CN114351885A - Assembled steel construction wind-resistant shock attenuation building - Google Patents

Abstract

The invention discloses an assembly type steel structure wind-resistant shock-absorbing building which comprises two anti-seismic frames, wherein the bottom of each anti-seismic frame is provided with a groove, a first sliding seat is fixedly installed at the inner top of each anti-seismic frame, a first sliding groove is formed in the center of the bottom of each first sliding seat, first springs are fixedly connected to positions, close to the tops, of two sides in each anti-seismic frame, and a connecting plate is fixedly connected to one side, opposite to the two first springs, of each anti-seismic frame. This assembled steel construction anti-wind shock attenuation building, through antidetonation frame, first slide, first spring, three hornblocks, first slider, the second slide, first post of moving away to avoid possible earthquakes, the second slider, the cooperation of spliced pole and trapezoidal piece is used, when assembled steel construction building is receiving vibrations, trapezoidal piece upwards or move down, two three hornblocks that can make in the antidetonation frame move mutually or mutually away from each other, two three hornblocks are continuous to extrude or reset first spring, thereby the realization plays vertical absorbing effect to the steel construction building.

Description

Assembled steel construction wind-resistant shock attenuation building

Technical Field

The invention relates to the technical field of fabricated steel structure buildings, in particular to a wind-resistant and shock-absorbing fabricated steel structure building.

Background

The fabricated building of a steel structure is a steel structure building which is fabricated and connected by assembling steel structure components produced in a factory at a construction site.

Traditional assembled steel construction building, most shock attenuation effect is poor, and the function of main equipment and high wind all can lead to the fact the vibrations of different degrees to assembled steel construction building to probably lead to the structure of building to receive the influence, shortened assembled steel construction building's life, can't satisfy user's user demand already. Therefore, we propose an assembled steel structure wind-resistant and shock-absorbing building.

Disclosure of Invention

The invention aims to provide an assembly type steel structure wind-resistant damping building, which aims to solve the problems that most of traditional assembly type steel structure buildings in the background art have poor damping effect, and the operation of large-scale equipment and strong wind can cause vibration of different degrees to the assembly type steel structure buildings, so that the structure of the building can be influenced, the service life of the assembly type steel structure building is shortened, and the use requirements of users cannot be met.

