KR101395048B1 - Efficiency enhancement equipment for solar photovoltaic power facilities - Google Patents

Abstract

Disclosed in the present invention is efficiency enhancement equipment of a solar light power facility which guarantees economic efficiency by being applied to a solar light module which is installed on a small scale such as a household and is improved to variously set a cooling water using method for cooling and cleaning. The efficiency enhancement equipment of the solar light power facility comprises a solar light module which generates electricity by collecting solar light and maintains or improves efficiency by spreading the cooling water to the solar light power facility. The efficiency enhancement equipment of the solar light power facility comprises a pressurized water source which pressurizes and supplies the cooling water; two or more cooling water spreading units which spread the cooling water provided from the pressurized water source to the solar light module; a cooling water distribution unit which distributes the cooling water provided from the pressurized water source to the cooling water spreading units in order; and a valve which prevents or allows the supply of the cooling water from the pressurized water source.

Description

[0001] DESCRIPTION [0002] Efficiency Enhancement Equipment for Solar Photovoltaic Power Facilities [

The present invention relates to an efficiency enhancement facility for a photovoltaic power generation facility, and more particularly, to an efficiency enhancement facility for a photovoltaic power generation facility that can be effectively applied to a solar power generation module installed in a small scale such as a home.

Generally, the method of using solar energy is divided into a method using solar heat and a method using sunlight. The method of using solar heat is a method of heating and generating electricity by using water heated by the sun, and a method of using sunlight is a method of generating electricity by using sunlight, It is called solar power generation.

Among the above-mentioned methods, photovoltaic power generation is a photovoltaic effect in which a photovoltaic panel having n-type doping on a silicon crystal and pn-junction is irradiated with sunlight to generate an electromotive force due to the photovoltaic energy, To generate electricity.

For this purpose, a solar cell for collecting sunlight, a photovoltaic module as an aggregate of solar cells, and a solar array for uniformly arranging solar cells are required.

For example, when light enters the solar module from the outside, the electrons in the conduction band of the p-type semiconductor are excited into the valance band by the incident light energy, One electron-hole pair (EHP) is formed in the p-type semiconductor. The electrons in the electron-hole pair are generated by an electron field existing between the p- And the current is supplied to the outside.

Unlike existing energy sources such as fossil raw materials, sunlight is a clean energy source that does not have the danger of global warming, such as greenhouse gas emissions, noise, environmental destruction, etc., and there is no fear of depletion. Unlike other types of wind and seawater, solar power generation facilities are free from installation and maintenance costs.

However, in the case of the most widely used silicon solar cell, when the temperature of the photovoltaic module is increased, a power reduction of 0.5% per 1 occurs. According to these characteristics, the output of photovoltaic power is highest in spring and autumn, not the longest summer. Such a temperature rise is a major cause of deteriorating the power generation efficiency of the photovoltaic power generation.

In addition, such a solar module has disadvantages that dust can be easily accumulated on the solar panel due to weather phenomenon such as yellow dust and bad weather. When dirt accumulates on the solar module, the solar module's light absorption rate is significantly lowered, and therefore the power generation efficiency may also be lowered.

In addition, when rain or snow falls on the solar panel in winter, the power generation efficiency may decrease.

In order to prevent deterioration of power generation efficiency due to such dirt, snow, and rain, an efficiency improvement facility (maintenance facility) of a solar power generation facility is used.

In order to improve the efficiency of solar power generation facilities, the cooling module which cools the temperature of the solar module and the cleaning and snow removal of the dirt, snow, rain etc. accumulated on the solar panel, It functions to maintain the solar power generation facilities.

Large-scale solar power generation facilities consist of efficiency enhancing equipments such as control devices equipped with various analog sensors, circuits for driving them, and software implementing artificial intelligence logic.

Recently, photovoltaic power generation facilities have been required to be manufactured in a home or commercial type having a small capacity of power generation capacity. In this case, it is difficult to implement the efficiency improvement facility configured to maintain the photovoltaic power generation facility at a high price.

Accordingly, there is a demand for an efficiency improvement facility capable of efficiently performing maintenance of a small-capacity solar power generation facility, which is manufactured at home or in an entry-level type, without employing expensive parts.

[Prior Art Literature]

Korean Patent Publication No. 2013-0007249

Japanese Patent Registration No. 2013-024031

It is an object of the present invention to provide a facility for efficiently improving the efficiency of a photovoltaic power generation system, which can be effectively applied to the maintenance and management of a small-capacity solar power generation facility,

According to an aspect of the present invention, there is provided an efficiency improvement device for a photovoltaic power generation facility that maintains or improves efficiency by injecting cooling water into a photovoltaic power generation system including a photovoltaic module that generates electricity by condensing sunlight A pressurized water source which pressurizes and supplies the cooling water; Two or more cooling water jetting means for jetting the cooling water supplied from the pressurized water source to the solar module; A cooling water distributing means for sequentially distributing the cooling water supplied from the pressurized water source to each of the cooling water injection means; And a valve for shutting off or opening the supply of cooling water from the pressurized water source.

And a control unit for controlling the opening and closing of the valve to control the injection of the cooling water and the injection amount.

The pressurized water source is preferably a water supply line.

The cooling water distributing means may be configured to sequentially switch the distribution direction of the cooling water by the pressure of the cooling water.

Wherein the cooling water distributing means comprises an inner rotating body having outlets corresponding to the plurality of cooling water spraying means and rotated by the pressure of the cooling water, wherein the opening of the discharging opening is sequentially And sequentially distributing the cooling water to the plurality of cooling water injection means.

Wherein the distributing means comprises a distribution body having a plurality of discharge ports through which cooling water is discharged radially and an inlet through which the cooling water flows, A distribution selecting unit that rotates at an upper portion of the distribution body to selectively open or shut off the plurality of discharge ports, forms a pressure chamber into which cooling water flows, and changes the height by cooling water flowing into the pressure chamber; A drive unit coupled to the distribution selection unit to rotate the distribution selection unit according to a height changed to the distribution selection unit; And a body case coupled to the dispensing body to receive the dispensing selection unit and the drive unit.

The distribution selection unit includes a lower housing having an inlet hole communicating with the inlet and an outlet hole communicating with an outlet of a portion of the plurality of outlets, and a lower housing coupled to the lower housing to form the pressure chamber, And an upper housing coupled to the lower housing such that the height of the distribution selecting unit is changed by the upper housing and the lower housing with the coupling unit to which the driving unit is coupled.

Wherein the drive unit includes: an outer tooth coupled with the distribution selection unit and moving upward and downward in accordance with a changed height of the distribution selection unit and having a plurality of teeth formed on an outer periphery thereof, and an upper tooth Dongbu Material; A first guide part protruding downward from an inner center of the main body case and having a plurality of first teeth for guiding the inclined surfaces of the outer teeth when the up and down moving parts move upward to rotate the up and down moving parts; And a second guide member disposed at a lower portion of the upper and lower movable members and having a plurality of second teeth for guiding the inclined surfaces of the inner teeth when the movable upper and lower members move downward to rotate the upper and lower movable members.

The driving unit may further include an elastic member elastically supporting the upper and lower movable members in the main body case such that the upper and lower movable members act in a direction in which the second guide member is positioned.

The main body case may include a confirmation window for confirming the discharge port opened by the distribution selection unit in a form of grasping the state of the drive unit.

