CN212743472U - Building structure roof beam connection structure that combats earthquake - Google Patents

Abstract

The utility model provides a building structure roof beam connection structure that combats earthquake belongs to building structure technical field, including the main structure body, the inboard fixedly connected with strengthening mechanism and the first buffer gear of position of main structure body, first buffer gear is located strengthening mechanism's inboard position, the inboard extreme angle position fixedly connected with second buffer gear and the atress mechanism of main structure body, the end angle surface setting of atress mechanism laminated structure main part. Through the strengthening mechanism, after finishing all the other mechanism's main part installations, the strengthening mechanism is the slope diagonal angle setting in the inboard of main structure, effectually reinforces main structure, strengthens main structure's structural strength, and the buffer layer is at first cushioned external force and vibrations, and the buffer beam when supporting the buffer layer, and the compression spring that the outer end position embedding set up cushions it when receiving external force to reach shock-resistant effect, the holistic bearing strength of a buffer mechanism is strengthened to the bracing piece.

Description

Building structure roof beam connection structure that combats earthquake

Technical Field

The utility model relates to a building structure field, more specifically relates to a building structure roof beam connection structure that combats earthquake.

Background

The building is made of clay, bricks, tiles, stones and wood for people; (reinforced concrete and section bars are used recently) and other building materials, such as houses, bridges, plants, gymnasiums, cave dwellings, water towers, temples and the like. In a broad sense, landscapes and gardens are also part of buildings. More broadly, nests that are intentionally created by animals may also be counted as buildings. The building comprises three elements: building functions, building techniques and building art images.

In the related art, the building earthquake engineering adopts the energy-consuming vibration of a damper or absorbs the resonance frequency to weaken the earthquake acting force, and adopts an earthquake-resistant fastener to fix the structure capable of bearing the earthquake. Because the seismic fasteners connect the two building structures, the integrity of the structures cannot be maintained when subjected to a vibration load, resulting in insecure connection between the building structures, which leads to poor seismic performance of the building, particularly in the vertical connection of the building structure beams.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem in the background to a building structure roof beam connection structure that combats earthquake is provided.

In order to achieve the above object, the utility model provides a following technical scheme: including the main structure body, the inboard position fixedly connected with strengthening mechanism and the first buffer gear of main structure body, first buffer gear is located strengthening mechanism's inboard position, main structure body's inboard extreme angle position fixedly connected with second buffer gear and atress mechanism, the end angle surface setting of atress mechanism laminating main structure body, strengthening mechanism includes gusset plate and first fixing bolt, first buffer gear includes the buffer layer, buffer bar and bracing piece, the buffer bar is located buffer layer both sides position, and the bracing piece is located between the buffer bar, second buffer gear includes inoxidizing coating and lag, lag fixed connection is on the protective layer surface, atress mechanism includes stressed layer and bottom plate, the fixed second set screw that sets up between bottom plate and the main structure body.

Preferably, the first fixing screws are fixedly connected to two end positions of the reinforcing plate and penetrate through the surface of the structural body.

Preferably, the positions of the two ends of the reinforcing plate are bevel angles, the bevel angles are larger than 90 degrees, and the inner side surfaces of the two ends of the reinforcing plate are attached to the structure main body.

Preferably, the buffer layer sets up to rubber block-shaped, and the inboard surface is the arc setting, and the buffer beam becomes two settings, and both totalities of buffer beam and buffer layer are "W" form, and the outer end of buffer beam is the dog-ear setting, and the embedding sets up compression spring between outer end position and the lag, and the front end of bracing piece is the triangle setting, and the inboard end angle surface of laminating inoxidizing coating sets up.

Preferably, the protective layer is a foamed rubber layer, arc-shaped grooves are distributed on the inner side surface of the protective layer, and the protective sleeve and the second fixing screws are arranged in a matched mode.

Preferably, the inner side surface of the bottom plate attaching structure main body is provided, and the stress layer is a hard plastic plate.

