KR101965812B1 - Solar Panel Cooling System - Google Patents

Abstract

The present invention improves the power generation efficiency by cooling the solar panel by spraying water when the power generation efficiency is lowered due to the increase of the panel temperature in the operation of the solar panel installed in the remote area where the maintenance personnel residence or water supply facility is not smooth, And more particularly, to a solar panel cooling system capable of recovering unused water and storing and recycling rainwater in case of a rainfall.

Description

[0001] Solar Panel Cooling System [

The present invention relates to a solar panel cooling system, and more particularly, to a solar panel cooling system for installing a solar panel installed in a remote area where maintenance personnel residence or water supply facility construction is not smooth, The present invention relates to a solar panel cooling system capable of recovering unevaporated water and saving and recycling rainwater in the event of rain.

In recent years, as the exhaustion of fossil fuels and environmental pollution problems have reached serious levels, active promotion of renewable energy and facility investment have been actively carried out. In particular, interest in research and development of power generation technology using photovoltaic panels Is increasing.

Solar cells used in solar panels convert part of the solar energy into electrical energy, while other solar energy acts as a factor to raise the temperature of the solar cell. Such a rise in the temperature of the solar panel leads to a decrease in the power generation efficiency of the solar cell, and in particular, it is necessary to cool the solar cell to a proper temperature in order to maintain the power generation efficiency.

For this purpose, many methods have been proposed to cool the surface of the solar panel by spraying cooling water on the surface to lower the surface temperature. However, the fact that the solar power plant is located in a place where the water supply is smooth, It is presupposed that a separate device for uniformly spraying water is installed.

However, in the situation where the re-use rate is considerably low due to the fact that the water sprayed on the solar panel is poured off, the solar power plant installed in the place such as the mountain or the field, It is not smooth and this cooling method can not be applied.

Of course, there are various ways to cool the solar panel, but it is impossible to instantly cool the panel when the temperature rises. Depending on the installation environment and scale of the solar panel, , Most solar power plants are operated remotely in a remote environment without resident manpower.

Japanese Patent Application Laid-Open No. 10-2015-0132088 (2015.11.25)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide an air conditioner which is capable of detecting water- And to provide a solar panel cooling system capable of collecting and reusing rainwater.

According to another aspect of the present invention, there is provided a cooling system for a solar panel having a ground and a slope so that the front surface faces the sun, the cooling system comprising: a rail formed along an upper boundary surface of the solar panel; A water distributing body having moving means including wheels formed to be movable along the rail portion, nozzles and a supply pipe capable of jetting water toward the solar panel; A collecting part formed below the solar panel and collecting water flowing down to the front; A water supply unit including a filter for filtering the recovered water, a tank for containing the filtered water, and a pump for supplying the water to the supply pipe; .

A control unit for monitoring an amount of power produced by the solar panel, a control unit for determining a cooling drive signal based on the measured surface temperature, the amount of produced power, and the programmed reference value, And a control unit for controlling the water supply unit and the water distribution body through the cooling driving signal. .

The controller may further include a power unit for storing a part of the power generated by the solar panel and supplying the power to the power source, a second determination unit for monitoring the cooling result through the measurement result of the temperature sensor and the monitoring result of the control unit during driving the water distribution body And a communication unit for transmitting a monitoring result of the second determination unit to a designated terminal, and the water supply unit and the water distribution body may be restarted by reflecting the monitoring result.

Preferably, the water supply unit is installed in the shade of the rear side of the solar panel, and the tank is provided with a shielding member for blocking transmission of the geothermal heat.

Preferably, the rail portion further includes an auxiliary rail interconnectable with a rail portion of a laterally adjacent solar panel, wherein the water distribution body is configured to close the nozzle during movement of the auxiliary rail.

In the present invention, in the operation of a solar panel installed in a remote area where the maintenance personnel residence or water supply facility is not smooth, efficient power generation can be achieved through immediate cooling when the power generation efficiency is lowered due to the increase of the panel temperature.

In particular, reflecting the installation structure of the solar panel, the entire panel can be evenly cooled by flowing down and moving the nozzle, and the flowing water can be recovered and reused or the rainwater can be collected, Can be used.

