CN212507043U - Light wallboard seismic strengthening structure - Google Patents

Abstract

The utility model discloses a light wallboard antidetonation reinforced structure, consolidate buffer including light wallboard and four, four are consolidated buffer and are set up respectively four edges of light wallboard both sides, it includes the upper fixed plate and installs last pull rod below the upper fixed plate to consolidate buffer, be connected with extension spring below the upper pull rod, the lower extreme of going up extension spring is connected with the upper boom, be connected with the riser below the upper boom, be connected with the lower beam below the riser, the lower extreme of lower beam is connected with down extension spring, be connected with the lower beam below lower extension spring, be equipped with the bottom plate below the lower beam, the bottom plate fixed connection be in one side lower extreme of light wallboard. Because the utility model discloses can improve the shock resistance of wallboard, make the utility model discloses it is safer to use.

Description

Light wallboard seismic strengthening structure

Technical Field

The utility model relates to a building engineering technical field, concretely relates to light wallboard reinforced structure that combats earthquake.

Background

Light wallboard plays very important effect in present building construction, and it is not only easily shaping, the mechanized production of being convenient for, and the wholeness is good, consequently uses very extensively, but current wallboard installation can not satisfy the antidetonation requirement, takes place the wallboard during the earthquake and warp or break easily, and the serious person can take place to collapse, consequently can't guarantee the security of using.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a safe in utilization, effectual light wallboard antidetonation reinforced structure of antidetonation.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a light wallboard antidetonation reinforced structure, includes light wallboard, still includes four and consolidates buffer, and four are consolidated buffer and are set up respectively four edges of light wallboard both sides, consolidate buffer including installing the upper fixed plate of light wallboard one side upper end with install the last pull rod below the upper fixed plate, be connected with extension spring below the last pull rod, the lower extreme of going up extension spring is connected with the upper boom, be connected with the riser below the upper boom, be connected with the lower beam below the riser, the lower extreme of lower beam is connected with down extension spring, be connected with down the pull rod below the lower extension spring, be equipped with the bottom plate below the lower beam, bottom plate fixed connection be in one side lower extreme of light wallboard.

Further, consolidate buffer still including installing last fixing base of light wallboard one side upper end and installing go up the last cylinder of fixing base lower extreme, the inside of going up the cylinder slides and is equipped with the piston, go up the below of piston and be connected with the extension rod, the lower extreme of going up the extension rod is connected with the fixed block, the fixed block is connected the left side of riser.

Furthermore, the fixing base is installed to light wallboard one side lower extreme, cylinder is installed down to the higher authority of fixing base down, sliding connection is equipped with down the piston in the cylinder down, the higher authority of piston is connected with the extension pole of downwardly extending, the upper end of extension pole of downwardly extending is connected the lower extreme of fixed block.

Furthermore, an upper sliding rod is arranged on the upper piston, an upper compression spring is sleeved on the upper sliding rod, the upper end of the upper compression spring is propped against the lower surface of the upper fixing seat, and the lower end of the upper compression spring is propped against the upper surface of the upper piston.

Furthermore, a lower sliding rod is connected below the lower piston, a lower compression spring is sleeved on the lower sliding rod, the upper end of the lower compression spring abuts against the lower surface of the lower piston, and the lower end of the lower compression spring abuts against the upper surface of the lower fixing seat.

Furthermore, the upper rod and the lower rod are vertically symmetrical, and the upper cylinder barrel and the lower cylinder barrel are vertically symmetrical.

According to the above technical solution, the utility model has the advantages that:

1. compared with the prior art, the utility model has reasonable structure, all the components play a role together, and the shock resistance of the whole building can be enhanced, so that the use is safer;

2. the utility model provides a consolidate buffer stable in structure can produce the cushion effect when the earthquake arrives, offsets the vibration effect that the earthquake brought, has greatly reduced the impact force that vibrations brought for the antidetonation effect improves greatly.

In addition to the above-described objects, features and advantages, the present invention has other objects, features and advantages. The present invention will be described in further detail with reference to the drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts. In the drawings:

fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a plan view of the installation position of the reinforcing buffer device of the present invention.

