CN221441762U - Anti-overturning tensile shock insulation support - Google Patents

Abstract

The utility model relates to the technical field of building tensile shock-insulation supports, and provides an anti-overturning tensile shock-insulation support, which comprises a bottom plate, wherein first mounting holes are formed in two sides of the top surface of the bottom plate, a lower mounting groove is fixedly connected to the middle part of the top surface of the bottom plate, a rubber pad is fixedly connected to the inner top surface of the lower mounting groove, an upper mounting groove is fixedly connected to the top end of the rubber pad, the top end of the upper mounting groove is bonded with a top plate through a hot vulcanization process, a movable groove can be driven to move back and forth in the horizontal direction through a set tensile assembly, the horizontal displacement position of the movable groove can be reset and pulled back according to the characteristics of a first spring, the tensile property of the device is improved, the displacement length of the movable groove can be limited by a limiting plate, meanwhile, the movable position of the movable groove driving the top plate is limited by the maximum limit displacement, the possibility of overturning of a building can be reduced when a large earthquake occurs, and the personal safety of people is protected.

Description

Anti-overturning tensile shock insulation support

Technical Field

The utility model relates to the technical field of building tensile shock insulation supports, in particular to an anti-overturning tensile shock insulation support.

Background

Earthquake is a natural disaster, which has been accompanied by the development of human history. Earthquake can cause serious damage to buildings which are places for life, work, study and the like. Earthquake waves are generated by the earthquake waves, so that the building generates vertical lifting and horizontal swinging, and when shearing or stretching stress of the building exceeds the ultimate strength of building construction, the building is broken and collapsed.

Through retrieval, the prior patent (bulletin number: CN 216475577U) discloses a shock insulation support, which comprises a body provided with a cavity and a telescopic platform vertically movably connected to the body, wherein a first shock absorption module is arranged in the cavity, the bottom end of the telescopic platform stretches into the body and is opposite to the first shock absorption module, two sides on the body are respectively provided with a transverse track, each track is movably connected with a sliding block, each sliding block is respectively provided with a transverse second shock absorption module between the sliding blocks and the body, and each sliding block is respectively connected with the telescopic platform in a rotating way through an upper connecting rod group. It has solved the easy damage of prior art isolation bearing and the relatively poor problem of shock attenuation effect.

However, in the above scheme, although the building can be isolated, the building is difficult to be subjected to larger tensile anti-overturning effect, so that the probability of overturning the building is larger when an earthquake occurs, the personal and property safety of people is threatened, and the practicability is poor.

In view of the above, the utility model provides an anti-overturning tensile shock insulation support.

Disclosure of utility model

The utility model provides an anti-overturning tensile shock insulation support, which solves the problem that the anti-overturning tensile shock insulation support is difficult to play a role in resisting tension and overturning for a building in the related technology.

The technical scheme of the utility model is as follows: the utility model provides an anti-overturning tensile shock insulation support, includes the bottom plate, its characterized in that, first mounting hole has been seted up to the top surface both sides of bottom plate, the top surface middle part fixedly connected with of bottom plate lower mounting groove the inside top surface fixedly connected with rubber pad of lower mounting groove, the top fixedly connected with of rubber pad goes up the mounting groove, the top of going up the mounting groove bonds through hot vulcanization technology has the roof, the second mounting hole has been seted up to the top surface both sides of roof, the top surface of bottom plate is provided with tensile subassembly, tensile subassembly's top is provided with the removal groove, the inside of removal groove is provided with buffer assembly;

The tensile assembly comprises a sliding rail, the sliding rail is fixedly connected to two sides of the top surface of the bottom plate, two ends of the sliding rail are fixedly connected with limiting plates, one side of each limiting plate is connected with a sliding rod in a penetrating and sliding mode, one end of each sliding rod is fixedly connected with a baffle, the other end of each sliding rod is fixedly connected to one end of each movable groove, and a first spring is arranged on the surface of each sliding rod between each limiting plate and each baffle in a surrounding mode.

Preferably, the two groups of the tensile assemblies are symmetrically distributed and arranged about the vertical center line of the bottom plate.

Preferably, the sliding rail is in a T shape, and the size of the baffle plate is larger than that of the first spring.

Preferably, the buffer assembly comprises a limiting rod, the limiting rod is fixedly connected to two ends of the inner portion of the movable groove, a second spring is arranged around the middle portion of the surface of the limiting rod, a movable block is connected to the surface of the limiting rod in a sliding mode, a connecting piece is fixedly connected to the top end of the movable block, a rotating rod is connected to the inner side of the connecting piece in a rotating mode, and the top end of the rotating rod is connected to the bottom face of the top plate in a rotating mode through the connecting piece.

Preferably, the moving blocks are provided with two groups, and the second springs are positioned between the two groups of moving blocks.

Preferably, a sliding hole is formed in one side of the moving block, and the limiting rod and the sliding hole formed in one side of the moving block are arranged in a matched mode.

Preferably, dampers are fixedly connected to the top surface of the bottom plate close to the left end and the right end, and third springs are arranged on the surfaces of the dampers in a surrounding mode.

