CN114412206A - Assembly type building based on BIM technology - Google Patents

Abstract

The invention relates to the technical field of auxiliary equipment of an assembly type building, in particular to an assembly type building based on a BIM technology, which aims at that a plurality of support rods are used for auxiliary support when a prefabricated part is assembled, angle measurement needs to be carried out on the prefabricated part manually in the supporting process, the process is complicated, and the assembly type building comprises a base; the first structural support and the second structural support are symmetrically arranged on the base, and the distance between the output ends of the first structural support and the second structural support is larger than the distance between the fixed ends of the first structural support and the second structural support; a straightness caliber that hangs down for measuring contained angle between main structure and the prefabricated component, the straightness caliber that hangs down sets up on the base, through the setting of base, first structure support piece, second structure support piece and straightness caliber that hangs down, has realized carrying out reliable fixed and the purpose of convenient regulation to the prefabricated component, has solved the low and loaded down with trivial details influence of process of traditional mode efficiency of construction.

Description

Assembly type building based on BIM technology

Technical Field

The invention relates to the technical field of auxiliary equipment of an assembly type building, in particular to an assembly type building based on a BIM technology.

Background

Building information modeling, abbreviated as BIM, is a unified and coordinated process from planning, designing, constructing to managing stages, and is operating software for converting the concept of using standards into corresponding data.

Ideally, the BIM process utilizes centralized digital three-dimensional modeling as a core resource. Each building participant plans the data model while also allowing other people's rights and data modifications. At this stage, the BIM model consists of detailed BIM units, such as doors, walls, equipment, etc.

The BIM image looks like a simple 3d cad file, and the BIM components are in fact more complex in the application and provide better operational flexibility. When creating a single component, each BIM component acts as a single unique element within the architectural form, when loaded into the project model, allows the user to see the relationship build between the component and other elements;

the prefabricated building refers to a building which is formed by assembling components prefabricated by a factory on a construction site. The prefabricated building has the advantages of convenient construction, fast engineering progress and the like. In recent years, prefabricated construction mode receives more and more extensive attention and application, and at present prefabricated component uses many spinal branchs vaulting pole to carry out auxiliary stay when the assembly, needs the manual work to carry out angle measurement to prefabricated component at the in-process that supports moreover to need carry out synchronous support to the two sides of prefabricated component, the process is more loaded down with trivial details, need provide a prefabricated building based on BIM technique to solve it to above problem.

Disclosure of Invention

To solve the above technical problems.

The application provides an assembly type building based on a BIM technology, which comprises a base; the first structural support and the second structural support are symmetrically arranged on the base, and the distance between the output ends of the first structural support and the second structural support is larger than the distance between the fixed ends of the first structural support and the second structural support; and the verticality measurer is used for measuring an included angle between the structure main body and the prefabricated part and is arranged on the base.

Preferably, the base comprises a connecting block, two mounting holes are symmetrically formed in the connecting block, and the two mounting holes face to two sides of the connecting block respectively; the rotating rod is arranged on the connecting block and is fixedly connected with the connecting block; and the rotating rod is arranged on the fixed plate and is rotatably connected with the fixed plate.

Preferably, the first structural support and the second structural support are consistent in structure, the first structural support comprises a connecting angle seat, and the connecting angle seat is connected with an embedded part arranged on the prefabricated part; the head part of the movable rod is hinged with the connecting angle seat; and the pushing assembly is arranged in the mounting hole, and the tail part of the pushing assembly is connected with the output end of the pushing assembly.

Preferably, the pushing assembly comprises a sleeve, the sleeve is arranged inside the mounting hole and is rotatably connected with the mounting hole; the limiting piece is arranged at the end part of the sleeve, and the diameter of the tail end of the movable rod is larger than the inner diameter of the limiting piece; and the spring is arranged in the sleeve, and the output end of the spring is connected with the tail end of the movable rod.

Preferably, the tail end of the movable rod is provided with a plurality of arc-shaped tooth sheets in an arrayed manner, and the inner edge of the sleeve is provided with a plurality of tooth sockets in an arrayed manner.

Preferably, the perpendicularity measurer comprises a right-angle plate, and contact sensors are arranged at the upper end and the lower end of the vertical surface of the right-angle plate; and the linear driver is arranged on the fixed plate, and the right-angle plate is arranged at the output end of the linear driver.

