CN217388120U - Building electromechanical pipeline erects supporting structure - Google Patents

Abstract

The utility model discloses a building electromechanical pipeline erects supporting structure relates to building electromechanical field, including supporting the pipe wall and connecting the bottom plate, connecting the bottom plate and being located two support between the pipe wall, connecting the side-mounting of bottom plate and installing antidetonation support, antidetonation support includes the fixing base, the shifting chute has been seted up to the upside of fixing base, the top of fixing base is provided with the supporting seat, the downside of supporting seat is provided with the movable block, be connected with the bumper shock absorber between the left and right sides wall of movable block of shifting chute, the upside four corners of supporting seat all is fixed with the screw rod, buffer spring has been cup jointed on the screw rod. The utility model discloses a buffer spring can cushion and consume electromechanical pipeline vibrations power in vertical side, can cushion through the bumper shock absorber and consume electromechanical pipeline vibrations power on the horizontal direction to can cushion electromechanical pipeline's vibrations effectively, make electromechanical pipeline installation stable.

Description

Building electromechanical pipeline erects supporting structure

Technical Field

The utility model relates to a building electromechanical field, concretely relates to building electromechanical pipeline erects supporting structure.

Background

Along with the continuous improvement of the requirements of people on the quality of life, the requirements on the quality of buildings are higher and higher. The electromechanical installation of large buildings is related to the quality of the whole construction project. Therefore, for the construction of large-scale buildings, the comprehensive layout of electromechanical installation pipelines must be made to ensure the engineering quality and reduce the engineering construction cost. The large building electromechanical installation comprises the professions of water supply and drainage, fire fighting, electrical, heating and ventilation, intelligent systems and the like, each profession is divided into different sub-items, and various electromechanical pipelines and equipment are dispersedly and crossly operated inside and outside the building according to different time periods and different construction surfaces. In the installation and distribution process of the electromechanical pipelines, the pipelines need to be hoisted and fixed by using the support, so that the pipelines are stably installed.

At present, most of the existing electromechanical pipeline supports of buildings are simple in structure, only play a role in supporting and fixing electromechanical pipelines, cannot effectively buffer vibration or impact on the electromechanical pipelines, and reduce the using effect of the supports.

Therefore, it is necessary to provide a support structure for mounting electromechanical pipelines to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a building electromechanical pipeline erects supporting structure to the building electromechanical pipeline supporting structure who proposes in solving above-mentioned background art is simple, only plays and supports the fixed action to electromechanical pipeline, can not cushion vibrations or the impact that electromechanical pipeline received effectively, has reduced the result of use's of support problem.

In order to achieve the above object, the present invention provides the following technical solutions: the support structure for erecting the electromechanical pipeline of the building comprises two support pipe walls and a connecting bottom plate, wherein the number of the support pipe walls is two, mounting grooves are formed in the two support pipe walls, first mounting holes are formed in the front side wall and the rear side wall of each mounting groove at equal intervals from top to bottom, the connecting bottom plate is positioned between the two support pipe walls, mounting blocks are fixed at the two ends of the connecting bottom plate respectively and are nested in the mounting grooves, first fixing holes are formed in the mounting blocks, threaded rods are nested in the middle of the first fixing holes in a sliding mode, the front end and the rear end of each threaded rod penetrate through the front mounting hole and the rear mounting hole respectively, locking nuts are sleeved at the front end and the rear end of each threaded rod, an anti-seismic support is installed on the upper side face of the connecting bottom plate and comprises a fixed seat, and a moving groove is formed in the upper side of the fixed seat, the improved structure of the automobile seat is characterized in that a supporting seat is arranged above the fixed seat, a moving block is arranged on the lower side of the supporting seat, the moving block is nested in the moving groove in a sliding mode, a shock absorber is connected between the left side wall of the moving groove and the left side wall of the moving block, an installation seat is arranged above the supporting seat, pipe clamps are arranged on the upper side of the installation seat, positioning holes are formed in the four corners of the installation seat, screw rods are fixed to the four corners of the upper side of the supporting seat, the positioning holes are penetrated through the upper ends of the screw rods, limiting nuts are sleeved on the top threads of the screw rods, buffer springs are sleeved on the screw rods, and the buffer springs are located between the installation seat and the supporting seat.

