KR20130131064A - Solar modules with self-cleaning feature, street lights and security cameras equipped with this - Google Patents

Abstract

The present invention relates to a solar cell module having a self-cleaning function, a street light having the same, and a security camera, capable of improving the power generation efficiency of a solar cell, and furthermore, reducing the power consumption for spraying water toward the top surface of the solar cell by easily cleaning the top surface of the solar cell and easily removing foreign substances loaded on the top surface of the solar cell.

Description

Solar cell module with self-cleaning function, street light and security camera equipped with it {SOLAR MODULES WITH SELF-CLEANING FEATURE, STREET LIGHTS AND SECURITY CAMERAS EQUIPPED WITH THIS}

The present invention can more easily wash the upper surface of the solar cell, as well as to more easily remove foreign matters, such as dust loaded on the upper surface of the solar cell can greatly improve the power generation efficiency of the solar cell. It can be, and further relates to a solar cell module having a self-cleaning function that can greatly reduce the power consumption consumed to spray water to the upper surface of the solar cell, a street lamp and a security camera having the same.

In general, the photovoltaic module or photovoltaic array has been left unattended for a long time while being exposed to the outside air.

Therefore, a phenomenon in which power generation efficiency decreases due to the loading of foreign matters including overheating or dust has occurred.

As the spread and spread of photovoltaic power generation is accelerated, the output improvement of photovoltaic power generation is considered to be a significant issue.

Conventional photovoltaic module cooling technologies are ineffective in cleaning the photovoltaic module, and the use of refrigerants other than water poses a risk of additional environmental pollution.

In order to solve this problem, recently, a nozzle for spraying water jet toward the photovoltaic array for cleaning, cooling or snow removal of the solar tube power generation array has been reciprocated on an elevated track parallel to the photovoltaic array. There has been proposed a photovoltaic array management device (Domestic Patent Registration No. 10-1038243) which reciprocates on orbits of a structure characterized in that the structure.

However, the photovoltaic array management device reciprocating on the track requires spraying high pressure water toward the photovoltaic array, so that the consumption rate of the power consumed to spray the high pressure water is not only high but also simply. Since the high pressure water is sprayed onto the surface of the photovoltaic array, the surface of the photovoltaic array cannot be wiped, and thus the removal efficiency of foreign matters including dust loaded on the surface of the photovoltaic array is low. There is a problem that the power generation efficiency of the photovoltaic array is reduced.

The present invention was created in order to solve the above-described problems, it is possible to more easily wash the upper surface of the solar cell, as well as to more easily remove foreign matters, such as dust loaded on the upper surface of the solar cell. The solar cell module having a self-cleaning function, which can greatly improve the power generation efficiency of the solar cell, and further reduce the power consumption consumed to spray water to the upper surface of the solar cell, street light having the same And providing a security camera.

The present invention for achieving the above object is provided in the lower portion of the solar cell for storing the water flowing along the upper surface of the solar cell; An injection rod provided on the solar cell and spraying water on an upper surface of the solar cell; A pump for supplying water stored in the reservoir to the spraying unit; It provides a solar cell module having a self-cleaning function comprising a; cleaning unit for cleaning the upper surface of the solar cell in the spraying state is spraying water on the upper surface of the solar cell.

Here, it is preferable that the upper portion of the reservoir is open.

In particular, the opening is formed in the upper portion of the reservoir, it is preferable that the evaporation suppression plate is provided on the inner upper side of the reservoir in a state located in the lower direction of the opening.

Here, the evaporation suppression plate is a rear inclination plate which is inclined downward in the direction of the front inner peripheral surface of the reservoir from the rear upper portion of the reservoir so as to be located in the lower direction of the opening; It is preferred that the rear inclination plate inclined upward in the direction of the front inner circumferential surface of the water storage tank;

And, the water level sensor for detecting the water level of the water stored in the reservoir; A non-sensing sensor for detecting outside rain; A discharge pipe provided at a lower portion of the reservoir to discharge water stored in the reservoir; An opening and closing valve provided in the discharge pipe to open and close the discharge pipe; And a control unit for controlling the opening / closing valve, the pump, and the cleaning unit according to the detection signal of the water level sensor and the detection signal of the non-sensing sensor.

