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

Abstract

The utility model relates to the technical field of buildings, in particular to an assembled building multi-space coordination scheduling structure, which comprises a bearing box, wherein a bearing plate is fixed in the bearing box, the outer wall of the bearing box is connected with a buckle, the top end of the bearing plate is provided with a main component cavity, one side of the inner wall of the main component cavity is connected with a soft cushion, and a partition plate is fixed below the bearing plate. According to the utility model, the bearing box is separated into the main component cavity through the bearing plate, the main component cavity and the building envelope components are placed, the soft cushion is adhered to the main component cavity to prevent the bearing box from being knocked in the transportation or hoisting process, the sliding plate reaches a preset position through the sliding groove and is fixed through the bolts to prevent the internal components of the limiting main component cavity from falling off, the space below the bearing plate is divided into a plurality of groups of small spaces through the partition plate, the loading box is arranged to facilitate the placement of the adapting small components, the bearing box is arranged to be a batch, the internal components in the corresponding range are conveniently placed through the main component cavity and the loading box, the batch is conveniently scheduled, and the occurrence of confusion is avoided.

Description

Multi-space coordination scheduling structure of assembled building

Technical Field

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

Background

A building assembled from prefabricated components at a worksite is referred to as an assembled building. According to the form and construction method of prefabricated components, the prefabricated building is divided into five types of block building, plate building, box type building, skeleton plate building and lifting plate and layer building, along with the development of modern industrial technology, the built house can be manufactured in batches and in a complete set like machine production, and the prefabricated house components are only required to be transported to a construction site for assembly, and when the components are assembled, the components are required to be lifted through a lifting tower, so that the coordination and the scheduling are required.

According to the scheduling method and system for the building construction assembly based on BIM, as disclosed by the publication No. CN115587688A, assembly sequence information of a plurality of single assembly construction members included in a building to be built is obtained, and storage sequence information of the plurality of single assembly construction members in a target storage space is determined based on the assembly sequence information; updating the assembly sequence information of the plurality of single-body assembly type building components based on the storage sequence information of the plurality of single-body assembly type building components to obtain corresponding assembly sequence updating information of the plurality of single-body assembly type building components; and carrying out transportation scheduling treatment on the plurality of single-body assembled building components based on the assembly sequence updating information corresponding to the plurality of single-body assembled building components. Based on the method, the problem of poor control effect on transportation scheduling of the assembled building components in the prior art can be solved.

In summary, the following technical problems exist in the prior art: in the construction process of the existing prefabricated building, some prefabricated components are placed in a disordered mode, management and control are easy to mix up, so that the prefabricated building cannot be effectively scheduled through a crane tower, and therefore the prefabricated building multi-space coordination scheduling structure is provided.

Disclosure of Invention

The utility model aims to provide an assembled building multi-space coordination scheduling structure so as to solve the problems in the background technology.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the utility model provides an assembled building multi-space coordination scheduling structure, includes bears the case, the inside of bearing the case is fixed with the loading board, and bears the outer wall connection of case and have the buckle, the top of loading board is provided with the main component chamber, and inner wall one side in main component chamber is connected with the cushion, the below of loading board is fixed with the division board, and one side of division board is provided with the loading box, the spout has been seted up to the inner wall opposite side in main component chamber, and the inside of spout wears out there is the slide.

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

Preferably, a sliding structure is formed between the loading box and the bearing box, and the bearing box forms a sliding structure through a sliding groove and a sliding plate.

Preferably, the motor is embedded in the partition plate, the power output end of the motor is connected with a bidirectional threaded rod, the sliding block is sleeved outside the bidirectional threaded rod, the sliding rail is arranged at the bottom end of the loading box, the chassis is fixed at the bottom of the loading box, the hydraulic cylinder is embedded in the chassis, the power output end of the hydraulic cylinder is connected with the pushing plate, and the roller is arranged at the bottom end of the pushing plate.

Preferably, the bidirectional threaded rod is in threaded connection with the sliding block, and the sliding block forms a sliding structure with the bidirectional threaded rod through a motor.

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

Preferably, the pushing plate forms a telescopic structure between the hydraulic cylinder and the chassis, and the hydraulic cylinders are uniformly distributed at equal intervals with respect to the bottom end surface of the chassis.

The above description shows that, by the above technical solution of the present application, the technical problem to be solved by the present application can be necessarily solved.

