CN211898584U - A earthquake-resistant structure for architectural design - Google Patents

Abstract

The utility model discloses an earthquake-resistant structure for architectural design, including stock, first steadying plate, second steadying plate and base, the bottom fixedly connected with shock-absorbing structure of second steadying plate, and the first steadying plate of shock-absorbing structure's bottom fixedly connected with, the inside of first steadying plate and second steadying plate all is provided with additional strengthening, the bottom fixedly connected with stock of first steadying plate, the bottom fixedly connected with anchor head of stock. The utility model discloses an install reinforced structure on the top of second steadying plate, for making the fixed effect in house better during the use, in to the ground reinforcement, through reinforced structure's setting, be provided with the preformed groove in the inside of dead lever during the use, the reinforcement muscle passes the preformed groove and fixes dead lever and room body coupling, consolidates the room body, and the setting through reinforced structure builds the fixity better in the room body, and it is safer to live in.

Description

A earthquake-resistant structure for architectural design

Technical Field

The utility model relates to an antidetonation technical field specifically is an earthquake-resistant structure for architectural design.

Background

Traditional housing construction does not make the antidetonation measure when building, and house foundation structural strength is big enough, can not effectively support, and the security performance of living is not high enough, needs a house antidetonation structure that the high antidetonation performance of security performance of living is good now, but current antidetonation structure that is used for architectural design has many problems or defects:

firstly, the traditional anti-seismic structure for building design is not firm enough in connection and fixation with a house, and the reinforcing effect is not good;

secondly, the structural strength of the internal supporting plate of the traditional anti-seismic structure for building design is not large enough, and the support is not stable enough;

thirdly, the traditional anti-seismic structure for architectural design cannot effectively absorb shock, and the anti-seismic effect is not good.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an earthquake-resistant structure for architectural design to the structure that proposes in solving above-mentioned background art is connected firmly inadequately with the house, backup pad inner structure intensity is big inadequately and the not good problem of shock attenuation effect.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an earthquake-resistant structure for architectural design, includes stock, first steadying plate, second steadying plate and base, the bottom fixedly connected with shock-absorbing structure of second steadying plate, and the first steadying plate of shock-absorbing structure's bottom fixedly connected with, the inside of first steadying plate and second steadying plate all is provided with additional strengthening, the bottom fixedly connected with stock of first steadying plate, the bottom fixedly connected with anchor head of stock, the top of second steadying plate is provided with the base, and the top of base is provided with the room body, the both sides fixedly connected with reinforced structure on second steadying plate top.

Preferably, reinforced structure from the top down has set gradually draw-in groove, chock, preformed groove, reinforcement muscle and dead lever, the inside of dead lever is provided with the preformed groove, and the inside swing joint of preformed groove has the reinforcement muscle, the inside in the room body is provided with the draw-in groove, one side fixedly connected with chock of reinforcement muscle.

Preferably, shock-absorbing structure from the top down has set gradually first connecting block, damping ring, block and second connecting block, the first connecting block of inside fixedly connected with of block, and the bottom fixedly connected with damping ring of first connecting block, the bottom fixedly connected with second connecting block of damping ring.

Preferably, be provided with the overhead kick line on the lateral wall of stock, and the overhead kick line is snakelike distribution on the lateral wall of stock.

Preferably, additional strengthening has from left to right set gradually cavity, connection piece, strengthening rib and stationary blade, the inside of cavity is provided with the connection piece, and the bottom fixedly connected with strengthening rib of connection piece, the bottom fixedly connected with stationary blade of strengthening rib, the strengthening rib is equidistant range in the inside of cavity.

Preferably, the top fixedly connected with fixed steel bar of second stabilizer plate, the inside of base is provided with the notch, and notch and fixed steel bar are the joint structure.

Compared with the prior art, the beneficial effects of the utility model are that: this an antidetonation structure for architectural design is rational in infrastructure, has following advantage:

(1) the reinforcing structure is arranged at the top end of the second stabilizing plate, so that the fixing effect of the house is better when the building is used, when the foundation is reinforced, the reserved groove is formed in the fixing rod when the building is used, the reinforcing rib penetrates through the reserved groove to connect and fix the fixing rod and the house body, the house body is reinforced, the house body is better in building fixation due to the arrangement of the reinforcing structure, and the house is safer to live in;

(2) the reinforcing structures are arranged inside the first stabilizing plate and the second stabilizing plate, the cavity is arranged inside the reinforcing structures, and the reinforcing ribs which are arranged at equal intervals are arranged inside the cavity to reinforce the structure inside the stabilizing plates, so that the internal strength of the stabilizing plates is higher, the supporting is more stable, the supporting and bearing performance of the first stabilizing plate and the second stabilizing plate is stronger, and the vibration is effectively prevented;

(3) through installing shock-absorbing structure between first steadying plate and second steadying plate, the crustal can control or the luffing motion during the earthquake, through have the shock attenuation ring at shock-absorbing structure internally mounted when using through shock-absorbing structure's setting, shock attenuation ring inside has certain buffering crushing resistance, can effectively prevent shaking to a certain extent, reduces the vibration degree in house, makes house live safer, and the possibility of empting during the earthquake reduces.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

fig. 2 is a schematic front view of the reinforcing structure of the present invention;

FIG. 3 is a front view of the reinforcing structure of the present invention;

fig. 4 is a front view structure diagram of the shock-absorbing structure of the present invention.