The dispensing body may be formed with a residual discharge hole for discharging the cooling water remaining in the dispensing body through the inlet.

Wherein the spraying means comprises a nozzle body for receiving the cooling water and spraying the cooling water in a pulse shape; A nozzle housing which surrounds the nozzle body and has a spray hole formed in a long left and right direction to discharge the cooling water discharged from the nozzle body in a flat shape; An opening degree adjusting member which rotates inside the nozzle housing to adjust an opening degree of the injection hole; And a knob provided at an upper portion of the nozzle housing to rotate the opening adjustment member.

Wherein the nozzle body is formed in a shape in which the inner space is narrowed and then widened so that the jetting force of the cooling water is improved; And an air inflow hole through which air is mixed with the cooling water discharged from the venturi and the outside air is introduced to discharge the cooling water in a pulse shape.

The nozzle body may include a discharge guide for collecting the cooling water of the nozzle housing to guide the discharge to the nozzle body when the supply of the cooling water is interrupted by dividing the internal space of the nozzle housing.

The discharge guide may further include a seal member provided at a portion in contact with the nozzle housing to seal the space between the nozzle housing and the discharge guide.

And a locking protrusion protruding outwardly is formed on one of the nozzle body and the nozzle housing, and a locking groove is formed on the other of the nozzle body and the nozzle housing to which the locking protrusion is coupled, so that the nozzle body and the nozzle housing are coupled to each other.

The opening adjustment member includes a body portion to which the knob is coupled; An opening adjusting plate part spaced apart from the body part and closely contacted with the inside of the nozzle housing to adjust an opening angle of the injection hole to adjust an injection angle of the cooling water; And a connection portion connecting the body portion and the end of the opening adjustment plate portion so that the opening adjustment plate is in close contact with the nozzle housing by an elastic force.

Therefore, according to the present invention, since the cooling water is supplied from the water pipe or the faucet without constituting the tank or the pump for supplying the cooling water, it is possible to provide an efficiency improvement facility applicable to a solar power generation facility that is manufactured at home or in a popular type have.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view for explaining a configuration of an embodiment of an efficiency improvement facility for a photovoltaic power generation facility according to the present invention; FIG.
Figures 2 to 5 are schematic diagrams illustrating a first embodiment for dispensing cooling water.
6 is a perspective view showing a flat cooling water jetting means of a solar module according to an embodiment of the present invention.
7 is an exploded perspective view of a flat type cooling water jetting means of a solar module according to an embodiment of the present invention.
8 is a side cross-sectional view of the flat cooling water injection means of the solar module according to the embodiment of the present invention.
Fig. 9 is a cross-sectional view taken along line AA in Fig. 10, showing the state in which the opening adjustment member opens the injection hole. Fig.
FIG. 10 is a cross-sectional view taken along the line AA in FIG. 10, showing the state in which the opening adjustment member closes the injection hole.
11 is a side cross-sectional view of a flat cooling water jetting means of a solar module according to an embodiment of the present invention, in which residual cooling water is discharged.
12 is a perspective view showing a cooling water distributing means of a solar power generation facility according to an embodiment of the present invention;
13 is an exploded perspective view of the cooling water distributing means of the solar power generation facility according to the embodiment of the present invention.
14 is a cross-sectional view of a distribution body constituting cooling water distributing means of a solar power generation facility according to an embodiment of the present invention;
15 is a plan view showing a distribution body constituting cooling water distributing means of a solar power generation facility according to an embodiment of the present invention;
16 is an exploded perspective view of a disassembling unit for disassembling the distribution selection unit constituting the cooling water distributing means of the photovoltaic power generation equipment according to the embodiment of the present invention.
17 is a side cross-sectional view of a distribution selection unit constituting cooling water distributing means of a photovoltaic power generation facility according to an embodiment of the present invention;
18 is an exploded perspective view in which a main body case and a distribution selection unit constituting cooling water distributing means of a solar power generation facility according to an embodiment of the present invention are disassembled.
19 is an exploded perspective view of a main body case and a distribution selection unit constituting cooling water distributing means of a solar power generation facility according to an embodiment of the present invention, viewed from the bottom.
20 is a side cross-sectional view of a cooling water distributing means of a solar power generation facility according to an embodiment of the present invention.
21 is a cross-sectional view of a solar power generation facility according to an embodiment of the present invention, the cooling water being introduced into the pressure chamber.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the terminology used herein is for the purpose of description and should not be interpreted as limiting the scope of the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention and thus various equivalents and modifications Can be.

1 is a schematic view for explaining a configuration of an efficiency improvement facility of a solar power generation facility according to the present invention.

The embodiment of the efficiency enhancement facility of the photovoltaic power generation facility according to the present invention shown in FIG. 1 includes a solar power generation facility including solar modules 10a and 10b for collecting sunlight to generate electricity, The control means 3, the cooling water distributing means 5, the cooling water supply pipe 7 and the cooling water spraying means 9a to 9d, And performs cooling water injection to the optical modules 10a and 10b. Here, the control means 3 has a configuration including the valve 30, the control unit 32, and the operation unit 34. [

Here, the pressurized water source 1, which pressurizes and supplies the cooling water, can be used as a water supply, and a cooling water supply pipe 7 is provided to receive the cooling water from the pressurized water source 1.

The valve 30 is installed in the cooling water supply pipe 7 to open or shut off the cooling water supply pipe 7.

The control unit 32 controls the opening and closing of the valve 30 to control the injection of the cooling water and the injection amount, and the user controls the control unit through the control unit 34.

The cooling water injecting means 9a to 9d inject the cooling water supplied from the pressurized water source 1 to the solar modules 10a and 10b and the cooling water distributing means 5 supplies the cooling water supplied from the pressurized water source 1 And sequentially distributes them to the means 9a to 9d, respectively.

Meanwhile, the efficiency improvement facility of the photovoltaic power generation facility of the present invention may further include a water softener filter (not shown) for treatment of hard water components, i.e., metal ion components, in the tap water. By including the water softening filter, the tap water can be softened to prevent accumulation of water in the solar module and the cooling water supply pipe. The installation position of the water softening filter is not particularly limited and may be provided at the rear end of the pressurized water source, the front end or the rear end of the valve. Further, a water softening filter may be provided in the pressurized water source.

The construction of the water softening filter is not particularly limited as long as it functions to soften the cooling water, but a cation exchange resin can be used typically.

FIGS. 2 to 5 are views illustrating a manner in which cooling water is sequentially distributed. By sequentially distributing the cooling water through the cooling water distributing means 5, the solar modules 10a And 10b, respectively.

That is, the distributing means 5 may be configured to sequentially supply the cooling water in the directions of arrows A to D in FIG. 1. In the first embodiment, as shown in FIGS. 2 to 5, A configuration in which cooling water is circulated while being distributed can be exemplified.

The cooling water can be supplied in the order of the cooling water injection means 9a, the cooling water injection means 9b, the cooling water injection means 9c and the cooling water injection means 9d as shown in Figs. 2 to 5, 2 to 5, the cooling water may be injected into the solar modules 10a and 10b.

2 to 5, since the distributing means 5 distributes the cooling water, the cooling water supplied from the pressurized water source 1 can be supplied through the respective cooling water supply pipes 7 with a sufficient pressure, (9a, 9b, 9c, 9d).

