JP3237870U - Solar heat utilization system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solar heat utilization system having enhanced utility value. SOLUTION: A solar heat utilization system 1 is installed on a roof of a building 2 and measures the temperature of a solar hot water panel 41 for warming the introduced water or an antifreeze liquid by solar heat and the temperature of the water or the antifreeze liquid in the solar hot water panel. Inside the first thermometer 8, a heat storage tank 3 installed on the ground or in the ground, storing water or antifreeze liquid heated by a solar hot water panel, and using the stored water or antifreeze liquid as a heat source, and a heat storage tank 3. Based on the measurement results of the second thermometer 9 that measures the temperature of the water or antifreeze liquid, the pump 44 that circulates water or antifreeze liquid from the heat storage tank 3 to the solar hot water panel, and the first thermometer 8 and the second thermometer 9. A control panel 10 for controlling the operation of the pump is provided, and the control panel stops the operation of the pump when the temperature value measured by the first thermometer 8 is equal to or less than a preset value. By doing so, the water or the antifreeze liquid in the solar hot water panel is dropped into the heat storage tank 3. [Selection diagram] Fig. 1

Description

The present invention relates to a solar heat utilization system.

At the United Nations General Assembly in 2015, the Sustainable Development Goals (SDGs) were adopted, and under Goal 7 of "Energy for everyone and cleanly", by 2030, "cheap and reliable for all people". Ensuring access to sustainable modern energy "is required. Under such circumstances, it is expected that a solar heat utilization system using a solar water heater (see, for example, Patent Document 1) will become more and more popular.

Japanese Patent Application Laid-Open No. 2022-038012

In such a solar heat utilization system, it is required to promote differentiation from other solar heat utilization systems and increase the utility value by enhancing the attractiveness as a product.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a solar heat utilization system with enhanced utility value.

(1) The present invention is a solar hot water panel installed on the roof of a building that heats the introduced water or antifreeze with solar heat, and a first thermometer for measuring the temperature of water or antifreeze in the solar hot water panel. And, a heat storage tank installed on the ground or in the ground, which stores water or antifreeze liquid heated by the solar hot water panel, and the stored water or antifreeze liquid is used as a heat source, and water or antifreeze liquid in the heat storage tank. The operation of the second thermometer for measuring the temperature, the pump for circulating water or antifreeze from the heat storage tank to the solar hot water panel, and the operation of the pump based on the measurement results of the first thermometer and the second thermometer. The control panel comprises a control panel for controlling the pump, and the control panel stops the operation of the pump when the temperature value measured by the first thermometer is equal to or less than a preset value. It is a solar heat utilization system characterized by dropping water or an antifreeze liquid in the solar hot water panel into the heat storage tank.

According to the solar heat utilization system according to the present invention, when the value of the temperature of water or antifreeze in the solar hot water panel is equal to or less than a preset value, the operation of the pump is stopped to obtain the solar hot water panel. Since the water or antifreeze in the water is dropped into the heat storage tank, it is possible to prevent the water or antifreeze from freezing in the solar hot water panel.

(2) In the present invention, the control panel also has a preset size difference between the temperature value measured by the first thermometer and the temperature value measured by the second thermometer. The solar heat utilization system according to (1) above, wherein the operation of the pump is started when the temperature exceeds the above.

According to the solar heat utilization system according to the present invention, the difference between the temperature value of water or antifreeze in the solar hot water panel and the temperature value of water or antifreeze in the heat storage tank is set in advance. Since the operation of the pump is started when the temperature exceeds the limit, the solar heat can be efficiently stored.

(3) The present invention also includes a water supply pipe that passes through the heat storage tank, and heat exchange is performed between the water or antifreeze liquid in the heat storage tank and the tap water in the water supply pipe. The solar heat utilization system according to the above (1) or (2).

According to the solar heat utilization system according to the present invention, heat is exchanged between the water or antifreeze liquid heated by the solar hot water panel and the tap water in the heat storage tank, so that the tap water is heated by the solar heat. Can be done.

(4) The present invention is also the solar heat utilization system according to (3) above, comprising a water heater to which tap water is supplied by the water supply pipe that has passed through the heat storage tank.