Preferably, the top of supporting the pipe wall is provided with the base, the connecting hole has been seted up on the base, is convenient for fix the supporting pipe wall at the wall top through the base, adopt stainless steel matter integration machine-shaping between supporting pipe wall and the base, joint strength is big, and long service life, and is not fragile.

Preferably, the connecting bottom plate and the mounting block are integrally formed by stainless steel, so that the connecting strength is high, the service life is long, and the connecting bottom plate is not easy to damage.

Preferably, the second mounting holes are formed in the connecting bottom plate at equal intervals, the fixing plates are fixed to the bottoms of the left side and the right side of the fixing seat, the fixing seat and the fixing plates are integrally formed, the second fixing holes are formed in the fixing plates and correspond to the second mounting holes, the fixing plates are connected with the connecting bottom plate through bolts, the fixing seat and the connecting bottom plate are simple to install, the anti-seismic support and the connecting bottom plate are simple to install, and the transverse position of the anti-seismic support is convenient to adjust through the plurality of second mounting holes.

Preferably, both sides all have seted up the spacing groove around the shifting chute, both sides all are fixed with the stopper around the movable block, the stopper slides and nests in the spacing inslot for the movable block is installed stably in the shifting chute, and the displacement is stable, can not break away from the shifting chute.

Preferably, the screw rod and the supporting seat are integrally machined and formed, so that the screw rod and the supporting seat are stably and firmly connected, the limiting nut is located in the positioning hole, and the gasket is arranged between the limiting nut and the contact surface of the mounting seat, so that the limiting nut is stably mounted, and the mounting seat can be effectively extruded.

Preferably, the number of the shock absorbers is four, the four shock absorbers are divided into two groups which are distributed on the left side and the right side of the moving block, one end of each shock absorber is connected with the moving block, the other end of each shock absorber is connected with the inner wall of the moving groove, the moving block which moves can be reset through the shock absorbers, and meanwhile, the shock transmitted by the moving block is consumed.

Preferably, the two ends of the pipe clamp are connected with the mounting seat through bolts, the connection is simple, and the pipeline can be fixed on the mounting seat through the pipe clamp.

In the technical scheme, the utility model provides a technological effect and advantage:

1. the vibration force of the electromechanical pipeline in the vertical direction can be buffered and consumed through the buffer spring between the supporting seat and the mounting seat, and the vibration force of the electromechanical pipeline in the horizontal direction can be buffered and consumed through the shock absorber between the fixed seat and the moving block, so that the vibration of the electromechanical pipeline can be effectively buffered, the influence of external vibration on the electromechanical pipeline can be buffered and eliminated, and the electromechanical pipeline is stably mounted;

2. the mounting structure comprises a mounting groove, first mounting holes are formed in the front side wall and the rear side wall of the mounting groove at equal intervals from top to bottom, first fixing holes in mounting blocks on a connecting base plate are aligned with first mounting holes of different heights, the mounting height of the connecting base plate can be adjusted, second fixing holes in an anti-seismic support are aligned with second mounting holes in different positions on the connecting base plate, the transverse position of the anti-seismic support can be adjusted, the vertical height and the transverse position of the anti-seismic support are adjusted, local adjustment can be conducted on the deviation of pre-paying-off of electromechanical pipeline mounting, the mounting quality of electromechanical pipelines is guaranteed, and reworking is avoided due to local position deviation.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a front view of the present invention;

FIG. 3 is a schematic view of the connecting bottom plate of the present invention;

FIG. 4 is a schematic view of the anti-seismic support of the present invention;

FIG. 5 is a cross-sectional view of the anti-seismic support of the present invention;

FIG. 6 is a schematic view of the fixing base of the present invention;

FIG. 7 is a schematic view of the support base of the present invention;

fig. 8 is a schematic view of the mounting base of the present invention;

fig. 9 is a connection diagram of the threaded rod and the lock nut of the present invention.

