CN214889392U - Anti-seismic support based on BIM - Google Patents

Abstract

The utility model discloses an antidetonation support based on BIM, including antidetonation case, U type frame and supporting box, the antidetonation spring is installed to the inside one end of antidetonation case, and antidetonation spring one end sliding connection has the antidetonation pole that extends to the antidetonation incasement portion, the articulated U type frame of one end of antidetonation case is kept away from to the antidetonation pole, and the both sides of the inside bottom of U type frame are provided with supporting box, adjust the inside bottom of U type frame that the structure set up in supporting box bottom, mounting structure sets up the inside bottom at supporting box, supporting box's top is provided with down the clamp, and the top of clamp is provided with down the clamp down, buffer structure sets up the both sides of clamp and lower clamp. The utility model discloses a set up antidetonation spring, rubber pad and friction plate, can finely offset the sense of vibration that outside and pipeline medium flow produced to can avoid vibrations to lead to the not hard up of bolt between the support, improve the safety in utilization.

Description

Anti-seismic support based on BIM

Technical Field

The utility model relates to a building engineering technical field specifically is an antidetonation support based on BIM.

Background

The Building Information Model (BIM) is a member that uses digitized building components to represent a real building, and is widely applied in the current building engineering in China, and in the building construction process, a support is usually required to support and limit a pipeline and the like, and in order to improve the use safety, the anti-seismic performance of the supports is usually required to be increased, but the existing anti-seismic support based on the BIM has many problems or defects:

first, the conventional seismic support based on BIM is poor in seismic resistance when in use, and can only resist external seismic sense generally, but the seismic sense generated by medium flowing in the pipeline cannot be well offset.

Second, traditional antidetonation support based on BIM does not have the regulation structure during the use, and the clamp highly fixed can not support the pipeline of difference.

Third, traditional antidetonation support based on BIM does not have mounting structure during the use, and when the clamp damaged or when being directed against different specification pipelines, the installation of clamp was changed very loaded down with trivial details.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an antidetonation support based on BIM to solve the relatively poor, inconvenient problem of adjusting and inconvenient installation of shock resistance that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: an anti-seismic support based on BIM comprises an anti-seismic box, a U-shaped frame and a support box, and further comprises an installation structure convenient to replace and install, an adjusting structure convenient to adapt to pipelines in different scenes and a buffer structure for improving the anti-seismic property of the support;

an anti-seismic spring is mounted at one end inside the anti-seismic box, an anti-seismic rod extending to the outside of the anti-seismic box is connected to one end of the anti-seismic spring in a sliding mode, one end, far away from the anti-seismic box, of the anti-seismic rod is hinged to a U-shaped frame, supporting boxes are arranged on two sides of the bottom end inside the U-shaped frame, and the adjusting structure is arranged at the bottom end inside the U-shaped frame at the bottom end of each supporting box;

the mounting structure is arranged at the bottom end inside the supporting box;

the top of supporting box is provided with down the clamp, and the top of clamp is provided with the clamp down, buffer structure sets up the both sides of clamp and lower clamp.

Preferably, buffer structure includes fixed threaded rod, fixed threaded rod rotates and connects the both sides at last clamp and lower clamp, and fixed threaded rod one end extends to supreme clamp and the inside arc case that installs through the bearing of clamp down, buffer spring is installed to one side equidistant of arc incasement portion, and buffer spring one end sliding connection has the arc frame that extends to arc case outside, the friction plate is installed to the one end of arc frame.

Preferably, the rubber pad is installed to the intermediate position department of going up the inside one end of clamp and lower clamp, and the shape of rubber pad is the arc.

Preferably, mounting structure includes mounting groove, installation piece, positive and negative lead screw, pole piece, kelly and draw-in groove, positive and negative lead screw rotates to be connected in the inside bottom of supporting box, and the both sides threaded connection on positive and negative lead screw surface has the pole piece, the kelly is installed on the top of pole piece, the mounting groove has been seted up to the both sides of supporting box inside top intermediate position department, and down clamp bottom both sides install with mounting groove matched with installation piece, the draw-in groove with kelly matched with has been seted up to installation piece inside one side upper end.