Furthermore, a temperature sensor for sensing the temperature of the water stored in the reservoir; It is preferable that a control unit for controlling the pump and the cleaning unit in accordance with the detection signal of the temperature sensor.

In addition, the cleaning unit and the cleaning member for cleaning the upper surface of the solar cell by moving left and right in contact with the upper surface of the solar cell; It is preferably made to include; a left and right moving member for moving the cleaning member to the left and right.

In addition, the left and right moving member and the drive motor provided on the upper portion of the solar cell; A lead screw axially coupled to the drive motor; A left and right moving body screwed with the lead screw to move left and right with the cleaning member; It is preferable that the guide rod is provided on the top of the solar cell in the state coupled to the left and right moving body to guide the left and right movement of the left and right moving body.

And, the cleaning member is preferably made of a wiper to move left and right by the left and right moving member in contact with the upper surface of the solar cell.

Alternatively, the cleaning member is preferably made of a brush to move left and right by the left and right moving member in contact with the upper surface of the solar cell.

In addition, the present invention is provided in the upper portion of the solar cell for storing the water flowing along the upper surface of the solar cell, and the injection table provided in the lower portion of the solar cell to spray water on the upper surface of the solar cell And, a pump for supplying water stored in the reservoir as the spraying unit, and a cleaning unit for cleaning the upper surface of the solar cell while the spraying table is spraying water on the upper surface of the solar cell. A solar cell module; It provides a street light comprising a; a luminaire provided in the lower direction of the solar cell module.

In addition, the present invention is provided in the upper portion of the solar cell and the reservoir for storing the water flowing along the upper surface of the solar cell, and provided in the lower portion of the solar cell to spray water on the upper surface of the solar cell And a cleaning unit for cleaning the upper surface of the solar cell in a state in which the spraying rod, a pump for supplying the water stored in the water storage tank with the spraying rod, and the spraying rod spray water on the upper surface of the solar cell. A solar cell module having a cleaning function; It provides a security camera comprising a; camera unit provided in the lower direction of the solar cell module.

According to the present invention, since the cleaning unit wipes and cleans the upper surface of the solar cell in a state in which the spray table is spraying water on the upper surface of the solar cell, particularly at low pressure, the upper surface of the solar cell can be more easily washed. It is possible to more easily remove foreign matters, including dust and the like loaded on the upper surface of the solar cell can greatly improve the power generation efficiency of the solar cell, and further, the injection rod is a low pressure water to the upper surface of the solar cell Since the injection, the power consumption consumed there is also an effect that can be greatly reduced.

1 is a side view schematically showing a solar module having a self-cleaning function of an embodiment of the present invention,
2 and 3 are side views schematically showing the internal state of the reservoir of FIG. 1, respectively.
4 is a plan view schematically illustrating a cleaning part;
5 is a partially enlarged cross-sectional view schematically illustrating an evaporation suppression plate,
6 is a partially enlarged cross-sectional view schematically showing a water level sensor,
7 is a partially enlarged cross-sectional view schematically showing a temperature sensor,
8 is a block diagram schematically showing a control state of the control unit,
Figure 9 is a side view schematically showing a street lamp having a solar module with the inventors self-cleaning function,
Figure 10 is a side view schematically showing a security camera having a solar module with the inventors self-cleaning function.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 is a side view schematically showing a solar module having a self-cleaning function of an embodiment of the present invention.

Solar module 300 having a self-cleaning function of an embodiment of the present invention is large, as shown in Figure 1, comprises a reservoir 10, the injection table 20, the pump 30 and the cleaning unit 40 .

2 and 3 are side views schematically showing the internal state of the reservoir 10 of FIG.

First, the reservoir 10 is provided in the lower portion of the solar cell 5 as shown in FIG.

In the reservoir 10, water 7 flowing down from the upper portion of the solar cell 5 along the upper surface of the solar cell 5 toward the lower direction of the solar cell 5 is stored.

The water stored in the reservoir 10 may be made of rain water.