The utility model provides a building structure roof beam connection structure that combats earthquake has following beneficial effect:

1. this kind of building structure roof beam antidetonation connection structure through strengthening mechanism, after finishing all the other mechanism's main parts installation, strengthening mechanism is slope diagonal angle setting in main structure's inboard, effectually reinforces main structure, strengthens main structure's structural strength, reaches antidetonation effect.

2. This kind of building structure roof beam antidetonation connection structure, the buffer layer at first cushions external force and vibrations, and the buffer beam is when supporting the buffer layer, and the compression spring that the outer end position embedding set up cushions it when receiving external force to reach shock-resistant effect, the holistic bearing strength of a buffer gear is strengthened to the bracing piece.

3. This kind of building structure roof beam connection structure that combats earthquake through second buffer gear, effectually cushions external force vibrations, and the arc recess that the inoxidizing coating bottom surface set up, effectual reinforcing shock-absorbing capacity.

4. This kind of building structure roof beam antidetonation connection structure carries out final support and buffering to the buffering external force that receives the structure main part through the atress mechanism, reaches antidetonation effect.

Drawings

Fig. 1 is a cross-sectional view of the overall structure of the present invention.

Fig. 2 is an exploded view of the overall structure of the present invention.

In FIGS. 1-2: 1-structural body, 2-reinforcing mechanism, 201-reinforcing plate, 202-first fixing screw, 3-first buffer mechanism, 301-buffer layer, 302-buffer rod, 303-support rod, 4-second buffer mechanism, 401-protective layer, 402-protective sleeve, 5-stress mechanism, 501-stress layer, 502-bottom plate and 6-second fixing screw.

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 2, in an embodiment of the present invention, an earthquake-proof connection structure for building structural beams includes a main structure 1, a reinforcing mechanism 2 and a first buffering mechanism 3 are fixedly connected to an inner side position of the main structure 1, the first buffering mechanism 3 is located at an inner side position of the reinforcing mechanism 2, a second buffering mechanism 4 and a force-receiving mechanism 5 are fixedly connected to an inner side end angle position of the main structure 1, the force-receiving mechanism 5 is disposed to be attached to an end angle surface of the main structure 1, the reinforcing mechanism 2 includes a reinforcing plate 201 and a first fixing bolt 202, the first buffering mechanism 3 includes a buffer layer 301, a buffer rod 302 and a support rod 303, the buffer rod 302 is located at two side positions of the buffer layer 301, the support rod 303 is located between the buffer rods 302, the second buffering mechanism 4 includes a protection layer 401 and a protection cover 402, the protection cover 402 is fixedly connected to a surface of the protection layer 401, the force-receiving, a second fixing screw 6 is fixedly arranged between the bottom plate 502 and the structure body 1.

In this embodiment, the first fixing screws 202 are fixedly connected to two ends of the reinforcing plate 201 and penetrate through the surface of the structural body 1.

In this embodiment, gusset plate 201 both ends position is the dog-ear setting, and the dog-ear angle is greater than 90, and the inboard surface setting of the both ends laminating structure main part 1 of gusset plate 201, through strengthening mechanism 2, after finishing all the other mechanism's main part installations, strengthening mechanism 2 is the slope diagonal angle setting in structure main part 1's inboard, and effectual structure main part 1 is consolidated, strengthens structure main part 1's structural strength, reaches antidetonation effect.

In this embodiment, the buffer layer 301 is set to be rubber block-shaped, and the inner side surface is arc-shaped, the buffer rod 302 is set up in two, and the buffer rod 302 and the buffer layer 301 are both generally "W" shaped, the outer end of the buffer rod 302 is bevel-shaped, and a compression spring is embedded between the outer end position and the protection sleeve 402, the front end of the support rod 303 is triangular, the inner side corner surface of the protection layer 401 is set, the buffer layer 301 firstly buffers external force and vibration, while the buffer rod 302 supports the buffer layer 301, the compression spring embedded at the outer end position buffers the external force, thereby achieving the anti-vibration effect, and the support rod 303 strengthens the overall bearing strength of the first buffer mechanism 3.