Preferably, the sliding grooves are transversely formed in the two sides of the top end of the supporting box, the sliding blocks are connected to the sliding grooves in a sliding mode, and the bottom ends of the sliding blocks are welded to one side of the top end of the clamping rod.

Preferably, adjust the structure and include fixed slot, rocking handle, type of falling L pole, regulating block, adjusting screw rod and adjustment tank, the both sides in the inside bottom of U type frame are seted up to the fixed slot, and the vertical rotation of the inside intermediate position department of fixed slot is connected with adjusting screw rod, adjusting screw rod bottom extends to the U type frame outside and installs the rocking handle, and the inside threaded connection of fixed slot on adjusting screw rod surface has the regulating block, the type of falling L pole that extends to U type frame outside is installed to the regulating block both sides, and the both sides welding of type of falling L pole top and supporting box bottom, the adjustment tank has been seted up to the inside bottom of U type frame of fixed slot both sides.

Preferably, the diameter of the cross section of the adjusting groove is equal to the diameter of the cross section of one side of the inverted L-shaped rod, and the adjusting grooves are symmetrically distributed about the vertical central axis of the fixing groove.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) by arranging the anti-seismic spring, the rubber pad and the friction plate, the arc-shaped box is moved towards the pipeline direction by rotating the fixed threaded rod, so that the friction plate is tightly attached to the outer wall of the pipeline, the arc-shaped frame is made to slide to compress the buffer spring, the friction plate is made to be tightly attached to the outer wall of the pipeline by utilizing the elasticity of the buffer spring, the clamping stability of the pipeline is improved, meanwhile, the arc-shaped frame can move to compress the buffer spring due to the vibration sense generated by the flowing of the medium in the pipeline, so that the vibration sense generated by the flowing of the medium in the pipeline is counteracted by utilizing the elasticity of the buffer spring, the arc-shaped rubber pad can further absorb the vibration of the pipeline, and meanwhile, when the vibration sense of the outside is transmitted to the bracket, the anti-seismic rod can slide to compress the anti-seismic spring in the anti-seismic box, so that the looseness of bolts between the brackets due to the outside and the self vibration can be avoided, the use safety is improved;

(2) through the arrangement of the adjusting structure, the rocking handle is rotated to drive the adjusting threaded rod to rotate, the adjusting threaded rod is matched with the adjusting block, so that the adjusting block rises to drive the inverted L-shaped rod to rise, the supporting box rises along with the adjusting threaded rod until the lower clamp completely clamps the lower surface of the pipeline, and the support can be suitable for pipelines in different scenes through the liftable lower clamp, the complexity of replacing U-shaped frames with different heights is avoided, and the practicability of the support is improved;

(3) through being provided with mounting structure and supporting box, through rotating positive and negative lead screw, utilize the cooperation of positive and negative lead screw and pole piece for the pole piece removes and drives the card pole steadily to break away from the draw-in groove completely, and later can stimulate down the clamp and make the mounting groove break away from with the installation piece, and then realize dismantling the clamp down fast, reduce staff's the installation and dismantle the degree of difficulty, improve the efficiency of clamp under the change, be convenient for this support to the antidetonation protection operation of different specification pipelines.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

fig. 2 is a schematic side view of the cross-sectional structure of the present invention;

FIG. 3 is a schematic view of a partial front view of the lower clamp of the present invention;

fig. 4 is a front view of the installation structure of the present invention.

In the figure: 1. an anti-seismic box; 2. an anti-seismic spring; 3. a U-shaped frame; 4. an upper hoop; 5. a rubber pad; 6. a lower hoop; 7. a mounting structure; 701. mounting grooves; 702. mounting blocks; 703. a positive and negative screw rod; 704. a rod block; 705. a clamping rod; 706. a card slot; 8. a support box; 9. an adjustment structure; 901. fixing grooves; 902. a rocking handle; 903. an inverted L-shaped bar; 904. an adjusting block; 905. adjusting the threaded rod; 906. an adjustment groove; 10. an anti-seismic rod; 11. an arc-shaped box; 12. a buffer spring; 13. fixing a threaded rod; 14. an arc-shaped frame; 15. a friction plate; 16. a chute; 17. a slide block.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1: referring to fig. 1-4, an anti-seismic support based on BIM includes an anti-seismic box 1, a U-shaped frame 3 and a support box 8, and further includes an installation structure 7 convenient for replacement and installation, an adjustment structure 9 convenient for adapting to pipelines in different scenes, and a buffer structure for improving the anti-seismic property of the support;

