CN220645400U - Three-dimensional anti-seismic steel structure factory building structure - Google Patents

Abstract

The utility model relates to a building structure technical field specifically is a three-dimensional antidetonation formula steel construction factory building structure, including ground, the last fixed surface on ground has a plurality of boxes, the inside of box is equipped with damper, damper is last to be equipped with the steelframe, every two be fixed with first steel and the third steel of connecting between the steelframe, the inside of first steel of connecting is equipped with buffer gear, be fixed with two second steel of connecting between first steel of connecting and the third steel of connecting, damper is including being fixed in the casing of box inner chamber lower surface. This three-dimensional antidetonation formula steel construction factory building structure, through damper, when taking place the earthquake, the steelframe can extrude first spring and rubber piece through fixed plate and connecting rod, simultaneously, the fixed plate can drive first movable block through first articulated rod and remove and extrude the second spring, carries out shock attenuation buffering to the steelframe through first spring and second spring, and the shock attenuation is effectual.

Description

Three-dimensional anti-seismic steel structure factory building structure

Technical Field

The application relates to the technical field of building structures, in particular to a three-dimensional anti-seismic steel structure factory building structure.

Background

The building structure is a framework structure which is formed by various components, roof trusses, beams, plates, columns and the like, can bear various functions, has a certain space function and can safely bear various normal loads of a building in the house building.

For example, chinese patent (publication number: CN 208293865U) discloses a steel building structure for factory building roof, which comprises an adjustable top plate and a device main body, wherein the outer surface of the lower end of the device main body is provided with support columns in parallel, the positions between two adjacent groups of support columns are provided with connecting columns, the adjustable top plate is arranged at the middle position of the outer surface of the upper end of the device main body, the outer surface of the upper end of the adjustable top plate is provided with a sun shield, a transparent plate is arranged at the position between the adjustable top plate and the sun shield, handles are movably mounted at the positions, close to two sides, of the outer surface of the lower end of the adjustable top plate, of the upper end of the device main body is fixedly provided with baffle plates, and the steel building structure for factory building roof is provided with the adjustable top plate, movable cross beams and handles, so that the use flexibility of the device is enhanced, the use performance of the device is improved, the device is convenient to use, and a better use prospect is brought.

Above-mentioned factory building roofing steel type building structure still has certain not enough, can switch the panel of different printing opacity properties through the adjustable roof that is equipped with, strengthened the flexibility of use and the multifunctionality of device, application scope is wide, but it lacks shock-absorbing structure in the use, because the factory building is the apparatus processing ground, when the earthquake leads to ground to appear vibrations, because factory building structure does not possess shock-resistant structure, the condition that leads to the factory building to collapse easily, thereby make the processing apparatus receive the pressure loss, influence processing, can cause unnecessary loss moreover, so put forward a three-dimensional shock-resistant steel structure factory building structure in order to solve above-mentioned problem.

Disclosure of Invention

Aiming at the defects of the prior art, the application provides a three-dimensional anti-seismic steel structure factory building structure, which has the advantages of solving the problems of the prior art.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides a three-dimensional antidetonation formula steel construction factory building structure, includes ground, the upper surface of ground is fixed with a plurality of boxes, the inside of box is equipped with damper, damper is last to be equipped with the steelframe, every two be fixed with first connecting steel and third connecting steel between the steelframe, the inside of first connecting steel is equipped with buffer gear, be fixed with two second connecting steel between first connecting steel and the third connecting steel;

the damping mechanism comprises a shell fixed on the lower surface of an inner cavity of the box body, a plurality of telescopic rods are fixed on the lower surface of the inner cavity of the shell, a first spring is sleeved on the outer surface of each telescopic rod, a plurality of connecting rods are fixed on the upper surface of each telescopic rod, a fixing plate is fixed on the upper surface of each connecting rod, a plurality of first fixing rods are fixed on the left side and the right side of the shell, a first moving block is connected to the outer surface of each first fixing rod in a sliding mode, a second spring is sleeved on the outer surface of each first fixing rod, and a first hinge rod is hinged to the upper surface of each first moving block.

By adopting the technical scheme, the first connecting steel is supported and buffered through the buffer mechanism, the steel frame is damped through the damping mechanism, and the damage of the steel frame is prevented.

Further, the upper surface of the first spring is fixed on the lower surface of the connecting rod, and the lower surface of the first spring is fixed on the lower surface of the inner cavity of the shell.

By adopting the technical scheme, the connecting rod and the steel frame are buffered and reset through the first spring.

Further, the connecting rod is T-shaped, connecting rod sliding connection is in the inside of casing.

