CN220353080U - Assembled building shock attenuation connection structure for building - Google Patents

Abstract

The utility model discloses an assembled building shock-absorbing connection structure for a building, which relates to the technical field of building connection and comprises a base and a shock-absorbing mechanism, wherein the shock-absorbing mechanism for reducing sound is arranged above the base, and the shock-absorbing mechanism for supporting is arranged above the shock-absorbing mechanism. This assembled building shock attenuation connection structure for building compares with current device, utilize first damping spring to antidetone, shock attenuation through base and shock-proof plate, make it more stable, thereby the security has been improved, reuse baffle and first sound absorption pad absorb sound, reduce its sound that sends when making the shock attenuation, absorb shock attenuation sound again through the second sound absorption pad, make shock attenuation sound reduce once more, thereby shock attenuation sound has been reduced, reuse pillar and shock strut utilize damping spring and second damping spring to carry out further shock attenuation, thereby its absorbing effect has been improved by a wide margin, stability has been improved simultaneously and the security has been increased.

Description

Assembled building shock attenuation connection structure for building

Technical Field

The utility model relates to the technical field of building connection, in particular to an assembled building shock absorption connection structure for a building.

Background

The energy dissipation device is arranged at certain parts (such as a support, a shear wall, a connecting joint or a connecting piece) of the structure, friction, bending (or shearing or torsion) and elastoplastic (or viscoelasticity) hysteresis deformation are generated through the energy dissipation device to dissipate or absorb the energy of the earthquake input structure so as to reduce the earthquake reaction of the main structure, thereby avoiding the structure from being damaged or collapsing and achieving the purpose of damping control.

The application number is as follows: CN202122432389.5, a shock attenuation building structure, through cylinder, first ring, first round bar, third ring, first spring, fourth round bar, third spring and the cooperation setting of second loop bar, during the use, can fix the cylinder through first ring and first round bar, and then when the cylinder takes place to rock, then the cooperation of first spring, third ring, fourth round bar, third spring and second loop bar is used, thereby reaches the absorbing effect, can slow down the damage of earthquake to the cylinder.

Similar to the above-mentioned application, there are currently disadvantages: during the use, the shock attenuation effect is relatively poor, therefore stability reduces, and then has reduced whole security, and comparatively troublesome when the installation supports, needs to consume certain time.

Accordingly, in view of the above, research and improvement are made on the existing structure and the defects, and an assembled building shock-absorbing connection structure for building is provided, so as to achieve the purpose of more practical value.

Disclosure of Invention

The utility model aims to provide an assembled building shock absorption connecting structure for a building, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an assembled building shock attenuation connection structure for building, includes base and damper, the top of base is provided with the anti-seismic mechanism who is used for reducing sound for the support damper sets up in anti-seismic mechanism's top, anti-seismic mechanism includes first damping spring, shock-resistant board, baffle and first sound pad of inhaling, the shock-resistant board is installed to first damping spring's top, the baffle is installed to the top both sides of base, the inboard of baffle is provided with first sound pad of inhaling, damper includes pillar, second sound pad, shock-absorbing column, shock-absorbing spring and second damping spring, the inboard of pillar is provided with the second and inhales the sound pad, the shock-absorbing column is installed to the inboard top of pillar, shock-absorbing spring is installed in the shock-absorbing column outside, second damping spring is installed to the lower extreme of shock-absorbing column.

Further, a supporting plate is arranged above the damping mechanism, and connecting blocks are arranged on two sides of the upper part of the supporting plate.

Further, the fixture for increasing the steadiness is installed to the top of connecting block, fixture includes iron plate, positive and negative threaded rod and threaded bearing, the internally mounted of iron plate has positive and negative threaded rod, the outside of positive and negative threaded rod is provided with threaded bearing.

Further, the clamping mechanism further comprises a clamping block, a supporting rod and a limiting clamping rod, wherein the clamping block is arranged above the threaded bearing, the supporting rod is arranged on one side of the clamping block, and the limiting clamping rod is arranged on the other side of the clamping block.

Further, the middle part of base is installed and is adjusted telescopic machanism of length, telescopic machanism includes fixed plate and spacing groove, spacing groove is seted up on the both sides top surface of fixed plate.

Further, telescopic machanism still includes bolt and fixed block, and the inside of spacing groove is provided with the bolt, the fixed block is installed to the lower extreme of bolt.