Preferably, the linear driver comprises a rack, and the rack is arranged on the fixed plate and is in sliding connection with the fixed plate; the gear is arranged on the fixed plate and is rotatably connected with the fixed plate; and the first handle is arranged on the gear. Preferably, the prefabricated building further comprises a steel wire rope, and one end of the steel wire rope is connected with the base.

Preferably, the assembly type building further comprises a winding component, the winding component is arranged on the base, and one end of the steel wire rope is connected with the winding component; and the steel wire rope brake is arranged on the base, and the steel wire rope penetrates through the output end of the steel wire rope brake.

Preferably, the winding assembly comprises a winding disc; the winding disc is rotatably arranged in the base through the linkage rod; and the second handle is connected with one end of the linkage rod.

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

1. the purposes of reliably fixing and conveniently adjusting the prefabricated part are achieved through the arrangement of the base, the first structural support piece, the second structural support piece and the verticality measurer, and the influences of low construction efficiency and complex working procedures in the traditional mode are solved;

2. the base is arranged, so that the first structural support and the second structural support can be matched to adapt to prefabricated parts with different sizes for connection;

3. according to the method, the prefabricated part can be stably fixed in an inverted triangle arrangement mode through the arrangement of the first structural supporting piece and the second structural supporting piece;

4. due to the arrangement of the arc-shaped tooth sheets and the tooth grooves, the situation that the prefabricated part is pushed to the other side by over-strong elasticity of the spring and the movable rod is conveniently retracted into the sleeve can be avoided;

5. by means of the arrangement of the verticality measurer, whether the prefabricated part is vertical to the structural main body or not can be quickly detected;

6. this application passes through the setting of wire rope, rolling subassembly and wire rope stopper, can provide the pulling force to prefabricated component, avoids the prefabricated component to fall to the another side and improves its stability to can adapt to not unidimensional prefabricated component.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a side view of the present invention;

FIG. 4 is a front view of the present invention;

FIG. 5 is a schematic perspective view of a first structural support according to the present invention;

FIG. 6 is a schematic view of the internal structure of a first structural support according to the present invention;

FIG. 7 is a side view of the base and perpendicularity gauge of the present invention;

FIG. 8 is a schematic perspective view of the base and perpendicularity gauge of the present invention;

FIG. 9 is a schematic perspective view of the second embodiment of the present invention;

FIG. 10 is a front view of the base and take-up assembly of the present invention;

fig. 11 is a sectional view taken along the line a-a of fig. 10.

The reference numbers in the figures are:

1-a base; 1 a-connecting block; 1a 1-mounting holes; 1 b-rotating rods; 1 c-a fixing plate;

2-a first structural support; 2 a-connecting angle seat; 2 b-a movable rod; 2b 1-arc blade; 2 c-a pushing assembly; 2c 1-sleeve; 2c 2-spacing piece; 2c 3-spring;

3-a second structural support;

4-a perpendicularity measurer; 4 a-square plate; 4a 1-contact sensor; 4 b-linear drive; 4b 1-rack; 4b 2-gear; 4b 3-first handle;

5-a steel wire rope;

6, winding the component; 6 a-a winding disc; 6 b-linkage rod; 6 c-a second handle;

7-a wire rope brake;

8-a structural body;

9-prefabricated parts.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

As shown in fig. 1, fig. 2 and fig. 3, the following preferred technical solutions are provided:

an assembly type building based on BIM technology comprises a base 1; the first structural support 2 and the second structural support 3 are symmetrically arranged on the base 1, and the distance between the output ends of the first structural support 2 and the second structural support 3 is larger than the distance between the fixed ends of the first structural support and the fixed ends of the second structural support; the verticality measurer 4 is used for measuring an included angle between the structural main body and the prefabricated part, and the verticality measurer 4 is arranged on the base 1;

specifically, in order to solve the technical problem that a plurality of support rods are needed to support a prefabricated part and measure the prefabricated part, the base 1 is fixedly installed on a structure main body, the structure main body is the ground, the prefabricated part is placed on the structure main body through a crane and is a wall, the perpendicularity of the prefabricated part needs to be measured at the moment, a worker operates the perpendicularity measurer 4, the output end of the perpendicularity measurer 4 extends out and is close to the side wall of the prefabricated part, the perpendicularity of the prefabricated part is determined through the output end of the perpendicularity measurer 4, the perpendicularity measurer 4 sends a signal to the worker when the prefabricated part and the structure main body are in a perpendicular state, the worker operates to enable the output ends of the first structure support 2 and the second structure support 3 to extend out, and the output ends of the first structure support 2 and the second structure support 3 are respectively connected with two sides of one surface of the prefabricated part, through the bifurcated arrangement of the first structural support member 2 and the second structural support member 3, the output ends of the two can be prevented from being close to influence the stability of the support.

