CN210887609U - High-rise building wall shock insulation built-in fitting - Google Patents

Abstract

The utility model provides a high-rise building wall shock insulation built-in fitting, including first built-in fitting and second built-in fitting, one side of first built-in fitting is through first spring and second built-in fitting swing joint, and one side fixed mounting of first built-in fitting has first buffer board, and the inside fixed mounting of first buffer board has the dowel steel, and the both sides face fixed mounting of dowel steel has first rack, and one side swing joint of first rack has the second rack. The utility model discloses first built-in fitting removes to the second built-in fitting through first spring and carries out pressure cushion when the wall receives vibration amplitude, be connected through lug and dashpot simultaneously again and support slow pressure, support the pressure that first built-in fitting and second built-in fitting outer wall received through the compression piece, fix the compression piece through the strengthening rib, it is impaired to prevent to receive the compression piece, the rethread stopper carries on spacingly to the strengthening rib simultaneously, make first built-in fitting and second built-in fitting outer wall compressive capacity be difficult to damage the deformation by force.

Description

High-rise building wall shock insulation built-in fitting

Technical Field

The utility model relates to a high-rise building technical field especially relates to a wall shock insulation built-in fitting.

Background

Along with the continuous advancing of industrial modernization and scientific and technological modernization steps, economy is prosperous, the living standard of people is continuously improved, the height of a building is continuously increased, but the shaking amplitude of the building is also continuously increased along with the increase of the height of the building, so that people provide the high-rise building shock insulation embedded part to well solve the problem, the existing shock insulation embedded part is poor in buffering capacity, and when the earthquake amplitude is too large, the shock insulation embedded part is easy to deform to weaken the shock insulation capacity, and therefore the problem is solved to provide the high-rise building wall shock insulation embedded part.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects existing in the prior art and providing a wall shock insulation embedded part for a high-rise building.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a wall surface shock insulation embedded part for a high-rise building comprises a first embedded part and a second embedded part, wherein one side of the first embedded part is movably connected with the second embedded part through a first spring;

the first embedded part comprises a first buffer plate, a dowel bar, a first rack, a second spring, a movable groove, a fixed rod, a second buffer plate, a limiting rod, a supporting block and a buffer groove, wherein the first buffer plate is fixedly arranged on one side of the first embedded part, the dowel bar is fixedly arranged in the first buffer plate, the first rack is fixedly arranged on two side surfaces of the dowel bar, the second rack is movably connected to one side of the first rack, the second spring is fixedly arranged at one end of the second rack, the movable groove is fixedly arranged at the bottom end of the second spring, the fixed rod is fixedly arranged on one side of the movable groove, the second buffer plate is fixedly arranged on one side of the fixed rod, the limiting rod is fixedly arranged on one side of the second buffer plate, and the supporting block is fixedly arranged at one end of the limiting rod;

the second embedded part comprises a pressed block, a reinforcing rib, a limiting block and a convex block, the pressed block is fixedly mounted in the second embedded part, the reinforcing rib is fixedly mounted in the pressed block, the limiting plate is fixedly mounted on one side of the reinforcing rib, and the convex block is fixedly mounted on one side face of the outer wall of the second embedded part.

As a further description of the above technical solution: and two ends of one side surface of the first embedded part are movably connected with the second embedded part through the first spring, and the internal structure of the first embedded part is consistent with that of the second embedded part.

As a further description of the above technical solution: the first buffer plate is of an arc-shaped structure, and one end of the first buffer plate is connected to one end of the first spring.

As a further description of the above technical solution: the first rack and the second rack are both in a trapezoidal shape and are mutually matched.

As a further description of the above technical solution: the pressure-receiving block is of a hollow round structure, and a plurality of pressure-receiving blocks are arranged inside the first embedded part and the second embedded part.

As a further description of the above technical solution: the reinforcing rib is formed by connecting two reinforcing steel bars in a staggered manner, and the diameter of the reinforcing rib is 3cm-5 cm.

As a further description of the above technical solution: the stopper is the L shape, and the stopper all connects in the crisscross junction of strengthening rib.

Has the advantages that:

1. the utility model discloses first built-in fitting removes to the second built-in fitting through first spring and carries out pressure cushion when the wall receives vibration amplitude, be connected through lug and dashpot simultaneously again and support slow pressure, support the pressure that first built-in fitting and second built-in fitting outer wall received through the compression piece, fix the compression piece through the strengthening rib, it is impaired to prevent to receive the compression piece, the rethread stopper carries on spacingly to the strengthening rib simultaneously, make first built-in fitting and second built-in fitting outer wall compressive capacity be difficult to damage the deformation by force.

