CN220228126U

CN220228126U - Building anti-seismic support

Info

Publication number: CN220228126U
Application number: CN202323163529.9U
Authority: CN
Inventors: 廖述成; 周峰
Original assignee: Suzhou Churun Ecological Technology Co ltd
Current assignee: Suzhou Churun Ecological Technology Co ltd
Priority date: 2023-11-23
Filing date: 2023-11-23
Publication date: 2023-12-22
Anticipated expiration: 2033-11-23

Abstract

The utility model discloses a building anti-seismic bracket which comprises a supporting plate, shock absorbers and a fixing component for fixing a pipeline, wherein the supporting plate is fixedly provided with the fixing component through the shock absorbers, the shock absorbers comprise two first shock absorbers and two second shock absorbers, the two first shock absorbers are obliquely and rotatably arranged at the lower parts of two sides of the supporting plate, the two second shock absorbers are respectively rotatably arranged at one end, far away from the supporting plate, of each first shock absorber, and one end, far away from the first shock absorbers, of each second shock absorber is fixedly connected with two sides of the fixing component. According to the utility model, one end of each first shock absorber far away from the supporting plate is respectively rotatably provided with one second shock absorber, one ends of the two second shock absorbers far away from the first shock absorbers are respectively fixedly connected with two sides of the fixing component, and a user firstly performs matched shock absorption through the two first shock absorbers and then performs transverse shock absorption through the two second shock absorbers.

Description

Building anti-seismic support

Technical Field

The utility model belongs to the technical field of building earthquake resistance, and particularly relates to a building earthquake-resistant support.

Background

An anti-seismic bracket is a structural device for improving the anti-seismic performance of a building and aims to reduce the damage of the earthquake to the building. It is generally designed as a rigid or deformable support system capable of absorbing and dispersing seismic energy, thereby improving the stability and safety of the building.

The utility model discloses an antidetonation support, including the link, the top central point of link puts fixedly connected with down the staple bolt, the movable frame is hollow structure, and the internally mounted of movable frame has interior pole, the top fixedly connected with limiting plate of interior pole, and the externally mounted of interior pole has the spring, the movable frame lower extreme passes through-hole and mount fixed connection, the bottom surface position of movable frame installs and is used for the cooperation limiting plate to carry out spacing solid fixed ring. Above-mentioned install the diagonal bar respectively at the both ends of link for when the support outside receives vibrations, can make the support follow outside vibrations skew, prevent that the support from being loose because of outside vibrations, through the top fixed mounting interior pole at the movable frame to install the spring in the outside of interior pole, make when vibrations, the spring can make interior pole drive the movable frame and reciprocate, thereby promote the antidetonation effect.

However, the conventional technology has some problems: the traditional device adopts a damping structure to vertically or obliquely install the transmission pipeline, but vibration in the transverse direction exists, and the traditional device cannot well eliminate the vibration in the transverse direction, so that the building anti-seismic bracket is provided.

Disclosure of Invention

Aiming at the problems in the prior art, the utility model provides a building anti-seismic bracket, which solves the problems that the traditional device adopts a damping structure to vertically or obliquely install a transmission pipeline, but the traditional device can not well eliminate the vibration in the transverse direction when vibrating.

The utility model discloses a building anti-seismic bracket, which comprises a supporting plate, shock absorbers and a fixing component for fixing a pipeline, wherein the fixing component is fixedly arranged on the supporting plate through the shock absorbers, the shock absorbers comprise two first shock absorbers and two second shock absorbers, the two first shock absorbers are obliquely and rotatably arranged at the lower parts of two sides of the supporting plate, the two second shock absorbers are respectively rotatably arranged at one end, far away from the supporting plate, of each first shock absorber, and one end, far away from the first shock absorber, of each second shock absorber is fixedly connected with two sides of the fixing component.

As the preferable mode of the utility model, the fixing component consists of a first arc-shaped clamping plate, a second arc-shaped clamping plate and a second screw rod, wherein the first arc-shaped clamping plate and the second arc-shaped clamping plate have the same structure, and the first arc-shaped clamping plate and the second arc-shaped clamping plate are symmetrically arranged.