In the figure: 1. a house body; 2. reinforcing the structure; 201. a card slot; 202. a bolt block; 203. reserving a groove; 204. reinforcing ribs; 205. fixing the rod; 3. fixing the steel bars; 4. a shock-absorbing structure; 401. a first connection block; 402. a shock-absorbing ring; 403. a block body; 404. a second connecting block; 5. chamfering; 6. an anchor rod; 7. an anchor head; 8. a first stabilizer plate; 9. a reinforcing structure; 901. a cavity; 902. connecting sheets; 903. reinforcing ribs; 904. a fixing sheet; 10. a second stabilizing plate; 11. a base; 12. a notch;

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. 1-4, the present invention provides an embodiment: an anti-seismic structure for building design comprises an anchor rod 6, a first stabilizing plate 8, a second stabilizing plate 10 and a base 11, wherein the bottom end of the second stabilizing plate 10 is fixedly connected with a damping structure 4, the damping structure 4 is sequentially provided with a first connecting block 401, a damping ring 402, a block body 403 and a second connecting block 404 from top to bottom, the first connecting block 401 is fixedly connected inside the block body 403, the damping ring 402 is fixedly connected to the bottom end of the first connecting block 401, and the second connecting block 404 is fixedly connected to the bottom end of the damping ring 402;

specifically, as shown in fig. 1 and 4, when in use, the earth crust can swing left and right or up and down during an earthquake by installing the damping structure 4 between the first stabilizing plate 8 and the second stabilizing plate 10, and when in use by arranging the damping structure 4, the damping ring 402 is installed inside the damping structure 4, so that the damping ring 402 has certain buffering and pressure resistance, can effectively prevent the earthquake to a certain extent, reduces the vibration degree of a house, ensures that the house is more safe to live, and reduces the possibility of toppling during the earthquake;

the bottom end of the shock absorption structure 4 is fixedly connected with a first stabilizing plate 8, reinforcing structures 9 are arranged inside the first stabilizing plate 8 and a second stabilizing plate 10, the reinforcing structures 9 are sequentially provided with a cavity 901, a connecting piece 902, reinforcing ribs 903 and fixing pieces 904 from left to right, the connecting piece 902 is arranged inside the cavity 901, the reinforcing ribs 903 are fixedly connected to the bottom end of the connecting piece 902, the fixing pieces 904 are fixedly connected to the bottom ends of the reinforcing ribs 903, and the reinforcing ribs 903 are arranged inside the cavity 901 at equal intervals;

specifically, as shown in fig. 1 and 3, when in use, the reinforcing structure 9 is installed inside the first stabilizing plate 8 and the second stabilizing plate 10, the cavity 901 is formed inside the reinforcing structure 9, and the reinforcing ribs 903 arranged at equal intervals are installed inside the cavity 901 to structurally reinforce the inside of the stabilizing plates, so that the internal strength of the stabilizing plates is higher, the supporting is more stable, the supporting and bearing performance of the first stabilizing plate 8 and the second stabilizing plate 10 is higher, and the vibration is effectively prevented;

the bottom end of the first stabilizing plate 8 is fixedly connected with an anchor rod 6, the outer side wall of the anchor rod 6 is provided with undercut grains 5, and the undercut grains 5 are distributed on the outer side wall of the anchor rod 6 in a snake shape, so that the contact area between the anchor rod 6 and a foundation is larger, and the anchor rod 6 and a bottom layer are more firmly installed and piled;

the bottom end of the anchor rod 6 is fixedly connected with an anchor head 7, the top end of the second stabilizing plate 10 is provided with a base 11, the top end of the second stabilizing plate 10 is fixedly connected with a fixing steel bar 3, a notch 12 is formed in the base 11, and the notch 12 and the fixing steel bar 3 are in a clamping structure, so that the base 11 and the room body 1 are connected more firmly, and the fixing effect is better;

the house body 1 is arranged at the top end of the base 11, the reinforcing structures 2 are fixedly connected to two sides of the top end of the second stabilizing plate 10, the reinforcing structures 2 are sequentially provided with clamping grooves 201, bolts 202, reserved grooves 203, reinforcing ribs 204 and fixing rods 205 from top to bottom, the reserved grooves 203 are arranged inside the fixing rods 205, the reinforcing ribs 204 are movably connected inside the reserved grooves 203, the clamping grooves 201 are arranged inside the house body 1, and the bolts 202 are fixedly connected to one sides of the reinforcing ribs 204;

specifically, as shown in fig. 1 and fig. 2, when in use, through the arrangement of the reinforcing structure 2, a reserved groove 203 is arranged in the fixing rod 205 when in use, the reinforcing rib 204 penetrates through the reserved groove 203 to connect and fix the fixing rod 205 and the room body 1, so as to reinforce the room body 1, and the room body 1 is arranged through the reinforcing structure 2, so that the building fixation performance is better, and the living is safer.

