JPH11108467A - Solar energy using device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To collect solar heat at a temperature under which the reliability of a power generation module is not deteriorated and eliminate a necessity for providing a space for a heat storage tank separately from a position for installing the module by providing a latent heat storage material which performs a phase change at a temperature not higher than a prescribed temperature in a solar heat collecting module. SOLUTION: A hybrid module receives solar energy and generates power by the power generation cell 3 of a solar photovoltaic power generation module. Heat produced by exhaust heat and the solar energy received by a part having no power generation cell 3 is stored in a liquid heating medium with which are filled heating medium passages 8 in a module for collecting solar heat received by the solar heat collecting plate 6 of a solar photovoltaic heat collecting module and in a latent heat storage material 7 provided in the rear surface of the solar heat collecting plate. The latent heat storage material 7 is mainly composed of, for example, sodium acetate trihydrate which performs a phase change at a temperature not higher than the temperature under which the power generation module is not broken. Even when abnormal heat is generated in the solar heat collecting module due to any accident, the latent heat storage material 7 is partly molten because of the phase change temperature of the latent heat storage material 7, so that the rise of temperature is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar energy utilizing apparatus which receives heat and obtains heat or electric power.

[0002]

2. Description of the Related Art Generally, when solar energy is used,
In most cases, the photovoltaic power generator and the solar heat collector are completely different in configuration, and only one of them is used. In addition, a method has been adopted in which the devices themselves are separate even if both are used. However, for the purpose of constructing a system capable of more effectively utilizing solar energy with respect to the light receiving area, a hybrid type solar energy utilizing apparatus in which both are integrated has been developed.

FIGS. 4 and 5 are block diagrams of a conventional hybrid panel and a solar energy utilization system disclosed in Japanese Patent Application Laid-Open No. 7-253249. FIG. 4 is a cross-sectional view of the hybrid panel. A heat insulating material 23 is formed on the inner surface of the panel case 22 of the hybrid panel 21 without gaps. Panel case 22 of hybrid panel 21
On the opposite side, transparent glass 28 is used to allow sunlight to enter.
Is inlaid. A hybrid collector 24 is formed on the heat insulating material 23. This hybrid collector 2
Reference numeral 4 denotes a water collector 25 on which solar cells 26 are stacked. The water heat collector 25 is formed by heat conductively forming a liquid heat medium conduit 27 as a liquid heat medium, for example, an antifreeze solution, on a heat collecting plate. Reference numeral 29 denotes a liquid heat medium inlet for introducing an antifreeze into the liquid heat medium conduit 27, and reference numeral 30 denotes a liquid heat medium outlet for taking out the antifreeze from the liquid heat medium conduit 27.

FIG. 5 is a system diagram of a solar energy utilization system using the hybrid panel 21. As shown in FIG. In this system, the hybrid panel 21 is mounted on a roof 52 of a house 51.
Install in such as. The hybrid collectors in the hybrid panel 21 are hybrid collectors 24A and 24A.
B and 24C are formed in parallel. 55 is a heat storage tank as a heat storage device, and a conduit 56 connects the heat storage tank 55 and the liquid heat medium inlet 29. A conduit 57 connects the heat storage tank 55 and the liquid heat medium outlet 30. With such a configuration, the liquid heat medium flows through the liquid heat medium conduit 27 via the conduits 56 and 57, and absorbs heat as water as a heat storage material in the heat storage tank 55 to store heat. Here, 62 is an inverter, and 63 is a commercial power supply.

[0005]

In the conventional hybrid solar energy utilization system as described above, when the amount of solar radiation is high and the outside air temperature is high, such as in summer, the heat medium circulation pump breaks down and the circulation of the heat medium occurs. If the temperature stops, the heat storage tank will not be able to collect heat, and not only the temperature of the solar heat collection module but also the temperature of the solar power generation module will increase.
There is a danger that the power generation efficiency of the power generation cell will be extremely reduced or the power generation cell itself will be damaged.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and realizes stabilization of the operating temperature of a heat collection module by using a latent heat storage material in a heat storage portion. When both functions of a power generation module are provided, a solar energy utilization device that can collect heat at a temperature that does not impair the reliability of the power generation module and eliminates the need to provide a heat storage tank space separately from the module installation location The purpose is to gain.