Compared with the prior art, the utility model provides an assembled building shock absorption connecting structure for a building, which has the following beneficial effects:

1. according to the utility model, the base and the shock-proof plate are used for shock resistance and shock absorption by using the first damping spring, so that the shock resistance and shock absorption are more stable, the safety is improved, the baffle plate and the first sound absorption pad are used for absorbing sound, so that the sound emitted by the shock-proof plate is reduced during shock absorption, the second sound absorption pad is used for absorbing the shock absorption sound again, the shock absorption sound is reduced, the shock absorption is reduced, the strut and the shock absorption column are used for further shock absorption by using the shock absorption spring and the second damping spring, the shock absorption effect is greatly improved, and meanwhile, the stability and the safety are improved;

2. according to the utility model, the clamping block is used for clamping the building beam frame, and the positive and negative threaded rods and the threaded bearings in the iron block are used for adjusting the space, so that the building beam frames with different widths are convenient to clamp and support, the clamping type fixed support also improves the convenience of operation, saves time, supports the clamping block by using the supporting rod, and enables the clamping block to be more stable, and the limiting clamping rod is used for enabling the clamping to be more stable, so that the clamping effect of the clamping block is improved;

3. according to the utility model, the length of the fixing plate can be adjusted through the fixing plate, and the fixing plate is limited and fixed through the limiting groove by using the bolts and the fixing blocks, so that the fixing plate can be adjusted according to the working requirements, the use range is improved, and meanwhile, the fixing plate is more convenient to use.

Drawings

FIG. 1 is a schematic diagram of the whole front view structure of an assembled building shock absorbing connection structure for a building;

FIG. 2 is a schematic cross-sectional view of an integral shock absorbing mechanism of an assembled building shock absorbing connection structure for a building according to the present utility model;

FIG. 3 is a schematic cross-sectional view of a clamping mechanism for a shock absorbing connection structure of an assembled building in accordance with the present utility model;

FIG. 4 is a schematic cross-sectional view of a telescopic mechanism of a shock absorbing connection structure for a building according to the present utility model;

fig. 5 is a schematic perspective view of a clamping mechanism of an assembled building shock-absorbing connection structure for a building.

In the figure: 1. a base; 2. an anti-vibration mechanism; 201. a first damping spring; 202. an anti-vibration plate; 203. a baffle; 204. a first sound absorbing pad; 3. a damping mechanism; 301. a support post; 302. a second sound absorbing pad; 303. a shock-absorbing column; 304. a damping spring; 305. a second damping spring; 4. a support plate; 5. a connecting block; 6. a clamping mechanism; 601. iron blocks; 602. positive and negative threaded rods; 603. a threaded bearing; 604. a clamping block; 605. a support rod; 606. a limit clamping rod; 7. a telescoping mechanism; 701. a fixing plate; 702. a limit groove; 703. a bolt; 704. and a fixed block.

Detailed Description

In order that the utility model may be readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings, in which, however, the utility model may be embodied in many different forms and are not limited to the embodiments described herein, but are instead provided for the purpose of providing a more thorough and complete disclosure of the utility model.

It will be understood that when an element is referred to as being "mounted" on another element, it can be directly on the other element or intervening elements may also be present; when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present; the terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs; the terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model; the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1-2, an assembled building vibration-damping connection structure for building comprises a base 1 and a vibration-damping mechanism 3, wherein the vibration-damping mechanism 2 for reducing sound is arranged above the base 1, the vibration-damping mechanism 3 for supporting is arranged above the vibration-damping mechanism 2, the vibration-damping mechanism 2 comprises a first damping spring 201, a vibration-damping plate 202, a baffle 203 and a first vibration-damping cushion 204, the vibration-damping plate 202 is arranged above the first damping spring 201, the baffles 203 are arranged on two sides above the base 1, the first vibration-damping cushion 204 is arranged on the inner side of the baffle 203, the vibration-damping mechanism 3 comprises a strut 301, a second vibration-damping cushion 302, a vibration-damping column 303, a vibration-damping spring 304 and a second damping spring 305 are arranged on the inner side of the strut 301, the vibration-damping column 303 is arranged on the outer side of the vibration-damping column, the second damping spring 305 is arranged at the lower end of the vibration-damping column 303, the vibration-damping plate 202 is more stable by utilizing the first damping spring 201, the safety is improved, the vibration-damping plate 203 and the first vibration-damping cushion 204 are utilized, the sound-damping effect is greatly improved by the second vibration-damping spring 302 and the vibration-damping spring, and the sound-damping effect is further improved by the second vibration-damping spring 302, and the sound is greatly reduced by the vibration-damping effect is further improved by the vibration-damping effect of the strut 301, and the sound is greatly reduced by the vibration-damping effect, and the vibration-damping effect is further improved by the vibration-damping effect is reduced by the vibration-damping effect, and the sound and the vibration-damping effect is greatly by the vibration-damping effect is reduced by the vibration-damping effect and the sound and the vibration-absorbing effect is reduced by the sound and the vibration;