As preferable in the utility model, the first arc-shaped clamping plate is fixedly provided with the second arc-shaped clamping plate through the second screw, and a clamping groove is formed between the first arc-shaped clamping plate and the second arc-shaped clamping plate.

As the preferable mode of the utility model, the supporting plate consists of transverse plates, sliding plates and first screw rods, wherein two sliding plates are arranged, a plurality of positioning holes are respectively formed in the two sliding plates, the sliding plates are in sliding connection with the transverse plates, and the sliding plates are fixedly arranged on the upper parts of the transverse plates through the first screw rods.

As the preferable one of the utility model, the lower part of one side of the sliding plate far away from the transverse plate is fixedly connected with a first installation seat, the first shock absorber is fixedly installed in the first installation seat, one end of the first shock absorber far away from the first installation seat is fixedly connected with a second installation seat, the second installation seat is rotatably provided with a third installation seat, the second shock absorber is fixedly installed in the third installation seat, and one end of the second shock absorber far away from the third installation seat is fixedly connected with the first arc-shaped clamping plate.

As the preferred structure of the utility model, the first shock absorber and the second shock absorber are the same, the first shock absorber consists of a shell, a telescopic rod and a spring, a channel which is matched with the telescopic rod in shape is formed in the shell, the telescopic rod is slidably arranged in the channel of the shell through the spring, a first air cavity is formed between the telescopic rod and the shell, a second air cavity is formed outside the shell, an air hole is formed between the first air cavity and the second air cavity of the shell, and the first air cavity penetrates through the second air cavity through the air hole.

Compared with the prior art, the utility model has the beneficial effects that: according to the utility model, the transmission pipeline is clamped and installed through the fixing component, the supporting plate is firstly fixed on the wall top during installation, then the fixing component is connected with the pipeline through the shock absorber for suspension support, so that the pipeline can be damped, two specific first shock absorbers are installed at the lower parts of two sides of the supporting plate in a tilting mode, two second shock absorbers are arranged, one end of each first shock absorber, which is far away from the supporting plate, is respectively and rotatably provided with one second shock absorber, one end of each second shock absorber, which is far away from the first shock absorber, is respectively and fixedly connected with two sides of the fixing component, a user firstly performs matched shock absorption through the two first shock absorbers, and then the two second shock absorbers perform transverse shock absorption, so that the problem of single shock absorption direction of traditional equipment is solved.

Drawings

FIG. 1 is a schematic view of the overall structure provided by an embodiment of the present utility model;

FIG. 2 is a schematic view of FIG. 1 at A provided by an embodiment of the present utility model;

fig. 3 is a schematic view of a second shock absorber according to an embodiment of the present utility model.

In the figure: 1. a support plate; 2. a first mount; 3. a first shock absorber; 4. a fixing assembly; 5. a second damper; 6. a second mounting base; 7. a third mount;

110. a cross plate; 120. a slide plate; 130. positioning holes; 140. a first screw;

410. a first arc splint; 420. a second arc splint; 430. a second screw;

510. a housing; 520. a telescopic rod; 530. a spring; 540. a first air chamber; 550. a second air chamber; 560. and (5) air holes.

Description of the embodiments

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings.

The structure of the present utility model will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 3, the building anti-seismic bracket provided by the embodiment of the utility model comprises a supporting plate 1, shock absorbers and a fixing component 4 for fixing a pipeline, wherein the supporting plate 1 is fixedly provided with the fixing component 4 through the shock absorbers, the shock absorbers comprise a first shock absorber 3 and a second shock absorber 5, the first shock absorbers 3 are arranged in two, the two first shock absorbers 3 are rotatably arranged at the lower parts of two sides of the supporting plate 1, the second shock absorbers 5 are arranged in two, one end, far away from the supporting plate 1, of each first shock absorber 3 is respectively rotatably provided with one second shock absorber 5, and one end, far away from the first shock absorbers 3, of each second shock absorber 5 is respectively fixedly connected with two sides of the fixing component 4.