[0007]

According to the present invention, there is provided a solar energy utilizing apparatus comprising a heat collecting module for receiving heat and collecting heat, wherein the heat collecting module has a predetermined temperature or less. It has a phase change latent heat storage material.

Further, in a solar energy utilization apparatus having a power generation module for receiving and receiving sunlight and a heat collection module for receiving and collecting heat, the heat collection module has a phase transition at a predetermined temperature or lower. It has a latent heat storage material.

The heat collecting module has a latent heat storage material formed on the back surface of the heat collecting member.

In the heat collecting module, the latent heat storage material and the heat medium passage are alternately formed in the heat collecting member.

Further, the heat collecting module covers the latent heat storage material with a covering member in order to protect the latent heat storage material from a heat medium, and fills the back surface of the heat collecting member with a large number of the coated latent heat storage material. The gap between the material groups is used as a heat medium passage.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described with reference to the drawings.

Embodiment 1 FIG. FIG. 1 is a configuration diagram schematically showing a solar energy utilization device according to Embodiment 1 of the present invention. A case where one hybrid module which is the most basic example is provided will be described. Two or more sheets are acceptable.

1 is a transparent body capable of protecting the surface of the hybrid module, 2 is a still air layer for reducing surface heat dissipation loss during heat collection, and 3 is a device having a photovoltaic effect using single crystal Si, amorphous, or the like. 4 is an adhesive such as EVA used for insulation and waterproofing, 5a is a transparent waterproof sheet, 5b is not necessarily transparent waterproof sheet, 6 is a heat collecting plate, 7 is a latent heat storage material Layer, 8
Denotes a heat collection pipe serving as a heat medium passage, 9 denotes an outer frame for integrating the respective members, and 10 denotes a heat insulating material.

Next, the operation of the first embodiment will be described. The photovoltaic module and the solar heat collecting module are in close contact with each other to form a hybrid module. Here, the hybrid module receives the solar energy, generates electric power in the power generation cell 3 of the solar power generation module, and receives the waste heat and the solar energy received by the heat collection plate 6 of the solar heat collection module received in a portion where the power generation cell 3 is not provided. Is stored in the liquid heat medium filled in the heat medium flow path 8 in the solar heat collecting module and the latent heat storage material 7 installed on the back surface of the heat collecting plate. This latent heat storage material 7
Phase transition at a predetermined temperature below the temperature that does not hurt the power generation module, such as 90 ° C., which is the upper limit temperature when performing a heat cycle test of a photovoltaic power generation module in accordance with JIS, for example, sodium acetate trihydrate Even if abnormal heat generation occurs in the heat collecting module due to some accident, the latent heat storage material 7 is kept at the phase transition temperature of the latent heat storage material 7.
Is partially melted and the temperature is prevented from rising. When utilizing the heat stored in the hybrid module, for example, a heat medium such as propylene glycol is supplied to recover heat by conduction from the latent heat storage material.

Accordingly, heat can be collected while maintaining a temperature at which there is no danger of damaging the power generation cell itself without lowering the power generation efficiency of the power generation cell during periods of high solar radiation and high outside air temperature such as in summer. Also, by forming a latent heat storage material on the back of the heat collecting member,
The heat of the heat collecting section can be efficiently stored in the heat storage material.

Embodiment 2 FIG. FIG. 2 is a configuration diagram schematically showing a solar energy utilization device according to a twenty-first embodiment of the present invention. A case where one hybrid module which is the most basic example is provided will be described. Two or more sheets are acceptable.

