CN216201560U

CN216201560U - Stacked assembled anti-seismic connecting frame

Info

Publication number: CN216201560U
Application number: CN202122073506.3U
Authority: CN
Inventors: 吴策皇; 陈萍
Original assignee: Guangzhou Tugu Building Technology Co ltd
Current assignee: Guangzhou Tugu Building Technology Co ltd
Priority date: 2021-08-30
Filing date: 2021-08-30
Publication date: 2022-04-05
Anticipated expiration: 2031-08-30

Abstract

The utility model discloses a stacked assembled anti-seismic connecting frame, which comprises a top surface connecting piece, a vertical anti-seismic piece and a transverse support, wherein the vertical anti-seismic piece is in clamping fit with the top surface connecting piece; the stacked assembled anti-seismic connecting frame is convenient to connect and assemble and convenient for stacking, assembling and using of a plurality of components.

Description

Stacked assembled anti-seismic connecting frame

Technical Field

The utility model relates to a stacked assembled anti-seismic connecting frame.

Background

Earthquake is also called earthquake and earth vibration, and is a natural phenomenon that the earth crust can generate earthquake waves during the vibration caused in the process of quickly releasing energy; the mutual extrusion collision between the plate and the plate on the ball causes the dislocation and the rupture of the plate edge and the plate inside, which is the main reason for causing the ground vibration.

The propagation modes of the seismic waves comprise longitudinal waves, transverse waves and surface waves, wherein the longitudinal waves are also called P waves to cause up-and-down bumping vibration of the ground, and the destructiveness is weak; the transverse wave is also called as S wave, which causes horizontal shaking of the ground and has strong destructiveness; surface waves, also known as L-waves, propagate along the ground surface and are the main cause of strong destruction of buildings.

The earthquake causes the vibration of the ground surface and is transmitted to the building body and the non-structural component, and based on the vibration, the mechanism of the anti-seismic support proposed by the prior art is used for dealing with the vibration.

In recent years, natural disasters such as typhoons, tsunamis and earthquakes frequently occur around the world, and very serious injuries are caused to the society and people. As is well known, when an earthquake occurs, the casualty rate caused by leakage or falling of pipelines accounts for more than half of the total casualties, and in order to reduce the loss, it is indispensable and mandatory to design the pipelines in buildings for earthquake-resistant installation.

The anti-seismic support limits the displacement of the attached electromechanical engineering facilities, controls the vibration of the facilities and transmits the load to various components or devices on the bearing structure. The anti-seismic support gives reliable protection to building electromechanical engineering facilities in the earthquake and bears the earthquake action from any horizontal direction; the anti-seismic support is checked according to the load borne by the anti-seismic support; all components forming the anti-seismic support are finished components, and the components connected with the fasteners are convenient to install; the limit of the anti-seismic support of the heat-insulating pipeline is designed according to the size of the pipeline after heat insulation, and the displacement generated by expansion with heat and contraction with cold of the pipeline is not limited.

When meeting the earthquake of earthquake fortification intensity in local area, the building water supply and drainage, fire control, heating, ventilation, air conditioning, gas, heating power, electric power, communication and other electromechanical engineering facilities after earthquake fortification can achieve the aims of lightening earthquake damage, reducing and preventing secondary disasters as much as possible, thereby achieving the purpose of reducing casualties and property loss.

The anti-seismic connecting frame is one of components in an anti-seismic support, and the existing anti-seismic connecting frame has the problem of inconvenient connection and assembly, and is particularly inconvenient to stack and assemble for the connection requirement among multiple layers and multiple components.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide a stacked assembled anti-seismic connecting frame which is convenient to connect and assemble and is convenient for stacking and assembling a plurality of components.

The technical scheme adopted by the utility model for solving the technical problems is as follows:

the utility model provides a range upon range of assembled antidetonation link, including the top surface connecting piece, and form centre gripping complex vertical antidetonation piece with the top surface connecting piece, and form fixed complex horizontal support with vertical antidetonation piece, the top surface connecting piece including the embedding piece, and set up in the embedding piece below to form fixed complex vertical screw with the embedding piece, horizontal support is including more than two crosspiece pieces, has the horizontal potential difference between each crosspiece piece, has the interval between the adjacent crosspiece piece, vertical antidetonation piece is including last antidetonation arm and lower antidetonation arm, it is located the crosspiece piece top at top to go up the antidetonation arm, the antidetonation arm is located the crosspiece piece top at bottom down.

Preferably, the crossbar member has an upper opening, and the vertical screw penetrates the transverse bracket downward through the upper opening.

Further, the upper shed department of horizontal member is formed with the bar screens, and the card has the mount pad in this bar screens, and this mount pad is the slice setting.

Preferably, the vertical screw is sleeved with a plurality of nut groups, and each nut group is correspondingly arranged at the connecting point of the vertical screw and the cross rod piece.