2. Secondly, cushion through first buffer board when the dashpot pressurized, it makes first rack can drive the second rack and reciprocate through the second spring in the movable tank and can effectually slow down the translation rate of dowel steel to drive the dowel steel toward a lateral shifting simultaneously, the pressure that makes the dashpot can effectually cushion, last the pressure that receives through the fixed rod to the dashpot supports slowly, the second buffer board can drive the gag lever post and consolidate dead lever post and dashpot junction through supporting the piece when the dead lever takes place the swing, let the dashpot stable in structure, be difficult to damage.

Drawings

FIG. 1 is a schematic top sectional view of the overall structure of the present invention;

fig. 2 is an enlarged schematic view of fig. 1A of the present invention;

fig. 3 is a front view of the overall structure of the present invention.

Illustration of the drawings:

a first embedded part 1; a first spring 101; a first buffer plate 102; a dowel bar 103; a first rack 104; a second rack 105; a second spring 106; a movable groove 107; a fixing bar 108; a second buffer plate 109; a stopper rod 110; a cancel block 111; a buffer tank 112; a second embedded part 2; a pressed block 201; a reinforcing rib 202; a stop block 203; and a bump 204.

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 of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-3, the wall surface shock insulation embedded part for the high-rise building comprises a first embedded part 1 and a second embedded part 2, wherein one side of the first embedded part 1 is movably connected with the second embedded part 2 through a first spring 101;

the first embedded part 1 comprises a first buffer plate 102, a dowel bar 103, a first rack 104, a second rack 105, a second spring 106, a movable groove 107, a fixed rod 108, a second buffer plate 109, a limiting rod 110, a resisting block 111 and a buffer groove 112, a first buffer plate 102 is fixedly installed on one side of a first embedded part 1, a dowel bar 103 is fixedly installed inside the first buffer plate 102, first racks 104 are fixedly installed on two side surfaces of the dowel bar 103, one side of each first rack 104 is movably connected with a second rack 105, one end of each second rack 105 is fixedly installed with a second spring 106, a movable groove 107 is fixedly installed at the bottom end of each second spring 106, a fixed rod 108 is fixedly installed on one side of each movable groove 107, a second buffer plate 109 is fixedly installed on one side of each fixed rod 108, a limiting rod 110 is fixedly installed on one side of each second buffer plate 109, and a resisting block 111 is fixedly installed at one end of each limiting rod 110;

the second embedded part 2 comprises a pressed block 201, a reinforcing rib 202, a limiting block 203 and a lug 204, the pressed block 201 is fixedly mounted inside the second embedded part 2, the reinforcing rib 202 is fixedly mounted inside the pressed block 201, the limiting block 203 is fixedly mounted on one side of the reinforcing rib 202, and the lug 204 is fixedly mounted on one side surface of the outer wall of the second embedded part 2.

Two ends of one side face of the first embedded part 1 are movably connected with the second embedded part 2 through the first springs 101, the internal structure of the first embedded part 1 is consistent with that of the second embedded part 2, and when the wall face is subjected to vibration amplitude, the first embedded part 1 moves towards the second embedded part 2 through the first springs 101 to perform pressure buffering.

Wherein, first buffer board 102 is the arc structure, and the one end of first buffer board 102 is connected in the one end of first spring 101, and first buffer board 102 can be through one end during buffer slot 112 pressurized to the bottom of first spring 101 toward one side extension and slow down pressure.

The first rack 104 and the second rack 105 are both in a trapezoid shape and are matched with each other, and when the first rack 104 moves, the second rack 105 can be driven to move up and down in the movable groove 107 through the second spring 106, so that the moving speed of the dowel bar 103 can be effectively reduced.

Wherein, the piece 201 that receives is the hollow circle structure, and is equipped with a plurality of in the inside of first built-in fitting 1 and second built-in fitting 2, can effectual increase first built-in fitting 1 and second built-in fitting 2's compressive capacity through the piece 201 that receives, makes and is difficult to damage.

The reinforcing rib 202 is formed by connecting two reinforcing steel bars in a staggered mode, the diameter of the reinforcing rib 202 is 3cm-5cm, the compression block 201 is reinforced through the reinforcing rib 202, and the situation that the compression block 201 is compressed too much to cause deformation so that the compression resistance of the first embedded part 1 and the second embedded part 2 is weakened is avoided.