As shown in fig. 3, the following preferred technical solutions are provided:

the base 1 comprises a connecting block 1a, two mounting holes 1a1 are symmetrically formed in the connecting block 1a, and the two mounting holes 1a1 face to two sides of the connecting block 1a respectively; the rotating rod 1b is arranged on the connecting block 1a and is fixedly connected with the connecting block 1 a; the rotating rod 1b is arranged on the fixed plate 1c and is rotatably connected with the fixed plate 1 c;

specifically, in order to solve the technical problem of adapting to support prefabricated parts with various sizes, because the included angle between the connecting block 1a and the structure body can not be determined to be always consistent when the prefabricated parts with different sizes are supported, the connecting block 1a is hinged with the fixing plate 1c through the rotating rod 1b, so that the first structure supporting piece 2 and the second structure supporting piece 3 can adapt to support at different angles, and the orientation angles of the first structure supporting piece 2 and the second structure supporting piece 3 can be fixed through the symmetrical outwards-deflected mounting holes 1a 1.

As shown in fig. 4 and 5, the following preferred technical solutions are provided:

the first structural support 2 and the second structural support 3 are consistent in structure, the first structural support 2 comprises a connecting angle seat 2a, and the connecting angle seat 2a is connected with an embedded part arranged on the prefabricated part; the head part of the movable rod 2b is hinged with the connecting angle seat 2 a; the pushing assembly 2c is arranged inside the mounting hole 1a1, and the tail part of the pushing assembly 2c is connected with the output end of the pushing assembly 2 c;

specifically, in order to solve the technical problem of adapting to support prefabricated parts with various sizes, when the verticality measurer 4 determines that the angle between the prefabricated part and the structural body is vertical, the movable rod 2b is pushed out through the pushing of the pushing assembly 2c, the connecting angle seat 2a is connected with an embedded part arranged on the prefabricated part after the movable rod 2b extends out, the prefabricated part is supported by the extended movable rod 2b, the movable rod 2b cannot retract into the pushing assembly 2c when the prefabricated part falls to one side of the base 1, and the distance between the two connecting angle seats 2a of the first structural support 2 and the second structural support 3 is larger than the distance between the two pushing assemblies 2c to form an inverted triangle stable support.

As shown in fig. 6, the following preferred technical solutions are provided:

the pushing assembly 2c comprises a sleeve 2c1, and the sleeve 2c1 is arranged inside the mounting hole 1a1 and is rotatably connected with the mounting hole; the limiting piece 2c2 is arranged at the end part of the sleeve 2c1, and the diameter of the tail end of the movable rod 2b is larger than the inner diameter of the limiting piece 2c 2; and a spring 2c3, wherein the spring 2c3 is arranged inside the sleeve 2c1, and the output end of the spring 2c3 is connected with the tail end of the movable rod 2 b;

specifically, in order to solve the technical problem of adapting to support prefabricated parts with different sizes, the tail end of the movable rod 2b is pushed by a spring 2c3 to extend out of the sleeve 2c1, the extending distance of the movable rod 2b is determined according to the joint of the connecting angle seat 2a and the prefabricated part, and the extending limit distance of the movable rod 2b is limited by a limit piece 2c 2.

As shown in fig. 6, the following preferred technical solutions are provided:

a plurality of arc-shaped tooth sheets 2b1 are arranged at the tail end of the movable rod 2b, and a plurality of tooth grooves are arranged at the inner edge of the sleeve 2c 1;

specifically, in order to solve the technical problem of controlling the position of the movable bar 2b, when the movable bar 2b is extended to a proper position or retracted to the inside of the sleeve 2c1, the action of the spring 2c3 on the movable bar 2b is avoided by the worker rotating the sleeve 2c1 so that the tooth grooves at the inner edge of the sleeve 2c1 are engaged with the arc-shaped teeth 2b1 at the tail end of the movable bar 2 b.