According to the solar heat utilization system according to the present invention, tap water heated by solar heat is heated by the water heater, so that the energy consumption in the water heater can be reduced.

(5) The present invention is also characterized by comprising a heat exchanger that exchanges heat between the air in the building and the water or antifreeze circulated from the heat storage tank. Or the solar heat utilization system according to (2).

According to the solar heat utilization system according to the present invention, heat exchange is performed between the water or antifreeze liquid heated by the solar hot water panel and the air in the building, so that the building is operated even when there is no sunlight. The air inside can be warmed by the heat of the sun.

(6) The present invention also has an introduction port for introducing air from above in the building, and a first flow path for guiding the air introduced through the introduction port to the underfloor of the building, and the building. It has a discharge port for discharging air from the window side of the floor, and has a second flow path for guiding air guided under the floor of the building by the first flow path to the discharge port under the floor, and the heat. The exchanger is the solar heat utilization system according to (5) above, characterized in that it is installed in the first flow path.

According to the solar heat utilization system according to the present invention, the air warmed by the solar heat is guided under the floor and then discharged by the window, so that the inside of the building can be efficiently warmed.

(7) The present invention is also characterized in that it is installed on the roof of the building, includes a solar panel that generates electricity by sunlight, and operates by the electric power generated by the solar panel (1) or The solar heat utilization system according to (2).

According to the solar heat utilization system according to the present invention, since it is operated by the electric power generated by the solar panel, it is not necessary to rely on a commercial power source, and the load on the environment can be reduced.

According to the solar heat utilization system described in the above (1) to (7) of the present invention, the utility value can be enhanced.

It is a schematic diagram which shows the solar heat utilization system which concerns on embodiment of this invention.

Hereinafter, the solar heat utilization system 1 according to the embodiment of the present invention will be described in detail with reference to the drawings.

First, the solar heat utilization system 1 according to the embodiment will be described with reference to FIG. FIG. 1 is a schematic view showing a solar heat utilization system 1.

The solar heat utilization system 1 shown in FIG. 1 is a system adopted in a building 2 such as a detached house, and realizes hot water supply and heating using the heat of the sun. Specifically, the solar heat utilization system 1 includes a heat storage tank 3, a solar water heater 4, a hot water supply facility 5, a heating facility 6, a photovoltaic power generation facility 7, a first thermometer 8, and a second thermometer 9. , A control panel 10, and the like.

The heat storage tank 3 is installed on the ground or in the ground to store water or antifreeze liquid heated by the solar water heater 4, and the stored water or antifreeze liquid is used as a heat source for the hot water supply equipment 5 and the heating equipment 6.

The solar water heater 4 is a device that uses solar heat to generate hot water. Specifically, the solar water heater 4 includes a solar water heater panel 41, pipes 42, 43, a pump 44, and the like. The solar hot water panel 41 is installed on the roof of the building 2 and heats the water or the antifreeze liquid introduced from the heat storage tank 3 by the solar heat. By connecting the heat storage tank 3 and the solar water heating panel 41, the pipe 42 becomes a pipe for introducing water or antifreeze from the heat storage tank 3 to the solar water heating panel 41. By connecting the solar water heater panel 41 and the heat storage tank 3 to each other, the pipe 43 serves as a pipe for introducing water or antifreeze from the solar water heater panel 41 to the heat storage tank 3. The pump 44 is provided in the middle of the pipe 42, and circulates water or antifreeze from the heat storage tank 3 to the solar hot water panel 41.

The hot water supply facility 5 is a facility for boiling hot water by using solar heat in combination with electricity or gas. Specifically, the hot water supply facility 5 includes a water supply pipe 51, a water heater 52, a faucet 53, and the like. The water supply pipe 51 is provided so as to pass through the heat storage tank 3. As a result, heat exchange is performed between the water or antifreeze liquid in the heat storage tank 3 and the tap water in the water supply pipe 51. The water heater 52 is provided in the middle of the water supply pipe 51, and tap water is supplied by the water supply pipe 51 that has passed through the heat storage tank 3. The water heater 52 is a device that uses electricity or gas to boil water. The faucet 53 is attached to the tip of the water supply pipe 51 and serves as an outlet for tap water or tap water heated by the heat storage tank 3 or the water heater 52.