an anti-seismic spring 2 is mounted at one end inside the anti-seismic box 1, an anti-seismic rod 10 extending to the outside of the anti-seismic box 1 is connected to one end of the anti-seismic spring 2 in a sliding mode, one end, far away from the anti-seismic box 1, of the anti-seismic rod 10 is hinged to the U-shaped frame 3, supporting boxes 8 are arranged on two sides of the bottom end inside the U-shaped frame 3, and an adjusting structure 9 is arranged at the bottom end inside the U-shaped frame 3 at the bottom end of each supporting box 8;

the mounting structure 7 is arranged at the bottom end inside the supporting box 8;

the top end of the support box 8 is provided with a lower clamp 6, the top end of the lower clamp 6 is provided with an upper clamp 4, and the buffer structure is arranged on two sides of the upper clamp 4 and the lower clamp 6;

referring to fig. 1-4, an anti-seismic support based on BIM further includes a buffering structure, the buffering structure includes a fixed threaded rod 13, the fixed threaded rod 13 is rotatably connected to two sides of the upper clamp 4 and the lower clamp 6, one end of the fixed threaded rod 13 extends into the upper clamp 4 and the lower clamp 6 and is provided with an arc box 11 through a bearing, one side of the inside of the arc box 11 is provided with buffering springs 12 at equal intervals, one end of each buffering spring 12 is slidably connected with an arc frame 14 extending to the outside of the arc box 11, and one end of each arc frame 14 is provided with a friction plate 15;

a rubber pad 5 is arranged at the middle position of one end inside the upper clamp 4 and the lower clamp 6, and the rubber pad 5 is arc-shaped;

specifically, as shown in fig. 1, 2 and 3, by rotating the fixed threaded rod 13, the arc-shaped box 11 moves toward the pipeline, so that the friction plate 15 is attached to the outer wall of the pipeline, and the arc-shaped frame 14 slides to compress the buffer spring 12, so that the friction plate 15 is attached to the outer wall of the pipeline by the elastic force of the buffer spring 12, thereby improving the clamping stability of the pipeline, and meanwhile, the shock generated by the medium flowing inside the pipeline can be moved by the arc-shaped frame 14 to compress the buffer spring 12, so that the shock generated by the medium flowing inside the pipeline can be offset by the elastic force of the buffer spring 12, and the arc-shaped rubber pad 5 can further absorb the shock of the pipeline, thereby improving the use safety.

Example 2: the mounting structure 7 comprises a mounting groove 701, a mounting block 702, a positive and negative screw rod 703, a rod block 704, a clamping rod 705 and a clamping groove 706, the positive and negative screw rod 703 is rotatably connected to the bottom end inside the supporting box 8, the rod block 704 is in threaded connection with two sides of the surface of the positive and negative screw rod 703, the clamping rod 705 is mounted at the top end of the rod block 704, the mounting groove 701 is formed in two sides of the middle position of the top end inside the supporting box 8, the mounting block 702 matched with the mounting groove 701 is mounted on two sides of the bottom end of the lower hoop 6, and the clamping groove 706 matched with the clamping rod 705 is formed in the upper end of one side inside the mounting block 702;

sliding grooves 16 are transversely formed in two sides of the top end inside the supporting box 8, sliding blocks 17 are connected inside the sliding grooves 16 in a sliding mode, and the bottom ends of the sliding blocks 17 are welded to one side of the top end of the clamping rod 705;

specifically, as shown in fig. 1, fig. 2 and fig. 4, the positive and negative screw rods 703 are rotated, the cooperation of the positive and negative screw rods 703 and the rod block 704 is utilized, and meanwhile, the sliding of the sliding block 17 in the sliding groove 16 is utilized, so that the rod block 704 moves to drive the clamping rod 705 to move stably to completely separate from the clamping groove 706, and then the lower clamp 6 can be pulled to separate the mounting groove 701 from the mounting block 702, so that the lower clamp 6 can be quickly disassembled, the difficulty in assembling and disassembling of workers is reduced, and the efficiency of replacing the lower clamp 6 is improved.