1 is a perspective view illustrating a solar panel installation according to an embodiment of the present invention;
2 is a partial perspective view showing a state of a water dispersion body according to an embodiment of the present invention,
3 is a perspective view showing a rear surface of a solar panel according to an embodiment of the present invention,
4 is a block diagram illustrating a configuration and a connection relationship according to an embodiment of the present invention;
FIG. 5 is a front view showing an installation state of the auxiliary rail according to the second embodiment of the present invention,
6 is a side view showing an installation of a reamer and a water dispersion body according to the third embodiment of the present invention.

Hereinafter, the structure of the solar panel cooling system of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a solar panel according to an embodiment of the present invention, FIG. 2 is a partial perspective view of a water dispersion body according to an embodiment of the present invention, and FIG. 3 is a cross- FIG. 4 is a block diagram illustrating a configuration and a connection relationship according to an embodiment of the present invention. Referring to FIG.

The present invention is basically applied to a solar panel 110 installed so as to have a ground and a slope so that the front surface faces the sun so that the surface temperature of the panel rises above a set temperature, The water dispenser 130, the collecting unit 140, the water supply unit 150, and the control unit 160, for example.

The solar panel 110 is a device for converting light energy of a sunlight into electric energy, and can be applied to a variety of commercial solar panels. In the present specification, a detailed description of the solar panel 110 is omitted in order to prevent the gist of the invention from being blurred. In addition, although there is no particular limitation on the place of installation, it is also possible to apply it to a solar power plant constructed in a place where panel cooling is not possible in consideration of economical aspects of operation together with ease of water supply and related infrastructure construction Do.

The rail part 120 is a structure for guiding or restricting the movement of the water dispersing body 130 for spraying water. In the present invention, the upper part of the upper part of the solar panel 110, that is, .

The water distributing body 130 is configured to spray water onto the entire surface of the solar panel and is basically installed on the rail 120 so as to be linearly movable along the rail 120. To this end, an electric moving means 131 for driving the wheel 132, as well as a wheel 132 having a shape corresponding to the rail 120, and a water pump 132 for spraying water toward the solar panel 110 And a supply pipe 134 for supplying water to the nozzle 133. The supply pipe 134 is connected to the nozzle 133 through the nozzle 133,

That is, the moving means 131 including the electric motor and the reduction gear drive the wheels 132 via the external control signal so that the water distributing body 130 moves in the lateral direction along the rail 120 A partition wall for restricting movement is provided on the left and right ends of the rail part 120 so that the water dispersion body 130 does not deviate from the length range of the rail part 120, It is obvious that a safety device such as a limit switch for stopping the moving means 131 in contact with the partition wall can be provided.

According to the present invention, the rail 120 is installed on the upper side of the inclined upper surface of the solar panel 110 and the water, that is, the cooling water is sprayed downward through the water distributing body 130 so that the water sprayed down along the inclined surface As the water dispersion body 130 moves in the lateral direction, uniform water spraying and cooling can be performed throughout the entire solar panel 110.

The collecting unit 140 collects water flowing down to the front of the solar panel 110 and is formed below the solar panel 110. The collecting unit 140 includes a trench- So that the water is not evaporated on the surface of the solar panel 110 but collected and collected without being discarded.

In addition, the collector 140 can collect rainwater flowing downward on the solar panel in a rainy day, so that efficient cooling water management such as collection and supply of cooling water can be performed even in a solar power plant installed in a place where water supply is not smooth.

The water supply unit 150 is configured to store the water collected and recovered through the collecting unit 140 and supply the collected water to the water distributing body 130 when necessary. A filter 152 for filtering the foreign matter, a tank 152 for receiving the filtered water through the filter 151, and a filter 152 for filtering the filtered water, And a pump 154 for supplying the water contained in the tank 152 to the supply pipe 134.

At this time, the tank 152 is installed in the shade of the rear side of the solar panel 110 so that the water contained therein can be naturally cooled through the wind in the state where the direct light is blocked. In order to prevent the temperature of the tank 152 from rising due to the geothermal heat in the summer, it is preferable to provide a shielding member 153 for blocking the transmission of the geothermal heat to the lower side of the tank 152.