On the other hand, the control means 3 constituted in the embodiment according to the present invention has a constitution in which the injection amount of the cooling water can be adjusted, and the injection amount of the cooling water supplied from the pressurized water source 1 is applied to the distribution means 5.

The manner in which the control unit 32 controls the valve 30 is not particularly limited, but is preferably designed to maximize the use efficiency of the cooling water. A control method capable of improving the use efficiency of the cooling water will be described as an example.

As a first example, this is a time-based control scheme. Specifically, the control unit 32 determines whether or not the drive start time is reached, and opens the valve 30 for a predetermined period of time at the drive start time. It is possible to set the opening time of the valve 30 in consideration of characteristics of the area and facilities where the solar power generation facility is installed.

Another example is the temperature control method. Specifically, it is determined whether the temperature difference between the temperature of the solar modules 10a, 10b and the temperature of the cooling water is equal to or greater than the temperature difference between the temperature of the solar modules 10a, 10b and the temperature of the cooling water. 10b and the measured value of the temperature difference between the cooling water and the cooling water is equal to or greater than the temperature difference between the temperature of the solar modules 10a, 10b and the temperature of the cooling water, the valve 30 is opened. The temperature difference between the solar modules 10a and 10b and the temperature of the cooling water can be set in consideration of the characteristics of the solar power generation facility and the area where the solar power generation facility is installed.

It is preferable to measure the pressure in the cooling water supply pipe 7 and to terminate the operation of the efficiency improvement apparatus when the pressure exceeds the predetermined pressure range. When the measured pressure exceeds the maximum value of the set pressure range, there is a problem such as freezing of the cooling water. If the measured pressure is below the minimum value of the set pressure range, there is a problem such as leakage of cooling water. And the startup is terminated for efficient use of the cooling water. Hereinafter, for ease of explanation, the cooling water jetting means should be unified with quotation mark '9', and the solar module should be unified with quotation mark '10'.

Hereinafter, the cooling water jetting means 9 according to an embodiment of the present invention will be described in more detail with reference to FIGS. 6 to 13. FIG.

The cooling water spraying unit 1100 of the solar module according to an embodiment of the present invention reduces the temperature of the solar module or removes foreign materials attached to the solar module by spraying cooling water for cooling and cleaning the solar module, It is a device that can improve the efficiency of solar module.

The cooling water spraying unit 1100 of the solar module may include at least one solar module to cool and clean the solar module.

6 to 8, the cooling water spraying unit 1100 of the photovoltaic module according to the embodiment of the present invention may include a nozzle body 1110.

The nozzle body 1110 can inject cooling water by increasing the spraying power of the cooling water supplied to the cooling water spraying means 1100 of the solar module.

Meanwhile, the nozzle body 1110 may include a venturi 1111. The venturi 1111 may be formed in such a shape that its internal shape is gradually narrowed and then widens in the direction in which the cooling water is injected so as to increase the injection force of the cooling water by using the venturi principle.

The venturi 1111 is compressed as the cooling water passes through a portion where the inside diameter narrows, and the compressed cooling water expands while passing through the expanded portion of the inside diameter, so that the jetting power of the cooling water can be increased.

The nozzle body 1110 may include an air inflow hole 1112. The air inflow hole 1112 can inject the cooling water passing through the venturi 1111 in a pulse shape or in a discontinuous form such as a pulse.

At this time, it is preferable that the air inflow hole 1112 is formed in the cooling water passing through the venturi portion 1111, more specifically, in the portion where the diameter is increased again in the venturi portion 1111.

That is, when the air inflow hole 1112 is formed in the venturi 1111, the air introduced into the air inflow hole 1112 having a relatively small size relative to the cooling water having a high spraying power is unevenly mixed, And can be injected in the form of a pulse.

In this way, when the cooling water is jetted in the form of pulses, the cooling water can improve the cooling and cleaning efficiency of the solar module.

The nozzle body 1110 may include a discharge guide 1113. The discharge guide 1113 collects the remaining cooling water in the cooling water spraying unit 9 of the solar module and discharges it back to the cooling water supply pipe for supplying the cooling water (refer to FIG. 11).

The discharge guide 1113 is formed in a shape that widens upward from the upper end portion of the nozzle body 1110, that is, a shape of a funnel, so that the cooling water remaining in the cooling water spraying means 9 of the solar module is supplied to the nozzle body 1110, To the cooling water supply pipe.

The diameter of the upper portion of the discharge guide 1113 may be formed to be large enough to be inserted into the nozzle housing 1130 to be described later and the nozzle housing 1130 and the discharge A seal member 1114 that hermetically seals the guide 1113 can be provided.

In addition, the nozzle body 1110 may include an engagement protrusion 1117. The engagement protrusion 1117 may be formed to protrude outward around the lower end of the nozzle body 1110 as a portion to which the rotation coupling member 1118 to be described later is engaged.

A sealing portion 1115 may be formed at a central portion of the nozzle body 1110 to seal the lower end portion of the nozzle housing 1130 by protruding outward from the periphery of the nozzle body 1110, A plurality of locking protrusions 1116 to which the nozzle housing 1130 is coupled may be formed radially.

The cooling water injection means 1100 of the solar module according to the embodiment of the present invention may include a nozzle housing 1130.

The nozzle housing 1130 can jet the cooling water injected through the nozzle body 1110 into a fan shape in a direction orthogonal to the nozzle body 1110.

The lower end of the nozzle housing 1130 may be opened so as to surround the upper end of the nozzle body 1110 and the hollow interior of the nozzle housing 1130 may be formed in an empty cylindrical shape. In the center of the upper end of the nozzle housing 1130, A through hole 1133 to which the knob 1170 is coupled may be formed.

A spray hole 1131 through which the cooling water is sprayed may be formed around the upper portion of the nozzle housing 1130. The spray hole 1131 may be formed in a flat shape, And can be formed long left and right.

Here, the spray hole 1131 is formed at a 180-degree angle around the center of the nozzle housing 1130 so that the cooling water can be sprayed at a maximum of 180 when the cooling water spraying means 1100 of the solar module is viewed from a plane. That is, a half of the circumference of the nozzle housing 1130 (see Fig. 9).

A locking groove 1135 in which the locking protrusion 1116 is fitted is formed in the peripheral portion of the lower end of the nozzle housing 1130 in correspondence with the locking protrusion 1116 so that the nozzle housing 1130 can be fitted into the nozzle body 1110 And a portion of the nozzle housing 1130 in which the locking groove 1135 is formed may be formed in a position corresponding to the locking protrusion 1116 at a position where the locking projection 1116 is formed, As shown in FIG.

A locking protrusion 1116 is formed around the lower end of the nozzle housing 1130 in place of the locking recess 1135 and the nozzle body 1110 is formed in a shape in which the locking recess 11135 and the locking protrusion 1116 are opposite to each other. A locking groove 1135 may be formed in the sealing portion 115 of the body 110 and coupled to each other.

The cooling water spraying unit 1100 of the solar module according to the embodiment of the present invention may include the opening adjustment member 1150. The opening adjustment member 1150 is provided inside the nozzle housing 1130 to adjust the opening degree of the spray hole 1131 through which the cooling water is sprayed.