In order to achieve the purpose, the invention provides the following technical scheme: an assembled steel structure wind-resistant shock-absorbing building comprises two anti-seismic frames, wherein the bottom of each anti-seismic frame is provided with a groove, a first slide seat is fixedly installed at the inner top of each anti-seismic frame, a first sliding chute is formed in the center of the bottom of each first slide seat, first springs are fixedly connected to the positions, close to the top, of two sides in each anti-seismic frame, connecting plates are fixedly connected to the opposite sides of the two first springs, triangular blocks are fixedly installed at the positions, close to the center, of the opposite sides of the two connecting plates, the two triangular blocks are symmetrically arranged, first sliding blocks are fixedly connected to the centers of the tops of the two triangular blocks, the tops of the two first sliding blocks penetrate through the inner parts of the first sliding chutes and are in contact with the inner parts of the first sliding chutes, second slide seats are fixedly installed at the positions, close to the bottom, of two sides in each anti-seismic frame, and second sliding chutes are formed in the opposite sides of the two second sliding seats, the bottom of one side, opposite to the two second sliding grooves, is connected with a second sliding block in a sliding mode, the opposite side of the two second sliding blocks penetrates through the outer portions of the two second sliding grooves respectively, a first shock-absorbing column is fixedly installed between the two second sliding blocks, a connecting column is fixedly connected to the position, close to the center, of the top of the first shock-absorbing column, a trapezoidal block is fixedly installed at the top of the connecting column, the bottom of the first shock-absorbing column penetrates through the outer portion of the shock-absorbing frame and is fixedly provided with a first inserting block, a first concave seat is arranged at the bottom of the first inserting block, a slot is formed in the top of the first concave seat, the bottom of the first inserting block penetrates through the inner portion of the first concave seat and is in contact with the inner wall of the first inserting block, a steel column is fixedly installed at the position, close to the center, the opposite side of the two shock-absorbing frames is fixedly provided with a second inserting block, and the opposite side of the two second inserting blocks is provided with a second concave seat, the opposite sides of the two second concave seats are respectively provided with a slot, the opposite sides of the two second inserting blocks respectively penetrate into the two second concave seats and are contacted with the inner walls of the second concave seats, a cross beam is arranged between the two second concave seats, the opposite sides of the cross beam are respectively fixedly provided with a hollow block, the inside of the hollow block is provided with a cavity, the two hollow blocks are symmetrically arranged in an opposite way, the positions of the inner top and the bottom of the hollow block close to one side are respectively provided with a third chute, the positions of the inner top and the bottom of the hollow block close to the other side are respectively provided with a spring groove, the opposite sides of the two spring grooves which are arranged up and down are respectively and fixedly connected with a second spring, the opposite sides of the two second springs which are arranged up and down are respectively and fixedly connected with a movable block, the outer walls of the two movable blocks are respectively contacted with the inner walls of the two spring grooves, and the opposite sides of the two movable blocks which are arranged up and down respectively penetrate to the outside of the two spring grooves, the centers of the opposite sides of the two movable blocks which are arranged up and down are fixedly connected with a first shaft bracket, the opposite sides of the two first shaft brackets which are arranged up and down are movably connected with a movable rod through a shaft lever, the positions close to one side in the two third sliding grooves are respectively connected with a third sliding block in a sliding way, the opposite sides of the two third sliding blocks which are arranged up and down are respectively penetrated to the outer parts of the two third sliding grooves, the position close to the center between the two third sliding blocks is fixedly connected with a movable plate, a second shaft frame is fixedly arranged near the center of one side of the movable plate, one ends of the two movable rods are respectively movably connected with two shaft rods fixedly arranged at one side of the second shaft frame, the back center position of fly leaf opposite side puts fixed mounting with the second post of moving away to avoid possible earthquakes, one side of second post of moving away to avoid possible earthquakes runs through to the outside of cavity piece, and one side that two second posts of moving away to avoid possible earthquakes carried on the back mutually respectively with the center fixed connection of two second concave seat relative one sides.

Preferably, the trapezoid block is an isosceles trapezoid, the inclined planes of the trapezoid block are respectively the same as the inclined planes of the two triangle blocks, and the inclined planes on the two sides of the trapezoid block are respectively contacted with the inclined planes on the opposite sides of the two triangle blocks.

Preferably, the first locating groove has been all seted up by both sides position of leaning on of first inserted block bottom, the first locating block of the equal fixedly connected with in both sides position of leaning on of bottom in the first spill seat, the top of two first locating blocks run through respectively to the inside in two first locating grooves and contact with the inner wall in first locating groove.

Preferably, the top position and the bottom position of the opposite side of the two second inserting blocks are fixedly connected with second positioning blocks, the top position and the bottom position of the back side of the two second concave seats are respectively provided with a second positioning groove, and the two second positioning blocks arranged at the two ends respectively penetrate through the insides of the two second positioning grooves and are in contact with the inner walls of the second positioning grooves.

Preferably, the top positions of the two sides of the first concave seat are connected with first screw rods in a threaded manner, one sides of the two first screw rods opposite to each other sequentially penetrate through the interiors of the first concave seat and the first insert block and are connected with the inner wall of the first insert block in a threaded manner, the two sides of the first screw rods opposite to each other in surface are connected with first fixing nuts in a threaded manner, and the two sides of the two first fixing nuts opposite to each other are respectively in contact with the two sides of the first concave seat.

Preferably, the top of the second concave seat and the bottom of the second concave seat are in threaded connection with a second screw rod, one side, opposite to the two second screw rods, of the upper and lower second concave seats sequentially penetrates through the interiors of the second concave seats and the second insertion blocks and is in threaded connection with the inner walls of the second insertion blocks, one side, opposite to the surfaces of the two second screw rods, of the upper and lower second screw rods is in threaded connection with a second fixing nut, and one side, opposite to the two second fixing nuts, of the upper and lower second fixing nuts is in contact with the top and the bottom of the second concave seat respectively.

Preferably, the two movable rods are arranged in a relatively inclined manner, and the two movable rods are in a transverse splayed structure.