1 is a transparent body capable of protecting the surface of the hybrid module, 2 is a still air layer for reducing surface heat dissipation loss during heat collection, and 3 is a device having a photovoltaic effect using single crystal Si, amorphous, or the like. 4 is an adhesive such as EVA used for insulation and waterproofing, 5a is a transparent waterproofing sheet, 5b is a waterproofing sheet such as a Tedra sheet which is not necessarily transparent, and 6 is a honeycomb-shaped assembly. Hot plate, 7 is a latent heat storage material packed layer, 8 is a heat medium passage,
Reference numeral 9 denotes an outer frame for integrating the members, and reference numeral 10 denotes a heat insulating material.

Next, the operation of the second embodiment will be described. The photovoltaic module and the solar heat collecting module are in close contact with each other to form a hybrid module. Here, the hybrid module receives the solar energy, generates electric power in the power generation cell 3 of the solar power generation module, and receives the waste heat and the solar energy received by the heat collection plate 6 of the solar heat collection module received in a portion where the power generation cell 3 is not provided. Is stored in the liquid heat medium filled in the heat medium flow path 8 in the solar heat collecting module and the latent heat storage material 7 installed on the back surface of the heat collecting plate. This latent heat storage material 7
Is a phase change below a temperature that does not hurt the power generation module, such as 90 ° C., which is the upper limit temperature when conducting a heat cycle test of a photovoltaic power generation module according to JIS, for example, latent heat storage mainly composed of sodium acetate trihydrate. Material.
When the heat stored in the hybrid module 1 is used, for example, a heat medium such as propylene glycol is supplied to recover heat by heat conduction from the latent heat storage material.

Therefore, heat can be collected while maintaining a temperature at which there is no danger of damaging the power generation cell itself without lowering the power generation efficiency of the power generation cell during periods of high solar radiation and high outside air temperature such as in summer. Further, the heat collecting module can be downsized by alternately forming the latent heat storage material and the heat medium flow passage in the heat collecting member.

Embodiment 3 FIG. 3 is a configuration diagram schematically showing a solar energy utilization device according to Embodiment 3 of the present invention. A case where one hybrid module which is the most basic example is provided will be described. Two or more sheets are acceptable.

1 is a transmissive body capable of protecting the surface of the hybrid module, 2 is a still air layer for reducing surface heat dissipation loss during heat collection, and 3 is a device having a photovoltaic effect using single crystal Si, amorphous, or the like. 4 is an adhesive such as EVA used for insulation and waterproofing, 5a is a transparent waterproofing sheet, 5b is a waterproofing sheet such as a Tedra sheet which is not necessarily transparent, 6 is a heat collecting plate, 7 is latent heat A group of capsules filled with a heat storage material, 8 is a heat medium passage utilizing the gap of the group of capsules, 9 is an outer frame for integrating the members, and 10 is a heat insulating material.

Next, the operation of the third embodiment will be described. The photovoltaic module and the solar heat collecting module are in close contact with each other to form a hybrid module. Here, the hybrid module receives the solar energy, generates power in the power generation cell 3 of the solar power generation module, and receives the exhaust heat and the solar energy received by the heat collection plate 6 of the solar heat collection module received in a portion where the power generation cell 3 is not provided. Is stored in the liquid heat medium filled in the heat medium flow path 8 in the solar heat collecting module and the latent heat storage material 7 installed on the back surface of the heat collecting plate. The latent heat storage material 7 is made of, for example, sodium acetate trihydrate, which undergoes a phase change below a temperature at which the power generation module is not damaged, such as 90 ° C., which is the upper limit temperature for performing a heat cycle test of a photovoltaic module according to JIS. It is a latent heat storage material mainly used. When the heat stored in the hybrid module 1 is used, for example, a heat medium such as propylene glycol is supplied to recover heat by heat conduction from the latent heat storage material.