Preferably, a T-shaped sliding groove is formed in the middle of the bottom end of the movable groove, and the size of the T-shaped sliding groove formed in the middle of the bottom end of the movable groove is matched with the size of the sliding rail.

The working principle and the beneficial effects of the utility model are as follows:

1. According to the utility model, through the tensile assembly, the movable groove is driven to move back and forth in the horizontal direction when an earthquake occurs, the horizontal displacement position of the movable groove can be reset and pulled back according to the characteristics of the first spring, the tensile performance of the device is improved, the displacement length of the movable groove can be limited by the limiting plate, meanwhile, the movable position of the movable groove driving the top plate is limited by the maximum limit displacement, the probability of overturning a building can be reduced when a large earthquake occurs, and the personal and property safety of people can be protected;

2. According to the utility model, the top plate drives the rotating rod to rotate through the buffer assembly, so that the moving block connected with the bottom end of the connecting piece is driven to slide, the second spring is compressed by the moving block, and meanwhile, the damper and the third spring are matched, so that vibration of a building is buffered and damped.

Drawings

The utility model will be described in further detail with reference to the drawings and the detailed description.

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a schematic view of a partial structure of the present utility model;

FIG. 3 is a schematic view of a structure between a tension member and a moving groove according to the present utility model;

FIG. 4 is a schematic cross-sectional view of a cushioning assembly of the present utility model;

FIG. 5 is a partially exploded view of a cushioning assembly according to the present utility model.

In the figure: 1. a bottom plate; 2. a first mounting hole; 3. a lower mounting groove; 4. a rubber pad; 5. an upper mounting groove; 6. a tension member; 601. a slide rail; 602. a limiting plate; 603. a slide bar; 604. a baffle; 605. a first spring; 7. a moving groove; 8. a buffer assembly; 801. a limit rod; 802. a second spring; 803. a moving block; 804. a connecting piece; 805. a rotating rod; 9. a damper; 10. a third spring; 11. a top plate; 12. and a second mounting hole.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below in conjunction with the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

The preferred embodiments of the anti-overturning tensile shock-insulation support provided by the utility model are shown in fig. 1 to 5: the utility model provides an anti-overturning tensile shock insulation support, which comprises a base plate 1 and is characterized in that, first mounting holes 2 are formed in the two sides of the top surface of the bottom plate 1, the inner top surface of the lower mounting groove 3 of which the middle part of the top surface of the bottom plate 1 is fixedly connected with a lower mounting groove 3 is fixedly connected with a rubber pad 4, the top end of the rubber pad 4 is fixedly connected with an upper mounting groove 5, the top end of the upper mounting groove 5 is bonded with a top plate 11 through a hot vulcanization process, second mounting holes 12 are formed in the two sides of the top surface of the top plate 11, a tensile component 6 is arranged on the top surface of the bottom plate 1, a movable groove 7 is arranged on the top end of the tensile component 6, and a buffer component 8 is arranged in the movable groove 7;

The tensile assembly 6 comprises a sliding rail 601, the sliding rail 601 is fixedly connected to two sides of the top surface of the bottom plate 1, two ends of the sliding rail 601 are fixedly connected with limiting plates 602, one side of each limiting plate 602 is connected with a sliding rod 603 in a penetrating and sliding mode, one end of each sliding rod 603 is fixedly connected with a baffle 604, the other end of each sliding rod 603 is fixedly connected to one end of each movable groove 7, and a first spring 605 is arranged on the surface of each sliding rod 603 between each limiting plate 602 and each baffle 604 in a surrounding mode.

In this embodiment, the tensile members 6 are provided with two groups, and the two groups of tensile members 6 are symmetrically distributed about the vertical center line of the bottom plate 1, so that the tensile effect of the device is increased, and the anti-overturning effect is realized.

In this embodiment, the slide rail 601 has a T-shape, and the size of the baffle 604 is larger than that of the first spring 605, so that the first spring 605 can be limited.

Example 2

On the basis of embodiment 1, a preferred embodiment of the anti-overturning tensile shock insulation support provided by the utility model is shown in fig. 1 to 5: the buffer assembly 8 comprises a limiting rod 801, the limiting rod 801 is fixedly connected to two ends of the inside of the moving groove 7, a second spring 802 is arranged around the middle of the surface of the limiting rod 801, a moving block 803 is connected to the surface of the limiting rod 801 in a sliding mode, a connecting piece 804 is fixedly connected to the top end of the moving block 803, a rotating rod 805 is connected to the inner side of the connecting piece 804 in a rotating mode, and the top end of the rotating rod 805 is connected to the bottom face of the top plate 11 in a rotating mode through the connecting piece 804.

In this embodiment, the moving blocks 803 are provided with two sets, and the second springs 802 are located between the two sets of moving blocks 803, so that the two sets of moving blocks 803 can compress the second springs 802.

In this embodiment, a sliding hole is formed in one side of the moving block 803, and the limiting rod 801 and the sliding hole formed in one side of the moving block 803 are arranged in a matching manner, so that the moving block 803 can stably slide on the surface of the limiting rod 801.