The reservoir 10 is the bottom plate 110, the front plate 120, the rear plate 130, one side plate (140 of FIG. 1) and the other side plate (Figs. 2 and 3) as shown in FIG. 150).

The bottom plate 110 may be horizontally provided in a lower direction of the solar cell 5.

The front plate 120 may be composed of a first front plate 121, a second front plate 122, and a third front plate 123.

The first front plate 121 may be integrally formed on the front side of the bottom plate 110.

The first front plate 121 may be inclined upward from the lower side to the upper side of the bottom plate 110 in an upward direction.

The second front plate 122 may be integrally formed on the upper side of the first front plate 121.

The second front plate 122 may be inclined upward in an upward rearward direction of the first front plate 121 from the lower side to the upper side.

The third front plate 123 may be integrally formed on the upper side of the second front plate 122.

The third front plate 123 may be inclined downward in an upper rear direction of the second front plate 122 from the upper side to the lower side.

The rear plate 130 may be composed of a first rear plate 131, a second rear plate 132, a third rear plate 133, a fourth rear plate 134, and a fifth rear plate 135. have.

The first rear plate 131 may be integrally formed on the rear side of the bottom plate 110.

The first rear plate 131 may be inclined upward in a rear upper direction of the bottom plate 110 from the lower side to the upper side.

The second rear plate 132 may be integrally formed on the upper side of the first rear plate 131.

The second rear plate 132 may be inclined upward from the lower side toward the lower side of the lower surface of the solar cell 5.

The third rear plate 133 may be integrally formed on an upper side of the second rear plate 132 and may be bolted to a lower side of the bottom surface of the solar cell 5.

The third rear plate 133 may be inclined downward in the direction of the inner circumferential surface of the first front plate 121 from the upper side to the lower side.

The fourth rear plate 134 may be integrally formed on the lower side of the third rear plate 133 and may be bolted to the lower side of the solar cell 5.

The fourth rear plate 134 may be inclined upward in the front upper direction of the bottom plate 110 from the lower side to the upper side so as to be parallel to the first front plate 121.

The fifth rear plate 135 may be integrally formed on the upper side of the fourth rear plate 134.

The fifth rear plate 135 may be inclined downward in the direction of the inner circumferential surface of the first front plate 121 from the upper side to the lower side.

The one side plate 140 of FIG. 1 may be vertically formed integrally with one side of the bottom plate 110.

The other side plate 150 of FIGS. 2 and 3 may be vertically formed integrally with the other side of the bottom plate 110.

In order to more easily prevent the water 7 including rainwater stored in the reservoir 10 from overflowing to the outside of the reservoir 10,

The upper and lower lengths (L ₁ of FIG. 5) of the first front plate 121 of the front plate 120 are lower than the second rear plate 132 of the rear plate 130 and the fourth rear plate 134. Longer than the upper and lower length (L ₂ of Figure 5) between the upper side is preferably formed.

On the other hand, the solar cell 5 may collect electricity to generate electricity or to collect electricity to generate electricity.

The center of the lower surface of the solar cell 5 may be provided in a bolted state on the upper portion of the support (9) perpendicular to the ground.

In particular, in order for the solar cell 5 to collect solar light at a higher efficiency or to collect solar heat at a higher efficiency, the solar cell 5 has the acute angle (α in FIG. 9) it may be inclined in the diagonal direction (상부).

Although not shown in the drawing, the pillar 9 may include a storage battery 101 (see FIG. 8) in which electricity generated by the solar cell 5 is stored.

4 is a plan view schematically illustrating the cleaning part 40.

Next, the spray table 20 is provided above the upper surface of the solar cell 5 to inject water (7) to the upper surface of the solar cell (5).

The injection rod 20 may extend a predetermined length in the left and right directions as shown in FIG.

The injection nozzle 210 for spraying water 7 supplied to the inside of the injection rod 20 to the upper surface of the solar cell 5 may be provided at a lower interval below the injection rod 20. .

Between the injector 20 and the upper surface of the upper surface of the solar cell 5, the fixing table 220 for providing the injector 20 on the upper surface of the solar cell 5 to be provided at regular intervals Can be.