The heating facility 6 is a facility that heats the inside of the building 2 by using the solar heat. Specifically, the heating equipment 6 includes a first flow path 61, a second flow path 62, a blower 63, a heat exchanger 64, and the like. The first flow path 61 has an introduction port 61a. The introduction port 61a introduces air into the first flow path 61 from above in the building 2. The first flow path 61 guides the air introduced through the introduction port 61a from above the building to below the floor. The second flow path 62 has a discharge port 62a. The discharge port 62a discharges air from the window side on the floor of the building 2. The second flow path 62 guides the air guided under the floor of the building 2 by the first flow path 61 to the discharge port 62a under the floor. The blower 63 is provided at an appropriate position in either the first flow path 61 or the second flow path 62, and creates an air flow in the first flow path 61 and the second flow path 62.

The heat exchanger 64 is a device that warms air by utilizing solar heat. Specifically, the heat exchanger 64 includes a radiator 641, pipes 642, 643, a pump 644, and the like. The radiator 641 is installed in the first flow path 61 and exchanges heat between the air in the building 2, that is, the first flow path 61, and the water or antifreeze liquid circulating from the heat storage tank 3. By connecting the heat storage tank 3 and the radiator 641 to the pipe 642, the pipe 642 serves as a pipe for introducing water or antifreeze from the heat storage tank 3 to the radiator 641. By connecting the radiator 641 and the heat storage tank 3 to each other, the pipe 643 serves as a pipe for introducing water or antifreeze from the radiator 641 to the heat storage tank 3. The pump 644 is provided in the middle of the pipe 643 and circulates water or antifreeze from the heat storage tank 3 to the radiator 641.

The photovoltaic power generation facility 7 is a facility that generates electricity with sunlight. Specifically, the photovoltaic power generation facility 7 includes a solar panel 71, a battery 72, a power transmission cable 73, a power cable 74, and the like. The solar panel 71 is installed on the roof of the building 2 and generates electricity by sunlight. The battery 72 stores the electric power generated by the solar panel 71, and the entire solar heat utilization system 1 operates by the stored electric power. Surplus power is sold as commercial power, and insufficient power uses commercial power. The power transmission cable 73 is connected between the solar panel 71 and the battery 72, so that the electric power generated by the solar panel 71 is supplied to the battery 72. The power cable 74 is connected between the battery 72 and each part of the solar heat utilization system 1, so that the electric power stored in the battery 72 is supplied to each part of the solar heat utilization system 1.

The first thermometer 8 measures the temperature of water or antifreeze in the solar hot water panel 41, and transmits the measured temperature value as a signal to the control panel 10. The second thermometer 9 measures the temperature of water or antifreeze in the heat storage tank 3, and transmits the measured temperature value as a signal to the control panel 10. The control panel 10 controls the operation of various parts of the solar heat utilization system 1. For example, the control panel 10 controls the operation of the pump 44 based on the measurement results of the first thermometer 8 and the second thermometer 9. Specifically, the control panel 10 stops the operation of the pump 44 when the temperature value measured by the first thermometer 8 is equal to or less than a preset value (for example, 0 ° C.). The water or antifreeze liquid in the solar hot water panel 41 is dropped into the heat storage tank 3. Further, in the control panel 10, the difference between the temperature value measured by the first thermometer 8 and the temperature value measured by the second thermometer 9 is a preset size (for example, 20 ° C.). When the difference) is exceeded, the operation of the pump 44 is started.

As described above, according to such a solar heat utilization system 1, the operation of the pump 44 is performed when the value of the temperature of water or antifreeze in the solar hot water panel 41 is equal to or less than a preset value. By stopping, the water or the antifreeze liquid in the solar hot water panel 41 is dropped into the heat storage tank 3, so that it is possible to prevent the water or the antifreeze liquid from freezing in the solar hot water panel 41.

