CN220504600U - Building engineering antidetonation reinforcing assembly with adjustable - Google Patents

Abstract

The utility model relates to the technical field of anti-seismic reinforcing plates, in particular to an adjustable building engineering anti-seismic reinforcing assembly which comprises a first anti-seismic plate, a second anti-seismic plate, two first telescopic rods, a swinging plate, a plurality of locking bolts, an extension plate and a plurality of limiting plates, wherein the first telescopic rods are arranged on the first anti-seismic plate; the upper end face of the first anti-seismic plate is provided with two fixing plates side by side, and the upper end face of the first anti-seismic plate is provided with a mounting groove; one end of the second anti-seismic plate is rotatably arranged on the two fixed plates; the limiting plates are arranged on the bottom surface of the second anti-seismic plate side by side; one end of the swinging plate is movably arranged in the mounting groove, and the other end of the swinging plate is provided with a sliding groove; one end of the extension plate extends into the chute, the other end of the extension plate is provided with a compression plate, and the extension plate is arranged on the swing plate through a plurality of locking bolts; the first telescopic link activity sets up the inner wall at second shock-resistant board and mounting groove. The utility model has simple structure, is convenient for supporting the wall body which is obliquely arranged, and has higher practicability.

Description

Building engineering antidetonation reinforcing assembly with adjustable

Technical Field

The utility model relates to the technical field of anti-seismic reinforcing plates, in particular to an adjustable building engineering anti-seismic reinforcing component.

Background

The building engineering is an engineering entity formed by building various house buildings and auxiliary facilities thereof and installing and moving lines, pipelines and equipment matched with the house buildings, wherein the house buildings are provided with top covers, beam columns, walls and foundations and can form inner spaces, the engineering required by production, living, study and public activities of people is met, the walls are reinforced by adopting anti-seismic reinforcing plates in the building engineering to increase the safety, and the existing anti-seismic reinforcing plates have no adjusting function, so that the applicability range of the anti-seismic performance of the existing anti-seismic reinforcing plates is reduced.

The utility model discloses an adjustable earthquake-resistant reinforcing plate for constructional engineering, which is characterized in that a second earthquake-resistant plate, a movable groove and a sliding column are arranged, so that the first earthquake-resistant plate and the second earthquake-resistant plate can be used in a separable manner, the wall body and the corner can be subjected to earthquake-resistant reinforcement, the use scene of the earthquake-resistant reinforcing plate is expanded, the practicability of the earthquake-resistant reinforcing plate is improved, and the earthquake-resistant reinforcing plate can perform a buffering effect when the wall body is impacted by external force through the constraint groove, the rigid spring and the extrusion plate, and the shock absorption of the earthquake-resistant reinforcing plate is improved.

But above-mentioned device rotates the second anti-seismic plate through the swivel becket that sets up to make first anti-seismic plate and second anti-seismic plate can support and antidetonation mutually perpendicular's wall body and corner, but present wall body is not mutually perpendicular completely, exists the condition that needs to carry out the slope to support, and above-mentioned device's practicality is lower.

Disclosure of Invention

The utility model aims to solve the problems in the background technology and provides an adjustable building engineering earthquake-resistant reinforcing component which is convenient for supporting a wall body which is obliquely arranged.

The technical scheme of the utility model is as follows: an adjustable building engineering anti-seismic reinforcement assembly comprises a first anti-seismic plate, a second anti-seismic plate, two first telescopic rods, a swinging plate, a plurality of locking bolts, an extension plate and a plurality of limiting plates;

the bottom surface of the first shock-resistant plate is provided with a first buffer cushion, the upper end surface of the first shock-resistant plate is provided with two fixing plates side by side, and the upper end surface of the first shock-resistant plate is provided with a mounting groove;

one end of the second shock-resistant plate is rotatably arranged on the two fixed plates, and a second buffer cushion is arranged on the upper end face of the second shock-resistant plate; the limiting plates are arranged on the bottom surface of the second anti-seismic plate side by side;

one end of the swinging plate is movably arranged in the mounting groove, and the other end of the swinging plate is provided with a sliding groove; one end of the extension plate extends into the chute, the other end of the extension plate is provided with a compression plate, and the extension plate is arranged on the swing plate through a plurality of locking bolts;

two first telescopic links are distributed side by side, and the both ends of every first telescopic link are movable the setting respectively in the inner wall of second shock-resistant board and mounting groove.

Preferably, the telescopic device further comprises a second telescopic rod and a sliding plate; the sliding plate is arranged in the mounting groove in a sliding way, and a groove for mounting the swinging plate is formed in the sliding plate; two ends of the second telescopic rod are respectively connected with the sliding plate and the inner wall of the mounting groove; one end of the swinging plate is rotatably arranged in the groove.

