CN215859283U

CN215859283U - Building site intelligence worker canopy

Info

Publication number: CN215859283U
Application number: CN202121887414.2U
Authority: CN
Inventors: 刘健; 张明刚; 曹恬野
Original assignee: Chongqing Silda Information Technology Co ltd
Current assignee: Chongqing Silda Information Technology Co ltd
Priority date: 2021-08-12
Filing date: 2021-08-12
Publication date: 2022-02-18
Anticipated expiration: 2031-08-12

Abstract

The utility model relates to the technical field of work sheds, in particular to an intelligent work shed for a construction site, which comprises a work shed body and is characterized in that: the work shed comprises a work shed body, a working shed body and a temperature sensor, wherein a self-power supply device is arranged on a ceiling of the work shed body, a cooling water guide pipe and a heat insulation water guide pipe are laid in the wall of the work shed body in a square wave shape, the cooling water guide pipe and the heat insulation water guide pipe are respectively connected with a refrigeration box and an auxiliary heating box through two water pumps, and the work shed body is internally provided with the temperature sensor and a PLC (programmable logic controller); in practical application, the PLC controls refrigeration or auxiliary heating according to a temperature signal of the temperature sensor, when refrigeration is needed, the water pump guides water refrigerated by the refrigeration box into the cooling water guide pipe to cool the wall body, so that the whole work shed is cooled, and when auxiliary heating is needed, the water pump guides water heated by the auxiliary heating box into the heat insulation water guide pipe to heat the wall body, so that the whole work shed is heated.

Description

Building site intelligence worker canopy

Technical Field

The utility model relates to the technical field of work sheds, in particular to an intelligent work shed for a construction site.

Background

At the building site, need set up so that supply the workman to have a rest of temporary rest ground, especially in the hot summer, but the current cooling method all realizes through fan or installation air conditioner in the hot summer, and this kind of mode need pull the electric wire on the building site, and not only the construction is troublesome, and the energy consumption is very big moreover, has the potential safety hazard in the complicated construction place of building site.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an intelligent construction site work shed aiming at the defects, and the intelligent construction site work shed has the characteristic of cooling in summer and keeping warm in winter.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the utility model provides a building site intelligence worker canopy, includes the worker canopy body, its characterized in that: the work shed comprises a work shed body and is characterized in that a ceiling of the work shed body is provided with a self-power supply device, a cooling water guide pipe and a heat insulation water guide pipe are laid in the wall of the work shed body in a square wave shape, the cooling water guide pipe and the heat insulation water guide pipe are respectively connected with a refrigeration box and an auxiliary heating box through two water pumps, a temperature sensor and a PLC (programmable logic controller) are arranged in the work shed body, the self-power supply device is respectively electrically connected with power input ends of the refrigeration box, the auxiliary heating box, the two water pumps, the temperature sensor and the PLC, the output end of the temperature sensor is electrically connected with the input end of the PLC, and the output end of the PLC is respectively electrically connected with the input ends of the refrigeration box, the auxiliary heating box and the two water pumps.

Further, the refrigeration case includes first casing, second casing and sets up the refrigeration pipe in the second casing, the refrigeration pipe with the second casing forms a closed box that the inside is filled with chlorinated alkane zeotropic mixture refrigerant that does not contain chlorine, the play water end of refrigeration pipe and the end of intaking are all worn out first casing outwards extends to be connected respectively the water pump with the play water end of cooling aqueduct, the second casing is located in the first casing, first casing with be equipped with the semiconductor refrigeration piece between the second casing, the power input end of semiconductor refrigeration piece with self-power supply device's output electricity is connected, the signal input part of semiconductor refrigeration piece with the output electricity of PLC controller is connected.

Furthermore, the auxiliary heating box comprises a third shell, a fourth shell and an auxiliary heating pipe arranged in the fourth shell, the auxiliary heating pipe and the fourth shell form a closed box body filled with heat-preservation and heat-conduction foam, the water outlet end and the water inlet end of the auxiliary heating pipe penetrate out of the third shell, the third shell extends outwards to be connected with the water pump and the water outlet end of the heat-preservation water guide pipe respectively, the fourth shell is located in the third shell, an electric heating wire is arranged between the third shell and the fourth shell, the power input end of a controller of the electric heating wire is electrically connected with the output end of the self-power supply device, and the signal input end of the controller of the electric heating wire is electrically connected with the output end of the PLC.

Furthermore, the self-powered device comprises a solar cell panel obliquely arranged on the ceiling and a storage battery electrically connected with the solar cell panel, and the output end of the storage battery is electrically connected with the power input ends of the refrigeration box, the auxiliary heating box, the two water pumps, the temperature sensor and the PLC respectively.

Furthermore, the wall body of the work shed body sequentially comprises a galvanized steel sheet layer, a heat insulation foam layer, a cooling water conduit, a heat preservation water conduit layer and a galvanized steel sheet layer from outside to inside.

Furthermore, the refrigeration pipe and the auxiliary heating pipe are all multilayer pipelines which are uniformly arranged in the second shell and the fourth shell from left to right, and each layer of pipeline is in a square waveform shape.

