CN216207164U - Building steel structure prestress detection equipment - Google Patents

Abstract

The utility model relates to the technical field of prestress detection, in particular to a prestress detection device for a building steel structure, which comprises a bottom plate, two movable plates, two connecting frames, a mounting plate, two first sliding plates, two second sliding plates, two supporting blocks, two groups of springs and a supporting plate for supporting a piece to be detected, wherein the bottom plate is provided with a first sliding plate and a second sliding plate; the two connecting frames are connected with the bottom plate side by side, and one connecting frame is provided with a controller; the mounting plate is connected with the two connecting frames, and a detector is arranged on the mounting plate; the controller is electrically connected with the detector; the supporting plate is arranged on the bottom plate; the bottom plate is provided with a moving assembly; the two first sliding plates are respectively connected with the two moving plates in a sliding manner, and each first sliding plate is provided with a limiting component; the two second sliding plates are respectively connected with the two moving plates in a sliding manner, and each second sliding plate is connected with each first sliding plate through each group of springs; the two supporting blocks are respectively arranged on the two moving plates. The utility model can detect the pieces to be detected with different sizes.

Description

Building steel structure prestress detection equipment

Technical Field

The utility model relates to the technical field of prestress detection, in particular to prestress detection equipment for a building steel structure.

Background

At present, with the improvement of national economic strength and the demand of urbanization development, city construction and design are more and more diversified, different house models have different model structures, and prestress detection of a steel plate is an important step in construction.

However, in the actual use process of the conventional detection equipment, the prestress detection can be performed only on the to-be-detected piece with one size specification, the application range is small, and the utilization rate is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a building steel structure prestress detection device capable of detecting pieces to be detected with different sizes aiming at the problems in the background technology.

The technical scheme of the utility model is as follows: a building steel structure prestress detection device comprises a bottom plate, two moving plates, two connecting frames, a mounting plate, two first sliding plates, two second sliding plates, two supporting blocks, two groups of springs and a supporting plate for supporting a piece to be detected;

the two connecting frames are connected with the bottom plate side by side, and one connecting frame is provided with a controller; the mounting plate is connected with the two connecting frames, and a detector is arranged on the mounting plate; the controller is electrically connected with the detector;

the supporting plate is arranged on the bottom plate; the two moving plates are respectively positioned at two sides of the supporting plate; the bottom plate is provided with a moving assembly used for moving the two moving plates;

the two first sliding plates are respectively connected with the end faces, close to each other, of the two moving plates in a sliding manner, and each first sliding plate is provided with a limiting assembly used for being fixed with each moving plate; the two second sliding plates are respectively connected with the two moving plates in a sliding manner, the two second sliding plates are respectively positioned right below the two first sliding plates, and each second sliding plate is connected with each first sliding plate through each group of springs; the two supporting blocks are respectively arranged on the two moving plates and are respectively positioned under the two second sliding plates, the end faces, close to each other, of the two supporting blocks are inclined planes, and the distance value between the bottom face of each supporting block and the upper end face of the bottom plate is smaller than the height value of the supporting plate.

Preferably, the limiting assembly comprises two connecting plates and two bolts; each moving plate is provided with a threaded blind hole; each connecting plate is connected with the upper end face of each first sliding plate, and a plurality of through holes are formed in each connecting plate; each bolt passes through one through hole and is screwed into one threaded blind hole.

Preferably, the moving assembly comprises two double-shaft motors and four threaded rods; the lower end face of each moving plate is provided with two sliding blocks; each sliding block is connected with the side end face of the bottom plate in a sliding manner; the two double-shaft motors are connected with the side end face of the bottom plate, and two output ends of each double-shaft motor are respectively connected with a threaded rod; one end of each threaded rod, which is far away from each double-shaft motor, is rotatably arranged on the connecting frame; the plurality of sliding blocks are respectively in threaded connection with the plurality of threaded rods; the controller is electrically connected with the two double-shaft motors.

Preferably, the two double-shaft motors are connected with the bottom plate through rubber pads.

Preferably, a plurality of bearings are also included; the threaded rods are respectively connected with the connecting frame in a rotating mode through a plurality of bearings.

Preferably, the end surfaces of each second sliding plate and each support block, which are close to each other, are provided with rubber layers.

Preferably, the upper end surface of the supporting plate is provided with an anti-slip layer.

Preferably, the support plate has a T-shaped projection.

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

in the embodiment, when the clamping device is used, a user pulls the connecting plate upwards to drive the first sliding plate to move upwards, the second sliding plate moves upwards under the action of the spring, then the bolt penetrates through the through hole and is screwed into the threaded blind hole in a spiral mode to fix the connecting plate, so that the first sliding plate is fixed, the distance between the second sliding plate and the supporting block is controlled, and pieces to be detected with different thicknesses can be clamped conveniently; a user places the piece to be detected on the supporting plate; then, the controller controls the double-shaft motor to start, so that the threaded rods rotate, the sliding blocks are in sliding connection with the bottom plate, the two moving plates are close to each other, the piece to be detected is in sliding connection with the inclined surface, the piece to be detected moves upwards under the pushing of the inclined surface, so that the two second sliding plates move upwards, and the two second sliding plates compress the two groups of springs; the two second sliding plates press the to-be-detected pieces on the two supporting blocks under the action of the two groups of springs, so that the to-be-detected pieces with different sizes can be clamped conveniently; and then the controller controls the detector to detect the piece to be detected.

