KR101589538B1 - Washing apparatus for solar photovoltaic module - Google Patents

Abstract

The present invention relates to a solar module, comprising: a plurality of nozzles for spraying washing water to a solar module; A dispensing unit for simultaneously supplying cleaning water to all or a part of the plurality of nozzles or supplying the cleaning water with a time lag; A rinse water supply unit connected to the dispensing unit and connected to the dispensing unit and supplying the rinse water to the dispensing unit; And a cleaning water supply unit connected to the cleaning water supply unit and the distribution unit to supply cleaning water from the cleaning water supply unit to the distribution unit or to naturally discharge the cleaning water remaining inside the piping and the distribution unit, Wherein the plurality of nozzles, the distributing unit, and the washing water supplying unit are sequentially arranged in the vertical direction with respect to the solar cell module, so that the surface of the solar cell module can be efficiently And particularly to a cleaning apparatus for a solar module capable of preventing freezing due to freezing of a drain line in winter by dewatering cooling water supplied through a drain line in particular.

Description

[0001] WASHING APPARATUS FOR SOLAR PHOTOVOLTAIC MODULE [0002]

The present invention relates to a cleaning device for a solar module, and more particularly, to a cleaning device for cleaning and cooling the surface of a solar module efficiently with a small amount of cooling water, To a cleaning device for a solar module capable of preventing freezing due to freezing of a drain line.

Recently, PV power generation facilities are becoming unmanned and larger, and it is necessary to install a large area solar module for electric power generation. Therefore, it is a place where people can hardly access, such as roofs, building walls, Is selected.

Therefore, the photovoltaic power generation facility is exposed to the external environment for a long time, and the amount of condensation is reduced due to scattered dust, algae discharge, dust, and other contaminants.

In addition, the temperature rise of the solar module due to the condensation of the sunlight causes a deterioration of the output of the solar power generation facility.

In the case of the most widely used solar cell, when the temperature of the solar module is increased by 1 ° C, the output of the solar module is reduced by 0.4 to 0.5%. In particular, during the summer, And the output is reduced to 15 to 20%.

Also, during the winter season, snow accumulated on the surface of the photovoltaic module is one of the direct causes of reducing the power generation output of the photovoltaic module.

Therefore, the photovoltaic power generation facility is required to cool or cool the temperature of the photovoltaic module and clean or snow-clothe the accumulated dirt, snow, rain, etc. in the photovoltaic module, There is also a need to equip facilities to maintain facilities.

Such solar power generation facility maintenance devices include a method of cleaning a solar module with a mechanical driving force such as a brush of a vehicle, a method of cleaning a solar module by connecting a water hose to the upper part of the solar module, In addition, there is a water injection method in which a solar module is washed by spraying water with a strong water pressure through a separate nozzle.

The method of using the brush has a disadvantage in that it is necessary to manufacture a separate brush suitable for the maintenance apparatus of the photovoltaic power generation facility and to provide a special method for cooling the photovoltaic module when it is overheated.

There is a drawback in that the method of flowing water through the water hose is not very effective in removing dirt or snow.

Therefore, although the water injection method for cleaning the solar module by spraying the water through the nozzle is effective, there is a disadvantage in that water is consumed because the water is sprayed with strong water pressure. Therefore, There is a limit.

Also, in areas with high snowfall in winter, snow that does not melt due to winter snowfall accumulates on the surface of the photovoltaic module, resulting in a decrease in solar power output, and the problem of the occurrence of freezing of drainage lines due to low temperature around the winter have.

Open Patent No. 10-2013-0077119 (published on Jul. 09, 2013) Domestic registered patent No. 10-0982263 (registered on September 08, 2010) Domestic registered patent No. 10-1301176 (registered on Aug. 22, 2013)

The present invention is to provide a cleaning device for a solar module which can efficiently clean and cool the surface of the solar module even if only the water pressure of a home is used without using a separate pump.

It is another object of the present invention to provide a cleaning device for a solar module capable of preventing freezing due to freezing of a drain line in winter by dewatering cooling water supplied through a drain line.

The various problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a solar module comprising: a plurality of nozzles for spraying washing water to a solar module; A dispensing unit for simultaneously supplying cleaning water to all or a part of the plurality of nozzles or supplying the cleaning water with a time lag; A rinse water supply unit connected to the dispensing unit and connected to the dispensing unit and supplying the rinse water to the dispensing unit; And a cleaning water supply unit connected to the cleaning water supply unit and the distribution unit to supply cleaning water from the cleaning water supply unit to the distribution unit or to naturally discharge the cleaning water remaining inside the piping and the distribution unit, Wherein the plurality of nozzles, the dispensing unit, and the cleaning water supply unit are sequentially arranged in the vertical direction with respect to the solar module.

The dispensing unit may include a number of first solenoid valves corresponding to the plurality of nozzles therein and connect the plurality of nozzles and the first solenoid valves to each other by piping, And a flow path for discharging the remaining washing water is formed.

The washing water supply unit may include a water pipe for supplying tap water as the washing water or an industrial water pipe for supplying industrial water as the washing water. The washing water supply unit supplies the ground water as the washing water And a pump connected to the groundwater supply pipe to raise the groundwater to the cleaning water supply and drainage unit.

The cleaning water supply unit includes an internal flow path formed by piping the distribution unit and the cleaning water supply unit, a second solenoid valve provided at an upper end of the internal flow path, and a second solenoid valve provided at a lower end of the internal flow path. A third solenoid valve and a controller for controlling the opening and closing of the second and third solenoid valves, and the third solenoid valve is connected to a drain line through which the washing water for cleaning and cooling the solar module is discharged .

The cleaning water supply unit includes an internal flow path formed by piping the distribution unit and the cleaning water supply unit, a second solenoid valve provided at an upper end of the internal flow path, and a second solenoid valve provided at a lower end of the internal flow path. 3 solenoid valve and a controller for controlling the opening and closing of the first solenoid valve incorporated in the dispensing unit together with the second and third solenoid valves, wherein the third solenoid valve is operable to perform a cleaning and cooling operation of the solar module And is connected to a drain line through which the completed washing water is discharged.