The utility model has the beneficial effects that:

in practical application, the temperature sensor feeds a temperature signal back to the PLC, the PLC controls refrigeration or auxiliary heating according to the temperature signal, when refrigeration is needed, the water pump guides water refrigerated by the refrigeration box into the cooling water guide pipe to cool the wall body, so that the whole work shed is cooled, and when auxiliary heating is needed, the water pump guides water heated by the auxiliary heating box into the heat insulation water guide pipe to heat the wall body, so that the whole work shed is heated.

Drawings

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

FIG. 2 is a schematic cross-sectional view of the refrigeration case of the present invention;

FIG. 3 is a schematic sectional view of the auxiliary heating tank of the present invention.

The greenhouse body 1 in the figure; a cooling water guide pipe 2; a warm-keeping aqueduct 3; a water pump 4; a refrigeration box 5; a first housing 51; a second housing 52; a cooling pipe 53; a semiconductor refrigeration plate 54; an auxiliary heating box 6; a third housing 61; a fourth housing 62; an auxiliary heat pipe 63; an electric heating wire 64; a solar panel 7.

Detailed Description

As shown in fig. 1 to 3, a building site intelligence worker canopy, including worker canopy body 1, its characterized in that: the ceiling of the work shed body 1 is provided with a self-power supply device, a cooling water guide pipe 2 and a heat insulation water guide pipe 3 are laid in the wall of the work shed body 1 in a square wave shape, the cooling water guide pipe 2 and the heat insulation water guide pipe 3 are respectively connected with a refrigeration box 5 and an auxiliary heating box 6 through two water pumps 4, a temperature sensor and a PLC controller are arranged in the work shed body 1, the self-power supply device is respectively electrically connected with the power input ends of the refrigeration box 5, the auxiliary heating box 6, the two water pumps 4, the temperature sensor and the PLC controller, the output end of the temperature sensor is electrically connected with the input end of the PLC controller, and the output end of the PLC controller is respectively electrically connected with the input ends of the refrigeration box 5, the auxiliary heating box 6 and the two water pumps 4.

In practical application, the temperature sensor feeds a temperature signal back to the PLC, the PLC controls refrigeration or auxiliary heating according to the temperature signal, when refrigeration is needed, the water pump 4 guides water which is refrigerated by the refrigeration box 5 into the cooling water guide pipe 2 to cool the wall body, so that the whole work shed is cooled, when auxiliary heating is needed, the water pump 4 guides water which is heated by the auxiliary heating box 6 into the heat-insulation water guide pipe 3 to heat the wall body, so that the whole work shed is heated.

As shown in fig. 1 to 3, the refrigeration box 5 includes a first housing 51, a second housing 52 and a refrigeration pipe 53 disposed in the second housing 52, the refrigeration pipe 53 and the second housing 52 form a closed box body filled with a chlorinated alkane non-azeotropic mixture refrigerant without chlorine, a water outlet end and a water inlet end of the refrigeration pipe 53 both penetrate through the first housing 51 and extend outward to be connected with the water pump 4 and the water outlet end of the cooling water conduit 2, respectively, the second housing 52 is located in the first housing 51, a semiconductor refrigeration sheet 54 is disposed between the first housing 51 and the second housing 52, a power input end of the semiconductor refrigeration sheet 54 is electrically connected with an output end of the self-powered device, and a signal input end of the semiconductor refrigeration sheet 54 is electrically connected with an output end of the PLC controller; in this embodiment, the refrigerating surface of the semiconductor refrigerating sheet 54 is close to the second housing 52, and the refrigerant in the second housing 52 and the semiconductor refrigerating sheet 54 perform double refrigeration on the water in the refrigerating pipe 53, so that the refrigerating efficiency of the refrigerating box 5 is effectively improved, and the refrigerating effect is enhanced.

As shown in fig. 1 to 3, the auxiliary heating box 6 includes a third casing 61, a fourth casing 62 and an auxiliary heating pipe 63 disposed in the fourth casing 62, the auxiliary heating pipe 63 and the fourth casing 62 form a closed box body filled with a heat-insulating and heat-conducting foam, a water outlet end and a water inlet end of the auxiliary heating pipe 63 both penetrate through the third casing 61 and extend outwards to connect the water pump 4 and a water outlet end of the heat-insulating and water-guiding pipe 3, respectively, the fourth casing 62 is disposed in the third casing 61, an electric heating wire 64 is disposed between the third casing 61 and the fourth casing 62, a power input end of a controller of the electric heating wire 64 is electrically connected with an output end of the thermal insulation and water-guiding device, and a signal input end of the controller of the electric heating wire 64 is electrically connected with an output end of the PLC controller; in this embodiment, the electric heating wire 64 heats the fourth casing 62, and then the auxiliary heat pipe 63 in the fourth casing 62 is heated, and the arrangement of the heat-insulating and heat-conducting foam can effectively reduce heat loss and improve heating efficiency.

