CN219510301U

CN219510301U - High shock resistance steel structure

Info

Publication number: CN219510301U
Application number: CN202223201309.6U
Authority: CN
Inventors: 刘成刚
Original assignee: Xinjiang Hao Chen Hui Xuan Heavy Industry Co ltd
Current assignee: Xinjiang Hao Chen Hui Xuan Heavy Industry Co ltd
Priority date: 2022-11-30
Filing date: 2022-11-30
Publication date: 2023-08-11
Anticipated expiration: 2032-11-30

Abstract

The utility model relates to the technical field of steel structures, and discloses a high shock resistance steel structure, which comprises a top seat and an outer support, wherein a pipe rack is arranged on the inner side of the outer support, a first inner joint block is arranged on the bottom surface of the top seat, a first outer joint block is rotatably connected to the end surface of the first inner joint block, a second inner joint block is arranged on the bottom surface of the first outer joint block, a second outer joint block is rotatably connected to the end surface of the second inner joint block, pin shafts are rotatably connected to the end surfaces of the first inner joint block and the second inner joint block, side grooves are formed in the inner side surfaces of the first outer joint block and the second outer joint block, a first fixed block is arranged on one side of the inner wall of the side groove, and a second fixed block is arranged on the other side of the inner wall of the side groove. This high shock resistance's steel construction through with footstock wall top surface fixed connection, can fix the pipeline through the pipe support, and when the pipeline takes place to rock, can cushion the shock attenuation to it.

Description

High shock resistance steel structure

Technical Field

The utility model relates to the technical field of steel structures, in particular to a steel structure with high shock resistance.

Background

The steel structure is a structure formed by steel materials, is one of main building structure types, mainly comprises steel beams, steel columns, steel separation frames and other components made of section steel, steel plates and the like, and each component or part is connected by adopting welding seams, bolts or rivets, so that the steel structure is light in dead weight, simple and convenient to construct and widely applied to the fields of large-scale plants, venues, super high-rise and the like.

Steel structure pipelines for conveying tap water, fire protection and natural gas are sometimes arranged on the tops of the wall surfaces of some buildings, and are mostly connected with the walls through bridges or screws, namely, the pipelines are suspended in the air through the bridges or screws, and the bridges or screws do not have the functions of shock resistance and multidirectional rotation buffering, so that when the wall body vibrates, the pipelines are likely to shake severely, the pipelines further drive the bridges or screws to shake, and the pipelines and the bridges or the screws fall off to be dangerous.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides a steel structure with high shock resistance, and solves the problem of low shock resistance and buffer capacity of a building steel structure pipeline bridge.

(II) technical scheme

In order to achieve the purpose of high shock resistance and buffer capacity of the building steel structure pipeline bridge, the utility model provides the following technical scheme: the utility model provides a steel construction of high shock resistance, includes footstock and outer support, the pipe support is installed to the inboard of outer support, the first interior splicing block is installed to the bottom surface of footstock, the terminal surface of first interior splicing block rotates and is connected with first outer splicing block, the second interior splicing block is installed to the bottom surface of first outer splicing block, the terminal surface of second interior splicing block rotates and is connected with the second outer splicing block, the terminal surface of first interior splicing block and second interior splicing block all rotates and is connected with the round pin axle, the side groove has all been seted up to the inside side of first outer splicing block and second outer splicing block, first fixed block is installed to the inner wall one side of side groove, the second fixed block is installed to the inner wall opposite side of side groove;

the outer fixed cylinder is installed on the end face of the first fixed block, the outer cylinder sliding groove is formed in the outer fixed cylinder, the limiting sliding plate is connected to the inner portion of the outer cylinder sliding groove in a sliding mode, the inner sliding rod is installed on the end face of the limiting sliding plate, and the spring is sleeved on the outer surface of the inner sliding rod and located in the outer cylinder sliding groove.

Preferably, both ends of the spring are fixedly connected with the limiting slide plate and the inner wall of the outer cylinder chute, and when the inner slide rod moves, the spring can be driven to stretch or shrink through the limiting slide plate.