The cleaning device for the photovoltaic module may further include a cleaning water supply unit installed on the pipe for interconnecting the cleaning water supply unit and the distribution unit and mixing air into the water passing through the cleaning water supply unit, And a two phase flow assembly for increasing the injection pressure.

The nozzle includes a nozzle connection port communicating with a pipe connected to the distribution unit and having a diameter smaller than that of the pipe, a nozzle fixture coupled to one end of the nozzle connection port to fix the nozzle connection port to the pipe, A discharge port including a hemispherical discharge end portion coupled to the other end portion of the nozzle connection port and having a discharge cut-out portion that is forwardly and reversibly rotatable and biased asymmetrically through one side, and a discharge port connected to the other end edge of the nozzle connection port, And a hemispherical nozzle cover in which a plurality of discharge holes are arranged in a line along a surface of the nozzle cover.

The distribution unit includes a main body defining an internal space in which the first solenoid valve is installed, an inlet port connected to each of the first solenoid valves, and a plurality of nozzles And a water distribution port through which a flow path communicating with the abnormal flow assembly side is formed, wherein the main body is detachably coupled to the solar module.

The controller includes a controller body including the second and third solenoid valves, a supply port provided at an upper end of the controller body and communicated with the water pipe and the second solenoid valve, A drain port communicated with the third solenoid valve provided at a lower end portion of the internal flow path connected to the second solenoid valve, a water supply and drainage flow path connected to the internal flow path and directed to an upper end side of the controller body, A water supply and discharge port connected to an upper end of the drainage flow passage and provided at an upper end portion of the controller main body and communicating with the abnormal flow assembly side; a first and second and third solenoid valves electrically connected to the first, second and third solenoid valves, And a control panel for controlling the operation and stop of the valve.

The abnormal flow assembly includes a flow body formed with a flow path whose diameter becomes narrower toward an intermediate portion as compared with an upper end portion and a lower end portion of the flow body, And a diffuser which is formed at an upper end of the flow body and has a plurality of discharge slits vertically penetrating the flow inlet.

The nozzle connecting port includes a cylindrical reduced diameter portion having an inner diameter smaller than that of the pipe, a rotation supporting flange extending from an outer peripheral surface of the end portion of the reduced diameter portion to receive the discharge port, And a diameter-enlarged portion having an inner diameter larger than that of the neck portion and being wrapped by the discharge port.

The nozzle may further include a cylindrical rotating body extending from an edge of the discharge end and mounted on the nozzle connecting port and rotated.

The distribution unit may further include a link piece provided on one side of the main body and capable of pivoting, and at least one clamp coupled to the end of the link piece so as to clamp the edge of the photovoltaic module .

The distribution unit may further include a module fixing bolt which is detachably coupled to the clamp and fixed to the edge of the solar module.

The main body includes a first casing piece including a pair of first facing surfaces facing each other and a first connecting surface interconnecting the pair of first surfaces, a pair of second facing surfaces facing each other, And a second connecting surface for interconnecting the pair of second surfaces, wherein the pair of second side edges and the pair of first side edges are detachably engaged to form the second space, A first casing piece and a second casing piece formed on both sides of the first and second casing pieces to form a connection hole which is coupled along an edge of both opened sides and in which an outer port of the first solenoid valve is exposed; Wherein the first connection surface faces the solar module, the second connection surface faces the abnormal flow assembly, and the inlet and outlet ports of the water distribution port face the first solenoid valve Characterized in that the connection with the internal port.

The main body includes a first fixing groove formed along both side edges of the pair of first surfaces and the first connecting surface to receive the edge of the side piece, And a second fixing groove formed along both side edges of the connection surface to receive the edge of the side piece.

The side piece may include at least one of a first surface of the pair of first surfaces, a portion of the first connecting surface, a second surface of one of the pair of second surfaces, A first half formed with a first notch groove corresponding to a part of the outer circumferential surface of the outer port of the first solenoid valve along the other edge excluding the outer edge, And the outer edge is joined along the rest of the first surface, the remainder of the first connecting surface, the remaining second surface of the pair of second surfaces, and the remainder of the second connecting surface, And a second half formed with a second notched groove corresponding to the remaining portion of the outer circumferential surface of the outer port of the first solenoid valve along the other edges except for the edge, the remaining edge of the first half and the remainder of the second half The edge according to the abutment as the abutment of claim 1 gyeolhom section and the second section fit gyeolhom characterized by forming the connection hole.

The main body includes a third surface having a predetermined area, a third connecting surface extending from the opposite end edges of the third surface and facing each other, and a second connecting surface extending from both ends of the third connecting surface, A fourth surface having a constant area; a fourth connecting surface extending from both edge portions of the fourth surface and opposed to each other; and a fourth connecting surface facing the fourth connecting surface, And a fourth casing piece including a second side face that is closed at both side edges of the third casing piece and is detachably coupled to the third casing piece to form the internal space, Wherein the water distribution port is disposed and the edges of the first side surface and the second side surface abut against each other to form a connection hole through which the outer port of the first solenoid valve is exposed.

The main body includes a third notched groove cut along the edge of the first side surface in a shape corresponding to a portion of the outer peripheral surface of the outer port of the first solenoid valve, and a second notched groove formed along the edge of the second side surface, And a fourth notched groove cut in a shape corresponding to a remaining portion of the outer circumferential surface of the outer port of the valve, wherein the third notched groove and the fourth notched groove abut each other to form the connection hole.

The main body includes a coupling union for interconnecting the water distribution port and the inner port of the first solenoid valve, and a connection unit for connecting between the outer port of the first solenoid valve and the end of the pipe connecting the nozzle And a waterproof rubber ring.

The cleaning device for a solar cell module may further include a filter mounted on a pipe for interconnecting the cleaning water supply unit and the internal flow path.

The cleaning device for a solar module according to the present invention can achieve the following effects.

First, the present invention can operate the water pressure of the direct water supplied from the domestic water pipe, that is, the rinse water supply unit, through the rinse water supply unit and lift it through the abnormal flow assembly without using a separate pump, It is possible to sufficiently clean and cool the photovoltaic module with only the water pressure supplied from the piping.