Compared with the prior art, the invention has the beneficial effects that:

the assembled steel structure wind-resistant shock-absorbing building is characterized in that the assembled steel structure wind-resistant shock-absorbing building is matched with the shock-absorbing frame, the first sliding seat, the first spring, the triangular blocks, the first sliding block, the second sliding seat, the first shock-absorbing column, the second sliding block, the connecting column and the trapezoidal blocks for use, when the assembled steel structure building is vibrated, the trapezoidal blocks move upwards or downwards to enable the two triangular blocks in the shock-absorbing frame to move oppositely or oppositely, the two triangular blocks continuously extrude or reset the first spring, so that the steel structure building is longitudinally damped, the hollow blocks, the third sliding grooves, the second springs, the movable blocks, the first shaft frame, the movable plates, the third sliding blocks, the second sliding frames, the movable rods and the second shock-absorbing column are matched for use, when the assembled steel structure building is vibrated, the second shock-absorbing column enables the movable plates to drive the two movable rods to continuously enable the movable blocks to compress and reset the second springs in the two spring grooves, thereby realized carrying out horizontal absorbing effect to steel construction building, improved the antidetonation effect, prolonged assembled steel construction building's life, satisfied user's user demand.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1;

FIG. 3 is an enlarged view of a portion of B of FIG. 1 according to the present invention;

FIG. 4 is a cross-sectional view of the first female socket and the first insert of the present invention;

FIG. 5 is a cross-sectional view of a second female socket and a second insert of the present invention;

FIG. 6 is a perspective view of the construction of the triangular block of the present invention;

FIG. 7 is a perspective view showing the structure of the trapezoidal block of the present invention;

fig. 8 is a front view of the structure of the present invention.