Drawings

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

Fig. 2 is a partially enlarged schematic view of a portion a in fig. 1.

FIG. 3 is a cross-sectional view of the moving plate assembly in accordance with one embodiment of the present invention.

Reference numerals: 1. a base plate; 2. moving the plate; 201. a threaded blind hole; 3. a connecting frame; 4. mounting a plate; 5. a detector; 6. a controller; 7. a first sliding plate; 8. a second sliding plate; 9. a support block; 91. a bevel; 10. a double-shaft motor; 11. a support plate; 12. a piece to be detected; 13. a slider; 14. a threaded rod; 15. a connecting plate; 1501. a through hole; 16. a bolt; 17. a spring.

Detailed Description

Example one

As shown in fig. 1-3, the prestress detection device for the building steel structure provided by the utility model comprises a bottom plate 1, two moving plates 2, two connecting frames 3, a mounting plate 4, two first sliding plates 7, two second sliding plates 8, two supporting blocks 9, two double-shaft motors 10, four threaded rods 14, two groups of springs 17 and a supporting plate 11 for supporting a to-be-detected element 12;

the two connecting frames 3 are connected with the bottom plate 1 side by side, and one connecting frame 3 is provided with a controller 6; the mounting plate 4 is connected with the two connecting frames 3, and the detector 5 is arranged on the mounting plate 4;

the supporting plate 11 is arranged on the bottom plate 1, the upper end face of the supporting plate 11 is provided with an anti-skid layer, the to-be-detected piece 12 is better supported through the anti-skid layer, and the stability of the supporting plate 11 for supporting the to-be-detected piece 12 is ensured; the projection shape of the supporting plate 11 is T-shaped, the contact area between the supporting plate 11 and the to-be-detected piece 12 is large, and the to-be-detected piece 12 is supported more stably; the two moving plates 2 are respectively positioned at two sides of the supporting plate 11; the two first sliding plates 7 are respectively connected with the end faces, close to each other, of the two moving plates 2 in a sliding manner, and each first sliding plate 7 is provided with a limiting component for fixing with each moving plate 2; the two second sliding plates 8 are respectively connected with the two moving plates 2 in a sliding manner, the two second sliding plates 8 are respectively positioned right below the two first sliding plates 7, and each second sliding plate 8 is connected with each first sliding plate 7 through each group of springs 17; the two supporting blocks 9 are respectively arranged on the two moving plates 2, the two supporting blocks 9 are respectively positioned under the two second sliding plates 8, the end surfaces of the two supporting blocks 9 close to each other are inclined surfaces 91, and the distance value between the bottom surface of each supporting block 9 and the upper end surface of the bottom plate 1 is smaller than the height value of the supporting plate 11; the end surfaces of each second sliding plate 8 and each supporting block 9, which are close to each other, are provided with rubber layers; it is convenient to protect the member to be detected 12.

The lower end face of each moving plate 2 is provided with two sliding blocks 13; each sliding block 13 is connected with the side end surface of the bottom plate 1 in a sliding manner; the two double-shaft motors 10 are both connected with the side end face of the bottom plate 1, and the two double-shaft motors 10 are both connected with the bottom plate 1 through rubber pads; the influence of vibration generated by the operation of the double-shaft motor 10 on the bottom plate 1 can be reduced through the rubber pads, and the workpiece 12 to be detected is prevented from falling off from the supporting plate 11 due to vibration. Two output ends of each double-shaft motor 10 are respectively connected with a threaded rod 14, and the two threaded rods 14 connected to each double-shaft motor 10 have opposite spiral directions; one end of each threaded rod 14, which is far away from each double-shaft motor 10, is rotatably arranged on the connecting frame 3 through a bearing; the bearing can be used for reducing the friction force between the low-threaded rod 14 and the connecting frame 3, and is beneficial to prolonging the service life of the threaded rod 14. The plurality of sliders 13 are respectively in threaded connection with a plurality of threaded rods 14; the controller 6 is electrically connected with the detector 5 and the two double-shaft motors 10, intelligent control can be achieved, and the working intensity of workers is reduced.

In this embodiment, when in use, a user places the to-be-detected piece 12 on the supporting plate 11; then, the controller 6 controls the double-shaft motor 10 to start, so that the threaded rods 14 rotate, the sliding blocks 13 are connected with the bottom plate 1 in a sliding mode, the two moving plates 2 approach to each other, the piece 12 to be detected is connected with the inclined surface 91 in a sliding mode, the piece 12 to be detected moves upwards under the pushing of the inclined surface 91, so that the two second sliding plates 8 move upwards, and the two groups of springs 17 are compressed by the two second sliding plates 8; the two second sliding plates 8 tightly press the pieces to be detected 12 on the two supporting blocks 9 under the action of the two groups of springs 17, so that the pieces to be detected 12 with different sizes can be clamped conveniently; the controller 6 controls the detector 5 to detect the object 12.

