CN215488028U - BIM-based pipeline installation device - Google Patents

Abstract

The utility model provides a BIM-based pipeline installation device, which belongs to the technical field of pipeline installation and comprises a base, a rotating piece, a driving assembly, an adjusting assembly and a clamping assembly; the rotating piece is rotatably arranged on the base and is internally provided with an accommodating cavity, the rotating piece can rotate on the base around the axis of the rotating piece, and the axis of the rotating piece is arranged along the vertical direction; the driving assembly is arranged on the base, is connected with the rotating piece and is used for driving the rotating piece to rotate; the adjusting assembly is inserted into the accommodating cavity, the top end of the adjusting assembly extends out of the accommodating cavity, and the adjusting assembly can slide along the vertical direction; the clamping assembly is connected with the top end of the adjusting assembly and used for clamping a pipeline. The BIM-based pipeline installation device provided by the utility model can realize accurate adjustment of the butt joint angle of the pipeline and improve the butt joint efficiency of the pipeline.

Description

BIM-based pipeline installation device

Technical Field

The utility model belongs to the technical field of pipeline installation, and particularly relates to a BIM-based pipeline installation device.

Background

The BIM is used for integrating engineering information, processes and resources of engineering projects in different stages in a whole life cycle into one model by establishing a virtual three-dimensional model of the architectural engineering, is conveniently used by all participants of the engineering and reduces the engineering production cost.

When the pipeline is installed, the pipeline is usually adjusted by manual carrying and is butted, and then the pipeline is connected and installed through a connecting piece, so that time and labor are wasted. And when the pipeline needs to be laid obliquely, the angle between the two pipelines is not easy to adjust, and the installation efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a BIM-based pipeline installation device, aiming at realizing accurate adjustment of a pipeline butt joint angle and improving the pipeline butt joint efficiency.

In order to achieve the purpose, the utility model adopts the technical scheme that: there is provided a BIM-based pipe installation apparatus, including:

a base;

the rotating piece is rotatably arranged on the base and is internally provided with an accommodating cavity, the rotating piece can rotate on the base around the axis of the rotating piece, and the axis of the rotating piece is arranged along the vertical direction;

the driving assembly is arranged on the base, is connected with the rotating piece and is used for driving the rotating piece to rotate;

the adjusting assembly is inserted into the accommodating cavity, the top end of the adjusting assembly extends out of the accommodating cavity, and the adjusting assembly can slide along the vertical direction; and

and the clamping assembly is connected with the top end of the adjusting assembly and used for clamping the pipeline.

In one possible implementation, the drive assembly includes:

the first gear is sleeved outside the rotating piece;

a second gear engaged with the first gear; and

and the first driver is arranged on the base, is connected with the second gear and is used for driving the second gear to rotate.

In one possible implementation, the adjusting assembly includes:

the sliding block is inserted into the accommodating cavity in a sliding mode along the up-down direction, the top end of the sliding block extends out of the accommodating cavity, and a rack is arranged on the side wall of the sliding block;

the third gear is arranged in the accommodating cavity and meshed with the rack;

the transmission rod is connected with the third gear, and two ends of the transmission rod are respectively in rotary connection with the accommodating cavity; and

and the second driver is arranged on the side wall of the rotating part, is connected with the transmission rod and is used for driving the transmission rod to rotate.

In one possible implementation, the top of the adjusting assembly has a receiving groove, and the clamping assembly includes:

the first clamping piece is arranged in the accommodating groove in a sliding mode along a preset path and achieves sliding action through the first air cylinder; and

the second clamping piece is arranged in the accommodating groove in a sliding mode along the preset path and is arranged opposite to the first clamping piece, and the second clamping piece achieves sliding action through a second cylinder.

In a possible implementation manner, a rolling member is further disposed in the accommodating groove, and the rolling member includes:

the fixing seat is connected with the accommodating groove and arranged between the first clamping piece and the second clamping piece; and

and the roller is rotatably arranged at the top of the fixed seat and is in rolling contact with the outer wall of the pipeline.

In one possible implementation, the clamping assembly includes:

the first hoop body is connected with the top of the adjusting assembly;

the second hoop body is oppositely arranged on the upper part of the first hoop body and is connected with the first hoop body through a threaded connecting piece; and

the fixing piece is threaded on the first hoop body and/or the second hoop body and can be abutted against the outer wall of the pipeline.

In one possible implementation, a gasket is connected to the abutting end of the fixing member.

In a possible implementation manner, a connecting sleeve is arranged on the first hoop body and/or the second hoop body, the connecting sleeve extends along the radial direction of a clamping space formed by the first hoop body and the second hoop body in a surrounding mode, and the fixing piece is in threaded connection with the connecting sleeve.