Furthermore, the nut group comprises an upper nut and a lower nut, the upper nut is abutted against the mounting seat, and the lower nut is abutted against the lower part of the cross rod piece.

Preferably, the clamping piece is assembled on the upper anti-seismic arm and the lower anti-seismic arm, the upper anti-seismic arm and the lower anti-seismic arm are provided with side openings, the vertical screw penetrates through the upper anti-seismic arm and the lower anti-seismic arm and is aligned with the side openings, one end of the clamping piece is abutted to the vertical screw, and the other end of the clamping piece is abutted to the side openings of the upper anti-seismic arm and the lower anti-seismic arm.

Furthermore, the holder including with vertical screw rod form the interior clamp that leans on, and with last antidetonation arm and the outer clamp that the antidetonation arm formed to lean on down, and run through outer clamp, and with the interior clamp form the stop screw who leans on.

Furthermore, the penetrating position between the limiting screw rod and the outer clamp body forms threaded fit, and the abutting position between the limiting screw rod and the inner clamp body forms rotatable annular concave-convex fit.

Preferably, the lateral openings of the upper anti-seismic arm and the lower anti-seismic arm are provided with limiting barbs, limiting teeth are formed at the limiting barbs, the tooth surfaces of the limiting teeth are arranged inwards, a limiting hook groove matched with the limiting barbs is formed in the outer clamp body, and hook teeth meshed with the limiting teeth are arranged in the limiting hook groove.

Further, the inner clamping body is of a curved structure, the curved surface direction of the inner clamping body faces the vertical screw rod, and the inner clamping body is attached to the vertical screw rod to form abutting fit.

The utility model has the beneficial effects that:

be a lamination supporting structure through adopting many vertical screw combinations of many horizontal rod spare collocation to be used for handling the load shock attenuation of multicomponent, especially aim at the object support that the polymorphic type mixes, its alternative and adjustability are higher, and the horizontal rod spare of the many vertical arrangements of this scheme of adoption carries out the layering and supports, still can freely nimble interval between the adjustment each horizontal rod spare via the collocation of vertical screw, in order to form different accommodation space's range upon range of package assembly, whole flexibility is strong, loading and unloading are convenient.

Drawings

FIG. 1 is a schematic view of an overall structure of a stacked and assembled anti-seismic connecting frame according to the present invention;

FIG. 2 is a schematic structural view of the upper half of a vertical seismic component of the stacked assembled seismic connection frame of the present invention;

FIG. 3 is a schematic view of a lower half structure of a vertical seismic component of a stacked and assembled seismic connection frame according to the present invention;

fig. 4 is a schematic structural view of a clamping member of a stacked and assembled anti-seismic connecting frame according to the present invention.

Detailed Description

The present invention is further described with reference to the following drawings and specific examples so that those skilled in the art can better understand the present invention and can practice the present invention, but the examples are not intended to limit the present invention.

Examples

Referring to fig. 1-4, a stacked assembled anti-seismic connecting frame includes a top surface connecting member 1, a vertical anti-seismic member 2 forming a clamping fit with the top surface connecting member 1, and a horizontal bracket 3 forming a fixed fit with the vertical anti-seismic member 2, where the top surface connecting member 1 includes an embedded member 11, and a vertical screw 12 arranged below the embedded member 11 and forming a fixed fit with the embedded member 11, the horizontal bracket 3 includes more than two cross-bar members 31, each cross-bar member 31 has a horizontal position difference, adjacent cross-bar members 31 have a space therebetween, the vertical anti-seismic member 2 includes an upper anti-seismic arm 21 and a lower anti-seismic arm 22, the upper anti-seismic arm 21 is located above the top cross-bar member 31, and the lower anti-seismic arm 22 is located above the bottom cross-bar member 31.

Crossbar member 31 has upper opening 32, vertical screw 12 downwards runs through horizontal support 3 via upper opening 32, crossbar member 31's upper opening 32 department is formed with bar screens 33, and the card has mount pad 34 in this bar screens 33, and this mount pad 34 is the slice setting, carries out the card of bar screens 33 through upper opening 32 and goes into to run through to bar screens 33 department.

The cover has a plurality of nut groups 4 on the vertical screw 12, and each nut group 4 corresponds and sets up in the junction point department of a vertical screw 12 and crossbar piece 31, nut group 4 is including last nut 41 and lower nut 42, last nut 41 supports and leans on mount pad 34, lower nut 42 supports and leans on in the below of crossbar piece 31, and it is spacing to carry out the nut to the department of running through on the bar screens 33.