Fig. 3 is a partially enlarged view of fig. 1 at K.

Fig. 4 is a partially enlarged view of fig. 1 at L.

Fig. 5 is a partial enlarged view of fig. 1 at M.

Labeled as: the light wall board comprises a light wall board 1, a reinforcing buffer device 20, an upper fixing plate 21, an upper pull rod 22, an upper extension spring 23, a lower fixing plate 24, a lower pull rod 25, a lower extension spring 26, a fixing block 27, a vertical plate 28, an upper rod 29, a lower rod 30, an upper fixing seat 31, an upper cylinder 32, an upper compression spring 33, an upper piston 34, an upper slide rod 341, an upper extension rod 35, a lower extension rod 36, a lower cylinder 37, a lower piston 38, a lower slide rod 381, a lower compression spring 39 and a lower fixing seat 40.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 5, the anti-seismic reinforcing structure for lightweight wall panels as shown in fig. 1, 2 and 3 comprises a lightweight wall panel 1 and four reinforcing and buffering devices 20, wherein the four reinforcing and buffering devices 20 are respectively arranged at four corners of two sides of the lightweight wall panel 1, the reinforcing buffer means 20 includes an upper fixing plate 21 installed at one side upper end of the lightweight wall panel 1 and an upper tie bar 22 installed below the upper fixing plate 21, an upper extension spring 23 is connected to the lower part of the upper pull rod 22, an upper rod 29 is connected to the lower end of the upper extension spring 23, a vertical plate 28 is connected below the upper rod 29, a lower rod 30 is connected below the vertical plate 28, the lower end of the lower rod 30 is connected with a lower extension spring 26, the lower surface of the lower extension spring 26 is connected with a lower pull rod 25, a lower fixing plate 24 is arranged below the lower pull rod 25, and the lower fixing plate 24 is fixedly connected to the lower end of one side of the light wall board 1.

As shown in fig. 4, the reinforcing buffer device 20 further includes an upper fixing seat 31 installed at the upper end of one side of the light wall board 1 and an upper cylinder 32 installed at the lower end of the upper fixing seat 31, an upper piston 34 is slidably arranged inside the upper cylinder 32, an upper extension rod 35 is connected below the upper piston 34, a fixing block 27 is connected to the lower end of the upper extension rod 35, the fixing block 27 is connected to the left side of the vertical plate 28, and the fixing block 27 and the vertical plate 28 are connected to each other, so that the effect between the parts can be enhanced, and the anti-seismic buffer effect is better.

Preferably, a lower fixing seat 40 is installed at the lower end of one side of the light wall board 1, a lower cylinder 37 is installed on the upper surface of the lower fixing seat 40, a lower piston 38 is slidably connected in the lower cylinder 37, a lower extension rod 36 is connected on the upper surface of the lower piston 38, the upper end of the lower extension rod 36 is connected to the lower end of the fixing block 27, the lower piston 38 and the upper piston 34 slide up and down, and can respectively drive the lower compression spring 39 and the upper compression spring 33 to generate elastic acting force, so that a part of buffering force is provided.

Preferably, an upper sliding rod 341 is disposed above the upper piston 34, an upper compression spring 33 is sleeved on the upper sliding rod 341, an upper end of the upper compression spring 33 is abutted against a lower surface of the upper fixing seat 31, and a lower end of the upper compression spring 33 is abutted against an upper surface of the upper piston 34.

Preferably, a lower sliding rod 381 is connected to the lower surface of the lower piston 38, a lower compression spring 39 is sleeved on the lower sliding rod 381, the upper end of the lower compression spring 39 abuts against the lower surface of the lower piston 38, and the lower end of the lower compression spring 39 abuts against the upper surface of the lower fixed seat 40.

Preferably, the upper rod 29 and the lower rod 30 are vertically symmetrical, and the upper cylinder 32 and the lower cylinder 37 are vertically symmetrical.