Example 3: the adjusting structure 9 comprises a fixing groove 901, a rocking handle 902, an inverted L-shaped rod 903, an adjusting block 904, an adjusting threaded rod 905 and an adjusting groove 906, wherein the fixing groove 901 is formed in two sides of the bottom end inside the U-shaped frame 3, the adjusting threaded rod 905 is vertically and rotatably connected to the middle position inside the fixing groove 901, the bottom end of the adjusting threaded rod 905 extends to the outside of the U-shaped frame 3 and is provided with the rocking handle 902, the adjusting block 904 is connected to the inner threads of the fixing groove 901 in the surface of the adjusting threaded rod 905, the inverted L-shaped rods 903 extending to the outside of the U-shaped frame 3 are arranged on two sides of the adjusting block 904, the top ends of the inverted L-shaped rods 903 are welded with two sides of the bottom end of the supporting box 8, and the adjusting grooves 906 are formed in the bottom ends inside the U-shaped frame 3 on two sides of the fixing groove 901;

the diameter of the cross section of the adjusting groove 906 is equal to that of the cross section of one side of the inverted L-shaped rod 903, and the adjusting groove 906 is symmetrically distributed around the vertical central axis of the fixing groove 901;

specifically, as shown in fig. 1 and 2, drive adjusting threaded rod 905 and rotate through rotating rocking handle 902, utilize adjusting threaded rod 905 and regulating block 904's cooperation, make regulating block 904 rise and drive the type of falling L pole 903 and rise, and then make supporting box 8 rise thereupon, block the pipeline lower surface completely until lower clamp 6, thereby lower clamp 6 through the liftable, make this support can be suitable for the pipeline of different scenes, improve this support practicality, and set up adjustment tank 906, guarantee the gliding stability from top to bottom of type of falling L pole 903.

The working principle is as follows: when the device is used, firstly, the anti-seismic box 1 and the U-shaped frame 3 are fixed on a wall top through bolts, then the rocking handle 902 is rotated to drive the adjusting threaded rod 905 to rotate, the adjusting block 904 is lifted to drive the inverted L-shaped rod 903 to lift by utilizing the matching of the adjusting threaded rod 905 and the adjusting block 904, and then the supporting box 8 is lifted along with the adjusting threaded rod 905 until the lower clamp 6 completely clamps the lower surface of a pipeline, so that the device is convenient for being suitable for pipelines with different heights;

then, the upper clamp 4 and the lower clamp 6 are fixed together through bolts, and then the fixed threaded rod 13 is rotated, so that the arc-shaped box 11 moves towards the direction of the pipeline, the friction plate 15 is made to cling to the outer wall of the pipeline, the arc-shaped frame 14 slides in the arc-shaped box 11 to compress the buffer spring 12, the friction plate 15 is made to cling to the outer wall of the pipeline by the aid of elasticity of the buffer spring 12, clamping stability of the pipeline is improved, meanwhile, vibration sense generated by medium flowing in the pipeline enables the arc-shaped frame 14 to move to compress the buffer spring 12, vibration sense generated by medium flowing in the pipeline is offset by the aid of elasticity of the buffer spring 12, vibration of the pipeline can be further absorbed by the arc-shaped rubber pad 5, and when external vibration sense is transmitted to the support, the anti-vibration rod 10 slides in the anti-vibration box 1 to compress the anti-vibration spring 2, and the anti-vibration performance of the support is further improved;

when the lower clamp 6 is damaged or needs the lower clamp 6 with different sizes, the positive and negative screw rods 703 can be rotated, the rod blocks 704 are matched with the positive and negative screw rods 703 and the rod blocks 704, so that the rod blocks 704 move to drive the clamping rods 705 to stably move to be completely separated from the clamping grooves 706, then the lower clamp 6 can be pulled to separate the mounting grooves 701 from the mounting blocks 702, the lower clamp 6 can be quickly dismounted, and the mounting and dismounting difficulty of workers is reduced.