Example two

As shown in fig. 2 to 3, compared with the first embodiment, the present embodiment further describes in detail the limiting assembly mentioned in the first embodiment, where the building steel structure prestress detecting apparatus provided by the present invention includes two connecting plates 15 and two bolts 16; each moving plate 2 is provided with a threaded blind hole 201; each connecting plate 15 is connected with the upper end surface of each first sliding plate 7, and a plurality of through holes 1501 are formed in each connecting plate 15; each bolt 16 is inserted through a respective through hole 1501 and screwed into a respective threaded blind hole 201.

In this embodiment, during the use, upwards stimulate connecting plate 15 through the user, drive first sliding plate 7 and upwards remove, second sliding plate 8 upwards removes under spring 17's effect, then pass a through-hole 1501 and screw in a screw thread blind hole 201 with bolt 16 again, fix connecting plate 15, thereby fix first sliding plate 7, control the distance between second sliding plate 8 and the supporting shoe 9, so that clamp tightly simple structure convenient to use to waiting of different thickness to detect piece 12.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited thereto, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.

Claims (8)

1. The building steel structure prestress detection equipment is characterized by comprising a bottom plate (1), two moving plates (2), two connecting frames (3), a mounting plate (4), two first sliding plates (7), two second sliding plates (8), two supporting blocks (9), two groups of springs (17) and a supporting plate (11) for supporting a piece to be detected (12);

the two connecting frames (3) are connected with the bottom plate (1) side by side, and a controller (6) is arranged on one connecting frame (3); the mounting plate (4) is connected with the two connecting frames (3), and the detector (5) is arranged on the mounting plate (4); the controller (6) is electrically connected with the detector (5);

the supporting plate (11) is arranged on the bottom plate (1); the two moving plates (2) are respectively positioned at two sides of the supporting plate (11); the bottom plate (1) is provided with a moving assembly for moving the two moving plates (2);

the two first sliding plates (7) are respectively connected with the end faces, close to each other, of the two moving plates (2) in a sliding mode, and each first sliding plate (7) is provided with a limiting assembly used for being fixed with each moving plate (2); the two second sliding plates (8) are respectively connected with the two moving plates (2) in a sliding manner, the two second sliding plates (8) are respectively positioned right below the two first sliding plates (7), and each second sliding plate (8) is connected with each first sliding plate (7) through each group of springs (17); two supporting blocks (9) are respectively installed on the two moving plates (2), the two supporting blocks (9) are respectively located under the two second sliding plates (8), the end faces, close to each other, of the two supporting blocks (9) are inclined faces (91), and the distance value between the bottom face of each supporting block (9) and the upper end face of the bottom plate (1) is smaller than the height value of the supporting plate (11).

2. The building steel structure prestress detection device according to claim 1, wherein the limiting assembly comprises two connecting plates (15) and two bolts (16); each moving plate (2) is provided with a threaded blind hole (201); each connecting plate (15) is connected with the upper end face of each first sliding plate (7), and a plurality of through holes (1501) are formed in each connecting plate (15); each bolt (16) passes through one through hole (1501) and is screwed into one threaded blind hole (201).

3. The building steel structure prestress detection device according to claim 1, wherein the moving assembly comprises two double-shaft motors (10) and four threaded rods (14); the lower end surface of each moving plate (2) is provided with two sliding blocks (13); each sliding block (13) is connected with the side end surface of the bottom plate (1) in a sliding manner; the two double-shaft motors (10) are connected with the side end face of the bottom plate (1), and two output ends of each double-shaft motor (10) are respectively connected with a threaded rod (14); one end of each threaded rod (14) far away from each double-shaft motor (10) is rotatably arranged on the connecting frame (3); the plurality of sliding blocks (13) are respectively in threaded connection with the plurality of threaded rods (14); the controller (6) is electrically connected with the two double-shaft motors (10).

4. The building steel structure prestress detection device according to claim 3, wherein the two double-shaft motors (10) are connected with the base plate (1) through rubber pads.

5. The building steel structure prestress detection device according to claim 3, further comprising a plurality of bearings; the threaded rods (14) are respectively connected with the connecting frame (3) in a rotating way through a plurality of bearings.

6. The building steel structure prestress detection equipment according to claim 1, wherein the end surfaces of each second sliding plate (8) and each support block (9) close to each other are provided with rubber layers.

7. The building steel structure prestress detection device according to claim 1, wherein an anti-skid layer is arranged on the upper end face of the support plate (11).

8. The building steel structure prestress detection device according to claim 1, wherein the projection shape of the support plate (11) is T-shaped.

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