On the other hand, the opening adjustment member 1150 may include a body portion 1151. The body portion 1151 is formed at a size smaller than the inner diameter of the nozzle housing 1130 and is inserted into the nozzle housing 1130 at a center portion of the nozzle housing 1130, A coupling hole 1153 of a vertically penetrating shape to which the knob 1170 to be coupled is coupled may be formed.

The opening adjustment member 1150 may include an opening adjustment plate portion 1155. The opening regulating plate portion 1155 contacts the inner circumferential surface of the nozzle housing 1130 to open or close the spray hole 1131 formed in the nozzle housing 1130 and has a circular arc having the same radius as the inner circumferential surface of the nozzle housing 1130 As shown in FIG.

On the other hand, the opening regulating plate portion 1155 may be positioned to be spaced apart from the body portion 1151 in the circumferential direction of the body portion 1151.

The opening adjustment member 1150 may include a connection portion 1157. The connection portion 1157 is formed so as to allow the opening portion of the body portion 1151 and the opening adjustment plate portion 1155 to be in close contact with the inner circumferential surface of the nozzle housing 1130 by the elastic force, Either end can be connected to each other.

9 to 10, the opening adjustment member 1150 configured as described above rotates about the central axis of the nozzle housing 1130 in the nozzle housing 1130 so that the opening adjustment plate 1155 is rotated about the center axis of the nozzle housing 1130, The angle at which the cooling water is injected through the injection hole 1131 can be controlled by closing the opening 1131.

In the embodiment, the angle of the cooling water injected through the injection holes 1131 is adjustable in a range of 90 to 180 when viewed from a plane (see FIGS. 9 and 10).

In addition, since the opening adjusting plate portion 1155 is brought into close contact with the inner circumferential surface of the nozzle housing 1130 by the elastic force, the cooling water can be prevented from leaking from the portion where the spray hole 1131 is hermetically sealed.

The cooling water jetting means 1100 of the photovoltaic module according to the embodiment of the present invention may include a knob 1170. The knob 1170 can adjust the opening of the spray hole 1131 by rotating the opening degree adjusting member 1150.

On the other hand, the knob 1170 can be positioned on the upper portion of the nozzle housing 1130 and is formed to have a circumference similar to the upper circumference of the nozzle housing 1130, A fin portion 1171 can be formed.

The outer peripheral surface of the knob 1170 may be formed with a serrated groove so that the user can easily rotate the knob 1170. The knob 1170 may be coupled to the nozzle housing 1130 so as to be rotatable at an upper portion of the nozzle housing 1130 .

The pin portion 1171 of the knob 1170 passes through the through hole 1133 formed at the center of the upper end portion of the nozzle housing 1130 and passes through the body of the opening adjustment member 1150 located inside the nozzle housing 1130 The knob 1170 and the opening adjustment member 1150 can be coupled to each other in such a manner as to be fitted to the coupling hole 1153 formed in the coupling portion 1151. [

The circumference of the pin portion 1171 is coupled with the opening degree adjusting member 1150 so that the pin portion 1171 can be easily rotated together with the opening degree adjusting member 1150 when the knob 1170 is rotated. And may be formed to include one or more planes.

In the embodiment, the fin portion 1171 is formed in a columnar shape, and both sides of the fin portion 1171 are cut off so as to include two planes.

The pin portion 1171 and the opening degree adjusting member 1150 are fastened to each other by bolts 1175 by a bolt 1175 so that the pin portion 1171 is not separated from the coupling hole 1153 of the opening degree adjusting member 1150, .

The cooling water spraying unit 1100 of the photovoltaic module according to the embodiment of the present invention may include a rotation coupling member 1118.

The rotation coupling member 1118 can couple the cooling water injection means 1100 of the solar module to the cooling water supply pipe.

The rotation coupling member 1118 may be rotatably coupled to the lower end of the nozzle body 1110. The rotation coupling member 1118 may be formed in a cylindrical shape and may have a threaded portion formed on a cooling water supply pipe A thread can be formed.

A grip protrusion 1118a protruding outwardly can be formed on the outer surface of the rotation coupling member 1118 so that a user can easily rotate the rotation coupling member 1118 to screw the cooling water supply pipe.

The rotation coupling member 1118 may be formed with a light incidence part 1119 which is gradually narrowed from the upper part to the lower part of the rotary engaging member 1118, The engagement protrusions 1117 protruding to the outside of the nozzle body 1110 are fitted to the lower ends of the light incidence parts 1119 with the lower end part of the light guide part 1110 inserted.

The lower end of the nozzle body 1110 is inserted into the upper portion of the rotary coupling member 1110 of the rotary coupling member 1118 so that the engagement protrusion 1117 of the nozzle body 1110 contacts the lower end of the light guide member 1119 The nozzle body 1110 can be easily coupled to the rotary engaging member 1118 and the rotation engaging member 1118 and the nozzle body 1110 can be firmly engaged with each other.

The functions and effects of the respective components of the cooling water jetting means 9a to 9d described above will be described.

The cooling water jetting means 1100 of the solar module according to the embodiment of the present invention is configured such that the fin portion 1171 of the knob 1170 is inserted into the nozzle housing 1130 while the opening degree adjusting member 1150 is inserted into the nozzle housing 1130 1130 inserted into the coupling hole 1153 formed in the body portion 1151 of the opening adjustment member 1150 through the through hole 1133 of the opening adjustment member 1150. [

At this time, a bolt 1175 is fastened to the pin portion 1171 to be coupled to each other to prevent the knob 1170 from being detached from the opening adjustment member 1150.

The nozzle housing 1130 to which the knob 1170 and the opening degree adjusting member 1150 are coupled is connected to the sealing portion 1115 so that the sealing portion 1115 of the nozzle body 1110 seals the lower end of the nozzle housing 1130 The formed locking protrusions 1116 engage with each other in such a manner that they are fitted into the locking grooves 1135 formed in the nozzle housing 1130. [

Here, the lower end of the nozzle body 1110 is provided with a rotation engaging member 1118 in such a form that the engaging shoulder 1117 of the nozzle body 1110 extends over the lower end of the light-interfering portion 1119 of the rotation engaging member 1118, Lt; / RTI >

The cooling water spraying unit 1100 of the solar module thus constructed is installed around the solar module so as to spray the cooling water on the top surface of the solar module and can supply cooling water to the cooling water spraying unit 1100 of the solar module The rotation coupling member 1118 is rotated so as to be screwed to the cooling water supply pipe.

On the other hand, when the cooling water spraying unit 1100 of the solar module is connected to the cooling water supply pipe, the cooling water is supplied from the cooling water supply pipe, and the supplied cooling water passes through the Venturi unit 1111 of the nozzle body 1110, Is increased.

The cooling water having passed through the venturi 1111 is injected through the injection hole 1131 of the nozzle housing 1130 in a pulse shape while being mixed with the air through the air inlet hole 1112 formed in the nozzle body 1110 .

At this time, in order to adjust the spraying angle of the cooling water in an optimal state suitable for the solar module, the opening adjustment plate portion 1155 of the opening adjustment member 1150 adjusts the opening of the spray hole 1131, The knob 1170 is rotated to adjust the angle of spray of the cooling water.