Above-mentioned building antidetonation support, press from both sides tight installation transmission pipeline through fixed subassembly 4, at first fix backup pad 1 at the wall top during the installation, then rethread bumper shock absorber comes to carry out suspended support to fixed subassembly 4 communicating pipeline for the pipeline can obtain the shock attenuation, and two specific first bumper shock absorbers 3 incline to rotate and install in backup pad 1 both sides lower part, and second bumper shock absorber 5 is equipped with two, and one end that backup pad 1 was kept away from to every first bumper shock absorber 3 rotates respectively and installs a second bumper shock absorber 5, and one end that first bumper shock absorber 3 was kept away from to two second bumper shock absorbers 5 respectively with fixed subassembly 4's both sides fixed connection, the user carries out the cooperation shock attenuation at first through two first bumper shock absorbers 3, then two second bumper shock absorbers 5 carry out horizontal shock attenuation, have solved the single problem of traditional equipment shock attenuation direction.

In this embodiment, when the fixing assembly 4 is fixed to the transmission pipe, the fixing assembly is composed of a first arc clamping plate 410, a second arc clamping plate 420 and a second screw 430, the first arc clamping plate 410 and the second arc clamping plate 420 have the same structure, the first arc clamping plate 410 and the second arc clamping plate 420 are symmetrically arranged, the second arc clamping plate 420 is fixed to the first arc clamping plate 410 through the second screw 430, and a clamping groove is formed between the first arc clamping plate 410 and the second arc clamping plate 420. In use, the transfer tube is placed in the clamping groove formed between the first arc clamping plate 410 and the second arc clamping plate 420, and then the second screw 430 is used to fix the first arc clamping plate 410 and the second arc clamping plate 420, thereby completing the fixation of the transfer plate.

In this embodiment, for conveniently adjusting the supporting angle of the first shock absorber 3 and the second shock absorber 5, the supporting plate 1 is composed of a transverse plate 110, a sliding plate 120 and a first screw 140, two sliding plates 120 are provided with two positioning holes 130, the sliding plate 120 is slidably connected with the transverse plate 110, the sliding plate 120 is fixedly mounted on the upper portion of the transverse plate 110 through the first screw 140, a user can adjust the position of the sliding plate 120 in advance, then the positioning holes 130 of the sliding plate 120 are aligned with screw holes of the transverse plate 110, the positioning holes 130 at different positions of the sliding plate 120 are connected with the first screw 140 to realize the position adjustment and fixation of the sliding plate 120, the position of the sliding plate 120 is not influenced by the normal use of the fixed assembly 4 for realizing the adjustment, one side lower portion of the sliding plate 120 away from the transverse plate 110 is fixedly connected with a first mounting seat 2, the first shock absorber 3 is fixedly mounted inside the first mounting seat 2, one end of the first shock absorber 3 away from the first mounting seat 2 is fixedly connected with a second mounting seat 6, the second mounting seat 6 is rotatably mounted with a third mounting seat 7, the second shock absorber 5 is fixedly mounted on the first mounting seat 7, and the first shock absorber 5 is fixedly mounted on the first mounting seat 7 is fixedly mounted on the side of the first mounting seat 7, and the first shock absorber 3 is fixedly mounted on the first mounting seat 3, and the first shock absorber is fixedly mounted on the first mounting seat 6 and is fixedly mounted on the first mounting seat 6.

In this embodiment, the first shock absorber 3 and the second shock absorber 5 have the same structure, in order to achieve the shock absorbing effect, the first shock absorber 3 is composed of a casing 510, a telescopic rod 520 and a spring 530, a channel matching the shape of the telescopic rod 520 is provided inside the casing 510, the telescopic rod 520 is slidably mounted inside the channel of the casing 510 through the spring 530, when vibration occurs, the transmission pipe can displace and reset through the spring 530, and in particular, a first air cavity 540 is formed between the telescopic rod 520 and the casing 510, so that damping can be increased when the air is compressed, and in order to achieve the same increase of damping when the telescopic rod 520 stretches out, a second air cavity 550 is provided outside the casing 510, an air hole 560 is further provided between the first air cavity 540 and the second air cavity 550 of the casing 510, the first air cavity 540 penetrates through the second air cavity 550 through the air hole 560, and air enters the second air cavity 550 for compression and discharge through the air hole 560 each time, so that the damping effect when the telescopic rod 520 stretches out and retracts is achieved, and the shock absorbing of the transmission pipe is completed.

