CN219316452U - Multi-space coordination scheduling structure of assembled building - Google Patents

Abstract

The utility model relates to the field of construction technology, in particular to an assembled building multi-space coordination dispatching structure, comprising a bearing box, a bearing plate is fixed inside the bearing box, and a buckle is connected to the outer wall of the bearing box, and the bearing plate A main component cavity is provided at the top of the main component cavity, and a cushion is connected to one side of the inner wall of the main component cavity, and a partition plate is fixed below the bearing plate. The bearing box of the utility model separates the main component cavity through the bearing plate, and places the main body and the enclosure structure components. The main component cavity is bonded with a cushion to avoid bumping during the transportation or hoisting of the load box. The slide plate reaches the predetermined position through the chute and is fixed by bolts to avoid The internal components of the limited main component cavity fall off, and the space under the bearing plate is divided into multiple groups of small spaces through the partition plate, and a loading box is provided to facilitate the placement of matching small components. The loading box is convenient for placing the assembled components of the corresponding range, and it is convenient for scheduling in batches to avoid confusion.

Description

A prefabricated building multi-space coordination scheduling structure

technical field

The utility model relates to the technical field of buildings, in particular to a multi-space coordination and dispatching structure of an assembled building.

Background technique

A building assembled on site by prefabricated components is called a prefabricated building. According to the form and construction method of prefabricated components, it is divided into five types: block building, plate building, box building, skeleton plate building and rising plate building. With the development of modern industrial technology, building houses can be like machine production. , Manufactured in batches and complete sets, as long as the prefabricated building components are transported to the construction site for assembly, the components need to be hoisted by the crane when assembling, so coordination and scheduling are required.

For example, a scheduling method and system for a BIM-based prefabricated building component whose publication number is CN115587688A, in the present invention, the assembly sequence information of a plurality of single prefabricated building components included in the building to be constructed is obtained, and based on the assembly The sequence information determines the storage sequence information of multiple single-fabricated building components in the target storage space; based on the storage sequence information of multiple single-fabricated building components, the assembly sequence of multiple single-fabricated building components Update the information to obtain the update information of the assembly sequence corresponding to multiple single-fabricated building components; based on the update information of the assembly sequence corresponding to multiple single-fabricated building components, carry out transportation scheduling for multiple single-fabricated building components deal with. Based on the above method, it is possible to improve the problem in the prior art that the management and control of the transportation scheduling of prefabricated building components is not good.

Based on the above, it can be seen that there are the following technical problems in the existing technology: during the construction process of the existing prefabricated buildings, some prefabricated components are placed in a chaotic manner, and the management and control are easily confused, so that the dispatching can not be carried out effectively through the hanging tower. Therefore, we provide A prefabricated building multi-space coordination scheduling structure is proposed.

Utility model content

The purpose of this utility model is to provide a prefabricated building multi-space coordination and scheduling structure to solve the problems raised in the above-mentioned background technology.

In order to solve the above-mentioned technical problems, the utility model adopts the following technical solutions:

A prefabricated building multi-space coordination and dispatching structure, including a bearing box, the inside of the bearing box is fixed with a bearing plate, and the outer wall of the bearing box is connected with buckles, the top of the bearing plate is provided with a main component cavity, and the main A cushion is connected to one side of the inner wall of the component cavity, a partition plate is fixed under the bearing plate, and a loading box is arranged on one side of the partition plate, and a chute is provided on the other side of the inner wall of the main component cavity. And the inside of the chute passes through a slide plate.

Preferably, the bearing box is welded to the bearing plate, and the bearing box is bonded to the cushion.

Preferably, a sliding structure is formed between the loading box and the carrying box, and a sliding structure is formed between the carrying box and the sliding plate through the chute.

Preferably, a motor is embedded inside the partition plate, and the power output end of the motor is connected to a two-way threaded rod, the outside of the two-way threaded rod is provided with a slide block, and the bottom end of the loading box is provided with a slide rail , the bottom of the bearing box is fixed with a chassis, and a hydraulic cylinder is embedded in the interior of the chassis, the power output end of the hydraulic cylinder is connected with a push plate, and the bottom end of the push plate is equipped with a roller.