Description of reference numerals:

the anti-vibration pipe comprises a supporting pipe wall 1, a connecting bottom plate 2, a mounting groove 3, a first mounting hole 4, a mounting block 5, a first fixing hole 6, a threaded rod 7, a locking nut 8, a second mounting hole 9, an anti-vibration support 10, a fixing seat 11, a fixing plate 12, a second fixing hole 13, a moving groove 14, a limiting groove 15, a supporting seat 16, a moving block 17, a shock absorber 18, a limiting block 19, a screw rod 20, a mounting seat 21, a pipe clamp 22, a positioning hole 23, a limiting nut 24, a buffer spring 25 and a connecting seat 26.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

The utility model provides a support structure for erecting electromechanical pipelines of a building as shown in figures 1 and 4-8, which comprises two support pipe walls 1 and two connecting bottom plates 2, wherein the number of the support pipe walls 1 is two, the connecting bottom plate 2 is positioned between the two support pipe walls 1, an anti-seismic support 10 is arranged on the upper side surface of the connecting bottom plate 2, the anti-seismic support 10 comprises a fixed seat 11, a moving groove 14 is arranged on the upper side of the fixed seat 11, a supporting seat 16 is arranged above the fixed seat 11, a moving block 17 is arranged on the lower side of the supporting seat 16, the moving block 17 is slidably embedded in the moving groove 14, shock absorbers 18 are connected between the left and right side walls of the moving groove 14 and the left and right side walls of the moving block 17, an installation seat 21 is arranged above the supporting seat 16, a pipe clamp 22 is arranged on the upper side of the installation seat 21, positioning holes 23 are arranged at four corners of the installation seat 21, the screw rods 20 are fixed at four corners of the upper side of the supporting seat 16, the upper ends of the screw rods 20 penetrate through the positioning holes 23, the top ends of the screw rods 20 are in threaded sleeve connection with limit nuts 24, the screw rods 20 are in sleeve connection with buffer springs 25, and the buffer springs 25 are located between the mounting seat 21 and the supporting seat 16.

The top of supporting pipe wall 1 is provided with base 26, the connecting hole has been seted up on base 26, is convenient for fix supporting pipe wall 1 at the wall top through base 26, adopt stainless steel matter integration machine-shaping between supporting pipe wall 1 and the base 26, joint strength is big, and long service life, and is not fragile.

Limiting grooves 15 are formed in the front side and the rear side of the moving groove 14, limiting blocks 19 are fixed to the front side and the rear side of the moving block 17, and the limiting blocks 19 are embedded in the limiting grooves 15 in a sliding mode, so that the moving block 17 is stably installed in the moving groove 14, is stable in displacement and cannot be separated from the moving groove 14.

The screw rod 20 and the supporting seat 16 are integrally formed, so that the screw rod 20 and the supporting seat 16 are stably and firmly connected, the limit nut 24 is located in the positioning hole 23, and a gasket is arranged between the contact surface of the limit nut 24 and the mounting seat 21, so that the limit nut 24 is stably mounted, and the mounting seat 21 can be effectively extruded.

The number of the dampers 18 is four, the four dampers 18 are divided into two groups and distributed on the left side and the right side of the moving block 17, one end of each damper 18 is connected with the moving block 17, the other end of each damper 18 is connected with the inner wall of the moving groove 14, the moving block 17 can be reset through the dampers 18, and meanwhile, vibration transmitted by the moving block 17 is consumed.

The two ends of the pipe clamp 22 are connected with the mounting seat 21 through bolts, so that the pipe clamp 22 is simple in connection and can fix a pipeline on the mounting seat 21.

