CN218411619U

CN218411619U - Steel construction building antidetonation check out test set

Info

Publication number: CN218411619U
Application number: CN202222946270.4U
Authority: CN
Inventors: 孙松夫
Original assignee: Shaoxing Binhai New Area Development Group Co ltd
Current assignee: Shaoxing Binhai New Area Development Group Co ltd
Priority date: 2022-11-01
Filing date: 2022-11-01
Publication date: 2023-01-31
Anticipated expiration: 2032-11-01

Abstract

The utility model relates to a steel construction building antidetonation check out test set belongs to antidetonation detection device technical field. It mainly can't carry out the problem of intensity simulation to current building steel structure, proposes following technical scheme: the building steel structure vibration control device comprises a bottom plate, a supporting plate, a fixing assembly and a power assembly, wherein the fixing assembly is used for fixing a building steel structure on the supporting plate, and the power assembly is used for controlling the supporting plate to vibrate up and down; four mounting columns are arranged on the bottom plate in a rectangular distribution manner, cavities are formed in the mounting columns, lifting plates are arranged in the cavities in a sliding manner, supporting columns are arranged on the lifting plates and penetrate through the inner wall of the top of the cavities, and the supporting columns are connected with the mounting columns in a sliding manner; the supporting plate is arranged at the top end of the supporting column, and a placing groove is formed in the upper surface of the supporting plate; the fixed assemblies are provided with a plurality of groups, and the plurality of groups of fixed assemblies are all arranged on the supporting plate; the power assembly is arranged on the bottom plate. The utility model discloses can carry out intensity simulation to the architectural steel structure.

Description

Steel construction building antidetonation check out test set

Technical Field

The utility model belongs to the technical field of antidetonation detection device technique and specifically relates to a steel construction building antidetonation check out test set.

Background

Earthquake resistance is one of the most important and difficult subjects faced by civil engineering at present. The foundations of earthquake-resistant houses are usually driven deep in firm rocks and can move with the vibration. Between 2 storied buildings and 5 storied buildings are supported by 20 groups of four-corner columns. A solid bottom floor. The white quartz wall panel is reinforced by steel pipes, and the design can bear left and right shaking. The pyramid shape has a low center of gravity and is therefore able to withstand shaking. The emergency escape ladder is arranged on the west wing, and the elevator is arranged on the east wing. All devices are locked on the wall and fixed, and all can bear up-and-down and left-and-right movement. The whole span is made of shockproof materials. Elasticity of higher floors

When the construction of carrying out the engineering or the support in disaster area, need put up the room of taking precautions against earthquakes of steel construction for use temporarily, at present the room of taking precautions against earthquakes is put up the completion back, and most all directly use, do not carry out the equipment that anti-seismic performance detected to the room outer wall that takes precautions against earthquakes after putting up the completion, thereby can't confirm the room outer wall shock resistance that takes precautions against earthquakes, can not guarantee the safety of the room of taking precautions against earthquakes in the use.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a steel construction building antidetonation check out test set to the problem that exists among the background art.

The technical scheme of the utility model: the steel structure building anti-seismic detection equipment comprises a bottom plate, a supporting plate, a fixing component and a power component, wherein the fixing component is used for fixing a building steel structure on the supporting plate, and the power component is used for controlling the supporting plate to vibrate up and down;

four mounting columns are arranged on the bottom plate in a rectangular distribution manner, cavities are formed in the mounting columns, lifting plates are arranged in the cavities in a sliding manner, supporting columns are arranged on the lifting plates and penetrate through the inner wall of the top of the cavities, and the supporting columns are connected with the mounting columns in a sliding manner; the supporting plate is arranged at the top end of the supporting column, and a placing groove is formed in the upper surface of the supporting plate; the fixed assemblies are provided with a plurality of groups, and the plurality of groups of fixed assemblies are all arranged on the supporting plate; the power assembly is arranged on the bottom plate.

Preferably, a plurality of first springs are further included; a plurality of first springs are all arranged in the cavity, and two ends of each first spring are respectively connected with the bottom of the lifting plate and the inner wall of the bottom of the cavity.

