CN219063631U - Cold radiation continuous temperature regulating system - Google Patents

Abstract

The utility model discloses a cold radiation continuous temperature regulating system, which comprises an underground heat exchange device, wherein a water outlet of the underground heat exchange device is fixedly connected with a water supply pump, one end of the water supply pump is fixedly connected with a water supply tank, one end of the water supply tank is fixedly connected with a first water supply pipeline and a second water supply pipeline, one end of the first water supply pipeline is fixedly connected with a ground heating structure, one end of the second water supply pipeline is fixedly connected with an air conditioning structure, a fresh air structure is arranged on the air conditioning structure, and one end of the fresh air structure is provided with an auxiliary energy supply structure; the utility model is provided with the auxiliary functional structure, the problem of solar energy acquisition time reduction caused by the fact that the solar power generation panel cannot be installed in the south in practical application is solved by the mirror plate structure, and when heating, the communication port between the auxiliary air pipe and the air inlet pipe can be opened, so that air passing through the auxiliary energy supply structure is heated, the effect of a solar heat collector can be replaced, and the cost for arranging the solar heat collector is saved.

Description

Cold radiation continuous temperature regulating system

Technical Field

The utility model belongs to the technical field of radiation cooling, and particularly relates to a cold radiation continuous temperature regulating system.

Background

The radiation cooling refers to a technical method for reducing the temperature of one or more surfaces in the inner surface of the enclosure structure to form a cold radiation surface and reducing the temperature by means of radiation heat exchange between the radiation surface and the human body, furniture and other surfaces of the enclosure structure.

In the solar-driven radiation cooling air conditioner and the radiation cooling method (publication No. CN 113899029A), a solar generator and a solar collector are arranged to provide power and heat for the cooling device respectively, but in practical use, the solar generator and the solar collector are limited in power, so that the areas of the solar generator and the solar collector are required to be increased in order to increase the generated energy and the supplied heat, but the building sun-facing area is limited, and meanwhile, the solar generator and the solar collector are high in cost, and the building sun-facing area is likely to be insufficient, so that the requirements cannot be met.

Therefore, it is necessary to invent a cold radiation continuous tempering system to solve the above problems.

Disclosure of Invention

In view of the above, the present utility model provides a continuous temperature control system for cold radiation to solve the above-mentioned problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a cold radiation continuous temperature regulation system, includes underground heat transfer device, underground heat transfer device's delivery port fixedly connected with working shaft, the one end fixedly connected with working shaft's of working shaft supply tank, the first working shaft of one end fixedly connected with and second working shaft of working shaft, the one end fixedly connected with ground of first working shaft warms up the structure, the one end fixedly connected with air conditioner structure of second working shaft, install fresh air structure on the air conditioner structure, auxiliary energy supply structure is installed to the one end of fresh air structure, underground heat transfer device's water inlet fixedly connected with return water pump, the one end fixedly connected with return water tank of return water pump.

Further, the floor heating structure comprises a temperature control device, one end of the temperature control device is fixedly connected with a water separator, one end of the water separator is fixedly connected with a capillary pipeline, a water outlet of the capillary pipeline is fixedly connected with a water collector, one end of the water collector passes through the temperature control device, one end of the water collector is fixedly connected with a first water return pipeline, and one end of the first water return pipeline is fixedly connected with a water return tank.

Further, the air conditioner structure comprises a hydraulic balance distributor, a water outlet of the hydraulic balance distributor is fixedly connected with a fan coil, a water outlet of the fan coil passes through the hydraulic balance distributor, a second water return pipeline is fixedly connected with a water outlet of the fan coil, and one end of the second water return pipeline is fixedly connected with a water return tank.

Further, the new trend structure includes the new trend unit, the air outlet and the fan coil phase-match of new trend unit, the one end fixedly connected with air-supply line of new trend unit, the middle part and the auxiliary energy supply structure of air-supply line are linked together.

Further, the auxiliary energy supply structure comprises a fixed frame, the fixed frame is installed on the outer wall, a solar power generation plate is fixedly installed on the inner side of the fixed frame, the solar power generation plate is electrically connected with an electric storage device, the electric storage device is located on the inner wall of the outer wall, and the electric storage device is electrically connected with a water supply pump and a water return pump.