11, when the cooling water is not supplied from the cooling water supply pipe, the cooling water remaining in the nozzle housing 1130 can not be injected into the spray hole 1131, 113 and then backwardly discharged to the cooling water supply pipe through the nozzle body 1110. [

Accordingly, the cooling water spraying unit 1100 of the solar module according to the embodiment of the present invention can efficiently perform cleaning and cooling of the solar module by spraying cooling water at an optimum angle suitable for cooling and cleaning of the solar module By providing the cooling water injecting means 1100 of the solar module in an optimized number, the facility cost can be reduced and the amount of cooling water used can be reduced.

In addition, the injection angle of the cooling water can be easily adjusted by rotating the knob 1170, and the cooling water injecting unit 1100 of the solar module can not be ejected to the nozzle housing 1130, Can be prevented from becoming impossible.

The nozzle housing 1130 and the nozzle body 1110 are coupled to each other by the locking protrusions 1116 and the locking grooves 1135 so that the cooling water injection means 1100 of the solar module can be easily manufactured.

In addition, the opening adjustment plate portion 1155 for sealing the injection hole 1131 can seal the injection hole 1131 by the elastic force to prevent the cooling water from flowing out from the sealed position, so that the cooling water can be injected at an accurate angle.

In addition, the venturi 1111 and the air inflow hole 1112 are formed in the nozzle body 1110 and the cooling water is jetted in the form of a pulse, so that the cooling effect and the cleaning effect of the cooling water can be improved.

Hereinafter, the cooling water distributing means 5 according to an embodiment of the present invention will be described in more detail with reference to FIGS. 12 to 15. FIG.

12 to 15, the cooling water distributing means 100 of the photovoltaic power generation facility according to the embodiment of the present invention may include a distribution body 110. [

The dispensing main body 110 is a part of the body of the cooling water distributing means 100. The dispensing main body 110 may include an inlet 111 through which the cooling water flows and an outlet 113 through which the introduced cooling water is discharged.

The inlet 111 may be formed in the dispensing body 110 such that it may enter the side of the dispensing body 110 and enter the upper portion of the center of the dispensing body 110, 110 to the sides of the dispensing body 110. The dispensing body 110 may include a plurality of dispensing bodies 110,

A plurality of outlets 113 may be formed and a plurality of outlets 113 may be arranged radially around the inflow port 111 formed at the center when the dispensing body 110 is viewed from a plane.

The inlet ports 111 are connected to each other by a hose to receive cooling water. Each of the discharge ports 113 is connected to each of the discharge nozzles by a hose to supply cooling water introduced into the inlet port 111 Of the spray nozzle.

At this time, a hose coupling member 190 may be coupled to the outer end of the inlet port 111 and the outlet port 113 to form a thread so that the hose may be screwed.

Since the inlet 111 and the outlet 113 are formed around the dispensing main body 110 in the dispensing main body 110, the dispensing nozzle and the coolant supply device can be easily connected to the dispensing main body 110, The installation space of the cooling water distributing means 100 of the photovoltaic system can be minimized.

The dispensing body 110 may include a bracket 130. This bracket 130 can easily fix the cooling water distributing means 100 of the photovoltaic power generation facility to a side wall, a floor, a ceiling, and the like.

Meanwhile, the bracket 130 may be formed in a plate shape, and the bracket 130 may be formed with a bolt hole through which a fastening member such as a bolt can be inserted and fastened.

The bracket 130 may have a body fitting portion 131 protruding upward from the periphery of the bracket 130. A locking protrusion 133 protruding outward is formed at the end of the body fitting portion 131, Can be formed.

At this time, the distribution body 110 is formed with a locking groove 117 in which a locking protrusion 133 is fitted in a portion corresponding to the locking protrusion 133 so that the locking protrusion 133 of the bracket 130 is inserted into the distribution body 110, The bracket 130 can be easily coupled to the distribution body 110 in such a manner as to be fitted in the locking groove 117 of the bracket 130. [

A locking protrusion 133 is formed in the distribution body 110 and a locking groove 117 is formed in the bracket 130 so that the locking protrusion 133 and the locking protrusion 117 are fitted to each other But it can also be configured as a losing form.

The dispensing body 110 may then include a sidewall portion 115. The side wall part 115 may be formed in a shape that protrudes upwardly from the upper surface of the distribution body 110 with respect to the inflow port 111 as a part in which the distribution selection unit 200 to be described later is received.

At this time, both the inlet 111 and the outlet 113 are located inside the side wall 115.

In the embodiment, four outlets 113 are formed so that the portion of the outlet 113 positioned inside the side wall portion 115 is radially spaced 90 from the inlet 111.

In addition, a residual discharge hole 119 may be formed in the dispensing main body 110. The residual discharge hole 119 is formed in the inlet port 111 and the outlet port 111. When the supply of the cooling water to the inlet port 111 is stopped, (110) so as to be communicated with the inlet (111) from the inner upper surface of the side wall (115) so as to be able to discharge through the inlet (111).

Since the residual discharge hole 119 is formed, the cooling water remaining in the distribution body 110 can be discharged through the inlet 111, so that the cooling water distributing means 100 can be prevented from being damaged have.

13, 16 and 17, the cooling water distributing means 100 of the photovoltaic power generation equipment according to the embodiment of the present invention may include a distribution selection unit 200. [

The distribution selection unit 200 may be configured to selectively open the outlet 113 of a plurality of outlets 113 to discharge the cooling water only to the outlet 113 selected by the distribution selection unit 200.

The distribution selection unit 200 may be seated in the side wall portion 115 so as to be rotatable within the side wall portion 115 of the distribution body 110 and the distribution selection unit 200 may receive the inlet The height H of the cooling water may be changed by the pressure.

That is, when the cooling water is introduced through the inlet 111, the distribution selection unit 200 increases the height H of the distribution selection unit 200 where the height H becomes high and the supply of the cooling water is cut off, H is again returned to the initial height H so that the height H is lowered.

Meanwhile, the distribution selection unit 200 may include a lower housing 210 and an upper housing 230.

The lower housing 210 may be formed in the shape of a container having an open top and a bottom wall of the lower housing 210 may be formed at a position corresponding to the inlet 111 so that cooling water flowing through the inlet 111 An inlet hole 211 is formed in the lower housing 210 so that the cooling water flowing into the lower housing 210 through the inlet hole 211 is discharged to the outlet 113 A discharge hole 213 may be formed at a portion corresponding to the discharge hole 213.

Here, the discharge hole 213 may be formed only at a position corresponding to one of the plurality of discharge ports 113, and may be formed at a position corresponding to all the discharge ports 113, as in the embodiment, A sealing member 250 may be installed on the lower housing 210 to seal part of the discharge holes 213. In this case,

The sealing member 250 may be formed in a plate shape and may be formed to have a size capable of sealing a part of the discharge holes 213 of the plurality of discharge holes 213. Around the sealing member 250, A plurality of pin holes 251 are formed.

The lower housing 210 is provided with a plurality of protruding pins 217 at a portion where the closure member 250 is to be seated so that the protruding pin 217 is fitted into the pin hole 251, Member 250 can be engaged.

The upper housing 230 may be coupled to the lower housing 210 to form a pressure chamber 220 therein and the lower housing 210 may be inserted into the lower portion of the lower housing 210, And the open upper portion of the lower housing 210. As shown in Fig.

The top surface of the upper housing 230 may be formed as a wall so as to surround the driving unit 300 and a seating part 233 on which the driving unit 300 is seated. And a coupling portion 231 projecting upwardly and coupled to the drive unit 300 may be provided at the central portion.