The fixing stand 220 may be formed of one side fixing stand 221 and the other fixing stand 222.

An upper center portion of the one side fixing stand 221 may be welded in a state in which one side of the spray table 20 penetrates.

The lower side of the one side stand 221 may be fixed in a variety of ways, such as bolt fixing on the upper surface of the solar cell (5).

An upper center portion of the other side fixing stand 222 may be welded in a state in which the other side of the injection table 20 penetrates.

The lower side of the other side stand 222 may be fixed in a variety of ways, such as bolt fixing on the upper surface of the solar cell (5).

Next, the pump 30 supplies water 7 including rain water, etc. stored in the reservoir 10 to the spray table 20.

The pump 30 may be provided in a bolt fixed state at the center of the lower surface of the solar cell (5).

A supply line 310 including a hose or the like may be provided between the pump 30 and the reservoir 10 and between the pump 30 and the spray table 20.

The supply line 310 may include a lower supply line 311 and an upper supply line 312.

The lower side of the lower supply line 311 may be connected to the rear side of the bottom plate 110 of the reservoir 10 so that the lower side of the lower supply line 311 communicates with the inside of the reservoir 10.

The upper side of the lower supply line 311 may be connected to the lower side of the pump (30).

The lower side of the upper supply line 312 may be connected to the upper side of the pump (30).

An upper side of the upper supply line 312 may be connected to a rear center of the injector 20 so that the upper side of the upper supply line 312 communicates with the injector 20.

The pump 30 may supply the water 7 including rainwater stored in the reservoir 10 through the supply line 310 to the inside of the spray table 20.

In order to reduce the electrical consumption rate of the pump 30 driven by receiving electricity from the storage battery 101, the pump 30 may be made of a low pressure pump, in particular, the injection due to the pump 30 made of a low pressure pump Base 20 is to spray the low-pressure water (7) to the upper surface of the solar cell (5).

On the other hand, the controller 100 to be described later may be provided with a timer (not shown) in a push button or a dial button method.

Through the timer (not shown), the manager of the solar cell 5 may set information regarding the time when the spraying rod 20 injects the low pressure water 7 to the upper surface of the solar cell 5. have.

The information on the time for spraying the low pressure water 7 to the upper surface of the solar cell 5 by the sprayer 20 set to the timer (not shown) may be a water spraying time zone or a water spraying time interval. have.

The information on the time to spray the low-pressure water (7) to the upper surface of the solar cell 5 is the water spray time zone, the water spray time zone is, for example, 1 pm, 3 pm, 4 pm, 7 pm Occation,

At 1 pm, 3 pm, 4 pm, and 7 pm, the control unit 100 may spray the low pressure water 7 onto the upper surface of the solar cell 5, respectively. The pump 30 is operated together with the cleaning part 40.

When the information on the time to inject the low pressure water (7) to the upper surface of the solar cell 5 is the water spray time interval, the water spray time interval is 30 minutes,

The control unit 100 together with the cleaning unit 40 so that the spray table 20 can spray the low pressure water 7 to the upper surface of the solar cell 5 at intervals of 30 minutes. Will be activated.

Next, the cleaning unit 40 may be provided on the upper surface of the solar cell 5 to be located in the lower direction of the spraying table 20.

The cleaning unit 40 cleans the upper surface of the solar cell 5 by spraying the low pressure water 7 onto the upper surface of the solar cell 5 by the sprayer 20. It is more easily removed by foreign substances including dust and the like loaded on the upper surface of (5).

Next, water 7 flowing down from the upper portion of the solar cell 5 along the upper surface of the solar cell 5 to the lower direction of the solar cell 5 is more easily introduced into the reservoir 10. The upper portion of the reservoir 10 may be opened in order to be stored.

More specifically, as shown in FIGS. 2 and 3, the fifth rear plate 135 of the rear plate 130 of the reservoir 10 so that the opening 10a may be formed in the upper portion of the reservoir 10. The opening 10a may be formed between the lower side and the lower side of the third front plate 123 of the front plate 120 of the reservoir 10.