Preferably, the two-way threaded rod is threadedly connected to the slider, and the slider forms a sliding structure through the motor and the two-way threaded rod.

Preferably, the slider is fixedly connected to the loading box, and the loading box forms a sliding structure through the slider and the partition plate.

Preferably, the push plate forms a telescopic structure through the hydraulic cylinder and the chassis, and the hydraulic cylinders are evenly distributed equidistantly with respect to the bottom surface of the chassis.

It can be seen from the above description that the technical problem to be solved in the present application must be solved through the above technical solution of the present application.

At the same time, through the above technical solutions, the utility model at least has the following beneficial effects:

The bearing box of the utility model separates the main component cavity through the bearing plate, and places the main body and the enclosure structure components. The main component cavity is bonded with a cushion to avoid bumping during the transportation or hoisting of the load box. The slide plate reaches the predetermined position through the chute and is fixed by bolts to avoid The internal components of the limited main component cavity fall off, and the space under the bearing plate is divided into multiple groups of small spaces through the partition plate, and a loading box is provided to facilitate the placement of matching small components. The loading box is convenient for placing the assembled components of the corresponding range, and it is convenient for scheduling in batches to avoid confusion.

The utility model facilitates component dispatching in the same range and different spaces through multiple sets of loading boxes. The motor drives the two-way threaded rod to rotate, so that the slider slides along the two-way threaded rod, and drives the loading box to slide out of the carrying box, which is convenient for the scheduling or work of the crane tower. Personnel handling, so as to coordinate and dispatch the assembly components on a regional scale, and at the same time, there is a slide rail at the bottom of the loading box, which is convenient for the loading box to slide stably in the loading box.

The utility model facilitates the telescopic movement of the push plate through the operation of the hydraulic cylinder, thereby pushing the rollers to pass through the chassis, so that the carrying box can move flexibly, and after being manually or mechanically dragged to the corresponding accurate position for coordination, it is convenient for the components to be carried out through the hanging tower. scheduling.

Description of drawings

Fig. 1 is the structural representation of the utility model;

Fig. 2 is the utility model sectional structure schematic diagram;

Fig. 3 is a structural schematic diagram of the utility model loading box;

Fig. 4 is a structural schematic diagram of the push plate of the present invention.

In the figure: 1. Loading box; 2. Loading plate; 3. Main member cavity; 4. Cushion; 5. Buckle; 6. Loading box; 7. Partition plate; 8. Chute; 1, motor; 11, two-way threaded rod; 12, slider; 13, slide rail; 14, chassis; 15, hydraulic cylinder; 16, push plate; 17, roller.

Detailed ways

In order to make the purpose, technical solution and advantages of the utility model clearer, the utility model will be further described in detail below in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the utility model, and are not intended to limit the utility model.

Implementation Case 1

As shown in Figure 1, Figure 2 and Figure 3, the utility model provides a technical solution: a multi-space coordinated dispatching structure of an assembled building, including a bearing box 1, and a bearing plate 2 is fixed inside the bearing box 1, carrying The outer wall of the box 1 is connected with buckles 5, the top of the bearing plate 2 is provided with a main component cavity 3, the inner wall side of the main component cavity 3 is connected with a cushion 4, and the lower part of the bearing plate 2 is fixed with a partition plate 7 to separate One side of the board 7 is provided with a loading box 6, and the other side of the inner wall of the main member cavity 3 is provided with a chute 8, and a slide plate 9 is pierced inside the chute 8, and the loading box 1 is welded to the loading board 2, and the loading box 1 Adhesively connected with the cushion 4, a sliding structure is formed between the loading box 6 and the loading box 1, and the sliding structure is formed between the loading box 1 through the chute 8 and the sliding plate 9, and the loading box 1 is separated from the main component cavity 3 by the loading plate 2 , to place the main body and the enclosure structure components, the main component cavity 3 is bonded with the cushion 4 to avoid bumping of the carrying box 1 during transportation or hoisting, the sliding plate 9 reaches the predetermined position through the chute 8 and is fixed by bolts to avoid limiting the internal components of the main component cavity 3 Falling off, the space under the bearing plate 2 is divided into multiple groups of small spaces through the partition plate 7, and a loading box 6 is provided to facilitate the placement of matching small components. The bearing box 1 is set as a batch, and the interior is passed through the main component cavity 3 and the loading box. 6. It is convenient to arrange the assembled components of the corresponding range, and it is convenient to schedule in batches to avoid confusion.