Wherein, stopper 203 is the L shape, and stopper 203 all connects in the crisscross junction of strengthening rib 202, fixes strengthening rib 202 through stopper 203, takes place the swing when preventing strengthening rib 202 pressurized and leads to damaging and receive piece 201.

The working principle is as follows: when the device is used, when the wall surface is subjected to vibration amplitude, the first embedded part 1 moves to the second embedded part 2 through the first spring 101 to buffer pressure, meanwhile, the lug 204 is connected with the buffer groove 112 to buffer pressure, then, the pressure applied to the outer walls of the first embedded part 1 and the second embedded part 2 is buffered through the pressure-applied block 201, the pressure-applied block 201 is fixed through the reinforcing rib 202 to prevent the pressure-applied block 201 from being damaged, meanwhile, the reinforcing rib 202 is limited through the limiting block 203, so that the outer walls of the first embedded part 1 and the second embedded part 2 have strong pressure resistance and are not easy to damage and deform, then, when the buffer groove 112 is pressed, the first buffer plate 102 buffers, and simultaneously drives the force transmission rod 103 to move towards one side to enable the first rack 104 to drive the second rack 105 to move up and down in the movable groove 107 through the second spring 106, so as to effectively slow down the moving speed of the force transmission rod 103, make the pressure of dashpot 112 can effectually cushion, and the pressure that receives dashpot 112 through dead lever 108 at last supports and cushions, and second buffer board 109 can drive gag lever post 110 and consolidate dead lever 108 and dashpot 112 junction through supporting piece 111 when dead lever 108 takes place the swing, lets dashpot 112 stable in structure, is difficult to damage.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. A high-rise building wall surface shock insulation embedded part comprises a first embedded part (1) and a second embedded part (2), and is characterized in that one side of the first embedded part (1) is movably connected with the second embedded part (2) through a first spring (101);

the first embedded part (1) comprises a first buffer plate (102), a dowel bar (103), a first rack (104), a second rack (105), a second spring (106), a movable groove (107), a fixed rod (108), a second buffer plate (109), a limiting rod (110), a resisting block (111) and a buffer groove (112), wherein the first buffer plate (102) is fixedly installed on one side of the first embedded part (1), the dowel bar (103) is fixedly installed inside the first buffer plate (102), the first rack (104) is fixedly installed on two side faces of the dowel bar (103), the second rack (105) is movably connected on one side of the first rack (104), the second spring (106) is fixedly installed on one end of the second rack (105), the movable groove (107) is fixedly installed at the bottom end of the second spring (106), and the fixed rod (108) is fixedly installed on one side of the movable groove (107), a second buffer plate (109) is fixedly installed on one side of the fixing rod (108), a limiting rod (110) is fixedly installed on one side of the second buffer plate (109), and a supporting block (111) is fixedly installed at one end of the limiting rod (110);

the second embedded part (2) comprises a pressed block (201), a reinforcing rib (202), a limiting block (203) and a lug (204), the pressed block (201) is fixedly mounted inside the second embedded part (2), the reinforcing rib (202) is fixedly mounted inside the pressed block (201), the limiting block (203) is fixedly mounted on one side of the reinforcing rib (202), and the lug (204) is fixedly mounted on one side surface of the outer wall of the second embedded part (2).

2. The wall surface shock-insulation embedded part for the high-rise building as claimed in claim 1, wherein two ends of one side surface of the first embedded part (1) are movably connected with the second embedded part (2) through first springs (101), and the internal structure of the first embedded part (1) is consistent with that of the second embedded part (2).

3. The wall surface seismic isolation embedded part of the high-rise building as claimed in claim 1, wherein the first buffer plate (102) is of an arc structure, and one end of the first buffer plate (102) is connected to one end of the first spring (101).

4. The wall surface seismic isolation embedded part for the high-rise building as claimed in claim 1, wherein the first rack (104) and the second rack (105) are both trapezoidal and are matched with each other.

5. The wall surface shock-insulation embedded part for the high-rise building as claimed in claim 1, wherein the pressure-bearing blocks (201) are of a hollow circular structure, and a plurality of pressure-bearing blocks are arranged inside the first embedded part (1) and the second embedded part (2).

6. The wall surface seismic isolation embedded part of the high-rise building as claimed in claim 1, wherein the reinforcing ribs (202) are formed by connecting two reinforcing steel bars in a staggered manner, and the diameter of each reinforcing rib (202) is 3cm-5 cm.

7. The wall surface seismic isolation embedded part for the high-rise building as claimed in claim 1, wherein the limiting blocks (203) are L-shaped, and the limiting blocks (203) are connected at the joints where the reinforcing ribs (202) are staggered.

Images