 110, two equal fixed mounting of fixed block 220 are on the lateral wall of elevator 210, pivot 230 rotates and runs through two fixed blocks 220, electric telescopic handle 240's one end and pivot 230 fixed connection, detection pole 260 rotates through connecting rod 250 and electric telescopic handle 240's the other end and is connected, actuating mechanism 270 fixed mounting is on elevator 210's lateral wall, actuating mechanism 270 is connected with the transmission of pivot 230.

When specifically setting up, through setting up elevator 210, elevator 210 is installed on elevating module 110, pivot 230 sets up on elevator 210 through two fixed blocks 220, actuating mechanism 270 drives pivot 230 rotatory, it is rotatory to realize driving electric telescopic handle 240, thereby can be with electric telescopic handle 240 rotatory to level, then swivelling joint pole 250 and test bar 260, angle of adjustment, promote base subassembly 10, make test bar 260 stretch out to bridge beam body one side, elevating module 110 can drive elevator 210 and go up and down, thereby realize driving test bar 260 and go up and down, be convenient for detect, can realize simultaneously that test bar 260 and electric telescopic handle 240 accomodate, and is convenient for use.

Further, the rotation connected mode between connecting rod 250 and electric telescopic handle 240 and the rotation connected mode between detection pole 260 and connecting rod 250 are prior art, and connecting rod 250 one end and electric telescopic handle 240 one end rotate the junction and have certain frictional force simultaneously, and detection pole 260 one end and connecting rod 250 one end rotate the junction and also have certain frictional force, make connecting rod 250 and detection pole 260 can not be according to self gravity, the automatic pivoted condition appears.

Referring to fig. 2 and 4, the base assembly 10 includes a bottom plate 100 and a plurality of rollers 200, the rollers 200 are all fixedly mounted on the bottom of the bottom plate 100, the lifting assembly 110 is fixedly mounted on the top of the bottom plate 100, the lifting assembly 110 includes a vertical plate 1110 and a lifting mechanism 1120, and the vertical plate 1110 is fixedly mounted on the bottom plate 100.

Elevating system 1120 fixed mounting is on riser 1110, and elevator 210 and riser 1110 sliding contact set up, have seted up on riser 1110 and have run through mouthful 1130, and elevating system 1120's one end is passed and is run through mouthful 1130 and elevator 210 fixed connection, and elevating system 1120 includes first motor 1121, threaded rod 1122 and internal thread piece 1123, and first motor 1121 fixed mounting is on the lateral wall of riser 1110.

Threaded rod 1122 and the drive shaft fixed connection of first motor 1121, on threaded rod 1122 was located to the threaded cover of internal thread piece 1123, internal thread piece 1123 passed through run-through 1130 and elevator 210 fixed connection, elevating system 1120 still includes installation piece 1124, installation piece 1124 fixed mounting is on the lateral wall of riser 1110, the one end and the installation piece 1124 of threaded rod 1122 rotate to be connected.

When specifically setting up, bottom plate 100 bottom installation gyro wheel 200 is convenient for promote bottom plate 100 and remove, and bottom plate 100 top is installed simultaneously and is pushed away the handle to and install the current display processing equipment who links to each other with detection pole 260, first motor 1121 and second motor 2720 mounting means are prior art.

Further, first motor 1121 drives threaded rod 1122 and rotates, sets up the internal thread with threaded rod 1122 looks adaptation in the internal thread piece 1123 to make internal thread piece 1123 move on threaded rod 1122, internal thread piece 1123 is the T type setting, makes internal thread piece 1123 slide on riser 1110, realizes driving elevator 210 and slides on riser 1110.

Referring to fig. 3 and 4, the driving mechanism 270 includes a supporting plate 2710, a second motor 2720 and a connecting shaft 2730, the second motor 2720 is fixedly mounted on the sidewall of the lifting block 210 through the supporting plate 2710, the connecting shaft 2730 is fixedly connected to a driving shaft of the second motor 2720, the driving mechanism 270 further includes a driving shaft 2740, the driving shaft 2740 is in transmission connection with both the connecting shaft 2730 and the rotating shaft 230, and the rotating shaft 230 is fixedly sleeved with the sleeve block 30.

One end of the electric telescopic rod 240 is fixedly connected with the sleeve block 30, a first belt pulley and a second belt pulley are fixedly sleeved on the connecting shaft 2730 and the transmission shaft 2740 respectively, the first belt pulley is in transmission connection with the second belt pulley, a first flat gear and a second flat gear are fixedly sleeved on the rotating shaft 230 and the transmission shaft 2740 respectively, and the first flat gear and the second flat gear are meshed.

When specifically setting up, the connected mode between electric telescopic handle 240 and the cover piece 30 is prior art, and second motor 2720 drives connecting axle 2730 and rotates, realizes driving pivot 230 through transmission shaft 2740 and rotates to the realization drives electric telescopic handle 240 and rotates, thereby can control electric telescopic handle 240's angle.

Further, the rotating shaft 230 rotates, the electric telescopic rod 240 can be controlled to rotate in a vertical state, the storage purpose is achieved, meanwhile, the connecting rod 250 and the detecting rod 260 can rotate, the mutual fitting is achieved, and therefore the storage purpose is achieved.

The working principle of the nondestructive testing device for the defects of the bridge body is as follows: promote bottom plate 100 through the push pedal and remove to the bridge floor on, then start second motor 2720, second motor 2720 drive shaft drives connecting axle 2730 and rotates, connecting axle 2730 is through first belt pulley and second belt pulley, it rotates to drive transmission shaft 2740, transmission shaft 2740 is through first bevel gear and second bevel gear, the realization drives pivot 230 and rotates, thereby drive electric telescopic handle 240 through nest block 30 and rotate, the realization rotates electric telescopic handle 240 to horizontal position department from vertical position and stops.