As shown in fig. 1 to 3, the self-powered device includes a solar panel 7 obliquely disposed on the ceiling and a storage battery electrically connected to the solar panel 7, and an output end of the storage battery is electrically connected to the power input ends of the refrigeration box 5, the auxiliary heating box 6, the two water pumps 4, the temperature sensor and the PLC controller, respectively; in this embodiment, solar cell panel 7 converts solar energy into the electric energy, the battery is with this electric energy storage simultaneously for temperature sensor, PLC controller, water pump 4, refrigeration case 5 and auxiliary heating case 6 provide required electric energy, realize self power supply, green.

As shown in fig. 1 to 3, the wall body of the work shed body 1 sequentially comprises a galvanized steel sheet layer, a heat insulation foam layer, a cooling aqueduct, a heat preservation aqueduct layer and a galvanized steel sheet layer from outside to inside; in this embodiment, the arrangement of the heat insulation foam effectively reduces the loss in the refrigeration or auxiliary heating process of the present invention.

As shown in fig. 1 to 3, the cooling pipes 53 and the auxiliary heating pipes 63 are all multi-layer pipes, and are respectively and uniformly arranged in the second shell 52 and the fourth shell 62 from left to right, and each layer of pipe is in a square wave shape; in this embodiment, the arrangement and arrangement of the pipes in the second and

fourth casings

52 and 62 are effective to increase the cooling area of water in the cooling pipe 53 and to increase the heating area of water in the auxiliary heating pipe 63, thereby improving the cooling and heating efficiency.

The specific embodiments described herein are merely illustrative of the spirit of the utility model. Various modifications, additions and substitutions for the described embodiments may be made by those skilled in the art without departing from the scope and spirit of the utility model as defined by the accompanying claims.

Claims

1. The utility model provides a building site intelligence worker canopy, includes worker's canopy body (1), its characterized in that: the ceiling of work shed body (1) is equipped with from power supply unit, be square wave form in the wall body of work shed body (1) and laid cooling aqueduct (2) and cold-proof aqueduct (3), cooling aqueduct (2) and cold-proof aqueduct (3) are connected with refrigeration case (5) and auxiliary heating case (6) through two water pumps (4) respectively, be equipped with temperature sensor and PLC controller in work shed body (1), from power supply unit respectively with refrigeration case (5), auxiliary heating case (6), two water pumps (4), temperature sensor and PLC controller's power input end electricity is connected, temperature sensor's output with the input electricity of PLC controller is connected, the output of PLC controller respectively with the input electricity of refrigeration case (5), auxiliary heating case (6), two water pumps (4) is connected.

2. A worksite intelligent studio as defined in claim 1, wherein: the refrigeration box (5) comprises a first shell (51), a second shell (52) and a refrigeration pipe (53) arranged in the second shell (52), the refrigerating pipe (53) and the second casing (52) form a closed box body filled with chlorine-free chloralkane non-azeotropic mixed refrigerant, the water outlet end and the water inlet end of the refrigerating pipe (53) penetrate through the first shell (51) and extend outwards to be respectively connected with the water pump (4) and the water outlet end of the cooling water guide pipe (2), the second shell (52) is positioned in the first shell (51), a semiconductor refrigerating sheet (54) is arranged between the first shell (51) and the second shell (52), the power supply input end of the semiconductor refrigerating sheet (54) is electrically connected with the output end of the self-powered device, and the signal input end of the semiconductor refrigerating sheet (54) is electrically connected with the output end of the PLC controller.

3. A worksite intelligent studio as defined in claim 2, wherein: the auxiliary heat box (6) comprises a third shell (61), a fourth shell (62) and an auxiliary heat pipe (63) arranged in the fourth shell (62), the auxiliary heat pipe (63) and the fourth shell (62) form a closed box body filled with heat-insulating and heat-conducting foam, the water outlet end and the water inlet end of the auxiliary heat pipe (63) penetrate through the third shell (61) and extend outwards to be respectively connected with the water pump (4) and the water outlet end of the heat-preservation water guide pipe (3), the fourth shell (62) is positioned in the third shell (61), an electric heating wire (64) is arranged between the third shell (61) and the fourth shell (62), the power supply input end of the controller of the electric heating wire (64) is electrically connected with the output end of the self-powered device, and the signal input end of the controller of the electric heating wire (64) is electrically connected with the output end of the PLC controller.

4. A worksite intelligent studio as defined in claim 1, wherein: the self-powered device comprises a solar cell panel (7) obliquely arranged on the ceiling and a storage battery electrically connected with the solar cell panel (7), and the output end of the storage battery is electrically connected with the power input ends of the refrigeration box (5), the auxiliary heating box (6), the two water pumps (4), the temperature sensor and the PLC respectively.

5. A worksite intelligent studio as defined in claim 1, wherein: the wall body of the work shed body (1) sequentially comprises a galvanized steel sheet layer, a heat insulation foam layer, a cooling water conduit, a heat preservation water conduit layer and a galvanized steel sheet layer from outside to inside.

6. A worksite intelligent studio as defined in claim 3, wherein: the refrigeration pipe (53) and the auxiliary heating pipe (63) are all multilayer pipelines which are respectively and uniformly arranged in the second shell (52) and the fourth shell (62) from left to right, and each layer of pipeline is in a square wave shape.