Here, the present invention can efficiently wash and cool water by means of an abnormal flow assembly in which air is mixed with water supplied to the nozzle side so that even a small amount of cooling water can be efficiently cleaned and cooled. Therefore, unnecessary waste of water can be reduced .

Particularly, the present invention can be applied to cleaning and cooling water such as industrial water and ground water as well as tap water supplied from the domestic water pipe as described above with cleansing water, so that it can be used in any environment where water exists Excellent versatility.

Accordingly, the present invention is characterized in that various kinds of filters are mounted on the piping connecting between the rinse water supply part and the rinse water supply part such as the water pipe, the industrial water pipe and the ground water pipe, and various kinds of foreign substances mixed in the industrial water In the case of general tap water, activated carbon filter can be used to remove chlorine contained in tap water. In addition, in case of groundwater, components such as calcium or magnesium ions, which generate water, can be easily removed Therefore, various kinds of filters can be selectively used depending on the kind of water used as the washing water.

In addition, the present invention can uniformly transfer the water pressure supplied from the water pipe through the plurality of nozzles injected so that the angle can be adjusted uniformly over the entire area of the solar module, thereby achieving an excellent cleaning effect.

In particular, since the nozzle, the dispensing unit, the abnormal flow assembly, and the cleansing water supply / discharge unit are sequentially arranged in the vertical direction, the water sprayed through the nozzle and the remaining water can be drained in the gravity direction naturally, .

It will be appreciated that various embodiments of the inventive concepts of the present invention can provide various effects not specifically mentioned.

1 is a conceptual diagram showing the overall structure of a cleaning apparatus for a solar module according to an embodiment of the present invention.
2 is a perspective view showing an outer appearance of a nozzle, which is a main part of a cleaning apparatus for a solar module according to an embodiment of the present invention;
FIG. 3 is an exploded side conceptual view showing the overall structure of a nozzle, which is a main part of a cleaning apparatus for a solar module according to an embodiment of the present invention.
4 is an exploded perspective view showing the overall structure of a distribution unit which is a main part of a cleaning apparatus for a solar module according to an embodiment of the present invention.
5 is an exploded perspective view showing the overall structure of a distribution unit which is a main part of a cleaning apparatus for a solar module according to another embodiment of the present invention.
6 is a partially cutaway perspective view showing an internal structure of a controller, which is a main part of a cleaning apparatus for a solar module according to an embodiment of the present invention,
FIG. 7 is a cross-sectional perspective view showing an internal structure of the abnormal flow assembly, which is a main part of a cleaning apparatus for a solar module according to an embodiment of the present invention,

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings.

However, the present invention is not limited to the embodiments described herein but may be embodied in other forms.

Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the concept of the invention to those skilled in the art.

In the drawings, the thicknesses of layers and regions are exaggerated for clarity.

Terms such as top, bottom, top, bottom, or top, bottom, etc. are used to distinguish relative positions in components.

For example, in the case of naming the upper part of the drawing as upper part and the lower part as lower part in the drawings for convenience, the upper part may be named lower part and the lower part may be named upper part without departing from the scope of right of the present invention .

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention.

The singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a part or a combination thereof is described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning in the context of the relevant art and are to be construed as ideal or overly formal in meaning unless explicitly defined in the present application Do not.

Hereinafter, preferred embodiments of a cleaning apparatus for a solar module according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual view showing the overall structure of a cleaning apparatus for a solar module according to an embodiment of the present invention.

As shown in the drawing, the washing water supplied from the washing water supply unit 60 is supplied to the solar module 20 through the plurality of nozzles 20, 20, 20, and 20 via the washing water supply unit C and the distribution unit 30. [ It can be understood that the structure is a structure in which cleaning and cooling are performed while being sprayed at a uniform pressure on the substrate 10.

The plurality of nozzles 20, 20, 20 and 20 are for spraying cleaning water to the solar module 10 and the distribution unit 30 is for cleaning the whole or a part of the plurality of nozzles 20, 20, 20, For example, at the same time or at a time difference.

The cleaning water supply unit 60 is connected to the distribution unit 30 through piping and supplies cleaning water to the distribution unit 30. In the present invention, the cleaning water supply unit 60 is shown as a water supply pipe 61. However, But may be, for example, an industrial water pipe or an underground water pipe supplied with industrial water or ground water, respectively.

The washing water supplying and discharging part C is piped to the washing water supplying part 60 and the dispensing unit 30 and supplies the washing water from the washing water supplying part 60 to the dispensing unit 30, The inside of the washing water or cleaning water supply portion C and the pipes 71 and 72 that have been sprayed from the cleaning water supply portion 20, 20 and 20 and have been cleaned and cooled by the solar cell module 10 and the cleaning water remaining in the distribution unit 30 So that the cleansing water is naturally discharged.

Accordingly, the plurality of nozzles 20, 20, 20, 20, the dispensing unit 30, and the washing water supplying and discharging portion C are sequentially arranged in the vertical direction on the basis of the solar module 10, The finished or remaining washing water can be discharged naturally along the gravity direction.

It is to be understood that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention.

The plurality of nozzles 20, 20, 20, and 20 are used to supply washing water to the solar module 10 as described above. The spraying angle of the washing water can be adjusted. Will be described in detail.

The dispensing unit 30 includes a plurality of nozzles 20, 20, 20 and 20 and a corresponding number of first solenoid valves 31 therein. The dispensing unit 30 includes a plurality of nozzles 20, 20, 1 solenoid valves 31 are connected to each other to form a flow path for supplying washing water to each of the plurality of nozzles 20, 20, 20, 20 or discharging used washing water.

The rinse water supply unit 60 may include a water pipe 61 for supplying tap water as cleansing water and may include an industrial water pipe for supplying industrial water as cleansing water although not specifically shown.

As described above, when the tap water or the industrial water is used as the washing water, the washing water supply portion 60 supplies the tap water or the industrial water to the washing water supply portion C to be described later at a constant pressure. However, a pump (not shown) may be required when ground water is used as the washing water.

The cleaning water supply unit 60 is connected to a groundwater supply pipe (not shown) connected to an underground pipe (not shown) to supply ground water as cleansing water and a cleaning water supply unit C connected to a groundwater supply pipe, And a pump for raising the ground water to the side.