The working principle is as follows: when an earthquake occurs, the lightweight wall panel 1 shakes, so that the upper extension spring 23 or the lower extension spring 26 generates tension and pulls the upper rod 29 or the lower rod 30 to move up and down, so that the vertical plate 28 moves upwards or downwards, the vertical plate 28 moves to carry the fixed block 27 with the movement, when the vertical plate 28 carries the fixed block 27 with the upward movement (namely, the upper extension spring 23 pulls the upper rod 29 to move upwards), the upper extension rod 35 carries the upper piston 34 with the upward movement, the upper compression spring 33 is compressed to generate a reaction force, so that a part of the impact force of the earthquake is counteracted, and conversely, when the vertical plate 28 carries the fixed block 27 with the upward movement (namely, the lower extension spring 26 pulls the lower rod 30 to move downwards), the lower extension rod 36 carries the lower piston 38 with the downward movement, at this time, the lower compression spring 39 is compressed, and the lower compression spring 39 is compressed to generate a reaction force, so that a part of the impact force of an earthquake is offset, and thus, under the elastic action, the influence of the impact of the earthquake on the light wallboard 1 is reduced, the deformation or cracking of the light wallboard 1 is reduced, the service life is longer, and the use of the light wallboard 1 is safer.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The light wallboard anti-seismic reinforcing structure comprises a light wallboard (1) and is characterized by further comprising four reinforcing buffer devices (20), wherein the four reinforcing buffer devices (20) are respectively arranged at four corners of two sides of the light wallboard (1), each reinforcing buffer device (20) comprises an upper fixing plate (21) arranged at the upper end of one side of the light wallboard (1) and an upper pull rod (22) arranged below the upper fixing plate (21), an upper stretching spring (23) is connected below the upper pull rod (22), the lower end of the upper stretching spring (23) is connected with an upper rod (29), a vertical plate (28) is connected below the upper rod (29), a lower rod (30) is connected below the vertical plate (28), the lower end of the lower rod (30) is connected with a lower stretching spring (26), and a lower pull rod (25) is connected below the lower stretching spring (26), a lower fixing plate (24) is arranged below the lower pull rod (25), and the lower fixing plate (24) is fixedly connected to the lower end of one side of the light wall plate (1).

2. The light wallboard earthquake-resistant reinforcement structure of claim 1, characterized in that, the reinforcement buffer device (20) further comprises an upper fixing seat (31) installed at the upper end of one side of the light wallboard (1) and an upper cylinder (32) installed at the lower end of the upper fixing seat (31), an upper piston (34) is arranged inside the upper cylinder (32) in a sliding manner, an upper extension rod (35) is connected below the upper piston (34), the lower end of the upper extension rod (35) is connected with a fixing block (27), and the fixing block (27) is connected to the left side of the vertical plate (28).

3. The light wallboard seismic strengthening structure of claim 2, wherein the lower fixing seat (40) is installed at the lower end of one side of the light wallboard (1), the lower cylinder (37) is installed on the upper surface of the lower fixing seat (40), the lower piston (38) is slidably connected in the lower cylinder (37), the lower extension rod (36) is connected to the upper surface of the lower piston (38), and the upper end of the lower extension rod (36) is connected to the lower end of the fixing block (27).

4. The lightweight wallboard seismic strengthening structure of claim 3, wherein an upper sliding rod (341) is disposed on the upper piston (34), an upper compression spring (33) is sleeved on the upper sliding rod (341), the upper end of the upper compression spring (33) is supported against the lower surface of the upper fixing seat (31), and the lower end of the upper compression spring (33) is supported against the upper surface of the upper piston (34).

5. The lightweight wallboard seismic strengthening structure of claim 4, wherein a lower sliding rod (381) is connected to the lower surface of the lower piston (38), a lower compression spring (39) is sleeved on the lower sliding rod (381), the upper end of the lower compression spring (39) is pressed against the lower surface of the lower piston (38), and the lower end of the lower compression spring (39) is pressed against the upper surface of the lower fixing seat (40).

6. The lightweight wall panel seismic strengthening structure of claim 5, wherein the upper rod (29) and the lower rod (30) are vertically symmetrical, and the upper cylinder (32) and the lower cylinder (37) are vertically symmetrical.

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