In a possible implementation manner, the bottom of the base is provided with a pulley.

In a possible implementation manner, the driving assembly includes a third driver, and the third driver is disposed on the base and connected to the bottom of the rotating member to drive the rotating member to rotate around its own axis.

The BIM-based pipeline installation device provided by the utility model has the beneficial effects that: compared with the prior art, the BIM-based pipeline installation device has the advantages that two pipelines to be connected are respectively placed on the two sets of the device, the clamping assemblies clamp the pipelines, the rotation angle of the rotating piece is adjusted through the driving assembly, the pipelines meet the preset laying path, and then the heights of the pipelines in the vertical direction are adjusted through the adjusting assemblies, so that the two pipelines to be connected can be quickly aligned and connected. This device can carry out angle and height adjustment to the pipeline, need not artifical transport pipeline at the in-process that removes the pipeline, has reduced the labour, can make the pipeline satisfy laying of predetermineeing the route, and application range is extensive.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed for the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a BIM-based pipe installation apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of an adjustment assembly used in one embodiment of the present invention;

fig. 3 is a schematic structural diagram of a BIM-based pipe installation apparatus according to a second embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a clamping assembly according to a second embodiment of the present invention;

fig. 5 is a schematic structural diagram of a BIM-based pipe installation apparatus according to a third embodiment of the present invention.

In the figure: 1. a base; 2. a first driver; 3. a second gear; 4. a rotating member; 401. an accommodating chamber; 5. a third driver; 6. a first gear; 7. a bearing connector; 8. a slider; 801. a rack; 802. a containing groove; 9. a first clip piece; 10. a second clip; 11. a pulley; 12. a second band body; 13. a first hoop body; 14. a threaded connection; 15. a fixing member; 1501. a gasket; 16. connecting sleeves; 17. a second driver; 18. a transmission rod; 19. a third gear; 20. a first cylinder; 21. a second cylinder; 22. a fixed seat; 23. and a roller.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

Referring to fig. 1 and 3, and fig. 5, a BIM-based pipe installation apparatus according to the present invention will now be described. The BIM-based pipeline installation device comprises a base 1, a rotating piece 4, a driving assembly, an adjusting assembly and a clamping assembly; the rotating piece 4 is rotatably arranged on the base 1 and is internally provided with an accommodating cavity 401, the rotating piece 4 can rotate on the base 1 around the axis of the rotating piece 4, and the axis of the rotating piece 4 is arranged along the vertical direction; the driving assembly is arranged on the base 1, is connected with the rotating piece 4 and is used for driving the rotating piece 4 to rotate; the adjusting assembly is inserted into the accommodating cavity 401, the top end of the adjusting assembly extends out of the accommodating cavity 401, and the adjusting assembly can slide along the vertical direction; the clamping assembly is connected with the top end of the adjusting assembly and used for clamping the pipeline.

Compared with the prior art, the BIM-based pipeline installation device provided by the utility model has the advantages that two pipelines to be connected are respectively placed on the two sets of the device, the clamping assemblies clamp the pipelines, the rotation angle of the rotating part 4 is adjusted through the driving assembly, the pipelines meet a preset laying path, and then the heights of the pipelines along the vertical direction are adjusted through the adjusting assemblies, so that the two pipelines to be connected can be quickly aligned and connected. This device can carry out angle and height adjustment to the pipeline, need not artifical transport pipeline at the in-process that removes the pipeline, has reduced the labour, can make the pipeline satisfy laying of predetermineeing the route, and application range is extensive.

Optionally, a bearing connecting piece 7 is arranged outside the rotating piece 4, and is rotatably connected with the base 1 through the bearing connecting piece 7.

In some embodiments, referring to fig. 1 and 3, the driving assembly includes a first gear 6, a second gear 3 and a first driver 2, wherein the first gear 6 is sleeved outside the rotating member 4; the second gear 3 is meshed with the first gear 6; the first driver 2 is arranged on the base 1 and connected with the second gear 3 for driving the second gear 3 to rotate.

In this embodiment, the first gear 6 of first driver 2 drive rotates, and first gear 6 meshes with second gear 3 to drive the synchronous revolution of second gear 3, through the angle of the angle modulation pipeline of rotating member 4, make the pipeline can satisfy different angle of laying, reduced the labour that the manual work rotated the pipeline and consumed, improved regulation efficiency.

Optionally, the first driver 2 is a motor.