Hereinafter, the cleaning, cabinet and drainage operations of the cleaning apparatus for a solar module according to an embodiment of the present invention will be described with reference to the structure including the water pipe 61 something to do.

On the other hand, the rinse water supply / discharge portion C is connected to the distribution unit 30 and the rinsing water supply portion 60 by piping to form an internal flow path 41, the internal flow path 41 communicates with the water supply pipe 61, A second solenoid valve 42 is provided at the upper end of the inner flow path 41 and a third solenoid valve 43 is provided at the lower end of the inner flow path 41. The first, And 43 for controlling the opening and closing of the door.

The present invention also includes a piping 72 for interconnecting a piping water flow path 46 to be described later which is communicated with the internal flow path 41 of the cleaning water supply portion C, that is, the internal flow path 41, And an abnormal flow assembly (50) mounted on the nozzle (20, 20, 20, 20) for increasing the jetting pressure of the washing water supplied into the plurality of nozzles .

Here, the nozzles 20, 20, 20, 20, the distribution unit 30, the abnormal flow assembly 50, and the controller 40 are sequentially arranged in the vertical direction from the solar module 10 side, So that the water remaining in the pipes 71 and 72 can be discharged through the drain line 73 naturally in the gravity direction.

Although not shown in the drawings, a clamping device (not shown) may be separately provided on each of the nozzles 20 so as to spray clean water while adjusting an angle by fixing it to a frame edge of the solar module 10 .

2 and 3, it can be understood that the nozzle 20 includes a nozzle connection port 21, a nozzle fixture 22, a discharge port 23, and a nozzle cover 24.

The nozzle connection port 21 is communicated with the pipe 71 connected to the distribution unit 30 and has a smaller diameter than the pipe. The nozzle fixing port 22 is connected to one end of the nozzle connection port 21, 21) to the pipe (71).

The discharge port 23 includes a hemispherical discharge end 23a coupled with the other end of the nozzle connection port 21 and having a discharge cut-out portion 23s which is forwardly and reversibly rotatable and biased asymmetrically through one side will be.

The nozzle cover 24 is a hemispherical member that is coupled to the other end edge of the nozzle connecting hole 21 and incorporates a discharge port 23 and a plurality of discharge holes 24h are arranged in a line along the surface.

Therefore, the nozzle 20 is also provided with a discharge cut-off portion 23s formed in a manner asymmetrically passing through the nozzle connecting portion 21 in a manner that the washing water supplied through the nozzle connecting portion 21 is biased to one side in accordance with forward and reverse rotation of the discharge end portion 23a The direction of discharge of the washing water is irregularly formed so that the washing water can be discharged through the discharge hole 24h through the discharge cutout 23s at different spray angles.

More specifically, the nozzle connecting hole 21 has a rotation support flange 21f extending from the outer peripheral surface of the end portion of the cylindrical reduced-diameter portion 21s having an inner diameter smaller than that of the pipe 71, And a diameter enlarged portion 21b protruding on the rotary support flange 21f and having an inner diameter larger than the reduced diameter portion 21s and being wrapped by the discharge port.

The nozzle 20 further includes a cylindrical rotating body 23b that extends from the edge of the discharge end 23a and is mounted on the nozzle connecting hole 21 and rotates so that the rotating body 23b is connected to the nozzle connecting port 21 And can be smoothly rotated and supported by the rotation supporting flange 21f.

Accordingly, the user appropriately rotates the rotary body 23b in a reverse direction so as to adjust the angle at which the washing water is sprayed through the discharge hole 24h, thereby adjusting the position of the discharge cut-out portion 23s and spraying the washing water You can do it.

Of course, it is preferable that the nozzle cover 24 is made of a transparent or translucent material so that the user can visually identify the stopped position after the discharge cutout portion 23s is rotated.

The dispensing unit 30 is provided to supply the washing water to the plurality of nozzles 20, 20, 20 and 20 as described above. The dispensing unit 30 includes a main body 30a and a water distribution part 30b It is possible to recognize that the structure is included.

That is, the dispensing unit 30 is capable of uniformly distributing the hydraulic pressure of the washing water supplied with the elevated hydraulic pressure while passing through the abnormal flow assembly 50 to be described later.

The main body 30a forms an internal space in which the first solenoid valve 31 is housed.

The water distribution port 30b is installed in the main body 30a and has an inlet port 30p connected to each of the first solenoid valves 31 and has a plurality of nozzles 20, And a flow path communicating with the side of the flow assembly 50 is formed.

That is, the internal flow path of the water distribution port 30b is symmetrically formed so as to uniformly distribute and supply the hydraulic pressure of the washing water supplied through the abnormal flow assembly 50, which will be described later.

The main body 30a is preferably provided with a clamp 30c connected to the solar module 10 by a link piece 30k so that the main body 30a can be detachably coupled to the solar module 10. [

The link piece 30k is rotatably provided on one side of the main body 30a and the clamp 30c is rotatably coupled to the end of the link piece 30k to clamp at least one edge of the solar module 10 With the above-described members, it can be regarded as technical means for allowing the main body 30a to be detachably coupled to the solar module 10. [

At this time, the distribution unit 30 further includes a module fixing bolt 30cb which is detachably coupled to the clamp 30c and fixed to the edge of the solar module 10 as shown in an enlarged part on the upper left side of FIG. 4 .

The module fixing bolts 30cb are detachably fastened to the clamps 30c by screws so that the ends of the module fixing bolts 30cb come into contact with the edge of the solar module 10 in contact with the clamp 30c Thereby preventing damage to the edge of the solar module 10 due to the clamping or unclamping of the clamp 30c and maintaining a clean fixed state.

The main body 30a may have a structure including the first and second casing pieces 32 and 33 and the side piece 34 so that assembly and disassembly are facilitated without any additional tool.

That is, the first casing piece 32 includes a pair of first surfaces 32a and 32a facing each other and a first connecting surface 32c connecting the pair of first surfaces 32a and 32a to each other .