The coupling unit 231 may be formed into a rod shape and may be formed into a rod shape having a polygonal periphery so as to rotate the distribution selection unit 200 by receiving the driving force of the driving unit 300 .

On the other hand, a guide groove 215 is formed on the periphery of the lower housing 210 so as to extend upward and downward. A guide protrusion 235 protrudes inward from the inner circumference of the upper housing 230, The lower housing 210 and the upper housing 230 can be engaged with each other in such a manner that the lower housing 210 and the upper housing 230 are fitted into the guide groove 215.

The distribution selection unit 200 configured as described above is configured such that the upper housing 230 and the lower housing 210 are coupled to each other to form a pressure chamber 220 therein, The height H of the distribution selection unit 200 is increased so that the pressure of the pressure chamber 220 increases and the upper housing 230 is separated from the upper portion of the lower housing 210. [

On the other hand, when the inflow of the cooling water into the pressure chamber 220 is cut off, the cooling water is discharged through the discharge hole 213 and the pressure of the pressure chamber 220 is reduced. Therefore, the upper housing 230 The height H of the distribution selection unit 200 is lowered to the initial position, that is, downward.

That is, when the cooling water flows into the pressure chamber 220, the distribution selection unit 200 moves the upper housing 230 upward to the upper portion of the lower housing 210. When the cooling water flows out of the pressure chamber 220, The height H of the distribution selection unit 200 is lowered so that the upper housing 230 coming down from the upper housing 230 descends again.

In this manner, the height of the dispense selection unit 200 is adjusted so that the drive unit 300, which will be described later, can be operated.

18 and 19, the cooling water distributing means 100 of the photovoltaic power generation equipment according to the embodiment of the present invention may include a main body case 150.

The main body case 150 can receive and seal the distribution selection unit 200 and the drive unit 300 installed in the distribution body 110.

The body case 150 may be formed to cover and seal the upper part of the dispensing main body 110. A screw fixing hole 151 is formed around the main body case 150, Such as a fastening member.

A check window 153 may be formed at the center of the upper portion of the main body case 150. The check window 153 may include a transparent cap 155 such as glass or synthetic resin for visually checking the inside of the main body case 150, As shown in Fig.

A plurality of unit fixing portions 157 formed in a rod shape in which the drive unit 300 is fixed are formed in the periphery of the inside of the main body case 150, more specifically around the check window 153, .

A locking protrusion 159 protruding inwardly may be formed at a central portion of the body case 150.

In addition, the main body case 150 may include a height (H) restricting member 170. The height H limiting member 170 is provided inside the body case 150 to prevent the height H of the distribution selecting unit 200 from being increased so that the distribution selecting unit 200 does not become higher than a predetermined height H. [ .

The height restriction member 170 supports the upper periphery of the distribution selection unit 200 and more specifically the upper housing 230 to limit the upward movement of the upper housing 230 beyond a predetermined height H. [ can do.

The height restriction member 170 is formed with a support hole 171 through which the seating portion 233 of the upper housing 230 is inserted and supported in a central portion of the upper housing 230. When the upper housing 230 is moved, And the height limiting member 170 may guide the movement of the upper limit member 170. The height limiting member 170 may guide the movement of the upper limit member 170 to the upper surface of the main body case 150, May be coupled to the case 150.

As shown in FIG. 18 to FIG. 21, the apparatus may include a driving unit 300 of a photovoltaic power generation facility according to an embodiment of the present invention.

This drive unit 300 can rotate the distribution selection unit 200 by operation of the distribution selection unit 200. [

Meanwhile, the driving unit 300 may include a first guide unit 310. The first guide part 310 may be provided to protrude downward from the inside of the main body case 150, that is, between the check window 153 of the main body case 150 and the unit fixing part 157 .

The first guide part 310 is formed in a cylindrical shape and a plurality of first teeth 311 having an inclined surface 311a which is downward or upward can be formed at a lower end thereof.

In addition, the driving unit 300 may include a vertical moving member 330.

The upper and lower housing members 330 and 330 are coupled to each other at an upper portion of the coupling portion 231 of the upper housing 230 to move together with the upper and lower housings 230 to rotate the upper housing 230 The selection and distribution unit can be rotated.

An outer tooth 331 having an inclined surface 331a of a shape corresponding to the first teeth 311 may be formed on an outer surface of the upper and lower movable bodies 330. An inner tooth 331 may be formed on the inner surface of the upper and lower teeth 330, An inner tooth 337 having an inclined surface 337a upward or downward at a position shifted from the outer tooth 331 may be formed.

A coupling hole 339 in which the coupling portion 231 of the upper housing 230 is inserted may be formed at the center of the upper and lower movable members 330 where the inner teeth 337 are formed, A shape corresponding to the shape of the coupling portion 231, that is, a polygonal shape may be formed so as to rotate together with the upper and lower movable members 330 without slipping with each other.

Further, on the lower periphery of the upper and lower movable members 330, a support protrusion 333 protruding outwardly to support an elastic member 370 to be described later may be formed.

The upper end of the center portion of the upper and lower movable members 330 is inserted into the inside of the check window 153 to display a display unit 335 on which markings such as characters or symbols are formed to indicate the rotating direction of the distribution selecting unit 200 .

The drive unit 300 may include a second guide member 350. The second guide member 350 may be disposed at a lower portion of the upper and lower movable members 330 and may be coupled to the end of the unit fixing portion 157 of the body case 150.

The second guide member 350 may be formed in a plate shape. The second guide member 350 may protrude in a cylindrical shape to be inserted into the upper and lower movable members 330 at the center of the second guide member 350, A second tooth 351 having an inclined surface 351a engaging with the second tooth 351 may be formed.

A through hole 353 is formed in the periphery of the second guide member 350 so that a fastening member such as a bolt passes through the through hole 353 of the second guide member 350 and is fastened to the unit fastening portion 157 The second guide member 350 can be fixed to the unit fixing portion 157. [

Further, the drive unit 300 may include an elastic member 370. The elastic member 370 is formed so that an elastic force acts on the vertical moving member 330 located between the first guide part 310 and the second guide member 350 in a direction in which the second guide member 350 is positioned The second guide member 350 can be resiliently supported by the main body case 150.

The elastic member 370 may be formed as a coil spring and the elastic member 370 may have a shape in which one end is supported by the main body case 150 and the other end is secured to the support jaw 333 of the upper and lower movable members 330 And may be installed between the main body case 150 and the upper and lower movable members 330.

When the height H of the distribution selection unit 200 is increased, the driving unit 300 constructed as described above overcomes the elastic force of the elastic member 370 so that the upper and lower moving parts 330 move upward, The upper and lower teeth 331 are guided by the inclined face 311a of the first tooth 311 and the inclined face 331a of the outer tooth 331 while being meshed with the first tooth 311, The material 330 rotates (see Fig. 21).

On the other hand, when the height H of the distribution selection unit 200 is lowered, the upper and lower movable members 330 move downward by the elastic member 370, and to the inside of the upper and lower movable members 330, The second guide member 350 is inserted and the inner tooth 337 is engaged with the second tooth 351 so that the inner tooth 337 is guided by the inclined surface 337a and the inclined surface 351a of the second tooth 351, So that the upper and lower teeth 330 are further rotated in the direction in which they are rotated when the first teeth 311 and the teeth 331 are engaged with each other (see FIG. 20).