As shown in fig. 7, the following preferred technical solutions are provided:

the verticality measurer 4 comprises a right-angle plate 4a, and contact sensors 4a1 are arranged at the upper end and the lower end of the vertical surface of the right-angle plate 4 a; the linear driver 4b is arranged on the fixing plate 1c, and the right-angle plate 4a is arranged at the output end of the linear driver 4 b;

specifically, in order to solve the technical problem of rapidly measuring whether the prefabricated part is vertical or not, the fixing plate 1c is horizontally arranged on the top surface of the structure body, a worker drives the right-angle plate 4a to be close to the prefabricated part through the linear driver 4b, information is timely fed back through the two contact sensors 4a1, the prefabricated part is in a vertical state when the two contact sensors 4a1 are both in contact with the vertical surface of the prefabricated part, and the prefabricated part is in a non-vertical state when only a single contact sensor 4a1 is in contact with the prefabricated part.

As shown in fig. 8, the following preferred technical solutions are provided:

the linear driver 4b comprises a rack 4b1, and the rack 4b1 is arranged on the fixed plate 1c and is connected with the fixed plate in a sliding way; and a gear 4b2, the gear 4b2 is arranged on the fixed plate 1c and is rotatably connected with the fixed plate; and a first handle 4b3, the first handle 4b3 disposed on the gear 4b 2;

specifically, in order to solve the technical problem of driving the right-angle plate 4a to be close to the prefabricated part, a worker holds the first handle 4b3 and drives the first handle to rotate, the first handle 4b3 drives the gear 4b2 to rotate, and the gear 4b2 drives the right-angle plate 4a to be close to the surface of the prefabricated part through the rack 4b 1.

As shown in fig. 9, the following preferred technical solutions are provided:

the assembly type building further comprises a steel wire rope 5, and one end of the steel wire rope 5 is connected with the base 1;

specifically, in order to solve the technical problem of improving the stability of the prefabricated part, the prefabricated part is supported on one side only so as to avoid the prefabricated part from being guided to the other side, and a worker connects the prefabricated part with the base 1 through a steel wire rope 5.

As shown in fig. 9, the following preferred technical solutions are provided:

the assembly type building further comprises a winding component 6, the winding component 6 is arranged on the base 1, and one end of the steel wire rope 5 is connected with the winding component 6; the steel wire rope brake 7 is arranged on the base 1, and the steel wire rope 5 penetrates through the output end of the steel wire rope brake 7;

specifically, in order to solve the technical problem that the steel wire rope 5 is complex to use, a worker can unreel the steel wire rope 5 through the reeling assembly 6, the steel wire rope 5 is connected with the prefabricated part through the embedded part after unreeling to the proper length, and then the steel wire rope 5 is locked by the steel wire rope brake 7 to provide the pulling force for the prefabricated part.

As shown in fig. 10 and 11, the following preferred technical solutions are provided:

the winding assembly 6 comprises a winding disc 6 a; the winding disc 6a is rotatably arranged on the linkage rod 6 b;

specifically, in order to solve the technical problem that different sizes of prefabricated parts need different length wire ropes 5, the staff operates according to the length of required wire ropes 5, and rotates the linkage 6b through the second handle 6c, and the linkage 6b drives the wire ropes 5 to unreel or reel.

The purpose of reliably fixing and conveniently adjusting the prefabricated part is realized through the arrangement of the base 1, the first structural support 2, the second structural support 3 and the verticality measurer 4, the influence of low construction efficiency and complicated process in the traditional mode is solved, the base 1 can be matched with the first structural support 2 and the second structural support 3 to adapt to the prefabricated parts with different sizes for connection, the prefabricated part can be stably fixed through the inverted triangle arrangement mode through the arrangement of the first structural support 2 and the second structural support 3, the situation that the spring 2c3 excessively strongly pushes the prefabricated part to fall to the other side and the movable rod 2b is conveniently retracted into the sleeve 2c1 can be avoided through the arrangement of the arc-shaped tooth sheets 2b1 and the tooth grooves, whether the prefabricated part is perpendicular to the structural body can be quickly detected through the arrangement of the verticality measurer 4, through the arrangement of the steel wire rope 5, the winding assembly 6 and the steel wire rope brake 7, pulling force can be provided for the prefabricated part, the prefabricated part is prevented from falling to the other side, the stability of the prefabricated part is improved, and the prefabricated part can adapt to prefabricated parts with different sizes.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A BIM technology-based fabricated building is characterized by comprising a base (1); and