Water 7 flowing down from the upper portion of the solar cell 5 along the upper surface of the solar cell 5 to the lower direction of the solar cell 5 passes through the opening 10a to allow the reservoir 10 ) Can flow into the interior.

5 is a partially enlarged cross-sectional view schematically illustrating the evaporation suppression plate 50.

Next, as shown in FIG. 5, an evaporation suppression plate 50 may be provided to minimize evaporation of the water 7 introduced into the reservoir 10 and stored at a predetermined height.

The evaporation suppression plate 50 may be provided in the upper side of the reservoir 10 in a state located in the lower direction of the opening (10a).

More specifically, the evaporation suppression plate 50 includes a rear inclination plate 510 and a front inclination plate 520.

The rear inclination plate 510 may be located in a lower direction of the opening 10a.

The rear inclined plate 510 is the fifth rear plate 135 of the rear plate 130 of the reservoir 10 in a state inclined downward from the rear upper portion of the reservoir 10 toward the front inner circumferential surface of the reservoir 10. It can be integrally formed on the lower side of the.

The front inclination plate 520 may be integrally formed under the rear inclination plate 510.

The front inclination plate 520 may be inclined upward in the direction of the front inner circumferential surface of the water storage tank 10 at the lower side of the rear inclination plate 510.

Since the water molecules that become gas while the water stored in the reservoir 10 is evaporated must rise between the openings 10a and the evaporation suppression plate 50 after rising to the inside of the reservoir 10. It is possible to stay in the interior of the reservoir 10 for a long time, thereby minimizing the evaporation of the water (7) stored in the interior of the reservoir (10).

6 is a partially enlarged cross-sectional view schematically showing the water level sensor 60, FIG. 7 is a partially enlarged cross-sectional view schematically showing the temperature sensor 200, Figure 8 is a block schematically showing the control state of the controller 100 It is also.

Next, as shown in Figures 6 to 8, the water level sensor 60, the non-sensing sensor 70, the discharge pipe 80 and the opening and closing valve 90 and the control unit 100 may be provided.

The water level sensor 60 may detect the water level of the water 7 stored in the reservoir 10.

The water level sensor 60 may be composed of an upper water level sensor 610 and a lower water level sensor 620.

The upper water level sensor 610 may be provided on the inner peripheral surface of the first front plate 121 of the front plate 120 of the reservoir 10.

The lower water level sensor 620 may be provided below the inner circumferential surface of the first front plate 121 of the front plate 120 of the reservoir 10.

The non-sensing sensor 70 may detect an external rain.

The non-sensing sensor 70 may be provided on, for example, the outer circumferential surface of the support 9 or the outer circumferential surface of the reservoir 10 to detect rain from the outside, but the position of the non-sensing sensor 70 is not limited thereto. It is provided on the outer circumferential surface of the battery 5 can detect the rain falling from the outside, such as to detect the rain falling from the outside.

The discharge pipe 80 may be vertically formed at the front side of the bottom plate 110 of the reservoir 10 in a state in communication with the interior of the reservoir 10.

The discharge pipe 80 may discharge water 7 including rainwater stored in the reservoir 10 in the lower direction of the reservoir 10.

The opening and closing valve 90 may be provided at an intermediate portion of the discharge pipe 80 to open and close the discharge pipe 80.

The control unit 100 may control the opening / closing valve 90, the pump 30, and the cleaning unit 40 according to a detection signal of the water level sensor 60 and a detection signal of the non-sensing sensor 70. Can be.

For example, the control unit 100 may be provided on the outer circumferential surface of the support 9, but is not necessarily limited thereto, and may be provided in the reservoir 10 or the solar cell 5. It may be provided in.

When the non-sensing sensor 70 detects an external rain, the pump 30 and the cleaning unit 40 are stopped by the control of the controller 100.

Rain falling from the outside is introduced into the reservoir 10 through the opening (10a) of the reservoir 10, thereby allowing rain water to be stored in the reservoir (10).