Preferably, the device further comprises a plurality of U-shaped plates, a plurality of connecting blocks and a plurality of bolts; two ends of each first telescopic rod are respectively connected with two connecting blocks; the plurality of U-shaped plates are arranged in the second anti-seismic plate and the mounting groove; each connecting block is respectively installed on each U-shaped plate through each bolt.

Preferably, the swinging plate is provided with a handle.

Preferably, the device further comprises a plurality of reinforcing plates; two ends of each reinforcing plate are respectively connected with each limiting plate and the second anti-seismic plate.

Preferably, the device further comprises a support plate; the backup pad is installed on the up end of first shock-resistant board.

Preferably, the inner wall of the mounting groove is provided with clamping rubber.

Preferably, the first shock-resistant plate and the second shock-resistant plate are respectively provided with a round angle.

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

the user pushes the second anti-seismic plate to swing through the first telescopic rod, so that the first anti-seismic plate and the second anti-seismic plate support walls with different angles; simultaneously, the swinging plate is pulled by the handle, the extending plate is pressed on the second anti-seismic plate by the plurality of locking bolts, so that the swinging plate and the extending plate stably support the second anti-seismic plate, the second anti-seismic plate is more stable to install, and the wall surface is stably supported and reinforced.

The user promotes the sliding plate through the second telescopic link that sets up and removes, and then makes the sliding plate promote swing plate and extension board and removes and make the pinch plate compress tightly on the limiting plate towards the second shock-resistant plate, and then makes swing plate and extension board carry out steady rest to the second shock-resistant plate, has further improved the practicality of device.

Drawings

Fig. 1 is a perspective view of the present utility model.

Fig. 2 is a schematic view of an installation structure of a telescopic rod in the present utility model.

Fig. 3 is an enlarged partial schematic view at a in fig. 2.

Fig. 4 is a schematic view of a support structure according to the present utility model.

Reference numerals: 1. a first shock-resistant plate; 11. a first cushion pad; 101. a mounting groove; 2. a support plate; 3. a second shock-resistant plate; 31. a second cushion pad; 4. a fixing plate; 5. a first telescopic rod; 6. a U-shaped plate; 7. a connecting block; 8. a bolt; 9. a second telescopic rod; 10. a sliding plate; 11. a swinging plate; 12. a handle; 13. a locking bolt; 14. an extension plate; 15. a limiting plate; 16. reinforcing plate.

Detailed Description

Example 1

As shown in fig. 1 to 4, the adjustable building engineering earthquake-resistant reinforcing component provided by the utility model comprises a first earthquake-resistant plate 1, a second earthquake-resistant plate 3, two first telescopic rods 5, a swinging plate 11, a plurality of locking bolts 13, an extension plate 14 and a plurality of limiting plates 15.

The bottom surface of the first shock-resistant plate 1 is provided with a first buffer cushion, the upper end surface of the first shock-resistant plate 1 is provided with two fixing plates 4 side by side, and the upper end surface of the first shock-resistant plate 1 is provided with a mounting groove 101; the inner wall of the mounting groove 101 is provided with clamping rubber; also comprises a support plate 2; the support plate 2 is mounted on the upper end face of the first shock-resistant plate 1.

One end of the second shock-resistant plate 3 is rotatably arranged on the two fixed plates 4, and a second buffer cushion 31 is arranged on the upper end surface of the second shock-resistant plate 3; rounded corners are arranged on the first shock-resistant plate 1 and the second shock-resistant plate 3; a plurality of limiting plates 15 are arranged on the bottom surface of the second shock-resistant plate 3 side by side; also included are a plurality of stiffening plates 16; each limiting plate 15 and the second shock-resistant plate 3 are connected to the both ends of every reinforcing plate 16 respectively, and the limiting plate 15 is stably supported through the reinforcing plate 16 that sets up, and then the intensity of the limiting plate 15 has been improved.

One end of the swinging plate 11 is movably arranged in the mounting groove 101, the other end of the swinging plate 11 is provided with a sliding groove, and the swinging plate 11 is provided with a handle 12; one end of the extension plate 14 extends into the sliding groove, the other end of the extension plate 14 is provided with a pressing plate, and the extension plate 14 is mounted on the swing plate 11 through a plurality of locking bolts 13.

The two first telescopic rods 5 are distributed side by side, and two ends of each first telescopic rod 5 are movably arranged on the inner walls of the second shock-resistant plate 3 and the mounting groove 101 respectively; the device also comprises a plurality of U-shaped plates 6, a plurality of connecting blocks 7 and a plurality of bolts 8; two ends of each first telescopic rod 5 are respectively connected with two connecting blocks 7; a plurality of U-shaped plates 6 are installed in the second shock-resistant plate 3 and the installation groove 101; each connecting block 7 is respectively arranged on each U-shaped plate 6 through each bolt 8; the first telescopic rod 5 is movably installed through the plurality of U-shaped plates 6, the plurality of connecting blocks 7 and the plurality of bolts 8, and the telescopic rod is simple in structure and convenient to use.