Working principle: when using, press from both sides tight installation transmission pipeline through fixed subassembly 4, at first fix backup pad 1 at the wall top during the installation, then rethread bumper shock absorber comes to carry out suspension support to fixed subassembly 4 communicating pipeline for the pipeline can obtain the shock attenuation, and two specific first bumper shock absorbers 3 rotate and install in backup pad 1 both sides lower part, and second bumper shock absorber 5 is equipped with two, and every first bumper shock absorber 3 is kept away from backup pad 1's one end and is rotated one second bumper shock absorber 5 of installation respectively, and two second bumper shock absorbers 5 are kept away from first bumper shock absorber 3's one end respectively with fixed subassembly 4's both sides fixed connection, and the user is through two first bumper shock absorbers 3 at first carrying out the cooperation shock attenuation, then two second bumper absorbers 5 carry out horizontal shock attenuation, have solved the single problem of traditional equipment shock attenuation direction.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. Building antidetonation support, including backup pad (1), bumper shock absorber and be used for fixed pipeline's fixed subassembly (4), backup pad (1) pass through bumper shock absorber fixed mounting fixed subassembly (4), its characterized in that: the shock absorber comprises a first shock absorber (3) and a second shock absorber (5), wherein the first shock absorber (3) is provided with two shock absorbers, the two shock absorbers are rotatably mounted on the lower portions of two sides of the supporting plate (1), the second shock absorber (5) is provided with two shock absorbers, each shock absorber is provided with two shock absorbers, the first shock absorber (3) is away from one end of the supporting plate (1) and is rotatably mounted with one shock absorber (5), and the two shock absorbers are away from one end of the first shock absorber (3) and are fixedly connected with two sides of the fixing component (4).

2. A building anti-seismic bracket as claimed in claim 1, wherein: the fixing assembly (4) is composed of a first arc-shaped clamping plate (410), a second arc-shaped clamping plate (420) and a second screw (430), the first arc-shaped clamping plate (410) and the second arc-shaped clamping plate (420) are identical in structure, and the first arc-shaped clamping plate (410) and the second arc-shaped clamping plate (420) are symmetrically arranged.

3. A building anti-seismic bracket as claimed in claim 2, wherein: the first arc-shaped clamping plate (410) is fixedly provided with the second arc-shaped clamping plate (420) through the second screw rod (430), and a clamping groove is formed between the first arc-shaped clamping plate (410) and the second arc-shaped clamping plate (420).

4. A building anti-seismic bracket as claimed in claim 2, wherein: the support plate (1) comprises a transverse plate (110), sliding plates (120) and first screw rods (140), the sliding plates (120) are provided with two positioning holes (130) respectively formed in the two sliding plates (120), the sliding plates (120) are in sliding connection with the transverse plate (110), and the sliding plates (120) are fixedly mounted on the upper portions of the transverse plate (110) through the first screw rods (140).

5. A building anti-seismic bracket as defined in claim 4, wherein: the utility model discloses a scooter, including cross plate (110), slide (120), first mount pad (2) of one side lower part fixedly connected with of cross plate (110), first mount pad (2) inside fixed mounting first bumper shock absorber (3), first bumper shock absorber (3) are kept away from one end fixedly connected with second mount pad (6) of first mount pad (2), second mount pad (6) rotate and install third mount pad (7), second bumper shock absorber (5) fixed mounting is in inside third mount pad (7), second bumper shock absorber (5) are kept away from one end fixed connection of third mount pad (7) first arc splint (410).

6. A building anti-seismic bracket as claimed in claim 1, wherein: the novel air-conditioning device is characterized in that the first shock absorber (3) and the second shock absorber (5) are identical in structure, the first shock absorber (3) is composed of a shell (510), a telescopic rod (520) and a spring (530), a channel which is anastomotic in shape with the telescopic rod (520) is formed in the shell (510) in an inside mode through the spring (530), a first air cavity (540) is formed between the telescopic rod (520) and the shell (510), a second air cavity (550) is formed outside the shell (510), an air hole (560) is formed between the first air cavity (540) and the second air cavity (550) of the shell (510), and the first air cavity (540) is communicated with the second air cavity (550) through the air hole (560).