The control unit 160 is a processing device for detecting a temperature rise state of the solar panel 110 and performing a cooling operation by controlling the water distributing body 130 and the water supplying part 150. In the first embodiment of the present invention, A detailed configuration of the power supply unit, the temperature sensor 162, the control unit 163, the first determination unit 164 and the second determination unit 165, and the communication unit 166 are provided.

The power supply unit 161 is configured to partially store the power generated by the solar panel 110 and is basically made of a rechargeable battery to supply power for operating the system of the present invention. In other words, since the power generated through the solar panel 110 is stored and used without a separate commercial power source, it is possible to operate the self power supply and the unmanned system even in a remote area where the power supply infrastructure is not provided.

The temperature sensor 162 is a sensor for measuring the surface temperature of the solar panel 110. The temperature sensor 162 is installed on the back surface or the side surface of the panel so as to prevent water from flowing to the front surface of the solar panel 110, Will be detected.

The control unit 163 monitors the amount of power generated by the solar panel in real time. As described above, since the temperature rise of the solar panel is achieved by reducing the amount of electric power generated, the controller 163 real- And the temperature value measured through the temperature sensor 162, it is possible to determine whether or not the reduction in the amount of production of the electric power due to the temperature increase is occurring, or whether the decrease in the amount of electric power production is due to the temperature increase or other weather conditions.

The first determination unit 164 determines the surface temperature measured through the temperature sensor 162 and the produced power amount confirmed through the control unit 163 and a programmed reference value to generate a cooling driving signal do.

That is, even if the temperature of the solar panel 110 rises, the temperature may be lowered due to the blocking of the light due to clouds or the like, so that the cooling drive signal is generated when the temperature rise of the panel leads to a decrease in the power generation amount Accordingly, the water supply unit 150 and the water distribution body 130 are controlled, so that efficient cooling management can be performed. In addition, it is possible to generate a cooling drive signal when cooling is required according to a judgment standard that reflects various predictions of the installation site.

The second determination unit 165 monitors the cooling result through the measurement result of the temperature sensor 162 and the monitoring result of the control unit 163 while the water dispersion body 130 is being driven through the cooling driving signal In addition, when the panel is cooled and the generated amount of power is restored, the cooling is stopped immediately, so that an unnecessary cooling operation can not be performed. When the controller 160 determines that the cooling is not performed smoothly by reflecting the monitoring result, The controller 150 and the water dispersing body 130 can be restarted.

The communication unit 166 is made up of a commercial mobile phone communication module and the like. The management unit 166 can recognize the monitoring result of the second determination unit 165 under an unmanned solar power plant or a remote monitoring system, To the designated terminal.

FIG. 5 is a front view showing an installation of the auxiliary rail according to the second embodiment of the present invention. In the first embodiment, although the present invention has been described with reference to the structure for cooling a single solar panel 110, The present invention is applicable to a solar power plant having a certain scale or more installed with the solar panel 110 aligned.

At this time, the water distributing body 130 may be provided for each of the solar panels 110. However, in a single row of the solar panels 110 located on the left and right, the respective solar panels are connected to each other through a separate auxiliary rail 121 So that the cooling operation can be performed through the single water distributing body 130 by the connection.

For this, the rail 120 in the second embodiment of the present invention may further include an auxiliary rail 121 which can be interconnected with a rail portion of a laterally adjacent solar panel, and a coupling using a bolt and a nut The auxiliary rail 121 can be installed in a manner that the rail 120 extends laterally in various manners.

The water distributing body 130 can be moved in the lateral direction along the auxiliary rail 121 connected to the rail 120. In consideration of the moving range, the water pipe 134 and the power cable do.

At this time, while the water distributing body 130 moves along the auxiliary rail 121, it is necessary to stop the water injection so that unnecessary consumption of water is prevented. Accordingly, the water distributing body 130 senses the auxiliary rail 121 during movement And a valve 136 interlocked with the sensing unit 135 to close the nozzle 133 as the movement of the auxiliary rail 121 is detected through the sensing unit .