Preferably, the outer fixed cylinder, the inner slide bar and the spring are all in arc shapes, the outer fixed cylinder, the inner slide bar and the spring form a telescopic spring rod, the outer fixed cylinder and the inner slide bar are symmetrically arranged at one hundred eighty degrees, the outer fixed cylinder and the inner slide bar at two sides are symmetrically arranged at one hundred eighty degrees, and when the telescopic spring rod at one side is stretched, the telescopic spring rod at the other side can be contracted, so that the buffering and damping capacity of a pipeline can be improved.

Preferably, the side groove is a step-shaped groove, the pin shaft is rotationally connected with the side groove with smaller diameter, the first fixed block is fixedly connected with the side groove with larger diameter, the second fixed block is fixedly connected with the pin shaft, and the second fixed block is slidably connected with the inner wall of the side groove with larger diameter, namely, the pin shaft is fixedly connected with the first inner connecting block and the second inner connecting block, when the first outer connecting block rotates, the telescopic spring rod formed by the outer fixed cylinder, the inner sliding rod and the spring can be driven to stretch or shrink through the first fixed block and the second fixed block, and similarly, the telescopic spring rod can be driven to stretch or shrink when the second outer connecting block rotates, so that the first outer connecting block and the second outer connecting block can buffer the pipeline when rotating.

Preferably, the first inner joint block and the first outer joint block form a hinge block through a pin shaft, the second inner joint block and the second outer joint block form a hinge block through a pin shaft, the rotation directions of the hinge blocks at the upper end and the lower end are mutually perpendicular, namely the hinge blocks formed by the first inner joint block, the first outer joint block and the pin shaft at the front side and the rear side or the left side and the right side, and the hinge blocks formed by the second inner joint block, the second outer joint block and the pin shaft can enable the pipeline to swing in a multidirectional manner and simultaneously buffer and damp in a multidirectional manner.

Preferably, one end of the outer side of the outer support is fixedly connected with the second outer block, so that the outer support can drive the second outer block to swing, and the pipeline can rotate in multiple directions and is buffered and damped.

Compared with the prior art, the utility model provides a steel structure with high shock resistance, which comprises the following components

The beneficial effects are that:

1. this high shock resistance's steel construction, the articulated piece of constituteing through the first interior piece of front end, first outer piece and round pin axle to and the articulated piece of the second interior piece of rear end, second outer piece and round pin axle constitution can make the pipeline swing in the fore-and-aft direction, and when the pipeline front-and-aft direction is swung, can drive the expansion spring pole that outer fixed cylinder, interior slide bar and spring constitute and stretch or shrink, thereby can cushion the shock attenuation to the pipeline of front-and-aft direction swing through the expansion spring pole.

2. When the pipeline is vibrated and sways in the left-right direction, the pipeline can swing in the left-right direction through the hinging block formed by the first inner hinging block at the front end of the left end, the first outer hinging block and the pin shaft and the hinging block formed by the second inner hinging block at the right end, the second outer hinging block and the pin shaft, and the directionally swinging pipeline can be buffered and damped through the telescopic spring rod.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a bottom view of the structure of the present utility model;

FIG. 3 is an exploded view of a first inner joint block and a first outer joint block of the present utility model

Fig. 4 is a front sectional view of the outer stator of the structure of the present utility model.

Wherein: 1. a top base; 2. an outer bracket; 3. a pipe rack; 4. a first inner joint block; 5. a first external block; 6. a second inner joint block; 7. a second outer block; 8. a pin shaft; 9. a side groove; 10. a first fixed block; 11. an outer fixed cylinder; 12. an outer barrel chute; 13. a limit sliding plate; 14. an inner slide bar; 15. a spring; 16. and a second fixed block.