Preferably, the fixing assembly comprises a threaded rod and a knob; the threaded rod transversely penetrates through the inner wall of the transverse side of the placing groove and is in threaded connection with the supporting plate; the knob sets up the one end that is located the standing groove at the threaded rod.

Preferably, the fixing assembly further comprises a backing plate; the backing plate sets up the one end that is located the standing groove at the threaded rod, and the backing plate is the elastic component.

Preferably, the power assembly comprises a mounting plate, a rotating shaft, a cam and a motor; the mounting plate is arranged on the bottom plate, the rotating shaft is rotatably arranged on one lateral side of the mounting plate, and the cam is arranged at one lateral end of the rotating shaft, which is far away from the bottom plate; the motor is arranged on the mounting plate and is in driving connection with the rotating shaft.

Preferably, be provided with the installation cavity in the mounting panel, the cam inboard evenly is provided with a plurality of spacing holes, and a plurality of spacing holes revolute the axle evenly distributed, are provided with in the installation cavity to be used for cam and mounting panel fixed connection's elastic component.

Preferably, the elastic component comprises a magnet, a limiting column, a second spring and an electromagnet; the magnet is arranged in the mounting cavity in a sliding manner, and the magnet slides along the transverse direction; the limiting column penetrates through one transverse side of the mounting plate and is arranged on the magnet, the limiting column is located in the limiting hole, and the limiting column is connected with the mounting plate and the cam in a sliding mode; the second spring is arranged between the inner wall of the mounting cavity and the magnet; the electromagnet is arranged on the inner wall of the mounting cavity and is magnetically connected with the magnet.

Compared with the prior art, the utility model discloses following profitable technological effect has:

when the utility model is in actual use, a worker only needs to put the building steel structure into the placing groove, then the knob is rotated to fix the building steel structure, and then the motor drives the rotating shaft to rotate through the starting motor, so that the cam is driven to rotate, the vertical vibration of the supporting plate is realized, and the vibration simulation of the building steel structure is realized; in addition, through setting up elastic component, can fix the cam, guarantee the utility model discloses stability during the use.

Drawings

Fig. 1 is a partial cross-sectional view of a first viewing angle of an embodiment of the present invention.

Fig. 2 is a partial cross-sectional view of a second perspective of an embodiment of the present invention.

Fig. 3 is a partially enlarged view of a portion a in fig. 2.

Reference numerals: 1. a base plate; 2. mounting a column; 201. a cavity; 3. a lifting plate; 4. a support pillar; 5. a first spring; 6. a support plate; 601. a placement groove; 7. a threaded rod; 8. a base plate; 9. a knob; 10. mounting a plate; 1001. a mounting cavity; 11. a rotating shaft; 12. a cam; 1201. a limiting hole; 13. an electric motor; 14. a magnet; 15. a limiting post; 16. a second spring; 17. an electromagnet.

Detailed Description

Example one

As shown in fig. 1-3, the utility model provides a steel structure building antidetonation check out test set, including bottom plate 1, a plurality of first spring 5, layer board 6, be used for building steel structure fix on layer board 6 fixed subassembly and be used for controlling layer board 6 power component that shakes from top to bottom;

four mounting columns 2 are distributed on the bottom plate 1 in a rectangular shape, cavities 201 are formed in the mounting columns 2, lifting plates 3 are arranged in the cavities 201 in a sliding mode, supporting columns 4 are arranged on the lifting plates 3, the supporting columns 4 penetrate through the inner wall of the top of the cavities 201, and the supporting columns 4 are connected with the mounting columns 2 in a sliding mode; the supporting plate 6 is arranged at the top end of the supporting column 4, and the upper surface of the supporting plate 6 is provided with a placing groove 601; the fixed components are provided with a plurality of groups, and the plurality of groups of fixed components are all arranged on the supporting plate 6; the power assembly is arranged on the bottom plate 1. A plurality of first springs 5 all set up in cavity 201, and the both ends of first spring 5 are connected with lifter plate 3 bottom and cavity 201 bottom inner wall respectively.