Therefore, heat can be collected while maintaining a temperature at which there is no danger of damaging the power generation cell itself without lowering the power generation efficiency of the power generation cell during periods of high solar radiation and high outside air temperature such as in summer. Further, even if the latent heat storage material is completely melted, its shape can be maintained, and even if extraordinary heat generation occurs, the power generation module can be protected without a temperature rise exceeding a certain level.

The components of the power generation / heat collection module of the present invention, the types of the latent heat storage material and the liquid heat medium, the heat retention performance,
The installation position and the like are not limited to those described in the embodiment.

[0026]

As described above, according to the present invention, in a solar energy utilizing apparatus provided with a heat collecting module for receiving and receiving sunlight, the heat collecting module has a latent heat that undergoes a phase transition below a predetermined temperature. By having the heat storage material, an abnormal temperature rise does not occur in the heat collecting module, and the degree of freedom in designing the heat collecting module is improved.

Further, in a solar energy utilization apparatus including a power generation module that receives sunlight and generates power and a heat collection module that receives heat and collects heat, the heat collection module undergoes a phase transition at a predetermined temperature or lower. By having a latent heat storage material, there is an effect that heat can be collected while maintaining a temperature at which there is no risk of damaging the power generation module itself without lowering the power generation efficiency of the power generation module during periods of high solar radiation and high outside air temperature such as in summer.

Further, in the heat collecting module, by forming the latent heat storage material on the back surface of the heat collecting member, the heat of the heat collecting portion can be efficiently stored in the heat storage material.

In the heat collecting module, the latent heat storage material and the heat medium passage are alternately formed in the heat collecting member, so that the heat collecting module can be downsized.

Further, the heat collecting module is configured to cover the latent heat storage material with a covering member in order to protect the latent heat storage material from the heat medium, fill the back surface of the heat collecting member with a large number of the coated latent heat storage material, and fill the latent heat storage material. By using the heat medium flow path as the gap between the material groups, the shape of the latent heat storage material can be maintained even when the latent heat storage material is completely melted. be able to.

[Brief description of the drawings]

FIG. 1 is a configuration diagram schematically showing a solar energy utilization device according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram schematically showing a solar energy utilization device according to a second embodiment of the present invention.

FIG. 3 is a configuration diagram schematically showing a solar energy utilization device according to a third embodiment of the present invention.

FIG. 4 is a cross-sectional view of a power generation / heat collection panel of a conventional solar energy utilization device.

FIG. 5 is an explanatory diagram showing a system diagram of a solar energy utilization system using the solar energy utilization device.

[Explanation of symbols]

1 surface permeable body, 2 still air layer, 3 power generation cell, 4
Insulation / waterproof adhesive, 5a transparent waterproof sheet, 5b waterproof sheet, 7 latent heat storage material filling layer, 8 heat medium flow path, 9 outer frame, 10 heat insulating material.

Claims (5)

[Claims] 1. A solar energy utilization device having a heat collection module for receiving and receiving sunlight, wherein the heat collection module has a latent heat storage material that undergoes a phase transition at a predetermined temperature or lower. Energy utilization device. 2. A solar energy utilization apparatus comprising: a power generation module that receives sunlight and generates electricity; and a heat collection module that receives heat and collects heat, wherein the heat collection module has a phase transition at a predetermined temperature or lower. A solar energy utilization device characterized by having a latent heat storage material. 3. The solar energy utilization device according to claim 1, wherein the heat collection module has a latent heat storage material formed on a back surface of the heat collection member. 4. The solar energy utilization device according to claim 1, wherein the heat collection module has a latent heat storage material and a heat medium flow path alternately formed in the heat collection member. 5. The latent heat storage module, wherein the latent heat storage material is covered with a covering member to protect the latent heat storage material from a heat medium, and a large number of the covered latent heat storage material are filled on the back surface of the heat collecting member, and the latent heat storage material is filled. The solar energy utilization device according to claim 1 or 2, wherein the gap between the material groups is a heat medium flow path.