In the figure: 1. an anti-seismic frame; 2. a first slider; 3. a first chute; 4. a first spring; 5. a connecting plate; 6. a triangular block; 7. a first slider; 8. a second slide carriage; 9. a second chute; 10. a first shock absorbing column; 11. a second slider; 12. connecting columns; 13. a trapezoidal block; 14. a steel column; 15. a first concave seat; 16. a first positioning block; 17. a first insert block; 18. a first positioning groove; 19. a first screw; 20. a first fixing nut; 21. a second insert block; 22. a cross beam; 23. a hollow block; 24. a third chute; 25. a spring slot; 26. a second spring; 27. a movable block; 28. a first pedestal; 29. a movable plate; 30. a third slider; 31. a second shaft frame; 32. a movable rod; 33. a second shock-absorbing column; 34. a second concave seat; 35. a second positioning groove; 36. a second positioning block; 37. a second screw; 38. and a second fixing nut.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: an assembly type steel structure wind-resistant shock-absorbing building comprises shock-resistant frames 1, wherein the number of the shock-resistant frames 1 is two, grooves are formed in the bottoms of the shock-resistant frames 1, first sliding seats 2 are fixedly installed at the inner tops of the shock-resistant frames 1, first sliding chutes 3 are formed in the centers of the bottoms of the first sliding seats 2, first springs 4 are fixedly connected to the top positions of two sides in the shock-resistant frames 1, connecting plates 5 are fixedly connected to opposite sides of the two first springs 4, triangular blocks 6 are fixedly installed at the center positions of opposite sides of the two connecting plates 5, the two triangular blocks 6 are symmetrically arranged, first sliding blocks 7 are fixedly connected to the centers of the tops of the two triangular blocks 6, the tops of the two first sliding blocks 7 penetrate through the inner portions of the first sliding chutes 3 and are in contact with the inner portions of the first sliding chutes 3, second sliding seats 8 are fixedly installed at the bottom positions of two sides in the shock-resistant frames 1, second sliding chutes 9 are formed in opposite sides of the two second sliding seats 8, the bottom positions of the opposite sides of the two second sliding grooves 9 are both connected with second sliding blocks 11 in a sliding manner, the opposite sides of the two second sliding blocks 11 respectively penetrate through the outer parts of the two second sliding grooves 9, a first shock-absorbing column 10 is fixedly arranged between the two second sliding blocks 11, a connecting column 12 is fixedly connected with the position close to the center of the top of the first shock-absorbing column 10, a trapezoidal block 13 is fixedly arranged at the top of the connecting column 12, the bottom of the first shock-absorbing column 10 penetrates through the outer part of the shock-absorbing frame 1 and is fixedly provided with a first inserting block 17, a first concave seat 15 is arranged at the bottom of the first inserting block 17, a slot is formed in the top of the first concave seat 15, the bottom of the first inserting block 17 penetrates through the inner part of the first concave seat 15 and is in contact with the inner wall of the first inserting block 17, a steel column 14 is fixedly arranged at the position close to the center of the bottom of the first concave seat 15, and second inserting blocks 21 are fixedly arranged at the opposite sides of the two shock-absorbing frames 1, the opposite sides of the two second inserting blocks 21 are respectively provided with a second concave seat 34, the opposite sides of the two second concave seats 34 are respectively provided with a slot, the opposite sides of the two second inserting blocks 21 respectively penetrate into the two second concave seats 34 and are contacted with the inner wall of the second concave seats 34, a cross beam 22 is arranged between the two second concave seats 34, the opposite sides of the cross beam 22 are respectively and fixedly provided with a hollow block 23, the inside of the hollow block 23 is provided with a cavity, the two hollow blocks 23 are symmetrically arranged in an opposite way, the positions close to one side of the top and the bottom of the hollow block 23 are respectively provided with a third sliding chute 24, the positions close to the other side of the top and the bottom of the hollow block 23 are respectively provided with a spring groove 25, the opposite sides of the two spring grooves 25 which are arranged up and down are respectively and fixedly connected with a second spring 26, the opposite sides of the two second springs 26 which are arranged up and down are respectively and fixedly connected with a movable block 27, the outer walls of the two movable blocks 27 are respectively contacted with the inner walls of the two spring grooves 25, opposite sides of two movable blocks 27 arranged up and down respectively penetrate through the outsides of the two spring grooves 25, the centers of opposite sides of the two movable blocks 27 arranged up and down are fixedly connected with a first shaft bracket 28, opposite sides of the two first shaft brackets 28 arranged up and down are movably connected with movable rods 32 through shaft rods, positions close to one side in the two third sliding grooves 24 are respectively connected with a third sliding block 30 in a sliding manner, opposite sides of the two third sliding blocks 30 arranged up and down respectively penetrate through the outsides of the two third sliding grooves 24, a movable plate 29 is fixedly connected between the two third sliding blocks 30 close to the center, a second shaft bracket 31 is fixedly arranged at the position close to the center of one side of the movable plate 29, one ends of the two movable rods 32 are respectively movably connected with the two shaft rods fixedly arranged at one side of the second shaft bracket 31, and a second shock-absorbing column 33 is fixedly arranged at the position close to the center of the other side of the movable plate 29, one side of the second shock absorbing columns 33 penetrates to the outside of the hollow block 23, and the opposite sides of the two second shock absorbing columns 33 are fixedly connected with the centers of the opposite sides of the two second concave seats 34 respectively.

In the invention: the trapezoid blocks 13 are isosceles trapezoids, the inclined planes of the trapezoid blocks 13 are the same as the inclined planes of the two triangle blocks 6 respectively, and the inclined planes on the two sides of the trapezoid blocks 13 are in contact with the inclined planes on the opposite sides of the two triangle blocks 6 respectively; the two triangular blocks 6 can be pushed back to each other by the movement of the trapezoidal blocks 13, so that the two first springs 4 are forced to be compressed.

In the invention: the bottom of the first insert block 17 is provided with first positioning grooves 18 at positions close to two sides, the bottom of the first concave seat 15 is fixedly connected with first positioning blocks 16 at positions close to two sides, and the tops of the two first positioning blocks 16 penetrate into the two first positioning grooves 18 respectively and are in contact with the inner walls of the first positioning grooves 18; the first positioning groove 18 and the first positioning block 16 are designed to ensure that the anti-seismic frame 1 and the steel column 14 can be stably positioned when being installed.

In the invention: the top and bottom positions of the opposite sides of the two second inserting blocks 21 are fixedly connected with second positioning blocks 36, the top and bottom positions of the back side in the two second concave seats 34 are respectively provided with a second positioning groove 35, and the two second positioning blocks 36 arranged at the two ends respectively penetrate through the insides of the two second positioning grooves 35 and are in contact with the inner walls of the second positioning grooves 35; a second locating block 36; the second positioning block 36 and the second positioning slot 35 are designed to play a role in positioning and stabilizing when the anti-seismic frame 1 and the cross beam 22 are installed.