The fixing component comprises a threaded rod 7, a backing plate 8 and a knob 9; the threaded rod 7 transversely penetrates through the inner wall of one transverse side of the placing groove 601, and the threaded rod 7 is in threaded connection with the supporting plate 6; the knob 9 is arranged at one end of the threaded rod 7 outside the placing groove 601. The backing plate 8 is arranged at one end of the threaded rod 7 positioned in the placing groove 601, and the backing plate 8 is an elastic piece.

Example two

As shown in fig. 1-3, the utility model provides a steel structure building antidetonation check out test set, including bottom plate 1, a plurality of first springs 5, layer board 6, be used for building steel construction fix on layer board 6 fixed subassembly and be used for controlling the power component that layer board 6 shakes from top to bottom;

four mounting columns 2 are distributed on the bottom plate 1 in a rectangular shape, cavities 201 are formed in the mounting columns 2, lifting plates 3 are arranged in the cavities 201 in a sliding mode, supporting columns 4 are arranged on the lifting plates 3, the supporting columns 4 penetrate through the inner wall of the top of the cavities 201, and the supporting columns 4 are connected with the mounting columns 2 in a sliding mode; the supporting plate 6 is arranged at the top end of the supporting column 4, and the upper surface of the supporting plate 6 is provided with a placing groove 601; the fixed components are provided with a plurality of groups, and the plurality of groups of fixed components are all arranged on the supporting plate 6; the power assembly is arranged on the bottom plate 1. A plurality of first springs 5 all set up in cavity 201, and first spring 5's both ends respectively with lifter plate 3 bottom and cavity 201 bottom inner wall connection.

The fixing component comprises a threaded rod 7, a backing plate 8 and a knob 9; the threaded rod 7 transversely penetrates through the inner wall of the transverse side of the placing groove 601, and the threaded rod 7 is in threaded connection with the supporting plate 6; the knob 9 is arranged at one end of the threaded rod 7 outside the placing groove 601. The backing plate 8 is arranged at one end of the threaded rod 7 positioned in the placing groove 601, and the backing plate 8 is an elastic piece.

The power assembly comprises a mounting plate 10, a rotating shaft 11, a cam 12 and a motor 13; the mounting plate 10 is arranged on the bottom plate 1, a rotating shaft 11 is rotatably arranged on one lateral side of the mounting plate 10, a mounting cavity 1001 is arranged in the mounting plate 10, a cam 12 is arranged at one lateral end, away from the bottom plate 1, of the rotating shaft 11, a plurality of limiting holes 1201 are uniformly formed in the inner side of the cam 12, the limiting holes 1201 are uniformly distributed around the rotating shaft 11, and an elastic assembly used for fixedly connecting the cam 12 and the mounting plate 10 is arranged in the mounting cavity 1001; the motor 13 is arranged on the mounting plate 10, and the motor 13 is in driving connection with the rotating shaft 11.

The elastic component comprises a magnet 14, a limiting column 15, a second spring 16 and an electromagnet 17; the magnet 14 is arranged in the mounting cavity 1001 in a sliding mode, and the magnet 14 slides in the transverse direction; the limiting column 15 penetrates through one transverse side of the mounting plate 10 and is arranged on the magnet 14, the limiting column 15 is located in the limiting hole 1201, and the limiting column 15 is connected with the mounting plate 10 and the cam 12 in a sliding mode; the second spring 16 is arranged between the inner wall of the mounting cavity 1001 and the magnet 14; the electromagnet 17 is arranged on the inner wall of the mounting cavity 1001, and the electromagnet 17 is magnetically connected with the magnet 14.