By adopting the technical scheme, the stability of the connecting rod during movement is improved, and the connecting rod is convenient to extrude the first spring.

Further, the steel frame is fixed on the upper surface of the fixed plate, and the upper surface of the first hinging rod is hinged on the lower surface of the fixed plate.

By adopting the technical scheme, the steel frame extrudes the first hinging rod through the fixing plate, so that the first hinging rod drives the first moving block to move and extrudes the second spring, and the steel frame is damped and buffered.

Further, the opposite sides of the left and right second springs are respectively fixed on the opposite sides of the two first moving blocks, and the opposite sides of the left and right second springs are respectively fixed on the left and right sides of the inner cavity of the box body.

By adopting the technical scheme, the first moving block moves and extrudes the second spring to buffer the steel frame.

Further, buffer gear is including seting up two recesses that are located first connecting steel lower surface, be fixed with the second dead lever between the left and right sides of recess inner chamber, the surface sliding connection of second dead lever has the second movable block, the third spring has been cup jointed to the surface of second dead lever, the lower surface of second movable block articulates there is the second articulated pole.

By adopting the technical scheme, the first connecting steel is supported and buffered through the buffer mechanism.

Further, two the opposite one side of second articulated rod articulates respectively in controlling two steelframe relative one sides, the upper surface of second movable block is fixed with T shape piece, the T shape groove has been seted up to the upper surface of recess inner chamber, T shape piece sliding connection is in the inside in T shape groove.

By adopting the technical scheme, through the cooperation of the second articulated rod and the second movable block, the first connecting steel is supported and buffered, and the first connecting steel is prevented from being bent downwards from the middle, so that the use is influenced.

Further, the opposite sides of the two third springs are respectively fixed on the opposite sides of the inner cavities of the two grooves, and the opposite sides of the two third springs are respectively fixed on the opposite sides of the two second moving blocks.

By adopting the technical scheme, the second movable block is damped through the third spring.

Compared with the prior art, the technical scheme of the application has the following beneficial effects:

1. this three-dimensional antidetonation formula steel construction factory building structure, through damper, when taking place the earthquake, the steelframe can extrude first spring and rubber piece through fixed plate and connecting rod, simultaneously, the fixed plate can drive first movable block through first articulated rod and remove and extrude the second spring, carries out shock attenuation buffering to the steelframe through first spring and second spring, and the shock attenuation is effectual.

2. This three-dimensional antidetonation formula steel construction factory building structure through buffer gear, and the steelframe drives first connecting steel and removes, makes the second movable block remove and extrudees the third spring, makes the second movable block play the supporting role to first connecting steel, prevents that first connecting steel from buckling the damage in the middle of because of vibrations.

Drawings

FIG. 1 is a schematic structural diagram of the present application;

FIG. 2 is a schematic view of a damping mechanism according to the present application;

fig. 3 is an enlarged schematic view of the structure at a in fig. 1 of the present application.

In the figure: 1. ground surface; 2. a case; 3. a damping mechanism; 301. a housing; 302. a telescopic rod; 303. a first spring; 304. a connecting rod; 305. a fixing plate; 306. a first fixing rod; 307. a second spring; 308. a first moving block; 309. a first hinge lever; 4. a steel frame; 5. a buffer mechanism; 501. a groove; 502. a second fixing rod; 503. a third spring; 504. a second moving block; 505. a second hinge lever; 6. a first connecting steel; 7. a second connecting steel; 8. a third connecting steel; 9. and a top plate.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

Referring to fig. 1, in this embodiment, a building structure of a three-dimensional anti-seismic steel structure factory building includes a ground 1, an upper surface of the ground 1 is fixed with a plurality of boxes 2, a damping mechanism 3 is arranged in the boxes 2, steel frames 4 are arranged on the damping mechanism 3, the steel frames 4 are damped through the damping mechanism 3, damage to the steel frames 4 is prevented, a first connecting steel 6 and a third connecting steel 8 are fixed between every two steel frames 4, a buffer mechanism 5 is arranged in the first connecting steel 6 and used for supporting and buffering the first connecting steel 6, two second connecting steels 7 are fixed between the first connecting steel 6 and the third connecting steel 8, and the two second connecting steels 7 are in an X shape and used for supporting and fixing the first connecting steel 6 and the third connecting steel 8.