In some embodiments, referring to fig. 2, the adjusting assembly includes a sliding block 8, a third gear 19, a transmission rod 18 and a second driver 17, the sliding block 8 is slidably inserted into the accommodating cavity 401 in the up-down direction, the top end of the sliding block extends out of the accommodating cavity 401, and a side wall of the sliding block 8 has a rack 801; the third gear 19 is arranged in the accommodating cavity 401 and meshed with the rack 801; the transmission rod 18 is connected with the third gear 19, and two ends of the transmission rod are respectively connected with the accommodating cavity 401 in a rotating manner; the second driver 17 is disposed on a side wall of the rotating member 2, and is connected to the transmission rod 18 for driving the transmission rod 18 to rotate.

The second driver 17 drives the transmission rod 18 to rotate, so as to drive the third gear 19 to rotate, and the rack 801 meshed with the third gear 19 moves up and down in the accommodating cavity 401 along with the rotation of the third gear 19, so as to adjust the height of the pipeline, enable the two pipelines to be in butt joint, and also enable the installation of the pipeline at a preset height. This simple structure can adjust the mounting height of pipeline, need not the manual work and lifts up the pipeline, has reduced labour consumption.

Optionally, the second driver 17 is a motor.

In some embodiments, referring to fig. 1 and fig. 2, the top of the adjusting assembly has an accommodating groove 802, the clamping assembly includes a first clamping piece 9 and a second clamping piece 10, the first clamping piece 9 is slidably disposed in the accommodating groove 802 along a predetermined path, and the first cylinder 20 realizes a sliding motion; the second clamping piece 10 is slidably disposed in the accommodating groove 802 along a predetermined path and is disposed opposite to the first clamping piece 9, and the second clamping piece 10 realizes a sliding motion through the second cylinder 21.

The first clamping piece 9 is driven by the first air cylinder 20 to be close to or far away from the second clamping piece 10, and the second clamping piece 10 is driven by the second air cylinder 21 to be close to or far away from the first clamping piece 9, so that the pipeline can be effectively clamped according to the diameter of the pipeline, the pipeline clamping device is suitable for pipelines with different diameters, and the application range is expanded. Meanwhile, the first clamping piece 9 and the second clamping piece 10 are driven by the first air cylinder 20 and the second air cylinder 21, so that the automatic clamping of the pipeline is completed, and the clamping efficiency is improved.

It should be noted that the "predetermined path" refers to a direction perpendicular to the axis of the pipe.

In some embodiments, referring to fig. 1 to 2, a rolling member is further disposed in the accommodating groove 802, the rolling member includes a fixing seat 22 and a roller 23, the fixing seat 22 is connected to the accommodating groove and disposed between the first clamping piece 9 and the second clamping piece 10; the roller 23 is rotatably arranged on the top of the fixed seat 22 and is used for rolling contact with the outer wall of the pipeline.

The two pipelines to be connected are respectively placed into the clamping assemblies of the two groups of devices, the two pipelines are respectively slid along the butt joint direction, so that the end parts of the two pipelines are in butt joint, then the pipelines are clamped through the clamping assemblies, and then the two pipelines are connected. The roller 23 can reduce the friction force between the roller and the pipeline, and the pipeline can be conveniently slid.

The "rolling surface" refers to the outer peripheral surface of the roller 23.

In some embodiments, referring to fig. 3 to 4, the clamping assembly includes a first hoop body 13, a second hoop body 12 and a fixing member 15, wherein the first hoop body 13 is connected with the top of the adjusting assembly; the second hoop body 12 is arranged on the upper part of the first hoop body 13 oppositely and is connected with the first hoop body 13 through a threaded connecting piece 14; the fixing member 15 is screwed into the first band 13 and/or the second band 12, and can abut against the pipe.

The pipe is placed in the first hoop body 13 and the second hoop body 12, then the first hoop body 13 and the second hoop body 12 are connected through the threaded connecting piece 14, the fixing piece 15 is rotated according to the diameter of the pipe, the fixing piece 15 is abutted to the pipe, and therefore the clamping and fixing of the pipe are completed. First hoop body 13 is connected with adjusting part, can reciprocate along with adjusting part, conveniently adjusts the height of pipeline. This convenient dismantlement of structure can realize with the quick installation of pipeline and dismantle, has improved the installation effectiveness, and can all carry out effective centre gripping to the pipeline of different diameters, avoids the pipeline to remove and influences the linkage effect.

In some embodiments, referring to fig. 3 to 4, the abutting end of the fixing member 15 is connected to a pad 1501.

Gasket 1501 can increase the area of contact with the pipeline outer wall, avoids damaging the pipeline when mounting 15 and pipeline butt, has improved the life of pipeline.

Optionally, the gasket 1501 is a rubber sheet or a sponge sheet, and reduces damage to the pipe by flexible contact.

In a possible implementation manner, referring to fig. 3 to 4, a connecting sleeve 16 is disposed on the first hoop body 13 and/or the second hoop body 12, the connecting sleeve 16 extends along a radial direction of a clamping space formed by the first hoop body 13 and the second hoop body 12, and the fixing member 15 is in threaded connection with the connecting sleeve 16.