Further, according to such a solar heat utilization system 1, the difference between the temperature value of water or antifreeze in the solar hot water panel 41 and the temperature value of water or antifreeze in the heat storage tank 3 is set in advance. Since the operation of the pump 44 is started when the size exceeds the specified size, the solar heat can be efficiently stored.

Further, according to such a solar heat utilization system 1, heat exchange is performed between the water or antifreeze liquid heated by the solar hot water panel 41 and tap water in the heat storage tank 3, so that tap water is used. It can be heated by the heat of the sun.

Further, according to such a solar heat utilization system 1, tap water heated by solar heat is heated by the water heater 52, so that the energy consumption in the water heater 52 can be reduced.

Further, according to such a solar heat utilization system 1, heat exchange is performed between the water or antifreeze liquid heated by the solar hot water panel 41 and the air in the building 2, so that there is no sunlight. However, the air inside the building 2 can be warmed by the solar heat.

Further, according to such a solar heat utilization system 1, since the air warmed by the solar heat is guided under the floor and then discharged by the window, the inside of the building 2 can be efficiently warmed.

Further, according to such a solar heat utilization system 1, since it is operated by the electric power generated by the solar panel 71, it is not necessary to rely on a commercial power source, and the load on the environment can be reduced.

The present invention is not limited to the above embodiment, and various changes can be made without departing from the spirit and technical idea. That is, the position, size, length, shape, material, quantity, etc. of each configuration can be changed as appropriate.

1 Solar heat utilization system 2 Building 3 Heat storage tank 4 Solar hot water heater 41 Solar hot water panel 42, 43 Piping 44 Pump 5 Hot water supply equipment 51 Water supply pipe 52 Water heater 53 Faucet 6 Heating equipment 61 1st flow path 61a Introductory port 62 2nd flow path 62a Outlet 63 Blower 64 Heat exchanger 641 Radiator 642,643 Piping 644 Pump 7 Solar power generation equipment 71 Solar panel 72 Battery 73 Transmission cable 74 Power cable 8 1st thermometer 9 2nd thermometer 10 Control panel

Claims (7)

A solar hot water panel installed on the roof of a building that heats the introduced water or antifreeze with solar heat,
A first thermometer that measures the temperature of water or antifreeze in the solar water heater,
A heat storage tank installed on the ground or in the ground to store water or antifreeze heated by the solar hot water panel, and the stored water or antifreeze is used as a heat source.
A second thermometer that measures the temperature of water or antifreeze in the heat storage tank,
A pump that circulates water or antifreeze from the heat storage tank to the solar hot water panel,
A control panel for controlling the operation of the pump based on the measurement results of the first thermometer and the second thermometer is provided.
When the temperature value measured by the first thermometer is equal to or less than a preset value, the control panel stops the operation of the pump to cause water or antifreeze in the solar hot water panel. A solar heat utilization system characterized by dropping the water into the heat storage tank. The control panel takes the opportunity that the difference between the temperature value measured by the first thermometer and the temperature value measured by the second thermometer exceeds a preset size. The solar heat utilization system according to claim 1, wherein the operation of the pump is started. A water supply pipe that passes through the heat storage tank is provided.
The solar heat utilization system according to claim 1 or 2, wherein heat exchange is performed between the water or the antifreeze liquid in the heat storage tank and the tap water in the water supply pipe. The solar heat utilization system according to claim 3, further comprising a water heater to which tap water is supplied by the water supply pipe that has passed through the heat storage tank. The solar heat utilization system according to claim 1 or 2, further comprising a heat exchanger that exchanges heat between the air in the building and the water or antifreeze circulated from the heat storage tank. A first flow path having an introduction port for introducing air from above in the building and guiding the air introduced through the introduction port to the underfloor of the building.
It has a discharge port for discharging air from a window on the floor of the building, and includes a second flow path for guiding air guided under the floor of the building by the first flow path to the discharge port under the floor.
The solar heat utilization system according to claim 5, wherein the heat exchanger is installed in the first flow path. Installed on the roof of the building, equipped with solar panels that generate electricity with sunlight,
The solar heat utilization system according to claim 1 or 2, wherein the solar panel is operated by electric power generated by the solar panel.

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