In the invention: the top positions of two sides of the first concave seat 15 close to the top are both in threaded connection with first screw rods 19, one opposite sides of the two first screw rods 19 sequentially penetrate through the interiors of the first concave seat 15 and the first insert block 17 and are in threaded connection with the inner wall of the first insert block 17, one opposite sides of the surfaces of the two first screw rods 19 are both in threaded connection with first fixing nuts 20, and one opposite sides of the two first fixing nuts 20 are respectively in contact with two sides of the first concave seat 15; the first screw 19 and the first fixing nut 20 are designed to enable the first insert 17 and the first female socket 15 to be fixedly mounted therebetween.

In the invention: a second screw rod 37 is in threaded connection with one side of the top and the bottom of the second concave seat 34, one side of each of the two vertically arranged second screw rods 37 opposite to each other sequentially penetrates through the interiors of the second concave seat 34 and the second insert block 21 and is in threaded connection with the inner wall of the second insert block 21, one side of each of the vertically arranged second screw rods 37 opposite to the surface is in threaded connection with a second fixing nut 38, and one side of each of the vertically arranged second fixing nuts 38 opposite to each other is in contact with the top and the bottom of the second concave seat 34; the second screw 37 and the second fixing nut 38 are designed to be able to fixedly attach the second insert block 21 to the second female socket 34.

In the invention: the two movable rods 32 are arranged in a relatively inclined manner, and the two movable rods 32 are in a transverse splayed structure; it can be ensured that the two movable rods 32, when forced to move, cause the movable block 27 to press the second spring 26.

The working principle is as follows: when the steel column 14 and the cross beam 22 are assembled, first the first insert blocks 17 at the bottom of the two first shock absorbing columns 10 are respectively inserted into the first concave seats 15 at the top of the two steel columns 14, so that the first positioning blocks 16 are positioned in the first positioning grooves 18, then the first screw rods 19 and the first fixing nuts 20 are used for fixing the first concave seats 15 and the first insert blocks 17, then the second insert blocks 21 on the two shock absorbing frames 1 are positioned in the second concave seats 34 at the two sides of the cross beam 22, so that the second positioning blocks 36 are positioned in the second positioning grooves 35, finally the second screw rods 37 and the second fixing nuts 38 are used for fixing the second insert blocks 21 and the second concave seats 34, the cross beam 22 and the steel column 14 are assembled with the shock absorbing frame 1, when the shock is received, the first shock absorbing column 10 at the top of the steel column 14 makes the trapezoidal blocks 13 of the connecting column 12 move up and down along with the up and down movement of the trapezoidal blocks 13, the two triangular blocks 6 can be pushed to move back and forth, meanwhile, the first sliding block 7 and the second sliding block 11 respectively move in the first sliding groove 3 and the second sliding groove 9, and can respectively play a role in limiting and stabilizing the triangular blocks 6 and the first shock absorbing column 10 when moving, at the moment, the two triangular blocks 6 move back and forth to enable the two connecting plates 5 to respectively extrude the two first springs 4, the vibration generated in the longitudinal direction can be weakened through the elastic resetting effect of the first springs 4, when the vibration is received, the second shock absorbing columns 33 on the two sides of the cross beam 22 move towards the hollow block 23 along with the vibration, at the moment, the two second shock absorbing columns 33 respectively and two movable plates 29 simultaneously move relatively, when the movable plates 29 move, the third sliding blocks 30 on the top and the bottom are respectively driven to move in the two third sliding grooves 24 in the hollow block 23, and as the two ends of the two movable rods 32 are respectively movably connected with the second shaft frame 31 and the two first shaft frames 28, when the movable plate 29 moves, the two movable rods 32 are driven to move obliquely, and at the same time, the angle of one side of the two movable rods 32 changes, so that the two movable blocks 27 are respectively pushed to compress the second springs 26 in the spring grooves 25, and the transverse beam 22 can be transversely damped.