The second casing piece 33 includes a pair of second surfaces 33a and 33a facing each other and a second connecting surface 33c connecting the pair of second surfaces 33a and 33a to each other, The edges of the pair of second faces 33a and 33a and the edges of the pair of first faces 32a and 32a are detachably coupled to form an inner space.

The side pieces 34 are closed at both open sides formed by the first casing piece 32 and the second casing piece 33 and are joined along the edges of both opened sides and are connected to the outer port of the first solenoid valve 31 Thereby forming a connection hole 34c through which the first electrode 31a is exposed.

The first connection surface 32c faces the solar module 10 and the second connection surface 33c faces the abnormal flow assembly 50 and the inlet port 30p of the water distribution port 30b faces the solar module 10, And is connected to the inner port 31b of the first solenoid valve 31.

The first casing piece 32 is provided with a pair of first surfaces 32a and 32a and a first fixing groove 35a formed along both side edges of the first connecting surface 32c and accommodating the edge of the side piece 34, Respectively.

The second casing piece 33 is provided with a pair of second surfaces 33a and 33a and second fixing grooves 33a and 33b which are formed along both side edges of the second connecting surface 33c and accommodate the edge of the side piece 34 35b.

Here, the first tongue piece 32t is extended from the edge of the first surface 32a of one of the pair of first surfaces 32a, 32a, and one of the pair of second surfaces 33a, And is fixed to the edge of the second surface 33a.

At this time, the second tongue piece 33t is extended from the edge of the remaining second surface 33a of the pair of second surfaces 33a, 33a, so that the remaining tongue piece 33a of the pair of first surfaces 32a, And is fixed to the edge of the first surface 32a.

The first and second tongues 32t and 33t act as a member for desorbing and coupling the first and second casing pieces 32 and 33. Although not shown in the drawing, A stepped portion having a shape corresponding to the first and second tongues 32t and 33t may be formed at the edges of the first and second surfaces 32a and 33a corresponding to the first and second tongues 32t and 33t.

The present invention further includes a plurality of hook pieces (not shown) at the edges of the first and second tongues 32t and 33t so that the first and second casing pieces 32 and 33 can be simply operated It is needless to say that the first and second casing pieces 32 and 33 can be prevented from being disassembled by the force exerted thereon.

In addition, the side piece 34 may be an embodiment of the structure including the first half 34a and the second half 34b for ease of assembly and disassembly.

That is, the first half 34a includes a first surface 32a of one of the pair of first surfaces 32a and 32a, a part of the first connecting surface 32c, and a pair of second surfaces 33a 33a of the first solenoid valve 31 and the outer edge along a part of the second connecting surface 33c and the outer port of the first solenoid valve 31 31a corresponding to a part of the outer circumferential surface.

The second half 34b includes the remaining first surfaces 32a and 32a of the pair of first surfaces 32a and 32a and the rest of the first connecting surface 32c and a pair of second surfaces 33a 33a of the first solenoid valve 31 and the outer surface of the second solenoid valve 31 are connected to the outer edge along the rest of the second connecting surface 33c and the outside of the first solenoid valve 31 And a second notched groove 34bg corresponding to the remaining portion of the outer circumferential surface of the port 31a.

The first cutout groove 34ag and the second cutout cutout 34bg abut each other while the remaining edge of the first cutout 34a and the remaining edge of the second cutout 34b abut each other, .

Here, the engaging tongue piece 34bt protrudes along the remaining edge of the second half piece 34b. Although not specifically shown, the engaging tongue piece 34bt is formed in a shape corresponding to the engaging tongue piece 34bt and is recessed along the remaining edge of the first half piece 34a So that the fastening force can be maintained by engaging with the engaging groove.

In the meantime, the present invention may be applied to an embodiment according to the structure of the main body 30a which is bisected by the third casing piece 35 and the fourth casing piece 36 as shown in FIG.

The third casing piece 35 has a third surface 35a having a constant area and a third connecting surface 35c extending from the opposite end edges of the third surface 35a and facing each other, And a first side 35s closing both side edges of the third connecting surface 35c.

The fourth casing piece 36 has a fourth surface 36a having a constant area and a fourth connecting surface 36c extending from the opposite end edges of the fourth surface 36a and facing each other, And a second side surface 36s closing both side edges of the fourth connection surface 36c and is detachably coupled with the third casing piece 35 to form an inner space.

The edges of the first side 35s and the second side 36s abut against each other to form a connection hole 34c through which the outer port 31a of the first solenoid valve 31 is exposed.

The connection hole 34c is formed by abutting the third notched groove 35bg and the fourth notched groove 36bg as shown in the figure.

The third groove 35bg is cut along the edge of the first side 35s to a shape corresponding to a part of the outer peripheral surface of the outer port 31a of the first solenoid valve 31. [

The fourth groove 36bg is cut along the edge of the second side 36s to a shape corresponding to the remaining portion of the outer peripheral surface of the outer port 31a of the first solenoid valve 31. [

Accordingly, the third casing piece 35 and the fourth casing piece 36 are coupled to each other to form an internal space in which the first solenoid valve 31 and the water distribution port 30b are to be built.

The main body 30a further includes a coupling union 30bu that interconnects the water distribution port 30b and the inner port 31b of the first solenoid valve 31, 1 solenoid valve 31 can be made easy and the airtightness can be maintained.

The main body 30a further includes a waterproof rubber ring 31ap mounted between the ends of the pipe 71 connecting between the outer port 31a of the first solenoid valve 31 and the nozzle 20, So that watertightness and hermeticity between the outer port 31a and the nozzle 20 can be maintained.

Of the elements constituting the cleaning water supply and supply portion C, the controller 40 controls the opening and closing of the second and third solenoid valves 42 and 43 as well as the opening and closing of the second and third solenoid valves 42 and 43, The supply port 44 and the drain port 45 as well as the water supply and drainage flow path 46 and the water supply and drainage port 47 as shown in FIG. And the control panel 48, as shown in FIG.

The controller main body 40b is provided with a space for housing the second and third solenoid valves 42 and 43. The controller main body 40b is provided with a main body base (not shown) for facilitating assembly and disassembly, 40ba and a main cover 40bb.