In addition, the top surface of the bottom plate 1 is fixedly connected with dampers 9 near the left end and the right end, and the surfaces of the dampers 9 are circumferentially provided with third springs 10, so that the damping effect of the device is further improved.

In addition, a T-shaped chute is disposed in the middle of the bottom end of the moving slot 7, and the size of the T-shaped chute disposed in the middle of the bottom end of the moving slot 7 is matched with the size of the sliding rail 601.

The working principle and the using flow of the utility model are as follows: firstly, the device is fixedly installed through a first installation hole 2 arranged on a bottom plate 1 and a second installation hole 12 arranged on a top plate 11, when earthquake vibration is transmitted to the top plate 11, the top plate 11 drives a rotating rod 805 arranged to rotate, so that a moving block 803 connected with the bottom end of a connecting piece 804 is driven to slide, the moving block 803 compresses a second spring 802, meanwhile, the top plate 11 compresses a damper 9 and a third spring 10, so that vibration received by a building is buffered and damped, and plastic deformation of hysteresis damping generated by a rubber pad 4 during the earthquake can absorb energy to assist in slowing down the impact of the earthquake on the building, and horizontal restoring force can be provided by the rubber pad 4, so that the damping effect of the device is improved, and the building is better protected;

Through the tensile member 6 that sets up, drive the removal groove 7 when the earthquake and can carry out the round trip movement in the horizontal direction, according to the characteristic of first spring 605, can reset the position of removal groove 7 horizontal displacement and pull back, increase the tensile properties of this device, limiting plate 602 can restrict the displacement length of removal groove 7, makes the removal groove 7 drive the shift position of roof 11 receive maximum limit displacement restriction simultaneously, can be when meetting great earthquake to reduce the harm to the building.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (8)

1. The utility model provides an anti-overturning tensile shock insulation support, includes bottom plate (1), its characterized in that, first mounting hole (2) have been seted up to the top surface both sides of bottom plate (1), the top surface middle part fixedly connected with of bottom plate (1) lower mounting groove (3) the inside top surface fixedly connected with rubber pad (4) of lower mounting groove (3), the top fixedly connected with of rubber pad (4) goes up mounting groove (5), the top of going up mounting groove (5) is through hot vulcanization technology bonding has roof (11), second mounting hole (12) have been seted up to the top surface both sides of roof (11), the top surface of bottom plate (1) is provided with tensile member (6), the top of tensile member (6) is provided with movable groove (7), the inside of movable groove (7) is provided with buffer assembly (8);

The tensile assembly (6) comprises a sliding rail (601), the sliding rail (601) is fixedly connected to two sides of the top surface of the bottom plate (1), two ends of the sliding rail (601) are fixedly connected with limiting plates (602), one side of each limiting plate (602) is connected with a sliding rod (603) in a penetrating and sliding mode, one end of each sliding rod (603) is fixedly connected with a baffle (604), the other end of each sliding rod (603) is fixedly connected to one end of the corresponding movable groove (7), and a first spring (605) is arranged on the surface of each sliding rod (603) between each limiting plate (602) and each baffle (604) in a surrounding mode.

2. The anti-overturning tensile shock-isolation support according to claim 1, wherein two groups of the tensile assemblies (6) are arranged, and the two groups of the tensile assemblies (6) are symmetrically distributed about the vertical center line of the bottom plate (1).

3. The anti-overturning tensile shock-isolation support according to claim 1, wherein the sliding rail (601) is T-shaped, and the size of the baffle (604) is larger than that of the first spring (605).

4. The anti-overturning tensile shock-insulation support according to claim 1, wherein the buffer component (8) comprises a limiting rod (801), the limiting rod (801) is fixedly connected to two ends of the inside of the moving groove (7), a second spring (802) is arranged around the middle of the surface of the limiting rod (801), a moving block (803) is slidably connected to the surface of the limiting rod (801), a connecting piece (804) is fixedly connected to the top end of the moving block (803), a rotating rod (805) is rotatably connected to the inner side of the connecting piece (804), and the top end of the rotating rod (805) is rotatably connected to the bottom surface of the top plate (11) through the connecting piece (804).

5. The anti-overturning tensile shock-resistant support according to claim 4, wherein two groups of moving blocks (803) are arranged, and the second spring (802) is located between the two groups of moving blocks (803).

6. The anti-overturning tensile shock-insulation support according to claim 4, wherein a sliding hole is formed in one side of the moving block (803), and the limiting rod (801) and the sliding hole formed in one side of the moving block (803) are arranged in a matched mode.

7. The anti-overturning tensile shock-insulation support according to claim 1, wherein dampers (9) are fixedly connected to the top surface of the bottom plate (1) close to the left end and the right end, and third springs (10) are circumferentially arranged on the surface of the dampers (9).

8. The anti-overturning tensile shock insulation support according to claim 1, wherein a T-shaped chute is arranged in the middle of the bottom end of the movable groove (7), and the size of the T-shaped chute arranged in the middle of the bottom end of the movable groove (7) is matched with the size of the sliding rail (601).