When the level of rainwater stored in the reservoir 10 gradually rises and the upper level sensor 610 of the water level sensor 60 detects rainwater,

Under the control of the controller 100, the open / close valve 90 opens the discharge pipe 80 so that the sediment may be discharged in the lower direction of the reservoir 10 together with rainwater stored in the reservoir 10. Make sure

As rainwater is discharged toward the bottom of the reservoir 10 through the discharge pipe 80, the level of rainwater in the reservoir 10 is gradually lowered, and thus the upper level of the water level sensor 60 is detected. When the sensor 610 does not detect the rainwater in the reservoir 10,

Under the control of the controller 100, the open / close valve 90 may close the discharge pipe 80 so that rainwater stored in the reservoir 10 may not be discharged toward the bottom of the reservoir 10. .

When the non-sensing sensor 70 does not detect the external rain, the control unit 100 controls the operation of the pump 30 and the cleaning unit 40 according to the output signal of the timer (not shown). Can be.

On the other hand, when the non-sensing sensor 70 does not detect the rain outside, the water level sensor 620 of the lower level sensor 60 of the water level sensor 60, including the rain water stored in the reservoir (10) ( 7) If it doesn't detect,

The control unit 100 stops the operation of the pump 30 and the cleaning unit 40.

Water (7) including the rain water stored in the reservoir 10, the lower level sensor 620 of the water level sensor 60 in the state that the non-sensing sensor 70 does not detect the external rain When you detect

The control unit 100 operates the pump 30 and the cleaning unit 40 according to the output signal of the timer (not shown).

Next, as shown in FIG. 7 and FIG. 8, the temperature sensor 200 may be further provided.

The temperature sensor 200 is, for example, the inner circumferential surface of the first front plate 121 of the front plate 120 of the reservoir 10 to be located between the upper water level sensor 610 and the lower water level sensor 620. It is provided in the middle can detect the temperature of the water (7) including rain water stored in the interior of the reservoir (10).

The control unit 100 may control the pump 30 and the cleaning unit 40 according to the detection signal of the temperature sensor 200.

The controller 100 may preset a reference temperature value.

The reference temperature value preset in the controller 100 may be a temperature value at which the water 7 including the rain water stored in the reservoir 10 may freeze, for example, 0 ° C.

When the temperature value of the water 7 including the rainwater in the reservoir 10 sensed by the temperature sensor 200 is equal to or less than the preset reference temperature value in the controller 100,

The control unit 100 stops the operation of the pump 30 and the cleaning unit 40.

When the temperature value of the water 7 including the rainwater in the reservoir 10 sensed by the temperature sensor 200 exceeds the reference temperature value preset in the controller 100,

The control unit 100 operates the pump 30 and the cleaning unit 40 according to the output signal of the timer (not shown).

Next, as shown in FIGS. 1, 2 and 4, the cleaning part 40 may include a cleaning member 410 and a left and right moving member 420.

The cleaning member 410 may move left and right in contact with the upper surface of the solar cell 5 to clean the upper surface of the solar cell 5.

The left and right moving members 420 may move the cleaning member 410 left and right under the control of the controller 100.

More specifically, the left and right moving members 420 may be formed to include a driving motor 421, a lead screw 422, a left and right moving body 423, and a guide rod 424 as shown in FIG. 4. .

The drive motor 421 may be provided in a bolt fixed state on the upper side of the solar cell (5).

The lead screw 422 is axially coupled with the drive motor 421 so that the lead screw 422 may be located in the lower direction of the spray table 20 by the drive motor 421 under the control of the controller 100. Can be reversed.

The lower side of the left and right moving body 423 may be screwed with the lead screw 422.

The left and right moving bodies 423 may move left and right together with the cleaning member 410.

On the lower side of the left and right moving body 423 is extended to a predetermined length in the lower direction of the solar cell 5 from the upper side of the solar cell (5) a left and right moving bar to move left and right along the left and right moving body (423) ( 423a) may be integral.

The cleaning member 410 may be provided at a lower portion of the horizontal bar 423a to move horizontally along the horizontal bar 423a.

When the lead screw 422 is rotated in the positive direction by a predetermined number of times by the drive motor 421, the left and right moving body 423 together with the cleaning member 410 is at one side of the solar cell (5) It may move in the other direction of the solar cell (5).