Detailed Description

Referring to fig. 1-4, the utility model provides a steel structure with high shock resistance, which comprises a top seat 1 and an outer support 2, wherein a pipe frame 3 is arranged on the inner side of the outer support 2, a first inner joint block 4 is arranged on the bottom surface of the top seat 1, a first outer joint block 5 is rotatably connected with the end surface of the first inner joint block 4, a second inner joint block 6 is arranged on the bottom surface of the first outer joint block 5, a second outer joint block 7 is rotatably connected with the end surface of the second inner joint block 6, pin shafts 8 are rotatably connected with the end surfaces of the first inner joint block 4 and the second inner joint block 6, side grooves 9 are respectively formed on the inner side surfaces of the first outer joint block 5 and the second outer joint block 7, a first fixed block 10 is arranged on one side of the inner wall of the side grooves 9, and a second fixed block 16 is arranged on the other side of the inner wall of the side grooves 9.

The outer fixed cylinder 11 is installed to the terminal surface of first fixed block 10, the urceolus spout 12 has been seted up to the inside of outer fixed cylinder 11, the inside sliding connection of urceolus spout 12 has spacing slide 13, and interior slide bar 14 is installed to the terminal surface of spacing slide 13, the surface of interior slide bar 14 and the inside that is located urceolus spout 12 have cup jointed spring 15, through with footstock 1 wall top surface fixed connection, can fix the pipeline through pipe support 3, and when the pipeline receives vibrations and the front and back direction takes place to rock, the articulated piece that constitutes through front end first inner joint 4, first outer joint 5 and round pin axle 8, and the articulated piece that rear end second inner joint 6, second outer joint 7 and round pin axle 8 constitute, can make the pipeline swing in the front and back direction, and can drive the expansion spring rod that outer fixed cylinder 11, interior slide bar 14 and spring 15 constitute when the pipeline swings in the front and back direction, same reason is passed through to the pipeline through expansion spring rod, when receiving vibrations and the left and right direction takes place to rock, can make the pipeline through left end first inner joint 4, first outer joint 5 and second outer joint 7 and round pin axle 8 and the articulated piece that can make the pipeline swing through the other end 6 and the articulated piece that the right direction can make the pipeline to swing through the articulated piece, thereby the pipeline can make the side and the vibration damper device to swing towards the right.

Further, two ends of the spring 15 are fixedly connected with the limiting slide plate 13 and the inner wall of the outer barrel chute 12, and when the inner slide rod 14 moves, the spring 15 can be driven to stretch or shrink through the limiting slide plate 13.

Further, the outer fixed cylinder 11, the inner slide rod 14 and the spring 15 are all in arc shapes, the outer fixed cylinder 11, the inner slide rod 14 and the spring 15 form a telescopic spring rod, the outer fixed cylinder 11 and the inner slide rod 14 on two sides are symmetrically arranged in one hundred eighty degrees, when the telescopic spring rod on one side is stretched, the telescopic spring rod on the other side can be contracted, and therefore buffering and damping capacity of a pipeline can be improved.

Further, the side groove 9 is a step groove, the pin shaft 8 is rotationally connected with the groove on the side with smaller diameter, the first fixed block 10 is fixedly connected with the groove on the side with larger diameter, the second fixed block 16 is fixedly connected with the pin shaft 8, the second fixed block 16 is slidably connected with the inner wall of the groove on the side with larger diameter, namely, the pin shaft 8 is fixedly connected with the first inner joint block 4 and the second inner joint block 6, when the first outer joint block 5 rotates, the telescopic spring rod formed by the outer fixed cylinder 11, the inner slide rod 14 and the spring 15 can be driven to stretch or shrink by the first fixed block 10 and the second fixed block 16, and similarly, the telescopic spring rod can be driven to stretch or shrink by the second outer joint block 7 when rotating, so that the first outer joint block 5 and the second outer joint block 7 can buffer a pipeline when rotating.

Further, the first inner joint block 4 and the first outer joint block 5 form a hinge block through the pin shaft 8, the second inner joint block 6 and the second outer joint block 7 form a hinge block through the pin shaft 8, and the rotation directions of the hinge blocks at the upper end and the lower end are mutually perpendicular, namely, the hinge blocks formed by the first inner joint block 4, the first outer joint block 5 and the pin shaft 8 at the front side and the rear side or the left side and the right side, and the hinge blocks formed by the second inner joint block 6, the second outer joint block 7 and the pin shaft 8 can enable a pipeline to swing in a multidirectional manner and can also be subjected to multidirectional buffering and damping.