The supply port 44 is provided at the upper end of the controller main body 40b to communicate with the water pipe 61 of the cleaning water supply unit 60 and the second solenoid valve 42. [

The drain port 45 is provided at the lower end of the controller body 40b and communicates with the third solenoid valve 43 provided at the lower end of the internal flow path 41 connected to the second solenoid valve 42, ).

The water supply and drainage flow path 46 is connected to the internal flow path 41 and is directed toward the upper end side of the controller main body 40b.

The water supply and drainage port 47 is connected to the upper end of the water supply and drainage flow path 46 and is provided at the upper end of the controller body 40b to communicate with the abnormal flow assembly 50 side.

The control panel 48 is electrically connected to the first, second and third solenoid valves 31, 42 and 43 to control the start and stop of the first, second and third solenoid valves 31, 42 and 43, The degree of pressure increase of the washing water passing through the abnormal flow assembly 50, which will be described later, together with the operation and opening / closing of the first, second and third solenoid valves 31, 42 and 43 to be controlled.

Specifically, the control panel 48 includes a display panel 48d for outputting images on a circuit board 48p, and a display panel 48d includes a cover plate 48c mounted between itself and the main cover 40bb ).

Here, a plurality of control buttons 49 are provided adjacent to the control panel 48, and on / off control of the entire apparatus and opening and closing operations of the first, second and third solenoid valves 31, 42, and 43 It will be possible.

At this time, the control buttons 49 will be described in detail. When the button array 49b arranged on the circuit board 48p is pressed, the on / off control of the entire apparatus and the first, second and third solenoid valves 31, 42, and 43, and a button cover 49c made of rubber, synthetic rubber, synthetic resin, or the like is provided on the button array 49b to prevent moisture infiltration You can do it.

Although the present invention is not specifically shown, it is also possible to perform various control operations through the use of a remote controller so as to enable remote control instead of the control panel 48, or through a control application of a portable terminal such as a cellular phone or a PDA Of course.

The abnormal flow assembly 50 is for increasing the jetting pressure of the washing water supplied to the plurality of nozzles 20, 20, 20 and 20 as described above. The plurality of nozzles 20, 20, 20, And the air is mixed with the washing water supplied to the distribution unit 30 side in order to reduce the water use amount of the washing water.

In general, the abnormal flow assembly 50 can reduce the water consumption by more than 30% in comparison with the existing apparatus.

Since the abnormal flow assembly 50 is disposed on the upper side of the controller 40, that is, the water pipe 61 of the cleaning water supply unit 60, the air injected into the abnormal flow assembly 50 flows from the water pipe 61 By accelerating the washing water supplied while rising toward the distribution unit 30, the effect of raising the jetting pressure of the plurality of nozzles 20, 20, 20, 20 without a separate pressurizing device can be obtained.

Therefore, as the jetting pressure of the washing water discharged from each of the nozzles 20, 20, 20, 20 passes through the abnormal flow assembly 50, the washing water is sprayed from each of the nozzles 20, 20, 20, Not only the distance is increased, but also the cooling and cleaning effect can be improved.

The structure of the abnormal flow assembly 50 will be described in more detail with reference to FIG.

That is, it can be understood that the abnormal flow assembly 50 includes the flow body 51, the air inflow passage 52, and the diffuser 53.

The flow body 51 is formed with a flow path 51f whose diameter becomes narrower toward the middle than the upper end and the lower end.

The air injection path 52 penetrates from the outer surface of the flow body 51 and communicates with the flow path 51f to form a flow path in which air flows into the flow path 51f.

The diffuser 53 is formed at the upper end of the flow body 51 and has a plurality of discharge slits 53s penetrating up and down.

The upper and lower connecting sleeves 55ca and 55cb are provided at the upper and lower ends of the flow body 51 respectively with an upper connecting sleeve 55ca and a lower connecting sleeve 55cb communicating with the flow passage 51f, And the side of the distribution unit 30 and the side of the controller 40 are connected to each other through the piping 72 through the piping fixtures 55a and 55b.

The cleaning apparatus for a solar module according to an embodiment of the present invention includes a pipe 72 for interconnecting the water pipe 61 of the cleaning water supply unit 60 and the internal flow path 41, It is needless to say that the present invention may be applied to an embodiment including a filter 80 (see Fig.

As shown in the present invention, when the washing water supplied through the plurality of nozzles 20, 20, 20 and 20 is tap water supplied from a general tap water, the filter 80 adopts an activated carbon filter to remove chlorine contained in tap water You will be able to remove it.

If the washing water supplied through the plurality of nozzles 20, 20, 20 and 20 is industrial water, the filter 80 can filter out various foreign substances mixed in the industrial water.

The filter 80 adopts a water-repellent filter to remove components that generate water when the washing water supplied through the plurality of nozzles 20, 20, 20, and 20 is ground water such as calcium or magnesium ions It will be possible.

Accordingly, in the present invention, not only the tap water supplied from the household water pipe 61 but also industrial water and ground water, such as washing water sprayed to the solar module 10 as described above, As it can be used for cooling, it can be used anywhere with water, and various kinds of filters can be selectively used depending on the kind of water used as the washing water.

The cleaning and cooling operations using the cleaning apparatus for a solar module according to an embodiment of the present invention will be briefly described in order.

First, the user fixes a plurality of nozzles 20, 20, 20, 20 connected to the piping 71, 71, 71, 71 from the distribution unit 30 to the edge of the solar module 10 as a clamp device, The distribution unit 30 is also fixed to the edge of the solar module 10 using the clamp 30c.

At this time, the user sequentially moves the distribution unit 30, the abnormal flow assembly 50, and the controller 40 (FIG. 10) from the plurality of nozzles 20, 20, 20, 20 fixed to the edge of the solar module 10, ).

Next, the user rotates the rotating body 23b of each of the nozzles 20, 20, 20, 20 in the forward and reverse directions to adjust the proper spraying angle.

Thereafter, the user operates the control panel 48 to turn on the power of the apparatus, operates the third solenoid valve 43 to the cutoff state, and the first and second solenoid valves 42 are all in the open state So that the washing water is supplied to the controller 40 from the water pipe 61 of the washing water supplying section 60.