the first structural support (2) and the second structural support (3) are symmetrically arranged on the base (1), and the distance between the output ends of the first structural support (2) and the second structural support (3) is larger than the distance between the fixed ends of the first structural support and the second structural support;

and the verticality measurer (4) is used for measuring an included angle between the structural main body and the prefabricated part, and the verticality measurer (4) is arranged on the base (1).

2. The prefabricated building based on the BIM technology as claimed in claim 1, wherein the base (1) comprises a connecting block (1a), two mounting holes (1a1) are symmetrically formed on the connecting block (1a), and the two mounting holes (1a1) are respectively directed to two sides of the connecting block (1 a); and

the rotating rod (1b), the rotating rod (1b) is arranged on the connecting block (1a) and is fixedly connected with the connecting block; and

a fixed plate (1c), and a rotating rod (1b) is arranged on the fixed plate (1c) and is rotatably connected with the fixed plate.

3. A prefabricated building based on BIM technology according to claim 2, wherein the first structural support (2) and the second structural support (3) are structurally identical, the first structural support (2) comprises a connection corner seat (2a), the connection corner seat (2a) is connected with an embedded part arranged on the prefabricated member; and

the head part of the movable rod (2b) is hinged with the connecting angle seat (2 a); and

the pushing assembly (2c), pushing assembly (2c) set up in the inside of mounting hole (1a1), the afterbody of pushing assembly (2c) is connected with the output of pushing assembly (2 c).

4. A prefabricated building based on BIM technology as claimed in claim 3, wherein the push assembly (2c) comprises a sleeve (2c1), the sleeve (2c1) is disposed inside the mounting hole (1a1) and rotatably connected thereto; and

the limiting piece (2c2), the limiting piece (2c2) is arranged at the end part of the sleeve (2c1), and the diameter of the tail end of the movable rod (2b) is larger than the inner diameter of the limiting piece (2c 2); and

and the spring (2c3), the spring (2c3) is arranged inside the sleeve (2c1), and the output end of the spring (2c3) is connected with the tail end of the movable rod (2 b).

5. A BIM-technology-based fabricated building as claimed in claim 4, wherein the movable bar (2b) is provided at its rear end with a plurality of arc-shaped teeth (2b1) in an array, and the sleeve (2c1) is provided at its inner periphery with a plurality of teeth slots in an array.

6. The BIM technology-based assembly type building according to claim 2, wherein the verticality measurer (4) comprises a rectangular plate (4a), and contact sensors (4a1) are arranged at the upper end and the lower end of the vertical surface of the rectangular plate (4 a); and

the linear driver (4b), linear driver (4b) set up in fixed plate (1c), and right-angle plate (4a) set up in the output of linear driver (4 b).

7. A BIM-technology-based fabricated building as claimed in claim 6, wherein the linear actuator (4b) comprises a rack (4b1), the rack (4b1) is disposed on the fixed plate (1c) and slidably connected thereto; and

the gear (4b2), the gear (4b2) is arranged on the fixed plate (1c) and is rotatably connected with the fixed plate; and

a first handle (4b3), wherein the first handle (4b3) is arranged on the gear (4b 2).

8. The prefabricated building based on the BIM technology as claimed in claim 1, wherein the prefabricated building further comprises a steel wire rope (5), and one end of the steel wire rope (5) is connected with the base (1).

9. The BIM technology-based assembly type building according to claim 8, wherein the assembly type building further comprises a winding component (6), the winding component (6) is arranged on the base (1), and one end of the steel wire rope (5) is connected with the winding component (6); and

wire rope stopper (7), wire rope stopper (7) set up on base (1), and wire rope (5) run through the output of wire rope stopper (7).

10. A BIM technology based prefabricated building according to claim 9, wherein the winding assembly (6) comprises a winding disc (6 a); and

the winding disc (6a) is rotatably arranged in the base (1) through the linkage rod (6 b); and

and the second handle (6c), and the second handle (6c) is connected with one end of the linkage rod (6 b).

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