In summary, the following steps: the assembled steel structure wind-resistant shock-absorbing building is characterized in that the assembled steel structure wind-resistant shock-absorbing building is used by matching the shock-resistant frame 1, the first sliding seat 2, the first spring 4, the triangular blocks 6, the first sliding block 7, the second sliding seat 8, the first shock-absorbing column 10, the second sliding block 11, the connecting column 12 and the trapezoidal blocks 13, when the assembled steel structure building is vibrated, the trapezoidal blocks 13 move upwards or downwards, the two triangular blocks 6 in the shock-resistant frame 1 can move oppositely or oppositely, the two triangular blocks 6 continuously extrude or reset the first spring 4, and therefore the steel structure building can be longitudinally damped, the hollow blocks 23, the third sliding grooves 24, the second spring 26, the movable blocks 27, the first shaft frame 28, the movable plate 29, the third sliding block 30, the second shaft frame 31, the movable rods 32 and the second shock-absorbing column 33 are matched for use, when the assembled steel structure building is vibrated, the second shock-absorbing column 33 enables the movable plates 29 to drive the two movable rods 32 to continuously enable the movable blocks 27 to be matched with the second shock-absorbing columns 25 in the two spring grooves 25 Two springs 26 compress and reset to realized carrying out horizontal absorbing effect to steel construction building, improved the antidetonation effect, prolonged assembled steel construction building's life, satisfied user's user demand.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an assembled steel construction anti-wind shock attenuation building, includes antidetonation frame (1), its characterized in that: the number of the anti-seismic frame (1) is two, a groove is formed in the bottom of the anti-seismic frame (1), a first sliding seat (2) is fixedly installed at the inner top of the anti-seismic frame (1), a first sliding groove (3) is formed in the center of the bottom of the first sliding seat (2), first springs (4) are fixedly connected to the positions, close to the top, of two sides in the anti-seismic frame (1), connecting plates (5) are fixedly connected to one sides, opposite to the first springs (4), of the two connecting plates (5), triangular blocks (6) are fixedly installed at the positions, close to the center, of one sides, opposite to the two connecting plates (5), the two triangular blocks (6) are symmetrically arranged, first sliding blocks (7) are fixedly connected to the centers of the tops of the two triangular blocks (6), the tops of the two first sliding blocks (7) penetrate through the inside of the first sliding groove (3) and are in contact with the inside of the first sliding groove (3), second sliding seats (8) are fixedly installed at the positions, close to the bottom, of two sides in the anti-seismic frame (1), second spout (9) have all been seted up to one side that two second slides (8) are relative, and the equal sliding connection in bottom position that leans on of one side that two second spouts (9) are relative has second slider (11), and one side that two second sliders (11) are relative runs through the outside to two second spouts (9) respectively, and fixed mounting has first shock absorber post (10) between two second sliders (11), the center position fixedly connected with spliced pole (12) that leans on at first shock absorber post (10) top, the top fixed mounting of spliced pole (12) has trapezoidal piece (13), the bottom of first shock absorber post (10) runs through to the outside and the fixed mounting of antidetonation frame (1) first inserted block (17), the bottom of first inserted block (17) is provided with first spill seat (15), the slot has been seted up at the top of first spill seat (15), the bottom of first inserted block (17) run through to the inside of first spill seat (15) and with the inner wall of first inserted block (17) The anti-seismic device comprises a first concave seat (15), a steel column (14) is fixedly mounted at the position close to the center of the bottom of the first concave seat (15), second inserting blocks (21) are fixedly mounted at one opposite sides of two anti-seismic frames (1), second concave seats (34) are arranged at one opposite sides of the two second inserting blocks (21), slots are formed in the opposite sides of the two second concave seats (34), one opposite sides of the two second inserting blocks (21) penetrate into the interiors of the two second concave seats (34) respectively and are in contact with the inner walls of the second concave seats (34), a cross beam (22) is arranged between the two second concave seats (34), hollow blocks (23) are fixedly mounted at one opposite sides of the cross beam (22), cavities are formed in the interiors of the hollow blocks (23), the two hollow blocks (23) are symmetrically arranged opposite to each other, third sliding grooves (24) are formed in the positions close to the top and the bottom of the hollow blocks (23), spring grooves (25) are respectively formed in the positions, close to the other side, of the top and the bottom in the hollow block (23), second springs (26) are respectively and fixedly connected to one sides, opposite to the two spring grooves (25), of the upper and lower parts, movable blocks (27) are respectively and fixedly connected to one sides, opposite to the two second springs (26), of the upper and lower parts, the outer walls of the two movable blocks (27) are respectively contacted with the inner walls of the two spring grooves (25), one sides, opposite to the two movable blocks (27), of the upper and lower parts are respectively penetrated to the outer parts of the two spring grooves (25), first shaft brackets (28) are respectively and fixedly connected to the centers of one sides, opposite to the two movable blocks (27), of the upper and lower parts, of the two first shaft brackets (28), are respectively and movably connected with movable rods (32) through shaft rods, and third sliding blocks (30) are respectively and slidably connected to the positions, close to one side, in the two third sliding grooves (24), the outside to two third spout (24) is run through respectively to the relative one side of two third slider (30) that set up from top to bottom, leans on central point between two third slider (30) to put fixedly connected with fly leaf (29), lean on central point of fly leaf (29) one side to put fixed mounting have second shaft bracket (31), the one end of two movable rods (32) respectively with two axostylus axostyle swing joint of second shaft bracket (31) one side fixed mounting, the leaning on central point of fly leaf (29) opposite side puts fixed mounting has second shock absorber post (33), one side of second shock absorber post (33) runs through to the outside of cavity piece (23), one side that two second shock absorber posts (33) were carried on the back respectively with the central fixed connection of the relative one side of two second spill seats (34).