Next, the washing water is accelerated from the controller 40 through the abnormal flow assembly 50 while being hydraulically supplied to the plurality of nozzles 20, 20, 20, 20, and the nozzles 20, 20, 20, 20), the solar module 10 is cleaned and cooled by the washing water sprayed from the respective discharge holes 24h.

Hereinafter, a process of completing the cleaning and cooling operation using the cleaning apparatus for a solar module according to an embodiment of the present invention and discharging the washing water will be briefly described.

First, the user locks the water supply pipe 61 of the cleaning water supply unit 60 and cuts off the supply of the cleaning water, and then operates the control panel 48 to maintain the open state of the first and second solenoid valves 42 , The third solenoid valve 43 is operated to the open state.

Next, the washing water can be discharged from the plurality of pipes 71, 72 through the controller 40 and the drain line 73 naturally in the gravity direction.

Finally, the user operates the control panel 48 to turn off the power of the apparatus.

As described above, according to the present invention, it is possible to efficiently clean and cool the surface of the solar module even if only the water pressure of a general household is used without using a separate pump, and the cooling water supplied through the drain line is drained by natural means, It is a fundamental technical idea to provide a cleaning device for a solar module capable of preventing freezing and freezing.

It will be apparent to those skilled in the art that many other modifications and applications are possible within the scope of the basic technical idea of the present invention.

10 ... photovoltaic module
20, 20, 20, 20 ... Nozzles
21 ... nozzle connector
21b ... diameter portion
21f ... rotation supporting flange
21s ... Shaft neck
22 ... nozzle fixture
23 ... outlet
23a ... discharge end
23b ... rotating body
23s ... discharge cutout
24 ... nozzle cover
24h ... discharge hole
30 ... distribution unit
30a ... body
30b ... water distribution portion
30bu ... Union Union
30c ... Clamp
30cb ... module fixing bolt
30k ... link piece
31 ... first solenoid valve
31a ... outer port
31ap ... waterproof rubber ring
31b ... inner port
32 ... first casing piece
32a, 32a ... first side
32c ... first connecting surface
32t ... 1st piece
33 ... second casing piece
33a, 33a ... second side
33c ... second connecting surface
33t ... 2nd tentacle
34 ... side
34a ... First half
34ag ... Section 1
34b ... second half
34bg ... Section 2
...
34c ... connection hole
40 ... controller
40b ... controller body
40ba ... main body base
40bb ... Main body cover
41 ... inner flow path
42 ... second solenoid valve
43 ... third solenoid valve
44 ... supply port
45 ... drain port
46 ... water supply and drainage
47 ... Water drain port
48 ... Control panel
48c ... cover plate
48d ... display panel
48p ... circuit board
49 ... Control button
49b ... button array
49c ... button cover
More than 50 ... flow assembly
51 ... flow body
51f ... flow channel
52 ... air injection port
53 ... diffuser
53s ... discharge slit
55a, 55b ... pipe fitting
55ca ... upper connection sleeve
55cb. Lower connection sleeve
60 ... cleaning water supply part
61 ... water piping
71, 72 ... piping
73 ... drain line
80 ... filter
C ... rinse water supply and discharge

Claims (22)