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 antidetonation support based on BIM, includes antidetonation case (1), U type frame (3) and supporting box (8), its characterized in that: the device also comprises an installation structure (7) convenient to replace and install, an adjusting structure (9) convenient to adapt to pipelines in different scenes and a buffer structure for improving the shock resistance of the bracket;

an anti-seismic spring (2) is mounted at one end inside the anti-seismic box (1), an anti-seismic rod (10) extending to the outside of the anti-seismic box (1) is connected to one end of the anti-seismic spring (2) in a sliding mode, one end, far away from the anti-seismic box (1), of the anti-seismic rod (10) is hinged to the U-shaped frame (3), supporting boxes (8) are arranged on two sides of the inner bottom end of the U-shaped frame (3), and the adjusting structure (9) is arranged at the inner bottom end of the U-shaped frame (3) at the bottom end of the supporting boxes (8);

the mounting structure (7) is arranged at the bottom end inside the supporting box (8);

the top of supporting box (8) is provided with down clamp (6), and the top of clamp (6) is provided with down clamp (4), the both sides of clamp (4) and lower clamp (6) are gone up in buffer structure setting.

2. A BIM based seismic support according to claim 1, wherein: buffer structure includes fixed threaded rod (13), fixed threaded rod (13) rotate to be connected in the both sides of last clamp (4) and lower clamp (6), and fixed threaded rod (13) one end extends to supreme clamp (4) and lower clamp (6) inside and install arc case (11) through the bearing, buffer spring (12) are installed to the equidistant one side of arc case (11) inside, and buffer spring (12) one end sliding connection has arc frame (14) that extend to arc case (11) outside, friction plate (15) are installed to the one end of arc frame (14).

3. A BIM based seismic support according to claim 1, wherein: go up clamp (4) and the intermediate position department of the inside one end of lower clamp (6) and install rubber pad (5), and the shape of rubber pad (5) is the arc.

4. A BIM based seismic support according to claim 1, wherein: mounting structure (7) include mounting groove (701), installation piece (702), positive and negative lead screw (703), pole piece (704), kelly (705) and draw-in groove (706), positive and negative lead screw (703) rotate to be connected in the inside bottom of supporting box (8), and the both sides threaded connection on positive and negative lead screw (703) surface has pole piece (704), kelly (705) are installed on the top of pole piece (704), mounting groove (701) have been seted up to the both sides of supporting box (8) inside top intermediate position department, and down clamp (6) bottom both sides install with mounting groove (701) matched with installation piece (702), installation piece (702) inside one side upper end seted up with kelly (705) matched with draw-in groove (706).

5. A BIM-based seismic brace according to claim 4, wherein: sliding grooves (16) are transversely formed in two sides of the top end of the inner portion of the supporting box (8), a sliding block (17) is connected to the inner portion of each sliding groove (16) in a sliding mode, and the bottom end of each sliding block (17) is welded to one side of the top end of the clamping rod (705).

6. A BIM based seismic support according to claim 1, wherein: the adjusting structure (9) comprises a fixing groove (901), a rocking handle (902), an inverted L-shaped rod (903), an adjusting block (904), an adjusting threaded rod (905) and an adjusting groove (906), the fixing groove (901) is formed in two sides of the bottom end of the interior of the U-shaped frame (3), and the middle position inside the fixed groove (901) is vertically and rotatably connected with an adjusting threaded rod (905), the bottom end of the adjusting threaded rod (905) extends to the outside of the U-shaped frame (3) and is provided with a rocking handle (902), and the inner part of the fixed groove (901) on the surface of the adjusting threaded rod (905) is connected with an adjusting block (904) by screw thread, two sides of the adjusting block (904) are provided with an inverted L-shaped rod (903) extending to the outside of the U-shaped frame (3), the top end of the inverted L-shaped rod (903) is welded with the two sides of the bottom end of the supporting box (8), and adjusting grooves (906) are formed in the bottom ends of the inner parts of the U-shaped frames (3) on the two sides of the fixing groove (901).

7. A BIM-based seismic brace according to claim 6, wherein: the diameter of the cross section of the adjusting groove (906) is equal to that of the cross section of one side of the inverted L-shaped rod (903), and the adjusting groove (906) is symmetrically distributed around the vertical central axis of the fixing groove (901).

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