The sensing unit 135 may be a switch-type sensing unit 135 having a roller at the lower end of the water distribution body 130, And the sensor 135 is in contact with the auxiliary rail 121 to form a step or a groove having a height different from that of the rail 120 so that the angle is adjusted. The valve 136 may be opened or closed.

In addition, it is obvious that the collection unit 140 is installed in each solar panel 110, and the collected water can be collected in one tank 152 and accommodated.

FIG. 6 is a side view showing the installation of a rail and a water distribution body according to the third embodiment of the present invention, in which the rail 120 is arranged on the upper side of the solar panel 110 in the same structure as the above- But is provided on the upper back side instead of the protruding shape. In this case, the water splitter 130 is also positioned on the back surface of the solar panel 110, and the shape of the nozzle 133 is formed such that the shape of the nozzle 133 can be sprayed from the top surface of the solar panel 110 from the back surface.

This is because, in order to effectively install the solar panel 110 per unit area in a solar power plant where a plurality of solar panels 110 are installed, the shadows generated from the front solar panel reach only the lower side of the rear solar panel Considering the installed characteristics.

In other words, when the rail portion is positioned above the solar panel as in the first embodiment in a state where the solar panel is installed without sufficient space in the front and rear intervals, a shadow may be formed on the rear solar panel.

Accordingly, when the present invention is applied to a previously installed solar panel, it is preferable that the rail 120 and the water dispersing unit 130 are positioned on the rear surface so as not to protrude above the solar panel 110, It is possible to prevent a drop in power generation due to shadows on the optical panel.

It is to be understood that the invention is not limited to the disclosed embodiment, but is capable of many modifications and variations within the scope of the appended claims. It is self-evident.

110: solar panel 120:
121: auxiliary rail 130: water distributing body
131: moving means 132: wheel
133: nozzle 134: supply pipe
135: sensing part 136: valve
140: collecting unit 150: water supply unit
151: filter 152: tank
153: shielding member 154: pump
160: control unit 161:
162: Temperature sensor 163:
164: first judgment unit 165: second judgment unit
166:

Claims (5)

1. A cooling system for a solar panel (110) installed so as to have a ground surface and an inclined surface with a front surface facing the sun,
A rail part 120 formed along an upper boundary surface of the solar panel 110 and including an auxiliary rail 121 that can be interconnected with a rail part of a laterally adjacent solar panel;
A moving means 131 including a wheel 132 formed to be movable along the rail 120 and a nozzle 133 and a supply pipe 134 formed so as to spray water toward the solar panel 110, And a sensing unit 135 for sensing the auxiliary rail 121 during the movement of the auxiliary rail 121. The sensing unit 135 senses the movement of the auxiliary rail 121 on the auxiliary rail 121, A water distribution body 130 having a valve 136 interlocked with the sensing part 135;
A collecting unit 140 formed below the solar panel 110 to collect the water flowing down to the front side;
A water supply unit 150 having a filter 151 for filtering the recovered water, a tank 152 for storing the filtered water, and a pump 154 for supplying the water to the supply pipe 134; ≪ / RTI >
The method according to claim 1,
A temperature sensor 162 for measuring the surface temperature of the solar panel 110, a controller 163 for monitoring the amount of power produced by the solar panel 110, And a first determination unit (164) for generating a cooling driving signal based on the determined reference value, and controlling the water supply unit (150) and the water distribution body (130) through the cooling driving signal; Further comprising: a cooling system for cooling the solar panel.
3. The method of claim 2,
The control unit 160 includes a power unit 161 for storing a part of electric power generated by the solar panel 110 and supplying the power to the power source, A second determination unit 165 for monitoring a cooling result through a monitoring result of the second unit 163 and a communication unit 166 for transmitting a monitoring result of the second determination unit 165 to a designated terminal, And the water supply unit (150) and the water distribution body (130) are restarted to reflect the result.
The method according to claim 1,
Wherein the water supply unit (150) is installed in the shade of the rear side of the solar panel (110), and a shielding member (153) for blocking transmission of the geothermal heat is provided in the tank.
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