The implementation mode is specifically as follows: the base 26 at the top of the two supporting pipe walls 1 is connected with the wall to realize the fixation of the support on the wall, the electromechanical pipeline is placed on the mounting seat 21 on the anti-seismic support 10, the pipe clamp 22 is sleeved on the electromechanical pipeline, the two ends of the pipe clamp 22 are connected with the mounting seat 21 through bolts to realize the fixation of the electromechanical pipeline, when the electromechanical pipeline vibrates, the mounting seat 21 is driven to vibrate, the mounting seat 21 vibrates to extrude the buffer spring 25 in the vertical direction, the buffer spring 25 can buffer and consume the vibration force of the electromechanical pipeline in the vertical direction, simultaneously the mounting seat 21 vibrates to cause the moving block 17 at the bottom of the supporting seat 16 to move in the moving groove 14 on the fixing seat 11, the moving block 17 moves to extrude the shock absorber 18, the shock absorber 18 can buffer and consume the vibration force of the electromechanical pipeline in the horizontal direction, thereby effectively buffering the vibration of the electromechanical pipeline and buffering and eliminating the influence of the external vibration on the electromechanical pipeline, make electromechanical pipeline installation stable, this embodiment has specifically solved most building electromechanical pipeline support simple structure who exists among the prior art, only plays to support the fixed action electromechanical pipeline, can not cushion the vibrations or the impact that electromechanical pipeline received effectively, has reduced the result of use problem of support.

As shown in fig. 1-3, 6 and 9, two of the support tube walls 1 are respectively provided with a mounting groove 3, the front and rear side walls of the mounting groove 3 are respectively provided with first mounting holes 4 at equal intervals from top to bottom, the two ends of the connecting bottom plate 2 are respectively fixed with a mounting block 5, the connecting bottom plate 2 and the mounting blocks 5 are integrally formed by stainless steel, the connecting strength is high, the service life is long, and the connecting bottom plate is not easy to damage, the mounting blocks 5 are nested in the mounting groove 3, the mounting blocks 5 are provided with first fixing holes 6, the middle parts of the first fixing holes 6 are slidably nested with threaded rods 7, the front and rear ends of the threaded rods 7 respectively penetrate through the front and rear first mounting holes 4, the front and rear ends of the threaded rods 7 are respectively sleeved with locking nuts 8, so as to align the first fixing holes 6 on the mounting blocks 5 on the connecting bottom plate 2 with the first mounting holes 4 with different heights, the mounting height of the connection base plate 2 can be adjusted.

Second mounting hole 9 has been seted up to connecting plate 2 equidistant, fixed plate 12 all is fixed with to the left and right sides bottom of fixing base 11, integration machine-shaping between fixing base 11 and the fixed plate 12, second fixed orifices 13 has been seted up on fixed plate 12, second fixed orifices 13 is corresponding with second mounting hole 9, pass through bolted connection between fixed plate 12 and the connecting plate 2 for fixing base 11 and connecting plate 2 between the installation is simple, thereby makes the installation simple between antidetonation support 10 and the connecting plate 2, and through a plurality of second mounting holes 9, is convenient for adjust the lateral position of antidetonation support 10.

The implementation mode specifically comprises the following steps: when the installation height of the electromechanical pipeline needs to be adjusted, the locking nuts 8 on the threaded rod 7 are taken down, the threaded rod 7 is extracted, then the installation blocks 5 at the two ends of the connection bottom plate 2 are moved, so that the first fixing holes 6 on the installation blocks 5 are aligned with the first installation holes 4 with different heights in the installation groove 3, the first fixing holes 6 are aligned with the first installation holes 4 with determined installation heights, then the threaded rod 7 is inserted, the locking nuts 8 are sleeved on the threads at the two ends of the threaded rod 7, the connection bottom plate 2 is fixed, the adjustment of the installation height of the connection bottom plate 2 is realized, the adjustment of the installation height of the electromechanical pipeline is realized, when the transverse position of the anti-seismic support 10 needs to be adjusted, the bolts at the joint of the upper fixing plate 12 of the anti-seismic support 10 and the connection bottom plate 2 are firstly disassembled, then the anti-seismic support 10 is moved, so that the second fixing holes 13 on the anti-seismic support 10 are aligned with the second installation holes 9 at different positions on the connection bottom plate 2, can adjust the lateral position of antidetonation support 10 to the realization is adjusted the vertical height and the lateral position of antidetonation support 10, and then can carry out local regulation to the deviation of electromechanical pipeline installation unwrapping wire in earlier stage, has guaranteed the installation quality of electromechanical pipeline, avoids local position deviation and takes place to do over again.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (8)