Further, rotating connecting rod 250 and test bar 260, realizing that the required detection angle of adjustment test bar 260, then starting electric telescopic handle 240, making electric telescopic handle 240 extend, will test bar 260 move one side department stop motion to the bridge beam body, then start first motor 1121, first motor 1121 drive shaft drives threaded rod 1122 and rotates, realizes driving internal thread piece 1123 downstream to drive test bar 260 downstream, be used for detecting the side of bridge beam body.

Further, promote to push away the handle, make bottom plate 100 remove, realize that detection pole 260 removes, be convenient for detect in succession, when accomodating, through first motor 1121, make the elevator 210 reset, then make electric telescopic handle 240 accomodate again, rotate connecting rod 250 and detection pole 260, make it accomodate, start second motor 2720 antiport at last, it can to realize that electric telescopic handle 240 resumes to vertical direction.

It should be noted that the specific model specifications of the electric telescopic rod 240, the first motor 1121 and the second motor 2720 need to be determined according to the actual specification of the device, and the specific model selection calculation method adopts the prior art, so detailed descriptions are omitted.

The power supply and the principle of the electric telescopic rod 240, the first motor 1121 and the second motor 2720 are clear to those skilled in the art, and will not be described in detail herein.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined or explained in subsequent figures.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (10)

1. A nondestructive testing device for bridge body defects is characterized by comprising

The lifting device comprises a base component (10), wherein a lifting component (110) is fixedly arranged at the top of the base component (10);

detection subassembly (20), detection subassembly (20) include elevator block (210), two fixed blocks (220), pivot (230), electric telescopic handle (240), connecting rod (250), detection pole (260) and actuating mechanism (270), elevator block (210) fixed mounting in on elevator block (110), two equal fixed mounting of fixed block (220) in on the lateral wall of elevator block (210), pivot (230) rotate and run through two fixed blocks (220), electric telescopic handle (240) one end with pivot (230) fixed connection, detection pole (260) pass through connecting rod (250) with electric telescopic handle (240)'s the other end rotates to be connected, actuating mechanism (270) fixed mounting in on the lateral wall of elevator block (210), actuating mechanism (270) with pivot (230) transmission is connected.

2. The nondestructive testing device for the defects of the bridge beam body of claim 1, wherein the base assembly (10) comprises a bottom plate (100) and a plurality of rollers (200), the plurality of rollers (200) are all fixedly mounted at the bottom of the bottom plate (100), and the lifting assembly (110) is fixedly mounted at the top of the bottom plate (100).

3. The nondestructive testing device for the defects of the bridge body of claim 2, wherein the lifting assembly (110) comprises a vertical plate (1110) and a lifting mechanism (1120), the vertical plate (1110) is fixedly installed on the bottom plate (100), the lifting mechanism (1120) is fixedly installed on the vertical plate (1110), the lifting block (210) is in sliding contact with the vertical plate (1110), a through hole (1130) is formed in the vertical plate (1110), and one end of the lifting mechanism (1120) penetrates through the through hole (1130) and is fixedly connected with the lifting block (210).

4. The nondestructive testing device for the defects of the bridge beam body according to claim 3, wherein the lifting mechanism (1120) comprises a first motor (1121), a threaded rod (1122) and an internal threaded block (1123), the first motor (1121) is fixedly mounted on the side wall of the vertical plate (1110), the threaded rod (1122) is fixedly connected with a driving shaft of the first motor (1121), the internal threaded block (1123) is sleeved on the threaded rod (1122), and the internal threaded block (1123) penetrates through the through hole (1130) to be fixedly connected with the lifting block (210).

5. The nondestructive testing device for the defects of the bridge body of claim 4, wherein the lifting mechanism (1120) further comprises a mounting block (1124), the mounting block (1124) is fixedly mounted on the side wall of the vertical plate (1110), and one end of the threaded rod (1122) is rotatably connected with the mounting block (1124).

6. The nondestructive testing device for the defect of the bridge beam body of claim 1, wherein the driving mechanism (270) comprises a supporting plate (2710), a second motor (2720) and a connecting shaft (2730), the second motor (2720) is fixedly installed on the side wall of the lifting block (210) through the supporting plate (2710), and the connecting shaft (2730) is fixedly connected with a driving shaft of the second motor (2720).

7. The nondestructive testing device for the defects of the bridge beam body of claim 6, wherein the driving mechanism (270) further comprises a transmission shaft (2740), and the transmission shaft (2740) is in transmission connection with both the connection shaft (2730) and the rotation shaft (230).

8. The nondestructive testing device for the defects of the bridge body of claim 1, wherein a sleeve block (30) is fixedly sleeved on the rotating shaft (230), and one end of the electric telescopic rod (240) is fixedly connected with the sleeve block (30).

9. The nondestructive testing device for the defects of the bridge body of claim 7, wherein the connecting shaft (2730) and the transmission shaft (2740) are respectively fixedly sleeved with a first belt pulley and a second belt pulley, and the first belt pulley is in transmission connection with the second belt pulley.

10. The nondestructive testing device for the defects of the bridge beam body of claim 7, wherein a first flat gear and a second flat gear are respectively fixedly sleeved on the rotating shaft (230) and the transmission shaft (2740), and the first flat gear and the second flat gear are meshed.

Images