2. The assembled steel structure wind-resistant and shock-absorbing building as claimed in claim 1, wherein: trapezoidal piece (13) are isosceles trapezoid, the inclined plane of trapezoidal piece (13) is the same with the inclination on two three hornblocks (6) inclined plane respectively, the inclined plane of trapezoidal piece (13) both sides contacts with the inclined plane of two three hornblocks (6) relative one side respectively.

3. The assembled steel structure wind-resistant and shock-absorbing building as claimed in claim 1, wherein: first locating slot (18) have all been seted up by both sides position of leaning on of first inserted block (17) bottom, the equal fixedly connected with first locating block (16) of both sides position of leaning on of bottom in first spill seat (15), the top of two first locating blocks (16) run through respectively to the inside of two first locating slots (18) and contact with the inner wall of first locating slot (18).

4. The assembled steel structure wind-resistant and shock-absorbing building as claimed in claim 1, wherein: the top position and the bottom position of leaning on of two relative one sides of second inserted block (21) equal fixedly connected with second locating piece (36), second constant head tank (35) have all been seted up to the top position and the bottom position of leaning on of one side of back in two second spill seats (34), and two second locating pieces (36) that both ends set up run through respectively to the inside of two second constant head tanks (35) and contact with the inner wall of second constant head tank (35).

5. The assembled steel structure wind-resistant and shock-absorbing building as claimed in claim 1, wherein: the top-leaning position of the two sides of the first concave seat (15) is connected with a first screw rod (19) in a threaded mode, one side, opposite to the two first screw rods (19), of the first concave seat (15) and the first inserting block (17) sequentially penetrates through the interior of the first concave seat and the inner wall of the first inserting block (17) in a threaded mode, one side, opposite to the surface of the two first screw rods (19), of the first concave seat is connected with a first fixing nut (20) in a threaded mode, and one side, opposite to the two first fixing nuts (20), of the two first concave seats is in contact with the two sides of the first concave seat (15) respectively.

6. The assembled steel structure wind-resistant and shock-absorbing building as claimed in claim 1, wherein: the top of the second concave seat (34) and the bottom of the second concave seat are connected with a second screw rod (37) through threads on one side, opposite to the two second screw rods (37), of the upper portion and the lower portion sequentially penetrates through the inside of the second concave seat (34) and the inside of the second insert block (21) and is connected with the inner wall of the second insert block (21) through threads, one side, opposite to the surface of the two second screw rods (37), of the upper portion and the lower portion is connected with a second fixing nut (38) through threads, and one side, opposite to the two second fixing nuts (38), of the upper portion and the lower portion are respectively in contact with the top and the bottom of the second concave seat (34).

7. The assembled steel structure wind-resistant and shock-absorbing building as claimed in claim 1, wherein: the two movable rods (32) are arranged in a relatively inclined way, and the two movable rods (32) are in a transverse splayed structure.

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