KR101898737B1 - Apparatus for generating of electric power by solar energy - Google Patents

Abstract

A solar thermal power generation apparatus according to the present invention comprises: a high-temperature plate receiving solar heat; A cooling plate spaced apart from the high temperature plate; And a thermoelectric element disposed between the high temperature plate and the cooling plate and converting heat energy into electric power, wherein the cooling plate is configured to discharge latent heat through evaporation of the cooling water.
As described above, according to the present invention, since the vacuum chamber is formed on the upper surface of the high-temperature plate, the incident solar heat can be prevented from being radiated by the convection with the ambient air, and the capillary groove is formed so that the capillary phenomenon occurs on the lower surface of the cooling plate Cooling water is formed as a water film while moving upward along the capillary groove, and is evaporated in association with the relative humidity of the atmosphere, thereby maximizing the cooling effect.
Accordingly, the present invention can increase the power generation amount by increasing the output of the thermoelectric element.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar-

The present invention relates to a solar power generation apparatus, which prevents incident solar heat from being radiated by convection with ambient air and maximizes the cooling effect as the cooling water is formed as a water film and evaporated while moving upward.

Fossil fuels, such as petroleum, are also used in power plants due to their numerous advantages.

However, due to limitations of fossil fuel reserves, there are many limitations and problems such as price surge and air pollution such as greenhouse effect. Therefore, there is a need for technology for alternative energy.

As a result, solar power generation has been proposed. Solar power generation is a solar energy energy utilization field that utilizes the fluctuating properties of sunlight. It is a technology used for heating, cooling and heating buildings by absorbing, storing, and converting solar heat.

In such a solar power generation, a thermoelectric element can be utilized. For example, a plurality of thermoelectric modules for power generation have a Seebeck effect in which a DC current is generated at both ends by bringing one end into contact with a high- The number of thermoelectric elements can be utilized. The plurality of thermoelectric elements are connected in series and the temperature difference is used to generate electricity.

Here, when the high temperature plate is irradiated with sunlight, the temperature of the high temperature plate is raised, but the heat radiation is simultaneously accompanied by the convection heat transfer with the ambient air as the temperature rises.

As a result, the temperature of the hot plate is maintained at the point where the heat input by the sunlight and the cooling heat by the ambient air are in equilibrium.

At this time, in order to increase the output of the thermoelectric element, it is necessary to maintain the high temperature plate temperature of the thermoelectric element at a high level.

Specifically, when a high temperature plate receives solar heat, the temperature rises, and electric power is generated in the process of heat transfer to the cooling plate through the thermoelectric element.

It is important to keep the temperature of the high temperature plate as high as possible and to keep the temperature of the cooling plate low because the amount of power generated in the power generated in this way increases in proportion to the heat transfer amount.

The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a cooling system for a solar panel, which prevents solar heat from being radiated by convection with ambient air, And a capillary groove is formed so that a vacuum chamber is formed on the upper surface of the high-temperature plate and a capillary phenomenon occurs on the lower surface of the cooling plate.

According to an aspect of the present invention, there is provided a solar thermal power generation system including: a high-temperature plate receiving solar heat; A cooling plate spaced apart from the high temperature plate; And a thermoelectric element disposed between the high temperature plate and the cooling plate and converting heat energy into electric power, the cooling plate being configured to discharge latent heat through evaporation of the cooling water,
The cooling plate may be formed of a cooling water tank having a structure in which a portion extending downwardly to receive cooling water is opened upward and a capillary structure may be formed on a lower surface which is an air- .

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Specifically, the capillary structure preferably includes a plurality of capillary grooves extending upward from the cooling water tank on the lower surface of the cooling plate.

It is also preferable that the upper surface of the high temperature plate is covered with a vacuum chamber.

In addition, the vacuum chamber is preferably made of a glass material.

In the solar thermal power generation apparatus according to the present invention, since the vacuum chamber is formed on the upper surface of the high-temperature plate, the incident solar heat can be prevented from being radiated by the convection with the ambient air, and the capillary tube The cooling water is formed as a water film while moving upward along the capillary groove and is evaporated in association with the relative humidity of the atmosphere, thereby maximizing the cooling effect.

Accordingly, the present invention has an advantage that the power generation amount can be increased by increasing the output of the thermoelectric element.

1 is a schematic view showing a solar power generation apparatus according to a preferred embodiment of the present invention.
2 is a view showing that cooling water is evaporated in a capillary groove of the solar power generator of FIG.

The solar energy generator of the present invention prevents the incident solar heat from being radiated by the convection with the ambient air and forms a water film as the water moves upward and evaporates to maximize the cooling effect, A capillary groove is formed so that a chamber is formed and a capillary phenomenon occurs on the lower surface of the cooling plate.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic view showing a solar thermal power generation apparatus according to a preferred embodiment of the present invention, and FIG. 2 is a view showing that cooling water is evaporated in a capillary groove of the solar power generation apparatus of FIG.

Referring to the drawings, reference numeral 20a denotes a high-temperature plate 10 that receives solar heat, a cooling plate 20 that is spaced apart from the high-temperature plate 10, and a cooling plate 20 that is disposed between the high- And a thermoelectric element (30).

The high-temperature plate 10 is formed as a heat-collecting portion for increasing the temperature by receiving solar heat and having an appropriate size to sufficiently receive solar heat. The specific configuration of the high-temperature plate 10 is not limited to the present invention, Of course it is.

When the sunlight is irradiated, the temperature of the high-temperature plate 10 is raised, but heat is simultaneously generated by the convection heat transfer with the ambient air as the temperature rises.