In this embodiment, inoxidizing coating 401 sets up to the foaming rubber layer, and the inboard surface distributes arc recess, and the supporting setting of lag 402 and second fixed screw 6 through second buffer gear 4, effectually cushions external force vibrations, and the arc recess that inoxidizing coating 401 bottom surface set up, effectual reinforcing shock-absorbing capacity.

In this embodiment, the bottom plate 502 is attached to the inner surface of the structural body 1, the stress layer 501 is a rigid plastic plate, and the external force buffered by the stress mechanism 5 on the structural body 1 is finally supported and buffered, so as to achieve the anti-seismic effect.

Use the utility model relates to a building structure roof beam antidetonation connection structure, at first, the user of service installs fixedly from inside to outside from the medial extremity position of main structure body 1 to straining device 5, second buffer gear 4, first buffer gear 3 and straining device 2, straining device 2 and straining device 5 carry out fixed connection to it through first reinforcement screw 202 and second fixed screw 6 respectively, in the in-process of using, first buffer gear 3 and second buffer gear 4 cushion the external force vibrations, and the intensity and the bearing capacity of 5 additional strengthening structure main parts 1 of straining device, when connecting second fixed screw 6, second fixed screw 6 passes bottom plate 502 and stress layer 501, in the front end embedding lag 402.

The above is only the preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, without departing from the concept of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent.

Claims (6)

1. The utility model provides a building structure roof beam connection structure that combats earthquake, includes main structure (1), its characterized in that: the structure comprises a structure body (1), wherein a reinforcing mechanism (2) and a first buffering mechanism (3) are fixedly connected to the inner side position of the structure body (1), the first buffering mechanism (3) is located at the inner side position of the reinforcing mechanism (2), the inner side end angle position of the structure body (1) is fixedly connected with a second buffering mechanism (4) and a stress mechanism (5), the stress mechanism (5) is arranged in a mode of being attached to the end angle surface of the structure body (1), the reinforcing mechanism (2) comprises a reinforcing plate (201) and a first fixing screw (202), the first buffering mechanism (3) comprises a buffering layer (301), a buffering rod (302) and a supporting rod (303), the buffering rod (302) is located at two sides of the buffering layer (301), the supporting rod (303) is located between the buffering rods (302), the second buffering mechanism (4) comprises a protection layer (401) and a protection layer (402), and the protection layer (402) is fixedly connected to, the stress mechanism (5) comprises a stress layer (501) and a bottom plate (502), and a second fixing screw (6) is fixedly arranged between the bottom plate (502) and the structure main body (1).

2. The seismic connection structure of building structural beams of claim 1, wherein: the first fixing screws (202) are fixedly connected to the two ends of the reinforcing plate (201) and penetrate through the surface of the structure body (1).

3. The seismic connection structure of building structural beams of claim 1, wherein: the two ends of the reinforced plate (201) are arranged in a folded angle mode, the folded angle is larger than 90 degrees, and the two ends of the reinforced plate (201) are attached to the inner side surface of the structure main body (1).

4. The seismic connection structure of building structural beams of claim 1, wherein: buffer layer (301) set up to rubber block shape, and the inboard surface is the arc setting, and buffer beam (302) become two settings, and both totalities of buffer beam (302) and buffer layer (301) are "W" form, and the outer end of buffer beam (302) is the dog-ear setting, and the embedding sets up compression spring between outer end position and lag (402), and the front end of bracing piece (303) is the triangle setting, and the inboard end angle surface setting of laminating inoxidizing coating (401).

5. The seismic connection structure of building structural beams of claim 1, wherein: the protective layer (401) is arranged to be a foaming rubber layer, arc-shaped grooves are distributed in the inner side surface of the protective layer, and the protective sleeve (402) and the second fixing screw (6) are arranged in a matched mode.

6. The seismic connection structure of building structural beams of claim 1, wherein: the inner side surface of the bottom plate (502) attached to the main structure body (1) is provided, and the stress layer (501) is a hard plastic plate.

Images