The connecting sleeve 16 extends along the radial direction of the first hoop body 13 and/or the second hoop body 12, and the connecting surface of the connecting sleeve and the fixing piece 15 is increased, so that the connection of the first hoop body 13 and/or the second hoop body 12 and the fixing piece 15 is more stable and firmer, and the influence of the connection failure on the connection of the pipelines is avoided.

In some embodiments, referring to fig. 1 to 4, the bottom of the base 1 is provided with a pulley 11.

After the angle and the height of the pipeline are adjusted, the pipeline is butted by the movable base 1, the labor force for moving the pipeline is reduced, and the installation efficiency is improved.

In some embodiments, referring to fig. 5, the driving assembly includes a third driver 5, and the third driver 5 is disposed on the base 1 and connected to the bottom of the rotating element 4 to drive the rotating element 4 to rotate around its axis.

The third driver 5 drives the rotating part 4 to rotate, so that the angle of the pipeline is adjusted, the pipeline can meet the preset laying path, the structure is simple, and the production cost is reduced.

Optionally, the third driver 5 is a motor, and an output shaft of the motor is connected with the rotating member 4. .

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. BIM-based pipe installation device, comprising:

a base;

the rotating piece is rotatably arranged on the base and is internally provided with an accommodating cavity, the rotating piece can rotate on the base around the axis of the rotating piece, and the axis of the rotating piece is arranged along the vertical direction;

the driving assembly is arranged on the base, is connected with the rotating piece and is used for driving the rotating piece to rotate;

the adjusting assembly is inserted into the accommodating cavity, the top end of the adjusting assembly extends out of the accommodating cavity, and the adjusting assembly can slide along the vertical direction; and

and the clamping assembly is connected with the top end of the adjusting assembly and used for clamping the pipeline.

2. The BIM-based pipe installation apparatus of claim 1, wherein the driving assembly comprises:

the first gear is sleeved outside the rotating piece;

a second gear engaged with the first gear; and

and the first driver is arranged on the base, is connected with the second gear and is used for driving the second gear to rotate.

3. The BIM-based pipe installation apparatus of claim 1, wherein the adjustment assembly comprises:

the sliding block is inserted into the accommodating cavity in a sliding mode along the up-down direction, the top end of the sliding block extends out of the accommodating cavity, and a rack is arranged on the side wall of the sliding block;

the third gear is arranged in the accommodating cavity and meshed with the rack;

the transmission rod is connected with the third gear, and two ends of the transmission rod are respectively in rotary connection with the accommodating cavity; and

and the second driver is arranged on the side wall of the rotating part, is connected with the transmission rod and is used for driving the transmission rod to rotate.

4. The BIM-based pipe installation apparatus of claim 1, wherein the top of the adjustment assembly has a receiving slot, the clamping assembly comprising:

the first clamping piece is arranged in the accommodating groove in a sliding mode along a preset path and achieves sliding action through the first air cylinder; and

the second clamping piece is arranged in the accommodating groove in a sliding mode along the preset path and is arranged opposite to the first clamping piece, and the second clamping piece achieves sliding action through a second cylinder.

5. The BIM-based pipe installation device of claim 4, wherein a rolling member is further disposed in the accommodating groove, the rolling member comprising:

the fixing seat is connected with the accommodating groove and arranged between the first clamping piece and the second clamping piece; and

and the roller is rotatably arranged at the top of the fixed seat and is in rolling contact with the outer wall of the pipeline.

6. The BIM-based pipe mounting apparatus as recited in claim 1, wherein the clamping assembly comprises:

the first hoop body is connected with the top of the adjusting assembly;

the second hoop body is oppositely arranged on the upper part of the first hoop body and is connected with the first hoop body through a threaded connecting piece; and

the fixing piece is threaded on the first hoop body and/or the second hoop body and can be abutted against the outer wall of the pipeline.

7. The BIM-based pipe mounting device of claim 6, wherein a gasket is attached to the abutting end of the fixture.

8. The BIM-based pipe installation device of claim 6, wherein the first hoop body and/or the second hoop body is provided with a connection sleeve, the connection sleeve extends along a radial direction of a clamping space formed by the first hoop body and the second hoop body, and the fixing member is in threaded connection with the connection sleeve.

9. The BIM-based pipe installation apparatus of claim 6, wherein the base is provided at the bottom thereof with pulleys.

10. The BIM-based pipe installation device according to claim 1, wherein the driving assembly includes a third driver, which is provided on the base and is connected to a bottom of the rotation member to drive the rotation member to rotate about its axis.

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