Said upper 21 and lower 22 anti-seismic arms are equipped with clamps 23, said upper 21 and lower 22 anti-seismic arms have lateral openings 24, said vertical screw 12 penetrates the upper 21 and lower 22 anti-seismic arms, and is aligned with the side opening 24, one end of the clamping piece 23 is abutted against the vertical screw 12, the other end is abutted against the side opening 24 of the upper anti-seismic arm 21 and the lower anti-seismic arm 22, the clamping piece 23 comprises an inner clamping body 231 which is abutted against the vertical screw 12, an outer clamping body 232 which is abutted against the upper anti-seismic arm 21 and the lower anti-seismic arm 22, and a limit screw 233 which penetrates through the outer clamping body 232 and is abutted against the inner clamping body 231, the inner clamping body 231 is of a curved structure, the curved surface direction of the inner clamp 231 faces the vertical screw 12 and forms a leaning fit after being attached to the vertical screw 12, the fixing of the upper 21 and lower 22 anti-seismic arms is achieved by using clamps 23.

The department of penetrating between limit screw 233 and the outer clamp 232 forms screw-thread fit, limit screw 233 forms rotatable annular unsmooth cooperation with the department of supporting of inner clamp 231, the side opening 24 department of going up antidetonation arm 21 and lower antidetonation arm 22 is formed with spacing barb 25, and this spacing barb 25 department is formed with spacing tooth 26, and the flank of tooth direction of spacing tooth 26 is for setting up inwards, it has spacing hook groove 27 with spacing barb 25 matched with to open on the outer clamp 232, has the gullet 28 with spacing tooth 26 engaged with in this spacing hook groove 27, realizes holding spacing through engagement structure.

The utility model has the beneficial effects that:

The above-described embodiments of the present invention are not intended to limit the scope of the present invention, and the embodiments of the present invention are not limited thereto, and various other modifications, substitutions and alterations can be made to the above-described structure of the present invention without departing from the basic technical concept of the present invention as described above, according to the common technical knowledge and conventional means in the field of the present invention.

Claims

1. The utility model provides a range upon range of assembled antidetonation link which characterized in that: including the top surface connecting piece, reach and form centre gripping complex vertical antidetonation piece with the top surface connecting piece, and form fixed complex horizontal support with vertical antidetonation piece, the top surface connecting piece including the embedding piece, and set up in the embedding piece below to form fixed complex vertical screw with the embedding piece, horizontal support is including more than two horizontal rod pieces, has the horizontal potential difference between each horizontal rod piece, has the interval between the adjacent horizontal rod piece, vertical antidetonation piece is including last antidetonation arm and lower antidetonation arm, it is located the horizontal rod piece top at top to go up the antidetonation arm, the antidetonation arm is located the horizontal rod piece top at bottom down.

2. The stacked assembled seismic connection according to claim 1, wherein: the transverse rod piece is provided with an upper opening, and the vertical screw rod penetrates through the transverse support downwards through the upper opening.

3. A stacked assembled seismic connection according to claim 2, wherein: the upper opening part of the transverse rod piece is provided with a bar-shaped clamping position, a mounting seat is clamped in the bar-shaped clamping position, and the mounting seat is arranged in a sheet shape.

4. The stacked assembled seismic connection according to claim 1, wherein: a plurality of nut groups are sleeved on the vertical screw, and each nut group is correspondingly arranged at the connecting point of the vertical screw and the transverse rod.

5. The stacked assembled seismic connection according to claim 4, wherein: the nut group comprises an upper nut and a lower nut, the upper nut is abutted against the mounting seat, and the lower nut is abutted against the lower part of the cross rod piece.

6. The stacked assembled seismic connection according to claim 1, wherein: go up antidetonation arm and antidetonation arm down and be equipped with the holder, it has the side opening with antidetonation arm down to go up antidetonation arm, vertical screw rod runs through last antidetonation arm and antidetonation arm down to align with the side opening, the one end and the vertical screw rod of holder form to support and lean on, and the other end forms with the side opening department of last antidetonation arm and lower antidetonation arm and supports and lean on.

7. The stacked assembled seismic connection frame of claim 6, wherein: the clamping piece comprises an inner clamping body which is abutted to the vertical screw rod, an outer clamping body which is abutted to the upper anti-seismic arm and the lower anti-seismic arm, and a limiting screw which penetrates through the outer clamping body and is abutted to the inner clamping body.

8. The stacked assembled seismic connection according to claim 7, wherein: the through part between the limit screw and the outer clamp body forms threaded fit, and the abutting part between the limit screw and the inner clamp body forms rotatable annular concave-convex fit.

9. The stacked assembled seismic connection frame of claim 8, wherein: the lateral opening department of going up antidetonation arm and lower antidetonation arm is formed with spacing barb, and this spacing barb department is formed with spacing tooth, and the flank of tooth direction of spacing tooth sets up for inwards, it has the spacing hook groove with spacing barb matched with to open on the outer clamp, this spacing hook inslot has the gullet tooth with spacing tooth engaged with.

10. The stacked assembled seismic connection according to claim 7, wherein: the inner clamp body is of a curved structure, and the curved surface direction of the inner clamp body faces to the vertical screw rod and is abutted and matched with the vertical screw rod after being attached to the vertical screw rod.