Meanwhile, through the technical scheme, the utility model has at least the following beneficial effects:

according to the utility model, the bearing box is separated into the main component cavity through the bearing plate, the main component cavity and the building envelope components are placed, the soft cushion is adhered to the main component cavity to prevent the bearing box from being knocked in the transportation or hoisting process, the sliding plate reaches a preset position through the sliding groove and is fixed through the bolts to prevent the internal components of the limiting main component cavity from falling off, the space below the bearing plate is divided into a plurality of groups of small spaces through the partition plate, the loading box is arranged to facilitate the placement of the adapting small components, the bearing box is arranged to be a batch, the internal components in the corresponding range are conveniently placed through the main component cavity and the loading box, the batch is conveniently scheduled, and the occurrence of confusion is avoided.

The utility model is convenient for carrying out component scheduling in different spaces in the same range through a plurality of groups of loading boxes, and drives the bidirectional threaded rod to rotate through motor work, so that the sliding block slides along the bidirectional threaded rod to drive the loading boxes to slide out of the bearing boxes, thereby facilitating crane tower scheduling or staff carrying, carrying out coordinated scheduling on assembly components in the regional range, and simultaneously, the bottom end of the loading box is provided with the sliding rail, thereby facilitating stable sliding of the loading boxes in the bearing boxes.

The utility model is convenient to drive the pushing plate to stretch and move through the hydraulic cylinder, so that the roller is pushed to penetrate out of the chassis, the bearing box is flexibly moved, and the components are convenient to dispatch through the crane after being manually or mechanically dragged to the corresponding accurate positions for coordination.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic cross-sectional view of the present utility model;

FIG. 3 is a schematic view of the structure of the loading box of the present utility model;

fig. 4 is a schematic diagram of a pusher plate structure according to the present utility model.

In the figure: 1. a carrying case; 2. a carrying plate; 3. a main component cavity; 4. a soft cushion; 5. a buckle; 6. a loading box; 7. a partition plate; 8. a chute; 9. a slide plate; 10. a motor; 11. a two-way threaded rod; 12. a slide block; 13. a slide rail; 14. a chassis; 15. a hydraulic cylinder; 16. a pushing plate; 17. and a roller.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Description of the preferred embodiments

As shown in fig. 1, 2 and 3, the present utility model provides a technical solution: the utility model provides an assembled building multi-space coordination dispatch structure, including bearing case 1, the inside of bearing case 1 is fixed with loading board 2, the outer wall connection of bearing case 1 has buckle 5, the top of loading board 2 is provided with main component chamber 3, inner wall one side of main component chamber 3 is connected with cushion 4, the below of bearing board 2 is fixed with division board 7, one side of division board 7 is provided with loading case 6, spout 8 has been seted up to the inner wall opposite side of main component chamber 3, slide 9 has been worn out to the inside of spout 8, bearing case 1 and loading board 2 welded connection, bearing case 1 and cushion 4 bond connection, constitute sliding structure between loading case 6 and the bearing case 1, bearing case 1 separates main component chamber 3 through slide 8 and slide 9, place main component chamber 3 and envelope structural member, main component chamber 3 bond cushion 4 avoids bearing case 1 transportation or hoist and mount process bump with, slide 9 reaches the preset position through the bolt fastening, avoid spacing main component chamber 3 internal component, the space of bearing board 2 below divides multiunit small-size space through division board 7, and be equipped with loading case 6 and place the confusing for setting up and be fit for carrying case 6 and take place the type component, the corresponding type of carrying case 1 and the batch is easy to take place, the batch is convenient for the dispatch is equipped with and is convenient for take place, the corresponding to take place and is in a batch type 3, and is convenient for be assembled to be in a batch type for the size.

Example two

The scheme in the first embodiment is further described below in conjunction with a specific working manner, and the details are described below:

as shown in fig. 1, fig. 2 and fig. 3, as a preferred embodiment, on the basis of the above manner, further, the motor 10 is embedded in the partition plate 7, the power output end of the motor 10 is connected with the bidirectional threaded rod 11, the slide block 12 is sleeved outside the bidirectional threaded rod 11, the bottom end of the loading box 6 is provided with the slide rail 13, the bidirectional threaded rod 11 is in threaded connection with the slide block 12, the slide block 12 forms a sliding structure with the loading box 6 through the motor 10 and the bidirectional threaded rod 11, the loading box 6 is fixedly connected with the loading box 6 through the slide block 12 and the partition plate 7, the components in the same range and different spaces are conveniently scheduled through the groups of loading boxes 6, the bidirectional threaded rod 11 is driven to rotate through the operation of the motor 10, the slide block 12 slides along the bidirectional threaded rod 11, the loading box 6 is driven to slide out of the loading box 1, so that the crane scheduling or the workers can coordinate and schedule the assembly components in regional scope, and meanwhile, the slide rail 13 is arranged at the bottom end of the loading box 6, so that the loading box 6 can stably slide in the loading box 1.