At this time, when the upper and lower movable members 330 move upward and the first teeth 311 and the outer teeth 331 are engaged with each other, the upper and lower movable members 330 rotate at an angle of 45 and the upper and lower movable members 330 When the inner tooth 337 and the second tooth 351 are engaged with each other, the upper and lower movable members 330 rotate at an angle of 45 and the upper and lower movable members 330 make a total of 90 angles .

Accordingly, as the upper and lower moving member 330 is rotated by the upward / downward movement of the upper moving member 330, the distribution selecting unit 200 coupled to the upper moving member 330 rotates together to rotate the plurality of radially arranged The cooling water can be sequentially discharged to the plurality of outlets 113 in such a manner that the outlet 113 and the discharge hole 213 are communicated with each other.

In order to adjust the rotation angle of the distribution selecting unit 200 that rotates when the upper and lower moving bodies 330 move up and down once, the outer teeth 331 and the inner teeth 337 of the upper and lower moving bodies 330, And the numbers of the first teeth 311 and the second teeth 351 to be engaged with the first tooth 311 and the second tooth 351 are respectively increased.

The functions and effects of the respective components of the cooling water distributing means 5 described above will be described.

The cooling water distributing means 100 of the photovoltaic power generation facility according to the embodiment of the present invention is constructed such that the lower housing 210 and the upper housing 230 are coupled to each other in the sidewall portion 115 of the distribution body 110, The unit 200 is seated.

The upper and lower movable members 330 are inserted into the center of the unit fixing part 157 of the main body case 150 and the first guide part 310 is fastened to the lower end of the unit fixing part 157 in this state The driving unit 300 is coupled to the main body case 150 in such a manner that the driving unit 300 is engaged by the member.

At this time, an elastic member 370 is positioned between the support jaw 333 of the upper and lower movable member 330 and the main body case 150, and the display portion 335 of the upper and lower movable member 330 is positioned between the support case 333 of the main body case 150 And is partially inserted into the check window 153 formed at the center and is coupled to the main body case 150 in a manner that the periphery of the height limiting member 170 is extended to the latching jaw 159 of the main body case 150.

The main body case 150 coupled to the driving unit 300 is coupled to the dispensing main body 110. At this time, the driving unit 300 is seated inside the seating portion 233 of the upper housing 230 The coupling unit 231 of the upper housing 230 is inserted into the coupling hole 339 formed at the lower center of the upper and lower movable members 330 so that the driving unit 300 and the distribution selection unit 200 are coupled to each other The main body case 150 and the dispensing main body 110 are engaged.

The cooling water distributing means 100 of the solar power generating apparatus configured as described above separates the bracket 130 coupled to the distribution body 110 and fixes the bracket 130 at a position where the cooling water distributing means 100 is to be installed, The dispensing body 110 is coupled to the bracket 130 in such a manner that the locking protrusion 133 is fitted into the locking groove 117 of the dispensing body 110.

A hose or piping connected to the spray nozzle is connected to the discharge port 113 formed around the distribution body 110 fixed to the bracket 130 and a cooling water supply facility Connect with hose or piping.

Here, when the spray nozzle is not connected to a part of the plurality of outlets 113, the outlet 113 is blocked with a stopper to prevent the outflow of the coolant to the outside.

When the cooling water distributing means 100 is installed in this manner, the cooling water is supplied from the cooling water supplying device so that the cooling water can be injected through the injection nozzle.

The cooling water is supplied to the pressure chamber 220 of the distribution selection unit 200 through the inlet 111 of the distribution body 110 and the inlet 211 of the distribution selection unit 200, And the height H of the distribution selection unit 200 is increased in such a manner that the upper housing 230 is moved upward from the lower housing 210 by the pressure of the cooling water to be supplied.

The upper housing 230 overcomes the elastic force of the elastic member 370 to move the upper moving member 330 upward and the upper moving member 330 moves to the upper side with the outer teeth 331, And rotates at an angle of 45 with the distribution selection unit 200 while being guided by the first teeth 311 of the part 310 (see Fig. 21).

When the supply of cooling water is cut off in the cooling water supply facility, the pressure in the pressure chamber 220 is lowered, and the upper housing 230, which has moved upward, moves back to the initial position, The height H of the distribution selection unit 200 is lowered.

At the same time, the upper and lower movable members 330 are also moved downward by the elastic members 370. The upper and lower movable members 330 are engaged with the second teeth 351 of the second guide member 350 located at the lower portion, 337 are engaged and guided, and rotated at an angle of 45 in the same direction as the direction in which they were rotated together with the distribution selection unit 200 (see Fig. 20).

When the upper and lower flow dividing members 330 are repeated one time up and down by the supply and interruption of the cooling water, the distribution selecting unit 200 rotates in the same direction at an angle of 90, The radially positioned discharge port 113 is sequentially opened to be communicated with the discharge hole 213 so that the cooling water can be sequentially supplied to the plurality of spray nozzles.

At this time, since the display window 335 for confirming the rotation of the upper and lower movable members 330 is provided as the confirmation window 153, it is possible to determine whether the cooling water is discharged through any one of the plurality of outlets 113 Can be confirmed.

On the other hand, an electromagnetic valve for supplying and blocking the cooling water is provided between the cooling water supply device and the inlet 111 so that the cooling water is supplied and blocked at regular intervals to sequentially supply the cooling water through the plurality of injection nozzles have.

The cooling water remaining in the cooling water distributing means 100 is discharged to the inlet 111 through the discharge hole 113 and the residual discharge hole 119. In particular, When the temperature is low as in winter, the cooling water distributing means 100 can be prevented from being frozen due to the residual cooling water.

Accordingly, the cooling water distributing means 100 of the photovoltaic power generation system according to the embodiment of the present invention distributes and supplies the cooling water sequentially to the respective injection nozzles by only supplying and interrupting the cooling water without using a separate power source, Maintenance cost and electricity consumption can be reduced.

Further, by sequentially supplying the cooling water to the plurality of injection nozzles, the efficiency of cleaning and cooling can be improved, and the consumption amount of the cooling water to be sprayed can be minimized.

In addition, since the cooling water can be supplied directly from the cooling water supply facility such as the water supply facility without the storage tank for temporarily storing the cooling water, the construction cost and installation place of the output improvement device can be reduced.

Further, the residual discharge holes 119 can be formed to prevent the occurrence of freezing due to the residual cooling water.

In addition, the check window 153 is provided to easily grasp the discharge port 113 through which the cooling water is discharged, and it is possible to easily grasp the clogging of the discharge port 113 or the failure of the spray nozzle.

Further, the discharge port 113 and the inlet port 111 are located around the distribution body 110, so that the installation can be easily performed, and the installation space can be minimized.

Further, since the bracket 130 is detachably coupled to the dispensing main body 110, there is an advantage that it is easy to install.

As described above, according to the embodiment of the present invention, water is supplied to the solar modules 10a and 10b without the need for a cooling water tank or a pump, and can be used for cleaning and cooling the solar modules 10a and 10b. 9b, 9c, and 9d configured in the solar modules 10a and 10b, the cooling water is supplied to the solar modules 10a and 10b in a high pressure state so that the solar modules 10a and 10b are efficiently As shown in FIG.