A plurality of nozzles for spraying washing water to the solar module;
A dispensing unit for simultaneously supplying cleaning water to all or a part of the plurality of nozzles or supplying the cleaning water with a time lag;
A rinse water supply unit connected to the dispensing unit and connected to the dispensing unit and supplying the rinse water to the dispensing unit;
A cleaning water supply / discharge unit connected to the cleaning water supply unit and the distribution unit, for supplying cleaning water from the cleaning water supply unit to the distribution unit, or for allowing the cleaning water remaining in the interior, the pipe, ; And
A two phase flow unit mounted on a pipe connecting the cleaning water supply unit and the dispensing unit to each other to increase the injection pressure of the washing water supplied to the plurality of nozzle sides by mixing air into water passing through the inside of the pipe, Assembly,
Wherein the plurality of nozzles, the distributing unit, and the cleaning water supply unit are sequentially arranged in the vertical direction with respect to the solar module,
Wherein the abnormal flow assembly comprises:
A flow body in which a flow path whose diameter becomes narrower toward an intermediate portion than a top end portion and a bottom end portion is formed,
An air injection path communicating with the flow path from the outer surface of the flow body and forming a flow path in which air is mixed into the water flowing through the flow path,
And a diffuser formed at an upper end of the flow body and having a plurality of discharge slits vertically penetrating therethrough.
Cleaning device for solar modules.
The method according to claim 1,
The distribution unit includes:
Wherein the first solenoid valve has a number of first solenoid valves therein corresponding to the plurality of nozzles, and the plurality of nozzles and the first solenoid valves are connected to each other by piping, and the washing water is supplied to each of the plurality of nozzles, And a flow path for discharging the water is formed.
Claim 1
The cleaning water supply unit,
And a water pipe for supplying tap water as the washing water or an industrial water pipe for supplying industrial water as the washing water.
The method according to claim 1,
The cleaning water supply unit,
A ground water supply pipe connected to the underground pipe for supplying the ground water as the washing water,
And a pump connected to the groundwater supply pipe to raise the groundwater to the cleaning water supply and supply unit.
The method according to claim 1,
The cleaning water supply /
An inner flow path connected to the distribution unit and the cleaning water supply unit,
A second solenoid valve provided at an upper end of the internal flow path,
A third solenoid valve provided at a lower end of the internal flow path,
And a controller for controlling the opening and closing of the second and third solenoid valves,
Wherein the third solenoid valve is connected to a drain line through which the washing water having been cleaned and cooled by the solar module is discharged.
The method according to claim 1,
The cleaning water supply /
An inner flow path connected to the distribution unit and the cleaning water supply unit,
A second solenoid valve provided at an upper end of the internal flow path,
A third solenoid valve provided at a lower end of the internal flow path,
And a controller for controlling the opening and closing of the first solenoid valve incorporated in the distribution unit together with the second and third solenoid valves,
Wherein the third solenoid valve is connected to a drain line through which the washing water having been cleaned and cooled by the solar module is discharged.
delete The method according to claim 1,
The nozzle
A nozzle connection port communicating with a pipe connected to the distribution unit and having a diameter smaller than that of the pipe,
A nozzle fixture coupled to one end of the nozzle connection port to fix the nozzle connection port to the pipe,
A discharge port including a hemispherical discharge end coupled to the other end of the nozzle connection port so as to be forwardly and reversely rotatable and having a discharge cut-out portion formed as a one-
And a hemispherical nozzle cover coupled to the other end edge of the nozzle connection port to house the discharge port and having a plurality of discharge holes arranged in a line along a surface thereof,
Wherein the nozzle is capable of adjusting an angle of spray of the washing water.
The method of claim 2,
The distribution unit includes:
A main body defining an inner space in which the first solenoid valve is built,
And a water distribution port formed in the main body and having an inlet / outlet port connected to each of the first solenoid valves, wherein a flow path communicating with the plurality of nozzles and the cleaning water supply / discharge portion side is formed,
Wherein the main body is detachably coupled to the solar module.
The method of claim 5,
The controller comprising:
A controller body including the second and third solenoid valves,
A supply port provided at an upper end of the controller body and communicating with the washing water supply unit and the second solenoid valve,
A drain port communicated with the third solenoid valve provided at a lower end portion of the internal flow passage provided at a lower end portion of the controller body and connected to the second solenoid valve,
A water supply and drainage flow path connected to the internal flow path and directed toward an upper end side of the controller main body,
A water supply and drainage port connected to an upper end of the water supply and drainage flow path and provided at an upper end portion of the controller main body and communicating with the abnormal flow assembly side,
And a control panel electrically connected to the second and third solenoid valves and controlling the operation of the second and third solenoid valves.
Wherein the abnormal flow assembly is mounted on a pipe connecting the cleaning water supply unit and the dispensing unit and includes an abnormal flow which increases the injection pressure of the washing water supplied to the plurality of nozzle sides by mixing air into the water passing through the inside of the pipe, further comprising a two phase flow assembly for the photovoltaic module.
delete The method of claim 8,
The nozzle connecting hole
A cylindrical-shaped reduced-diameter portion having an inner diameter smaller than that of the pipe,
A rotary support flange extending from an outer peripheral surface of an end portion of the reduced diameter portion to receive the discharge port,
And a diameter-enlarged portion projecting on the rotary support flange and having an inner diameter larger than that of the shaft-diameter portion and being wrapped by the discharge port.
The method of claim 8,
The nozzle
Further comprising a cylindrical rotating body extending from an edge of the discharge end and being mounted on the nozzle connecting port and rotated.
The method of claim 9,
The distribution unit includes:
A link piece provided on one side of the main body and rotatable,
Further comprising at least one clamp coupled to an end of the link piece to clamp the edge of the solar module.
15. The method of claim 14,
The distribution unit includes:
And a module fixing bolt detachably coupled to the clamp and fixed to the edge of the solar module.
The method of claim 9,
The main body includes:
A first casing piece including a pair of first facing surfaces facing each other and a first connecting surface interconnecting the pair of first surfaces,
A pair of second facing surfaces facing each other and a second connecting surface interconnecting the pair of second surfaces, wherein the pair of second surface edges and the pair of first surface edges are detachably coupled to each other, A second casing piece forming the internal space,
And a side piece formed by closing the opened both sides of the first casing piece and the second casing piece to form a connection hole which is coupled along the edge of the opened both side surfaces and in which the outer port of the first solenoid valve is exposed In addition,
Wherein the first connection surface faces the solar module,
Wherein the second connection surface faces the cleaning water supply /
And the inlet port of the water distribution port is connected to the inner port of the first solenoid valve, respectively.
18. The method of claim 16,
The main body includes:
A first fixing groove formed along both side edges of the pair of first surfaces and the first connecting surface to receive the edge of the side piece,
Further comprising a second fixing groove formed along both side edges of the pair of second surfaces and the second connecting surface to receive the edge of the side piece.
18. The method of claim 16,
The side piece
A first surface of one of the pair of first surfaces, a portion of the first connecting surface, a second surface of one of the pair of second surfaces, and an outer edge A first half piece formed with a first notch groove corresponding to a part of the outer circumferential surface of the outer port of the first solenoid valve along the other edge except for the outer edge,
A first surface of the pair of first surfaces, a remaining surface of the pair of first surfaces, a remaining surface of the first surface, a second surface of the remaining one of the pair of second surfaces, And a second half formed with a second notch corresponding to the remaining portion of the outer circumferential surface of the outer port of the first solenoid valve along the other edge except for the outer edge,
Wherein the connection hole is formed by abutting the first notched groove and the second notched groove with the remaining edge of the first half contacting the remaining edge of the second half. Device.
The method of claim 9,
The main body includes:
A third connecting surface extending from the opposite end edges of the third surface and facing each other and a first side covering the opposite side edges of the third connecting surface and the third connecting surface, A third casing piece,
A fourth surface having a constant area, a fourth connecting surface extending from the opposite end edges of the fourth surface and facing each other, and a second side closing the opposite side edges of the fourth surface and the fourth connecting surface And a fourth casing piece which is detachably coupled to the third casing piece to form the inner space,
The water distribution port is disposed between the third casing piece and the fourth casing piece,
And the edge of the first side and the side of the second side abut against each other to form a connection hole through which the outer port of the first solenoid valve is exposed.
The method of claim 19,
The main body includes:
A third notch formed in a shape corresponding to a portion of the outer circumferential surface of the outer port of the first solenoid valve along an edge of the first side surface,
Further comprising a fourth notch groove cut in a shape corresponding to a remaining portion of an outer circumferential surface of an outer port of the first solenoid valve along an edge of the second side surface,
And the third notch and the fourth notch are in contact with each other to form the connection hole.
The method of claim 19,
The main body includes:
A coupling union interconnecting the water distribution port and the inner port of the first solenoid valve,
Further comprising a waterproof rubber ring mounted between an outer port of the first solenoid valve and an end of a pipe connecting the nozzle.
The method of claim 5,
The cleaning device for a solar cell module,
Further comprising: a filter mounted on a pipe connecting the cleaning water supply unit and the internal flow path to each other.

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