1. Building machine electrical pipeline erects supporting structure, including supporting pipe wall (1) and connecting bottom plate (2), its characterized in that: the number of the supporting pipe walls (1) is two, two mounting grooves (3) are formed in the supporting pipe walls (1), first mounting holes (4) are formed in the front side wall and the rear side wall of each mounting groove (3) at equal intervals from top to bottom, the connecting bottom plate (2) is located between the two supporting pipe walls (1), mounting blocks (5) are fixed to the two ends of the connecting bottom plate (2), the mounting blocks (5) are embedded in the mounting grooves (3), first fixing holes (6) are formed in the mounting blocks (5), threaded rods (7) are slidably embedded in the middle of the first fixing holes (6), the front end and the rear end of each threaded rod (7) penetrate through the front mounting hole (4) and the rear mounting hole (4) respectively, locking nuts (8) are sleeved at the front end and the rear end of each threaded rod (7), and anti-seismic supports (10) are installed on the upper side faces of the connecting bottom plate (2), the anti-seismic support (10) comprises a fixed seat (11), a moving groove (14) is formed in the upper side of the fixed seat (11), a supporting seat (16) is arranged above the fixed seat (11), a moving block (17) is arranged on the lower side of the supporting seat (16), the moving block (17) is nested in the moving groove (14) in a sliding mode, shock absorbers (18) are connected between the left side wall and the right side wall of the moving groove (14) and the left side wall and the right side wall of the moving block (17), an installation seat (21) is arranged above the supporting seat (16), pipe clamps (22) are arranged on the upper side of the installation seat (21), positioning holes (23) are formed in four corners of the installation seat (21), screw rods (20) are fixed to four corners of the upper side of the supporting seat (16), the upper ends of the screw rods (20) penetrate through the positioning holes (23), and limit nuts (24) are sleeved on the top threads of the screw rods (20), the screw rod (20) is sleeved with a buffer spring (25), and the buffer spring (25) is located between the mounting seat (21) and the supporting seat (16).

2. The building electromechanical pipeline erection support structure of claim 1, wherein: the top of the supporting pipe wall (1) is provided with a base (26), the base (26) is provided with a connecting hole, and the supporting pipe wall (1) and the base (26) are integrally machined and formed by stainless steel.

3. The building electromechanical pipeline erection support structure of claim 1, wherein: the connecting bottom plate (2) and the mounting block (5) are integrally machined and formed by stainless steel materials.

4. The building electromechanical pipeline erection support structure of claim 1, wherein: second mounting hole (9) have been seted up to connecting plate (2) equidistant, fixed plate (12) have all been fixed to the left and right sides bottom of fixing base (11), integrated machine-shaping between fixing base (11) and fixed plate (12), second fixed orifices (13) have been seted up on fixed plate (12), second fixed orifices (13) are corresponding with second mounting hole (9), pass through bolted connection between fixed plate (12) and connecting plate (2).

5. The building electromechanical pipeline erection support structure of claim 1, wherein: limiting grooves (15) are formed in the front side and the rear side of the moving groove (14), limiting blocks (19) are fixed to the front side and the rear side of the moving block (17), and the limiting blocks (19) are slidably nested in the limiting grooves (15).

6. The building electromechanical pipeline erection support structure of claim 1, wherein: the screw rod (20) and the supporting seat (16) are integrally machined and formed, the limiting nut (24) is located in the positioning hole (23), and a gasket is arranged between the limiting nut (24) and the contact surface of the mounting seat (21).

7. The building electromechanical pipeline erection support structure of claim 1, wherein: the number of the shock absorbers (18) is four, the four shock absorbers (18) are divided into two groups which are distributed on the left side and the right side of the moving block (17), one end of each shock absorber (18) is connected with the moving block (17), and the other end of each shock absorber (18) is connected with the inner wall of the moving groove (14).

8. The building electromechanical pipeline erection support structure of claim 1, wherein: the two ends of the pipe clamp (22) are connected with the mounting seat (21) through bolts.

Images