In the utility model, when in use, a user pushes the second anti-seismic plate 3 to swing through the first telescopic rod 5, so that the first anti-seismic plate 1 and the second anti-seismic plate 3 support walls with different angles; simultaneously, through pulling swing board 11 through the handle, compress tightly extension board 14 on second shock-resistant board 3 through a plurality of lock bolts 13 that set up for swing board 11 and extension board 14 carry out stable support to second shock-resistant board 3, and the installation of second shock-resistant board 3 is more stable, has carried out stable support and reinforcement to the wall.

Example two

As shown in fig. 4, the present utility model provides an adjustable earthquake-proof reinforcement assembly for construction engineering, which further includes a second telescopic rod 9 and a sliding plate 10 as compared with the first embodiment; the sliding plate 10 is arranged in the mounting groove 101 in a sliding way, and a groove for mounting the swinging plate 11 is formed in the sliding plate 10; two ends of the second telescopic rod 9 are respectively connected with the sliding plate 10 and the inner wall of the mounting groove 101; one end of the swing plate 11 is rotatably installed in the groove.

In the utility model, when in use, a user pushes the sliding plate 10 to move through the second telescopic rod 9, so that the sliding plate 10 pushes the swinging plate 11 and the extending plate 14 to move towards the second shock-resistant plate 3, and the compressing plate is compressed on the limiting plate 15, so that the swinging plate 11 and the extending plate 14 stably support the second shock-resistant plate 3, and the practicability of the device is further improved.

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

Claims (8)

1. The adjustable building engineering earthquake-resistant reinforcing component is characterized by comprising a first earthquake-resistant plate (1), a second earthquake-resistant plate (3), two first telescopic rods (5), a swinging plate (11), a plurality of locking bolts (13), an extension plate (14) and a plurality of limiting plates (15);

the bottom surface of the first shock-resistant plate (1) is provided with a first buffer cushion, the upper end surface of the first shock-resistant plate (1) is provided with two fixing plates (4) side by side, and the upper end surface of the first shock-resistant plate (1) is provided with a mounting groove (101);

one end of the second shock-resistant plate (3) is rotatably arranged on the two fixed plates (4), and a second buffer pad (31) is arranged on the upper end surface of the second shock-resistant plate (3); the limiting plates (15) are arranged on the bottom surface of the second shock-resistant plate (3) side by side;

one end of the swinging plate (11) is movably arranged in the mounting groove (101), and the other end of the swinging plate (11) is provided with a sliding groove; one end of the extension plate (14) extends into the chute, the other end of the extension plate (14) is provided with a compression plate, and the extension plate (14) is arranged on the swinging plate (11) through a plurality of locking bolts (13);

two first telescopic rods (5) are distributed side by side, and two ends of each first telescopic rod (5) are movably arranged on the inner walls of the second shock-resistant plate (3) and the mounting groove (101) respectively.

2. An adjustable construction seismic reinforcement assembly according to claim 1, further comprising a second telescopic rod (9) and a sliding plate (10); the sliding plate (10) is arranged in the mounting groove (101) in a sliding way, and a groove for mounting the swinging plate (11) is formed in the sliding plate (10); two ends of the second telescopic rod (9) are respectively connected with the sliding plate (10) and the inner wall of the mounting groove (101); one end of the swinging plate (11) is rotatably arranged in the groove.

3. An adjustable constructional engineering seismic reinforcement assembly according to claim 1, further comprising a plurality of U-shaped plates (6), a plurality of connection blocks (7) and a plurality of bolts (8); two ends of each first telescopic rod (5) are respectively connected with two connecting blocks (7); a plurality of U-shaped plates (6) are arranged in the second shock-resistant plate (3) and the mounting groove (101); each connecting block (7) is respectively arranged on each U-shaped plate (6) through each bolt (8).

4. An adjustable constructional engineering seismic reinforcement assembly as in claim 1, wherein the swinging plate (11) is provided with handles (12).

5. An adjustable construction seismic reinforcement assembly as in claim 1, further comprising a plurality of reinforcement plates (16); two ends of each reinforcing plate (16) are respectively connected with each limiting plate (15) and the second anti-seismic plate (3).

6. An adjustable construction seismic reinforcement assembly according to claim 1, further comprising a support plate (2); the supporting plate (2) is arranged on the upper end face of the first shock-resistant plate (1).

7. An adjustable constructional engineering earthquake-proof reinforcement assembly according to claim 1, characterized in that the inner wall of the mounting groove (101) is provided with clamping rubber.

8. An adjustable constructional engineering earthquake-proof reinforcement assembly according to claim 1, characterized in that the first earthquake-proof plate (1) and the second earthquake-proof plate (3) are provided with rounded corners.