Embodiment two

The solution in Embodiment 1 will be further introduced in combination with specific working methods below, see the following description for details:

As shown in Figure 1, Figure 2 and Figure 3, as a preferred embodiment, on the basis of the above method, further, a motor 10 is embedded inside the partition plate 7, and the power output end of the motor 10 is connected with a two-way screw thread Rod 11, the outer cover of two-way threaded rod 11 is provided with slide block 12, and the bottom end of loading box 6 is provided with slide rail 13, and two-way threaded rod 11 is threadedly connected with slide block 12, and slide block 12 passes motor 10 and two-way threaded rod 11 A sliding structure is formed between them, the slider 12 is fixedly connected with the loading box 6, and the loading box 6 forms a sliding structure through the slider 12 and the partition plate 7, and multiple sets of loading boxes 6 facilitate the scheduling of components in different spaces in the same range. The motor 10 drives the two-way threaded rod 11 to rotate, so that the slider 12 slides along the two-way threaded rod 11, and drives the loading box 6 to slide out of the carrying box 1, which is convenient for the dispatching of the crane tower or the handling of the staff, so that the assembly components can be adjusted regionally. Coordination and scheduling are carried out. At the same time, a slide rail 13 is provided at the bottom of the loading box 6 to facilitate the stable sliding of the loading box 6 in the loading box 1 .

As shown in Fig. 1, Fig. 2 and Fig. 4, as a preferred embodiment, on the basis of the above-mentioned method, further, a chassis 14 is fixed on the bottom of the carrying case 1, and a hydraulic cylinder 15 is embedded in the interior of the chassis 14. The power output end of the cylinder 15 is connected with a push plate 16, and the bottom end of the push plate 16 is equipped with a roller 17. The push plate 16 forms a telescopic structure through the hydraulic cylinder 15 and the chassis 14, and the hydraulic cylinder 15 is equal to the bottom surface of the chassis 14. The distance is evenly distributed, and the hydraulic cylinder 15 works to facilitate the telescopic movement of the push plate 16, thereby pushing the roller 17 out of the chassis 14, so that the carrying box 1 can move flexibly, and after being manually or mechanically dragged to the corresponding accurate position for coordination, it is convenient The components are dispatched through the hanging tower.

Based on the above, we can see that:

The utility model aims at the technical problem: in the construction process of the existing prefabricated buildings, some prefabricated components are placed chaotically, and the management and control are easy to be confused, so that the scheduling cannot be effectively carried out through the hanging tower; the technical solutions of the above-mentioned embodiments are adopted. Simultaneously, the realization process of above-mentioned technical scheme is:

The carrying box 1 separates the main component cavity 3 above through the carrying plate 2, which is convenient for placing larger enclosure components such as walls and windows. The main component cavity 3 avoids damage caused by bumps during transportation through the cushion 4. 2. The space at the bottom is divided into several spaces by the partition plate 7, and a loading box 6 is installed, and small components suitable for the enclosure-type components are placed through the loading box 6, which facilitates the assembly of a corresponding batch in an area and coordinates scheduling It is more organized and standardized to avoid confusion. At the same time, it can be classified and placed through multiple groups of spaces. The carrying box 1 is convenient for the scheduling of the pendant through the welded buckle 5. After the sliding plate 9 slides to the corresponding position through the chute 8 opened in the carrying box 1, the sliding plate is fixed by bolts. After 9, limit the internal components of the main component cavity 3 to avoid falling off, and the motor 10 embedded in the partition plate 7 works to drive the two-way threaded rod 11 to rotate, and the two-way threaded rod 11 runs through the slider 12 and is threaded. The bearing at one end of the rod 11 is embedded in the inner wall of the partition plate 7 through bolts, so that the two-way threaded rod 11 drives the slider 12 to stably push the loading box 6 out of the loading box 1, which is convenient for the crane tower or manual adjustment of the internal structure. A slide rail 13 is provided between the bottom of the loading box 6 and the carrying box 1 to facilitate the stable sliding of the loading box 6. A hydraulic cylinder 15 is embedded inside the chassis 14 fixed at the bottom of the carrying box 1, and the push plate 16 is driven by the hydraulic cylinder 15. Stretch, and push the rollers 17 to pass through the chassis 14, so that the carrying box 1 can move flexibly, so as to coordinate the position by manual pushing or dragging by motor vehicles, and facilitate the dispatching of the pendant.