Referring to fig. 2, for shock absorption, the shock absorbing mechanism 3 in this embodiment includes a housing 301 fixed on the lower surface of the inner cavity of the housing 2, a plurality of telescopic rods 302 are fixed on the lower surface of the inner cavity of the housing 301, a first spring 303 is sleeved on the outer surface of the telescopic rods 302, the first spring 303 is made to perform linear compression motion through the telescopic rods 302, a connecting rod 304 is fixed on the upper surface of the plurality of telescopic rods 302, the connecting rod 304 and the steel frame 4 are buffered and reset through the first spring 303, a fixing plate 305 is fixed on the upper surface of the connecting rod 304, a plurality of first fixing rods 306 are fixed on the left side and the right side of the housing 301, a first moving block 308 is slidably connected on the outer surfaces of the upper and lower two first fixing rods 306, a second spring 307 is sleeved on the outer surface of the first fixing rods 306, the steel frame 4 is buffered and damped through the second spring 307, and a first hinge rod 309 is hinged on the upper surface of the first moving block 308.

Wherein, the upper surface of first spring 303 is fixed in the lower surface of connecting rod 304, and the lower surface of first spring 303 is fixed in the lower surface of casing 301 inner chamber, and through first spring 303 to connecting rod 304 and steelframe 4 buffering and reset, connecting rod 304 is the T shape, and connecting rod 304 sliding connection is in the inside of casing 301, makes things convenient for connecting rod 304 to extrude first spring 303.

In addition, the steel frame 4 is fixed on the upper surface of the fixing plate 305, the upper surface of the first hinge rod 309 is hinged on the lower surface of the fixing plate 305, and the steel frame 4 presses the first hinge rod 309 through the fixing plate 305, so that the first hinge rod 309 drives the first moving block 308 to move and presses the second spring 307, thereby damping and buffering the steel frame 4.

Also, opposite sides of the left and right second springs 307 are respectively fixed on opposite sides of the two first moving blocks 308, opposite sides of the left and right second springs 307 are respectively fixed on left and right sides of the inner cavity of the box 2, the first moving blocks 308 move and squeeze the second springs 307 to cushion and buffer the steel frame 4, rubber blocks are fixed on the lower surface of the inner cavity of the shell 301, and the rubber blocks play a damping role on the connecting rod 304.

In the damping mechanism 3 in this embodiment, when an earthquake occurs, the steel frame 4 can squeeze the first spring 303 and the rubber block through the fixing plate 305 and the connecting rod 304, meanwhile, the fixing plate 305 can drive the first moving block 308 to move and squeeze the second spring 307 through the first hinging rod 309, and the damping effect is good by damping and buffering the steel frame 4 through the first spring 303 and the second spring 307.

Referring to fig. 3, in order to support and buffer the first connecting steel 6, the buffer mechanism 5 in this embodiment includes two grooves 501 opened on the lower surface of the first connecting steel 6, a second fixing rod 502 is fixed between the left and right sides of the inner cavity of the groove 501, the outer surface of the second fixing rod 502 is slidably connected with a second moving block 504, the outer surface of the second fixing rod 502 is sleeved with a third spring 503, the third spring 503 damps the second moving block 504, and the lower surface of the second moving block 504 is hinged with a second hinge rod 505.

Wherein, two articulated poles 505 are articulated respectively in the opposite one side of controlling two steelframe 4 in one side that is opposite to each other, support and cushion first connecting steel 6 through articulated pole 505 and second movable block 504 cooperation, prevent that first connecting steel 6 from buckling downwards from the centre, influence the use, the upper surface of second movable block 504 is fixed with T shape piece, T shape groove has been seted up to the upper surface of recess 501 inner chamber, T shape piece sliding connection is in the inside in T shape groove, stability when increasing second movable block 504 and remove.

In addition, opposite sides of the two third springs 503 are respectively fixed on opposite sides of the inner cavities of the two grooves 501, opposite sides of the two third springs 503 are respectively fixed on opposite sides of the two second moving blocks 504, and the second moving blocks 504 are damped by the third springs 503.

The buffer mechanism 5 in this embodiment, the steel frame 4 drives the first connecting steel 6 to move, so that the second moving block 504 moves and presses the third spring 503, so that the second moving block 504 supports the first connecting steel 6, and the first connecting steel 6 is prevented from being bent and damaged from the middle due to vibration.

The working principle of the embodiment is as follows:

(1) When an earthquake occurs, the steel frame 4 drives the connecting rod 304 to move through the fixing plate 305, the telescopic rod 302, the first spring 303 and the rubber block are extruded through the connecting rod 304, meanwhile, the fixing plate 305 drives the first moving block 308 to slide on the outer surface of the first fixing rod 306 through the first hinging rod 309 and to extrude the second spring 307, the steel frame 4 is damped and buffered through the first spring 303 and the second spring 307, after buffering, the first spring 303 is reset, the connecting rod 304 drives the fixing plate 305 and the steel frame 4 to reset, meanwhile, the second spring 307 is reset, the second spring 307 enables the first moving block 308 to reset, and the first moving block 308 drives the fixing plate 305 and the steel frame 4 to reset through the first hinging rod 309.