When the utility model is used in practice, a worker only needs to put the building steel structure into the placing groove 601, then the knob 9 is rotated to fix the building steel structure, then the motor 13 drives the rotating shaft 11 to rotate through the starting motor 13, so as to drive the cam 12 to rotate, and the up-and-down vibration of the supporting plate 6 is realized, and further the vibration simulation of the building steel structure is realized; in addition, through setting up elastic component, can fix cam 12, guarantee the utility model discloses stability during the use.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited thereto, and various changes can be made without departing from the gist of the present invention within the scope of knowledge possessed by those skilled in the art.

Claims

1. The steel structure building earthquake-resistant detection equipment is characterized by comprising a base plate (1), a supporting plate (6), a fixing component for fixing a building steel structure on the supporting plate (6) and a power component for controlling the supporting plate (6) to vibrate up and down;

four mounting columns (2) are distributed on the base plate (1) in a rectangular shape, cavities (201) are formed in the mounting columns (2), a lifting plate (3) is arranged in the cavities (201) in a sliding mode, supporting columns (4) are arranged on the lifting plate (3), the supporting columns (4) penetrate through the inner wall of the top of the cavities (201), and the supporting columns (4) are connected with the mounting columns (2) in a sliding mode; the supporting plate (6) is arranged at the top end of the supporting column (4), and the upper surface of the supporting plate (6) is provided with a placing groove (601); the fixed components are provided with a plurality of groups, and the plurality of groups of fixed components are all arranged on the supporting plate (6); the power assembly is arranged on the bottom plate (1).

2. A steel structure building earthquake resistance detection apparatus as claimed in claim 1, further comprising a plurality of first springs (5); a plurality of first springs (5) are arranged in the cavity (201), and two ends of each first spring (5) are connected with the bottom of the lifting plate (3) and the inner wall of the bottom of the cavity (201) respectively.

3. The steel structure building earthquake resistance detection equipment according to the claim 1, wherein the fixing component comprises a threaded rod (7) and a knob (9); the threaded rod (7) transversely penetrates through the inner wall of the transverse side of the placing groove (601), and the threaded rod (7) is in threaded connection with the supporting plate (6); the knob (9) is arranged at one end of the threaded rod (7) which is positioned outside the placing groove (601).

4. A steel structure building earthquake resistance detection apparatus as claimed in claim 3 wherein the fixing assembly further comprises a backing plate (8); the backing plate (8) is arranged at one end of the threaded rod (7) in the placing groove (601), and the backing plate (8) is an elastic piece.

5. The steel structure building earthquake-resistant detection equipment according to claim 1, wherein the power assembly comprises a mounting plate (10), a rotating shaft (11), a cam (12) and a motor (13); the mounting plate (10) is arranged on the bottom plate (1), the rotating shaft (11) is rotatably arranged on one lateral side of the mounting plate (10), and the cam (12) is arranged at one lateral end, far away from the bottom plate (1), of the rotating shaft (11); the motor (13) is arranged on the mounting plate (10), and the motor (13) is in driving connection with the rotating shaft (11).

6. The steel structure building earthquake-resistant detection equipment according to claim 5, wherein a mounting cavity (1001) is formed in the mounting plate (10), a plurality of limiting holes (1201) are uniformly formed in the inner side of the cam (12), the limiting holes (1201) are uniformly distributed around the rotating shaft (11), and an elastic component for fixedly connecting the cam (12) and the mounting plate (10) is arranged in the mounting cavity (1001).

7. The steel structure building earthquake-resistant detection equipment according to claim 6, wherein the elastic component comprises a magnet (14), a limiting column (15), a second spring (16) and an electromagnet (17); the magnet (14) is arranged in the mounting cavity (1001) in a sliding mode, and the magnet (14) slides along the transverse direction; the limiting column (15) penetrates through one transverse side of the mounting plate (10) and is arranged on the magnet (14), the limiting column (15) is located in the limiting hole (1201), and the limiting column (15) is connected with the mounting plate (10) and the cam (12) in a sliding mode; the second spring (16) is arranged between the inner wall of the mounting cavity (1001) and the magnet (14); the electromagnet (17) is arranged on the inner wall of the mounting cavity (1001), and the electromagnet (17) is magnetically connected with the magnet (14).