Further, the mirror plate structure is vertically installed between solar panel top and the bottom, all fixed auxiliary air pipe of having seted up between the both sides side of solar panel, the one end of auxiliary air pipe all alternates the outer wall, and its tip and air-supply line fixed connection, the solenoid valve is installed to auxiliary air pipe and the junction of air-supply line, the inner wall laminating seal of fixed frame installs the glass cover, one side protrusion fixed frame of glass cover.

Further, the bottom of the glass cover is provided with ventilation holes, and the ventilation holes are inserted into the fixed frame to be communicated with the outside.

The utility model has the technical effects and advantages that:

the solar energy heat collector is characterized in that the auxiliary energy supply structure is arranged, the mirror plate in the mirror plate structure is matched with the solar direction and the wall surface direction, when the solar angle is deviated, sunlight and sunlight refracted by the solar energy power generation plate can be reflected back to the solar energy power generation plate, the problem that the solar energy acquisition time and efficiency are reduced due to the fact that the solar energy power generation plate cannot be installed in the south is solved, when the solar energy heat collector is used for cooling in summer, the electromagnetic valve seals the communication port between the auxiliary air pipe and the air inlet pipe, the device normally operates, and when the solar energy heat collector is used for heating in winter, the inner wall of the fixed frame is attached to and sealed with the glass cover, so that a greenhouse-like structure is formed inside the glass cover, the temperature inside the glass cover rises, part of light energy is converted into heat energy due to the fact that the mirror plate structure cannot be completely refracted, the temperature inside the glass cover rises further, and the communication port between the auxiliary air pipe and the air inlet pipe is opened at the moment, so that external air must pass through the auxiliary energy supply structure.

Additional features and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model. The objectives and other advantages of the utility model may be realized and attained by the structure particularly pointed out in the written description and drawings.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a schematic view of the structure of the glass cover of the present utility model;

FIG. 3 is a schematic view of a mirror plate structure of the present utility model.

In the figure: 1. an underground heat exchange device; 2. a water supply pump; 3. a water supply tank; 4. a first water supply line; 5. a second water supply line; 6. a floor heating structure; 601. a temperature control device; 602. a water separator; 603. a capillary line; 604. a water collector; 605. a first water return line; 7. an air conditioning structure; 701. a hydraulic balance distributor; 702. a fan coil; 703. a second water return line; 8. a fresh air structure; 801. a fresh air unit; 802. an air inlet pipe; 9. an auxiliary energy supply structure; 901. a fixed frame; 902. a solar power generation panel; 903. an electric storage device; 904. a mirror plate structure; 905. an auxiliary air pipe; 906. an electromagnetic valve; 907. a glass cover; 908. ventilation holes; 10. a water return pump; 11. and (5) returning to the water tank.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to the accompanying drawings 1-3 of the specification, the utility model provides a cold radiation continuous temperature regulating system, which comprises an underground heat exchange device 1, wherein a water outlet of the underground heat exchange device 1 is fixedly connected with a water supply pump 2, one end of the water supply pump 2 is fixedly connected with a water supply tank 3, one end of the water supply tank 3 is fixedly connected with a first water supply pipeline 4 and a second water supply pipeline 5, one end of the first water supply pipeline 4 is fixedly connected with a ground heating structure 6, one end of the second water supply pipeline 5 is fixedly connected with an air conditioning structure 7, a fresh air structure 8 is arranged on the air conditioning structure 7, one end of the fresh air structure 8 is provided with an auxiliary energy supply structure 9, a water inlet of the underground heat exchange device 1 is fixedly connected with a water return pump 10, and one end of the water return pump 10 is fixedly connected with a water return tank 11.

The utility model mainly uses the characteristic that the temperature of underground shallow soil is kept at about 10-20 ℃ throughout the year, the medium in the underground heat exchange device 1 circulates and exchanges heat with the soil in a closed mode to achieve the purpose of cooling and heating, heat in a building is transferred to the ground through a water supply pump 2 and a water return pump 10 in summer to cool the building, low-level heat energy in the ground is improved in grade through the water supply pump 2 and the water return pump 10 in winter to heat the building, water flow is sent into a water supply tank 3 from the underground heat exchange device 1 through the water supply pump 2, one water flow enters a ground heating structure 6 through a first water supply pipeline 4, the other water flow enters an air conditioning structure 7 through a second water supply pipeline 5, fresh air is blown and exchanges heat with the air conditioning structure 7 at the moment, the purpose of cooling and heating is achieved, and the two water flows after heat exchange enter a water return tank 11 through a first water return pipeline 605 and a second water return pipeline 703 respectively, and are sent into the underground heat exchange device 1 through the water return pump 10 for next round circulation.