Through the above settings, the present application must be able to solve the above technical problems, and at the same time, achieve the following technical effects:

The utility model facilitates component scheduling in different spaces in the same range through multiple sets of loading boxes 6, and the motor 10 drives the two-way threaded rod 11 to rotate, so that the slider 12 slides along the two-way threaded rod 11, and drives the loading box 6 to slide out of the carrying box 1 , which is convenient for the scheduling of the crane tower or the handling of the staff, so as to coordinate and dispatch the assembly components in a regional range, and at the same time, the bottom end of the loading box 6 is provided with a slide rail 13, which is convenient for the loading box 6 to slide stably in the loading box 1;

The utility model facilitates the telescopic movement of the push plate 16 through the operation of the hydraulic cylinder 15, thereby pushing the roller 17 out of the chassis 14, so that the carrying box 1 can move flexibly. The pendant dispatches the components.

Although the embodiments of the present invention have been shown and described, those skilled in the art can understand that various changes and modifications can be made to these embodiments without departing from the principle and spirit of the present invention , replacements and modifications, the scope of the present utility model is defined by the appended claims and their equivalents.

Claims (7)

1. The utility model provides an assembled building multi-space coordination scheduling structure, its characterized in that, including bearing case (1), the inside of bearing case (1) is fixed with loading board (2), and the outer wall connection who bears case (1) has buckle (5), the top of loading board (2) is provided with main component chamber (3), and inner wall one side of main component chamber (3) is connected with cushion (4), the below of loading board (2) is fixed with division board (7), and one side of division board (7) is provided with loading case (6), spout (8) have been seted up to the inner wall opposite side of main component chamber (3), and slide (9) are worn out to the inside of spout (8).

2. The multi-space coordination scheduling structure of the fabricated building according to claim 1, wherein the bearing box (1) is welded with the bearing plate (2), and the bearing box (1) is bonded with the soft cushion (4).

3. The multi-space coordination scheduling structure of the assembled building according to claim 1, wherein a sliding structure is formed between the loading box (6) and the bearing box (1), and the bearing box (1) forms a sliding structure with the sliding plate (9) through the sliding groove (8).

4. The multi-space coordination scheduling structure for the fabricated building according to claim 1, wherein a motor (10) is embedded in the partition plate (7), a power output end of the motor (10) is connected with a bidirectional threaded rod (11), a sliding block (12) is sleeved outside the bidirectional threaded rod (11), a sliding rail (13) is arranged at the bottom end of the loading box (6), a chassis (14) is fixed at the bottom of the loading box (1), a hydraulic cylinder (15) is embedded in the chassis (14), a pushing plate (16) is connected to the power output end of the hydraulic cylinder (15), and a roller (17) is installed at the bottom end of the pushing plate (16).

5. The multi-space coordination scheduling structure for the fabricated building according to claim 4, wherein the bidirectional threaded rod (11) is in threaded connection with the sliding block (12), and the sliding block (12) forms a sliding structure with the bidirectional threaded rod (11) through the motor (10).

6. The multi-space coordination scheduling structure for the fabricated building according to claim 4, wherein the sliding block (12) is fixedly connected with the loading box (6), and the loading box (6) forms a sliding structure with the partition plate (7) through the sliding block (12).

7. The modular building multi-space coordinated scheduling structure of claim 4, wherein

Is characterized in that the pushing plate (16) forms a telescopic structure with the chassis (14) through the hydraulic cylinder (15),

and the hydraulic cylinders (15) are uniformly distributed at equal intervals with respect to the bottom end surface of the chassis (14).

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