In addition, as described above, since the efficiency improvement facility can be constituted by low-cost components, the optimum efficiency improvement facility can be adopted for the solar power generation facility that is manufactured in the home or in the popular type.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

1: pressurized water source 3: control means
5: Distribution means 7: Cooling water supply pipe
9, 9a, 9b, 9c, 9d: cooling water injection means 30: valve
10, 10a, 10b: solar module 34:
32:
100: Cooling water distribution device of solar power generation facility 110: Distribution body
111: inlet 113: outlet
115: side wall portion 117: locking groove
119: Residual vent hole 130: Bracket
131: main body fitting portion 133: locking protrusion
150: main body case 151: screw fastening hole
153: Confirmation window 155: Transparent cap
157: unit fixing portion 159:
170: height restricting member 171: supporting ball
190: Hose coupling member 200: Distribution selection unit
210: lower housing 211: inflow hole
213: Exhaust hole 215: Guide groove
217: projecting pin 220: pressure chamber
230: upper housing 231:
233: seat part 235: guide projection
250: sealing member 251:
300: drive unit 310: first guide part
311a, 331a, 337a, 351a: an inclined surface 311: a first tooth
330: Shanghai East member 331: Outer teeth
335: display portion 337: inner teeth
350: second guide member 351: second toothed member
353: Through hole 370: Elastic member
1100: Cooling water injection nozzle of solar module
1110: nozzle body 1111: venturi portion
1112: Air inflow hole 1113: Discharge guide
1114: seal member 1115: sealing member
1116: locking protrusion 1117:
1118: rotation coupling member 1118a:
1119: light-incident portion 1130: nozzle housing
1131: Inlet hole 1133: Through hole
1135: locking groove 1150: opening adjustment member
1151: body portion 1153: engaging hole
1155: opening adjusting plate portion 1157: connecting portion
1170: knob 1171:
1175: Bolt

Claims (19)

1. An efficiency improvement system for a solar power generation facility that maintains or improves efficiency by injecting cooling water into a solar power generation facility including a solar cell module that generates electricity by condensing sunlight,
A pressurized water source for pressurizing and supplying the cooling water;
Two or more cooling water jetting means for jetting the cooling water supplied from the pressurized water source to the solar module;
A cooling water distributing means for sequentially distributing the cooling water supplied from the pressurized water source to each of the cooling water injection means; And
And a valve for shutting off or opening the supply of cooling water from the pressurized water source,
Wherein the cooling water distributing means is configured to sequentially switch the distribution direction of the cooling water by the pressure of the cooling water.
The method according to claim 1,
Further comprising a control unit for controlling the opening and closing of the valve to adjust the injection amount and the injection amount of the cooling water.
The method according to claim 1,
Wherein the pressurized water source is a water supply facility.
delete The method according to claim 1,
Wherein the cooling water distributing means comprises an inner rotating body having outlets corresponding to the plurality of cooling water spraying means and rotated by the pressure of the cooling water, wherein the opening of the discharging opening is sequentially And the cooling water is sequentially distributed to the plurality of cooling water jetting units.
The method according to claim 1,
Wherein the distributing means comprises:
A dispensing main body in which a plurality of discharge ports through which cooling water is discharged are formed radially and an inlet through which cooling water flows is formed at the center;
A distribution selecting unit that rotates at an upper portion of the distribution body to selectively open or shut off the plurality of discharge ports, forms a pressure chamber into which cooling water flows, and changes the height by cooling water flowing into the pressure chamber;
A drive unit coupled to the distribution selection unit to rotate the distribution selection unit according to a height changed to the distribution selection unit; And a main case coupled to the distribution body to receive the distribution selection unit and the drive unit.
The method according to claim 6,
Wherein the distribution selection unit comprises:
A lower housing having an inlet hole communicating with the inlet and an outlet hole communicating with an outlet of a portion of the plurality of outlet holes, and a pressure chamber coupled to the lower housing to form the pressure chamber, And an upper housing coupled to the lower housing so as to be movable upward and downward and having a coupling portion to which the driving unit is coupled.
The method according to claim 6,
The driving unit includes:
An upper and lower easel member coupled to the distribution selecting unit and including an outer tooth that moves up and down according to a changed height of the distribution selecting unit and has a plurality of outer teeth formed thereon and an inner tooth that has a plurality of inner teeth formed around the inner teeth;
A first guide part protruding downward from an inner center of the main body case and having a plurality of first teeth for guiding the inclined surfaces of the outer teeth when the up and down moving parts move upward to rotate the up and down moving parts; And a second guide member located at a lower portion of the upper and lower movable members and having a plurality of second teeth for guiding the inclined surfaces of the inner teeth when the movable upper and lower movable members move downward to rotate the movable upper and lower members. Efficiency facility of photovoltaic power generation facilities.
9. The method of claim 8,
The driving unit includes:
Further comprising an elastic member elastically supporting the upper and lower movable members in the main body case so that elastic force acts on the upper and lower movable members in a direction in which the second guide member is located. .
The method according to claim 6,
The main body case includes:
And a confirmation window for confirming an outlet opened by the distribution selection unit in a form of grasping the state of the drive unit.
The method according to claim 6,
The dispensing body comprises:
And a residual discharge hole for discharging the cooling water remaining in the distribution body through the inlet is formed.
The method according to claim 1,
Wherein the injection means
A nozzle body that receives the cooling water and ejects the cooling water in a pulse shape;
A nozzle housing which surrounds the nozzle body and has a spray hole formed in a long left and right direction to discharge the cooling water discharged from the nozzle body in a flat shape;
An opening degree adjusting member which rotates inside the nozzle housing to adjust an opening degree of the injection hole; And a knob provided at an upper portion of the nozzle housing to rotate the opening adjustment member.
13. The method of claim 12,
The nozzle body includes:
A venturi portion formed in a shape in which the inner space narrows and then widens so as to improve the jetting power of the cooling water; And an air inflow hole through which air is mixed with the cooling water discharged from the venturi and the outside air is introduced to discharge the cooling water in a pulse shape.
13. The method of claim 12,
The nozzle body includes:
And a discharge guide for collecting the cooling water of the nozzle housing and guiding the discharge of the cooling water to the nozzle body when the supply of the cooling water is stopped by dividing the internal space of the nozzle housing.
15. The method of claim 14,
The discharge guide
And a seal member provided at a portion in contact with the nozzle housing to seal the space between the nozzle housing and the discharge guide.
13. The method of claim 12,
A locking protrusion protruding outwardly is formed on one of the nozzle body and the nozzle housing and a locking groove is formed on the other of the nozzle body and the nozzle housing to which the locking protrusion is coupled to couple the nozzle body and the nozzle housing together Equipment for improving the efficiency of solar power generation facilities.
13. The method of claim 12,
Wherein the opening adjustment member comprises:
A body portion to which the knob is coupled;
An opening adjusting plate part spaced apart from the body part and closely contacted with the inside of the nozzle housing to adjust an opening angle of the injection hole to adjust an injection angle of the cooling water; And a connection portion connecting the body portion and the end of the opening adjustment plate portion so that the opening adjustment plate is in close contact with the nozzle housing by an elastic force.
The method according to claim 1,
Further comprising a water softening filter for softening the cooling water.
19. The method of claim 18,
Wherein the water softening filter comprises a cation exchange resin.

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