The working principle is as follows: when in use, the common house is built without earthquake-resistant setting when a foundation is dug, the house is easy to collapse and incline when being subjected to vibration during earthquake, and has serious potential safety hazard, the anchor rod 6 is firmly connected with the ground bottom during use, the second stabilizing plate 10 is firmly connected with the house, the base 11 is arranged at the bottom of the house during use, the notch 12 is arranged in the base 11, the fixing reinforcing steel bar 3 arranged at the top end of the second stabilizing plate 10 is clamped and fixed with the notch 12 arranged in the base 11 during building and then fixed through concrete, firstly, the reinforcing structure 2 is arranged at the top end of the second stabilizing plate 10, so that the fixing effect of the house is better during use, when the foundation is reinforced, the reserved groove 203 is arranged in the fixing rod 205 during use through the arrangement of the reinforcing structure 2, the reinforcing steel bar 204 passes through the reserved groove 203 to connect and fix the fixing rod 205 with the house body 1, so as to reinforce the house body 1, the house body 1 is arranged through the reinforced structure 2, so that the building fixation is better, and the living is safer;

secondly, the reinforcing structures 9 are arranged inside the first stabilizing plate 8 and the second stabilizing plate 10, the cavities 901 are formed in the reinforcing structures 9, the reinforcing ribs 903 which are arranged at equal intervals are arranged inside the cavities 901, and the interiors of the stabilizing plates are structurally reinforced, so that the internal strength of the stabilizing plates is higher, the supporting is more stable, the supporting and bearing performance of the first stabilizing plate 8 and the second stabilizing plate 10 is higher, and the vibration is effectively prevented;

finally, through installing shock-absorbing structure 4 between first stabilising plate 8 and second stabilising plate 10, the crust can control or luffing motion during the earthquake, through have shock attenuation ring 402 at shock-absorbing structure 4 internally mounted when using through shock-absorbing structure 4's setting, shock attenuation ring 402 is inside to have certain buffering crushing resistance, can effectively prevent vibrations to a certain extent, reduces the vibration degree in house, makes house live safer, and the possibility of empting during the earthquake reduces.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. An earthquake-resistant structure for architectural design, comprising an anchor rod (6), a first stabilising plate (8), a second stabilising plate (10) and a base (11), characterized in that: the bottom fixedly connected with shock-absorbing structure (4) of second stabilizer plate (10), and the first stabilizer plate (8) of bottom fixedly connected with of shock-absorbing structure (4), the inside of first stabilizer plate (8) and second stabilizer plate (10) all is provided with additional strengthening (9), the bottom fixedly connected with stock (6) of first stabilizer plate (8), the bottom fixedly connected with anchor head (7) of stock (6), the top of second stabilizer plate (10) is provided with base (11), and the top of base (11) is provided with the room body (1), the both sides fixedly connected with reinforced structure (2) on second stabilizer plate (10) top.

2. An earthquake-resistant structure for building design according to claim 1, wherein: reinforced structure (2) from the top down has set gradually draw-in groove (201), plunger (202), reservation groove (203), reinforcement muscle (204) and dead lever (205), the inside of dead lever (205) is provided with reservation groove (203), and the inside swing joint of reservation groove (203) has reinforcement muscle (204), the inside of the room body (1) is provided with draw-in groove (201), one side fixedly connected with plunger (202) of reinforcement muscle (204).

3. An earthquake-resistant structure for building design according to claim 1, wherein: shock-absorbing structure (4) from the top down has set gradually first connecting block (401), damping ring (402), block (403) and second connecting block (404), the first connecting block (401) of inside fixedly connected with of block (403), and the bottom fixedly connected with damping ring (402) of first connecting block (401), the bottom fixedly connected with second connecting block (404) of damping ring (402).

4. An earthquake-resistant structure for building design according to claim 1, wherein: be provided with overhead kick line (5) on the lateral wall of stock (6), and overhead kick line (5) are snakelike the distribution on the lateral wall of stock (6).

5. An earthquake-resistant structure for building design according to claim 1, wherein: the reinforcing structure (9) is sequentially provided with a cavity (901), a connecting piece (902), reinforcing ribs (903) and fixing pieces (904) from left to right, the connecting piece (902) is arranged inside the cavity (901), the reinforcing ribs (903) are fixedly connected to the bottom ends of the connecting piece (902), the fixing pieces (904) are fixedly connected to the bottom ends of the reinforcing ribs (903), and the reinforcing ribs (903) are arranged inside the cavity (901) at equal intervals.

6. An earthquake-resistant structure for building design according to claim 1, wherein: the top fixedly connected with fixed steel bar (3) of second stabilizer plate (10), the inside of base (11) is provided with notch (12), and notch (12) and fixed steel bar (3) are the joint structure.

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