(2) When an earthquake occurs, the steel frame 4 drives the first connecting steel 6 to move together, the first connecting steel 6 is subjected to certain deformation when moving, the first connecting steel 6 bends towards the middle, the second moving block 504 slides on the outer surface of the second fixing rod 502 and presses the third spring 503, when the second moving block 504 moves, the T-shaped block can be driven to slide in the T-shaped groove, the stability of the second moving block 504 during moving is improved, the third spring 503 is pressed by the second moving block 504, the second moving block 504 supports the first connecting steel 6, and the first connecting steel 6 is prevented from being damaged by bending from the middle due to vibration.

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. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present application have been shown and described, it will be understood by those of ordinary skill in the art that various changes, modifications, substitutions and alterations may be made to these embodiments without departing from the principles and spirit of the present application.

Claims (8)

1. The utility model provides a three-dimensional antidetonation formula steel construction factory building structure, includes ground (1), its characterized in that: the novel ground connection device is characterized in that a plurality of boxes (2) are fixed on the upper surface of the ground (1), damping mechanisms (3) are arranged in the boxes (2), steel frames (4) are arranged on the damping mechanisms (3), first connection steels (6) and third connection steels (8) are fixed between every two steel frames (4), a buffer mechanism (5) is arranged in each first connection steel (6), and two second connection steels (7) are fixed between each first connection steel (6) and each third connection steel (8);

the shock-absorbing mechanism (3) comprises a shell (301) fixed on the lower surface of an inner cavity of the box body (2), a plurality of telescopic rods (302) are fixed on the lower surface of the inner cavity of the shell (301), a first spring (303) is sleeved on the outer surface of each telescopic rod (302), connecting rods (304) are fixed on the upper surface of each telescopic rod (302), fixing plates (305) are fixed on the upper surface of each connecting rod (304), a plurality of first fixing rods (306) are fixed on the left side and the right side of the shell (301), a first moving block (308) is connected to the outer surface of each first fixing rod (306) in a sliding mode, a second spring (307) is sleeved on the outer surface of each first fixing rod (306), and a first hinging rod (309) is hinged to the upper surface of each first moving block (308).

2. The three-dimensional anti-seismic steel structure factory building construction of claim 1, wherein: the upper surface of the first spring (303) is fixed on the lower surface of the connecting rod (304), and the lower surface of the first spring (303) is fixed on the lower surface of the inner cavity of the shell (301).

3. The three-dimensional anti-seismic steel structure factory building construction of claim 1, wherein: the connecting rod (304) is T-shaped, and the connecting rod (304) is connected to the inside of the shell (301) in a sliding mode.

4. The three-dimensional anti-seismic steel structure factory building construction of claim 1, wherein: the steel frame (4) is fixed on the upper surface of the fixed plate (305), and the upper surface of the first hinging rod (309) is hinged on the lower surface of the fixed plate (305).

5. The three-dimensional anti-seismic steel structure factory building construction of claim 1, wherein: the opposite sides of the left and right second springs (307) are respectively fixed on the opposite sides of the two first moving blocks (308), and the opposite sides of the left and right second springs (307) are respectively fixed on the left and right sides of the inner cavity of the box body (2).

6. The three-dimensional anti-seismic steel structure factory building construction of claim 1, wherein: the buffer mechanism (5) comprises two grooves (501) formed in the lower surface of the first connecting steel (6), a second fixing rod (502) is fixed between the left side and the right side of the inner cavity of the groove (501), the outer surface of the second fixing rod (502) is slidably connected with a second moving block (504), a third spring (503) is sleeved on the outer surface of the second fixing rod (502), and a second hinging rod (505) is hinged to the lower surface of the second moving block (504).

7. The three-dimensional anti-seismic steel structure factory building construction of claim 6, wherein: two opposite sides of the second hinging rods (505) are respectively hinged to opposite sides of the left steel frame and the right steel frame (4), a T-shaped block is fixed on the upper surface of the second moving block (504), a T-shaped groove is formed in the upper surface of the inner cavity of the groove (501), and the T-shaped block is slidably connected to the inside of the T-shaped groove.

8. The three-dimensional anti-seismic steel structure factory building construction of claim 6, wherein: the opposite sides of the two third springs (503) are respectively fixed on the opposite sides of the inner cavities of the two grooves (501), and the opposite sides of the two third springs (503) are respectively fixed on the opposite sides of the two second moving blocks (504).