Further, one end of the outer side of the outer support 2 is fixedly connected with the second outer joint block 7, so that the outer support 2 can drive the second outer joint block 7 to swing, and the pipeline can rotate in multiple directions, and is buffered and damped.

When the pipeline is vibrated and swayed in the front-back direction, the pipeline can be swayed or contracted through the telescopic spring rod formed by the outer fixed cylinder 11, the inner slide rod 14 and the spring 15, and the pipeline can be buffered and damped through the telescopic spring rod, and in the same way, when the pipeline is vibrated and swayed in the left-right direction, the pipeline can be swayed in the left-right direction through the hinging block formed by the first inner hinging block 4 at the front end, the first outer hinging block 5 and the pin shaft 8 and the hinging block formed by the second inner hinging block 6 at the right end, the second outer hinging block 7 and the pin shaft 8, and the pipeline can be swayed in the front-back direction through the telescopic spring rod.

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

Claims

1. The utility model provides a steel construction of high shock resistance, includes footstock (1) and outer support (2), its characterized in that: the pipe rack (3) is installed on the inner side of the outer support (2), a first inner joint block (4) is installed on the bottom surface of the top seat (1), a first outer joint block (5) is rotationally connected to the end surface of the first inner joint block (4), a second inner joint block (6) is installed on the bottom surface of the first outer joint block (5), a second outer joint block (7) is rotationally connected to the end surface of the second inner joint block (6), pin shafts (8) are rotationally connected to the end surfaces of the first inner joint block (4) and the second inner joint block (6), side grooves (9) are formed in the inner side surfaces of the first outer joint block (5) and the second outer joint block (7), a first fixed block (10) is installed on one side of the inner wall of each side groove (9), and a second fixed block (16) is installed on the other side of the inner wall of each side groove (9);

the outer fixed cylinder (11) is installed to the terminal surface of first fixed block (10), urceolus spout (12) have been seted up to the inside of outer fixed cylinder (11), the inside sliding connection of urceolus spout (12) has spacing slide (13), interior slide bar (14) are installed to the terminal surface of spacing slide (13), the surface of interior slide bar (14) and be located the inside of urceolus spout (12) cup joint spring (15).

2. A steel structure with high shock resistance according to claim 1, characterized in that: two ends of the spring (15) are fixedly connected with the limiting slide plate (13) and the inner wall of the outer barrel chute (12).

3. A steel structure with high shock resistance according to claim 1, characterized in that: the outer fixed cylinder (11), the inner sliding rod (14) and the spring (15) are all in arc shapes, the outer fixed cylinder (11), the inner sliding rod (14) and the spring (15) form a telescopic spring rod, and the outer fixed cylinder (11) and the inner sliding rod (14) are symmetrically arranged at one hundred eighty degrees on two sides.

4. A steel structure with high shock resistance according to claim 1, characterized in that: the side groove (9) is a step-shaped groove, the pin shaft (8) is rotationally connected with the groove on the side with smaller diameter, the first fixed block (10) is fixedly connected with the groove on the side with larger diameter, the second fixed block (16) is fixedly connected with the pin shaft (8), and the second fixed block (16) is slidingly connected with the inner wall of the groove on the side with larger diameter.

5. A steel structure with high shock resistance according to claim 1, characterized in that: the first inner joint block (4) and the first outer joint block (5) form a hinge block through a pin shaft (8), the second inner joint block (6) and the second outer joint block (7) form a hinge block through a pin shaft (8), and the rotation directions of the hinge blocks at the upper end and the lower end are mutually perpendicular.

6. A steel structure with high shock resistance according to claim 1, characterized in that: one end of the outer side of the outer bracket (2) is fixedly connected with a second outer joint block (7).