That is, it is difficult for the high-temperature plate 10 to completely retain all the heat input by the sunlight, which causes heat loss due to cooling by ambient air.

The upper surface 10a of the high temperature plate 10 may be covered with the vacuum chamber 11 in order to prevent the generation of heat loss due to the ambient air contacting the high temperature plate 10 in this way. At this time, the upper surface 10a of the high-temperature plate 10 refers to the side of the side to which sunlight is irradiated.

The vacuum chamber 11 may be made of glass to allow sunlight to pass therethrough.

The vacuum chamber 11 serves to prevent the temperature of the high temperature plate 10 from being cooled by the convection with the air by removing the air serving as the heat transfer medium on the high temperature plate 10.

The output of the thermoelectric element 30 can be increased by keeping the temperature of the high temperature plate 10 high by the vacuum chamber 11.

The cooling plate 20 is arranged to be spaced apart from the high-temperature plate 10, and is configured to discharge latent heat through evaporation of the cooling water 1.

Specifically, the cooling plate 20 may have a cooling water tank 21 in which a cooling water 1 is received. That is, the cooling plate 20 has a structure in which a portion extending downward is opened upward to accommodate the cooling water 1.

In this manner, the lower structure having the upper opening so that the cooling water 1 is received in the cooling plate 20 functions as the cooling water tank 21.

At this time, any conventional cooling water automatic supplying device configured to continuously maintain the proper water level in the course of power generation can be utilized for supplying the cooling water 1 to the cooling water tank 21 of the cooling plate 20 Of course.

Here, the cooling plate 20 may have a capillary structure on the lower surface 20a extending from the cooling water tank 21 to the upper portion. Here, the lower surface 20a of the cooling plate 20 refers to an air-side surface on which the cooling plate 20 comes into contact with the atmosphere.

That is, the cooling plate 20 may have a capillary structure in the lower surface 20a so that the cooling water 1 accommodated in the cooling water tank 21 can move upward along the lower surface 20a.

Specifically, the capillary structure may include a plurality of concave and convex lines extending upward from the cooling water tank 21 on the lower surface 20a of the cooling plate 20. [

This concavo-convex line has a structure having a capillary groove 22 extending from the lower surface 20a to the upper side from the cooling water tank 21 in order to form a capillary structure on the lower surface 20a of the cooling plate 20. In this case, The cooling water 1 moves upward along the capillary groove 22.

The capillary groove 22 is formed as a fine groove on the lower surface 20a of the cooling plate 20. The capillary groove 22 may have an inverted triangle or a quadrangular cross section as shown in FIG. Any shape can be taken if it is a suitable shape that can cause the phenomenon.

The cooling water 1 of the cooling water tank 21 is moved upward in the capillary groove 22 so that the water film is always formed on the lower surface 20a of the cooling plate 20. [

As described above, the cooling plate 20 is in a state in which the cooling water 1 is continuously moved and held on the lower surface 20a through the structure of the capillary groove 22, so that the solar heat transferred from the high- 1) is evaporated, the cooling action is performed.

As described above, the cooling water (1) existing in the capillary groove (22) of the cooling plate (20) is determined depending on the humidity of the outside air and the evaporation temperature can be evaporated at a temperature of 100 degrees centigrade or less.

Since the latent heat is absorbed from the cooling plate 20 in order for the cooling water 1 to evaporate, the heat removal effect per unit area can be maximized rather than simply cooling the cooling plate 20 by air. As a result, Can be increased.

Of course, the cooling plate 20 can be simply cooled by the cooling water to cool it through the convection of the cooling water. However, such cooling through contact does not provide a cooling effect rather than removal of the latent heat.

The thermoelectric element 30 according to the present invention is disposed between the high-temperature plate 10 and the cooling plate 20 and is a member for converting heat energy into electric power. The thermoelectric element 30 is not limited to the present invention, Of course.

According to the present invention configured as described above, since the vacuum chamber 11 is formed on the upper surface 10a of the high-temperature plate 10, the incident solar heat can be prevented from being radiated by the convection with the ambient air, The capillary groove 22 is formed so that the capillary phenomenon occurs in the lower surface 20a of the capillary groove 22 so that the cooling water 1 is formed as a water film while moving upward along the capillary groove 22 and is evaporated in association with the relative humidity of the atmosphere, The effect can be maximized.

Accordingly, the present invention can increase the power generation amount by increasing the output of the thermoelectric element 30.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

1: cooling water 10: high temperature plate
10a: upper surface 11: vacuum chamber
20: cooling plate 20a:
21: cooling water tank 22: capillary groove
30: thermoelectric element

Claims (5)

A hot plate (10) receiving solar heat; A cooling plate 20 disposed apart from the high-temperature plate 10; And a thermoelectric element (30) disposed between the high temperature plate (10) and the cooling plate (20) and converting heat energy into electric power, wherein the cooling plate (20) And,
The cooling plate (20)
And the lower portion is formed by a cooling water tank 21 having an upwardly open structure for receiving the cooling water 1,
Wherein a capillary structure is formed on the lower surface (20a) which is an atmospheric side surface which is connected to the atmosphere and which extends from the cooling water tank (21) to the upper side.
delete The method according to claim 1,
Wherein the capillary structure comprises a plurality of capillary grooves extending upward from the cooling water tank (21) on a lower surface (20a) of the cooling plate (20).
The method according to claim 1 or 3,
Characterized in that the high temperature plate (10) is covered with a vacuum chamber (11) on its upper surface (10a).
5. The method of claim 4,
Wherein the vacuum chamber (11) is made of glass.

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