As shown in fig. 1, fig. 2 and fig. 4, as a preferred embodiment, further, on the basis of the above manner, the bottom of the carrying case 1 is fixed with the chassis 14, the hydraulic cylinder 15 is embedded in the chassis 14, the power output end of the hydraulic cylinder 15 is connected with the pushing plate 16, the bottom end of the pushing plate 16 is provided with the roller 17, the pushing plate 16 forms a telescopic structure with the chassis 14 through the hydraulic cylinder 15, the hydraulic cylinder 15 is uniformly distributed with respect to the bottom end of the chassis 14, the pushing plate 16 is conveniently driven to stretch and move by the working of the hydraulic cylinder 15, so that the roller 17 is pushed to penetrate out of the chassis 14, the carrying case 1 flexibly moves, and after being manually or mechanically dragged to a corresponding accurate position for coordination, the components are conveniently scheduled through the crane.

From the above, it can be seen that:

the utility model aims at the technical problems that: in the construction process of the existing fabricated building, some prefabricated components are placed in a disordered way, and management and control are easy to be confused, so that the prefabricated building cannot be effectively scheduled through a crane; the technical scheme of each embodiment is adopted. Meanwhile, the implementation process of the technical scheme is as follows:

the carrying case 1 separates the main component chamber 3 through loading board 2 in the top, be convenient for place the great wall, enclosure type components such as window, main component chamber 3 avoids taking place to collide with and cause the damage through cushion 4 in the transportation, loading board 2 bottom space is divided into a plurality of spaces through division board 7, and install loading case 6, place the small-size component with enclosure type component looks adaptation through loading case 6, be convenient for a regional scope equipment corresponds a batch, it is comparatively sorted to coordinate the dispatch and avoid confusion, simultaneously can carry out classification through multiunit space and place, loading case 1 is convenient for the crane dispatch through welded buckle 5, slide 9 slides behind the spout 8 that sets up through loading case 1 and corresponds the position, after fixed slide 9 through the bolt, it avoids droing to carry out to limit the main component intracavity 3 component, the motor 10 work of inlaying through division board 7, drive two-way threaded rod 11 rotates, two-way 11 runs through slider 12 and threaded connection, simultaneously two-way threaded rod 11 one end cover establishes the bearing, inlay bolt is at division board 7 inner wall, make two-way threaded rod 11 drive slider 12 stably promote the box 6 to slide out loading case 1, be convenient for carry out the crane frame or manual work to carry out the dispatch to the interior frame, can carry out classification through multiunit space, carry out classification place through multiunit space, carry out classification, carry out the hydraulic pressure cylinder 15 is convenient for carrying case 1, carry out the hydraulic pressure is carried out the chassis 15, and is carried out the chassis 15 is carried out the manual work and is carried out the chassis is carried out, and is carried out the chassis 15, and is carried out the flexible, and is carried out the chassis is 15, and is carried out the bottom and is easy to carry out 15, and is carried out the flexible, and is 13.

Through above-mentioned setting, this application must solve above-mentioned technical problem, simultaneously, realizes following technical effect:

the utility model is convenient for carrying out component scheduling in different spaces in the same range through a plurality of groups of loading boxes 6, and the motor 10 works to drive the bidirectional threaded rod 11 to rotate, so that the sliding block 12 slides along the bidirectional threaded rod 11 to drive the loading boxes 6 to slide out of the bearing box 1, thereby facilitating crane scheduling or staff carrying, carrying out coordinated scheduling on assembly components in the regional range, and simultaneously, the bottom end of the loading box 6 is provided with the sliding rail 13, thereby facilitating the stable sliding of the loading box 6 in the bearing box 1;

the utility model is convenient to drive the pushing plate 16 to stretch and move through the hydraulic cylinder 15, thereby pushing the roller 17 to penetrate out of the chassis 14, enabling the carrying case 1 to flexibly move, and facilitating the dispatching of components through the crane after manual or mechanical dragging to corresponding accurate positions for coordination.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in 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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