As shown in fig. 1, as a specific embodiment of the present utility model, the floor heating structure 6 includes a temperature control device 601, one end of the temperature control device 601 is fixedly connected with a water separator 602, one end of the water separator 602 is fixedly connected with a capillary pipeline 603, a water outlet of the capillary pipeline 603 is fixedly connected with a water collector 604, one end of the water collector 604 passes through the temperature control device 601, one end of the water collector 604 is fixedly connected with a first water return pipeline 605, and one end of the first water return pipeline 605 is fixedly connected with a water return tank 11.

When the water flow enters the temperature control device 601 from the first water supply pipeline 4 in use, the temperature control device 601 is arranged indoors, the indoor temperature and humidity are monitored, the water outlet temperature and speed are continuously adjusted according to the indoor dew point temperature, then the water flow enters the capillary pipeline 603 through the water separator 602 for radiation cooling or heating, the water flow after heat exchange enters the temperature control device 601 again through the water collector 604, and finally enters the water return tank 11 through the first water return pipeline 605.

As shown in fig. 1, as a specific embodiment of the present utility model, the air conditioning structure 7 includes a hydraulic balance distributor 701, a water outlet of the hydraulic balance distributor 701 is fixedly connected with a fan coil 702, a water outlet of the fan coil 702 passes through the hydraulic balance distributor 701, a water outlet of the fan coil 702 is fixedly connected with a second water return pipeline 703, one end of the second water return pipeline 703 is fixedly connected with a water return tank 11, the fresh air structure 8 includes a fresh air unit 801, an air outlet of the fresh air unit 801 is matched with the fan coil 702, one end of the fresh air unit 801 is fixedly connected with an air inlet pipe 802, and a middle part of the air inlet pipe 802 is communicated with the auxiliary energy supply structure 9.

When the utility model is used, water flow enters the balance distributor from the second water supply pipeline 5 and then enters the fan coil 702, and because the air outlet of the fresh air unit 801 is matched with the fan coil 702, the fresh air unit 801 exchanges heat with the fan coil 702 to supply cold or heat indoors, and the water flow after heat exchange enters the water return tank 11 through the second water return pipeline 703.

As shown in fig. 1 to 3, as a specific embodiment of the present utility model, the auxiliary power supply structure 9 includes a fixed frame 901, the fixed frame 901 is installed on an outer wall, a solar power panel 902 is fixedly installed on the inner side of the fixed frame 901, the solar power panel 902 is electrically connected to an electric storage device 903, the electric storage device 903 is located on the inner wall of the outer wall, the solar direct irradiation is avoided, the temperature is too high, and the electric storage device 903 is electrically connected to the water supply pump 2 and the water return pump 10.

The solar power generation panel 902 is arranged, light energy is converted into electric energy and stored in the electric storage device 903, electric power in the electric storage device 903 is extracted to supply power to the water supply pump 2 and the water return pump 10 when needed, and the solar power generation panel 902 can be installed with a larger area on the sunny side because a solar heat collector is not installed, so that the power supply deficiency caused by the power problem is overcome, and the device is more in line with the actual application requirements.

As shown in fig. 2-3, as a specific embodiment of the present utility model, a mirror structure 904 is vertically installed between the top end and the bottom end of the solar power panel 902, an auxiliary air duct 905 is fixedly installed between two sides of the solar power panel 902, one end of the auxiliary air duct 905 is inserted into an outer wall, the end of the auxiliary air duct 905 is fixedly connected with the air inlet duct 802, an electromagnetic valve 906 is installed at the connection position of the auxiliary air duct 905 and the air inlet duct 802, a glass cover 907 is installed on the inner wall of the fixed frame 901 in a bonding and sealing manner, one side of the glass cover 907 protrudes out of the fixed frame 901, an air hole 908 is formed at the bottom end of the glass cover 907, and the air hole 908 is inserted into the fixed frame 901 to be communicated with the outside.