as shown in fig. 1 and 3-4, a supporting plate 4 is installed above the damping mechanism 3, connecting blocks 5 are installed on two sides above the supporting plate 4, a clamping mechanism 6 used for increasing stability is installed above the connecting blocks 5, the clamping mechanism 6 comprises an iron block 601, a positive threaded rod 602 and a negative threaded rod 602 and a threaded bearing 603, the positive threaded rod 602 and the negative threaded rod 602 are installed inside the iron block 601, the threaded bearing 603 is arranged on the outer side of the positive threaded rod 602, the clamping mechanism 6 further comprises a clamping block 604, a supporting rod 605 and a limiting clamping rod 606, a clamping block 604 is installed above the threaded bearing 603, a supporting rod 605 is installed on one side of the clamping block 604, the limiting clamping rod 606 is installed on the other side of the clamping block 604, and the clamping block 604 clamps the clamping beam frame with different widths through the positive threaded rod 602 and the threaded bearing 603, so that the clamping support is convenient to clamp the beam frame with different widths, the convenience of operation is also improved, the time is saved, the supporting rod 604 is supported with stability, the limiting clamping rod 606 is reused, the clamping effect is more stable, and the clamping effect is improved; the telescopic machanism 7 of adjusting length is installed to the mid-mounting of base 1, telescopic machanism 7 includes fixed plate 701 and spacing groove 702, spacing groove 702 is seted up on the both sides top surface of fixed plate 701, telescopic machanism 7 still includes bolt 703 and fixed block 704, the inside of spacing groove 702 is provided with bolt 703, fixed block 704 is installed to the lower extreme of bolt 703, make it adjust the length through fixed plate 701, it is spacing fixed to it through spacing groove 702 utilization bolt 703 and fixed block 704 for can adjust according to the demand of work, thereby the scope of using has been improved, it is more convenient to let its use simultaneously.

Working principle: the assembled building shock absorption connecting structure for the building is characterized in that the base 1 and the shock-resistant plate 202 are used for shock resistance and shock absorption through the first damping spring 201, the baffle 203 and the first sound absorption pad 204 are used for absorbing sound, the second sound absorption pad 302 is used for absorbing the shock absorption sound again, the shock absorption sound is reduced again, the strut 301 and the shock absorption column 303 are used for further shock absorption through the shock absorption spring 304 and the second damping spring 305, the strut 604 is used for clamping the shock absorption connecting structure, the positive and negative threaded rods 602 and the threaded bearings 603 in the iron block 601 are used for adjusting the space of the strut, so that the beam frames with different widths are convenient to clamp and support, the strut 605 is used for supporting the strut 604, the strut 604 is enabled to be firmer, the limiting clamp rod 606 is used for firmer clamping, the fixed plate 701 is enabled to adjust the length, and the strut 702 and the fixed block 704 are used for limiting and fixing the strut blocks through the bolt 703, so that the beam frames with different widths can be adjusted according to working requirements.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. The utility model provides an assembled building shock attenuation connection structure for building, includes base (1) and damper (3), its characterized in that, the top of base (1) is provided with and is used for reducing the shock-resistant mechanism (2) of sound for support damper (3) set up in the top of shock-resistant mechanism (2), shock-resistant mechanism (2) are including first damping spring (201), shock-resistant plate (202), baffle (203) and first sound pad (204) of inhaling, shock-resistant plate (202) are installed to the top of first damping spring (201), baffle (203) are installed to the top both sides of base (1), the inboard of baffle (203) is provided with first sound pad (204), damper (3) are including pillar (301), second sound pad (302), shock-absorbing spring (304) and second damping spring (305), the inboard of pillar (301) is provided with second sound pad (302), shock-absorbing post (303) are installed to the inboard top of pillar (301), shock-absorbing spring (305) are installed to the inboard side, shock-absorbing spring (305) are installed down.

2. The assembled building shock absorption connection structure for the building according to claim 1, wherein a supporting plate (4) is arranged above the shock absorption mechanism (3), and connecting blocks (5) are arranged on two sides above the supporting plate (4).

3. The prefabricated building vibration-damping connection structure for building according to claim 2, wherein a clamping mechanism (6) for increasing stability is installed above the connecting block (5), the clamping mechanism (6) comprises an iron block (601), a positive threaded rod (602) and a threaded bearing (603), the positive threaded rod (602) is installed inside the iron block (601), and the threaded bearing (603) is arranged outside the positive threaded rod (602).

4. The prefabricated building shock absorption connection structure for construction according to claim 3, wherein the clamping mechanism (6) further comprises a clamping block (604), a supporting rod (605) and a limiting clamping rod (606), the clamping block (604) is installed above the threaded bearing (603), the supporting rod (605) is installed on one side of the clamping block (604), and the limiting clamping rod (606) is installed on the other side of the clamping block (604).

5. The assembled building shock absorption connection structure for the building according to claim 1, wherein a telescopic mechanism (7) for adjusting the length is installed in the middle of the base (1), the telescopic mechanism (7) comprises a fixing plate (701) and limiting grooves (702), and the limiting grooves (702) are formed in the upper surfaces of two sides of the fixing plate (701).

6. The prefabricated building vibration-damping connection structure for building according to claim 5, wherein the telescopic mechanism (7) further comprises a bolt (703) and a fixed block (704), the bolt (703) is arranged in the limiting groove (702), and the fixed block (704) is arranged at the lower end of the bolt (703).