According to the solar energy heat collector, the mirror plate structure 904 is arranged, the mirror plate in the mirror plate structure 904 is matched with the solar direction and the wall surface direction, when the solar angle is deviated, sunlight and sunlight refracted by the solar energy power panel 902 can be reflected back to the solar energy power panel 902, the problems of solar energy acquisition time and efficiency reduction caused by the fact that the solar energy power panel 902 cannot be installed in the south in practical application are solved, when the solar energy heat collector is used for cooling in summer, the electromagnetic valve 906 seals the communication port between the auxiliary air pipe 905 and the air inlet pipe 802, the solar energy heat collector normally operates, and when heating in winter, the inner wall of the fixing frame 901 is attached and sealed with the glass cover 907, so that a greenhouse-like structure is formed inside the glass cover 907, the internal temperature of the glass cover 907 is increased, part of light energy can be converted into heat energy due to the fact that the sunlight cannot be completely refracted by the mirror plate structure 904, the electromagnetic valve 906 opens the communication port between the auxiliary air pipe 905 and the air inlet pipe 802, the external air must pass through the auxiliary energy supply structure 9, the air passing through the auxiliary energy supply structure 9 can be heated, and utilized by the structure 8, and the solar energy collector can replace the solar energy collector with the auxiliary structure 9, and the energy collector can be used for saving the energy heat collector.

Although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (7)

1. A continuous temperature regulation system for cold radiation, comprising an underground heat exchange device (1), characterized in that: the utility model discloses a water supply pump, including underground heat transfer device (1), delivery port fixedly connected with working shaft (2) of underground heat transfer device (1), the one end fixedly connected with working shaft (3) of working shaft (2), the one end fixedly connected with first water supply line (4) and second water supply line (5) of working shaft (3), the one end fixedly connected with ground heating structure (6) of first water supply line (4), the one end fixedly connected with air conditioning structure (7) of second water supply line (5), install new trend structure (8) on air conditioning structure (7), supplementary energy supply structure (9) are installed to the one end of new trend structure (8), the water inlet fixedly connected with return water pump (10) of underground heat transfer device (1), the one end fixedly connected with return water tank (11) of return water pump (10).

2. A cold radiation continuous tempering system according to claim 1, wherein: the floor heating structure (6) comprises a temperature control device (601), one end fixedly connected with water knockout drum (602) of temperature control device (601), one end fixedly connected with capillary pipeline (603) of water knockout drum (602), delivery port fixedly connected with water collector (604) of capillary pipeline (603), one end of water collector (604) is through temperature control device (601), just one end fixedly connected with first water return pipeline (605) of water collector (604), one end fixedly connected with water return tank (11) of first water return pipeline (605).

3. A cold radiation continuous tempering system according to claim 1, wherein: the air conditioner structure (7) comprises a hydraulic balance distributor (701), a water outlet of the hydraulic balance distributor (701) is fixedly connected with a fan coil (702), a water outlet of the fan coil (702) passes through the hydraulic balance distributor (701), a water outlet of the fan coil (702) is fixedly connected with a second water return pipeline (703), and one end of the second water return pipeline (703) is fixedly connected with a water return tank (11).

4. A cold radiation continuous tempering system according to claim 1, wherein: fresh air structure (8) are including fresh air handling unit (801), the air outlet and the fan coil (702) phase-match of fresh air handling unit (801), the one end fixedly connected with air-supply line (802) of fresh air handling unit (801), the middle part and the auxiliary energy supply structure (9) of air-supply line (802) are linked together.

5. A cold radiation continuous tempering system according to claim 4, wherein: the auxiliary energy supply structure (9) comprises a fixed frame (901), the fixed frame (901) is installed on an outer wall, a solar power generation plate (902) is fixedly installed on the inner side of the fixed frame (901), the solar power generation plate (902) is electrically connected with an electric storage device (903), the electric storage device (903) is located on the inner wall of the outer wall, and the electric storage device (903) is electrically connected with a water supply pump (2) and a water return pump (10).

6. A cold radiation continuous tempering system according to claim 5, wherein: the solar energy power generation panel (902) top and bottom between vertical install mirror plate structure (904), all fixed auxiliary air pipe (905) of having seted up between the both sides side of solar energy power generation panel (902), the one end of auxiliary air pipe (905) all alternates the outer wall, and its tip and air-supply line (802) fixed connection, solenoid valve (906) are installed in the junction of auxiliary air pipe (905) and air-supply line (802), glass cover (907) are installed in the laminating of the inner wall laminating seal of fixed frame (901), one side protrusion fixed frame (901) of glass cover (907).

7. A cold radiation continuous tempering system according to claim 6, wherein: an air hole (908) is formed in the bottom end of the glass cover (907), and the air hole (908) is inserted into the fixed frame (901) to be communicated with the outside.

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