When the lead screw 422 is rotated in the reverse direction by a predetermined number of times by the driving motor 421, the left and right moving body 423 together with the cleaning member 410 is on the other side of the solar cell (5) The solar cell 5 may move in one direction.

The guide rod 424 may be provided at a predetermined height on the upper portion of the solar cell 5 so as to be located between the injection rod 20 and the lead screw 422.

A support 425 may be provided between the guide rod 424 and the upper portion of the solar cell 5 to support the guide rod 424 at a predetermined height.

The support 425 may be composed of one support 425a and the other support 425b.

One side of the guide rod 424 may be welded to an upper portion of the one side support 425a.

The lower part of the one side support 425a may be bolted to the upper one side of the solar cell (5).

The other side of the guide rod 424 may be welded to the top of the other support (425b).

The lower portion of the other support 425b may be bolted to the upper other side of the solar cell (5).

The guide rod 424 is axially coupled to the upper side of the left and right moving body 423 in a state penetrating the upper side of the left and right moving body 423 may guide the left and right movement of the left and right moving body 423.

Next, as shown in FIG. 2, the cleaning member 410 may be configured as a wiper 411 which is moved left and right by the left and right moving members 420 in contact with the upper surface of the solar cell 5.

Alternatively, as shown in FIG. 3, the cleaning member 410 may be formed of a brush 412 which is moved left and right by the left and right moving members 420 in contact with the upper surface of the solar cell 5.

The brush 412 is integrally formed at the lower side of the left and right movement bar 423a and extends at a predetermined length from the upper side of the solar cell 5 to the lower side of the solar cell 5. It may be integrally formed on the lower side.

9 is a side view schematically showing a street light having a solar module 300 having a self-cleaning function of the present inventors.

Next, the street light having a solar module 300 having a self-cleaning function of the present inventors is large, as shown in Figure 9, comprising a solar cell module 300 and a lamp 500 having the self-cleaning function. Can be.

The luminaire 500 may be provided at an upper front side of the support 9 so as to be provided in a lower direction of the solar cell module 300 to emit light under the control of the controller 100.

A connection table 800 may be integrally provided between the luminaire 500 and the upper front side of the support 9.

The rear side of the connecting table 800 may be integrally connected to the upper front outer peripheral surface of the support (9).

The front side of the connecting table 800 may be integrally connected to the rear side of the luminaire 500.

10 is a side view schematically showing a security camera having a solar module 300 having a self-cleaning function of the present inventors.

Next, the present invention security camera having a solar module 300 having a self-cleaning function is large, as shown in Figure 10, includes a solar cell module 300 and the camera unit 700 having the self-cleaning function. It can be done by.

The camera unit 700 may be provided on the upper front side of the support 9 so as to be provided in a lower direction of the solar cell module 300, and may photograph the vicinity of the support 9 under the control of the controller 100. .

The connecting table 800 may be integrally provided between the camera unit 700 and the upper front side of the support 9.

The rear side of the connecting table 800 may be integrally connected to the upper front outer peripheral surface of the support (9).

The front side of the connecting table 800 may be integrally connected to the upper portion of the camera unit 700.

According to the present invention configured as described above, the cleaning unit 40 is an upper surface of the solar cell 5 in a state in which the spray table 20 sprays water at a low pressure, particularly at the upper surface of the solar cell 5. Since wiping and cleaning, the upper surface of the solar cell 5 can be washed more easily, as well as foreign substances including dust, etc. loaded on the upper surface of the solar cell 5 can be more easily removed. The power generation efficiency of the solar cell 5 can be greatly improved, and furthermore, the power consumption ratio of the solar cell 5 can be greatly reduced since the spraying rod 20 injects water to the upper surface of the solar cell 5 at low pressure. There is an advantage to that.

10; Reservoir, 20; Sandblast,
30; Pump, 40; Cleaner.

Claims (12)

A reservoir (10) provided under the solar cell (5) for storing water (7) flowing along the upper surface of the solar cell (5);
A spraying unit 20 disposed above the solar cell 5 and spraying water 7 onto an upper surface of the solar cell 5;
A pump (30) for supplying the water (7) stored in the reservoir (10) to the spray table (20);
And a cleaning part 40 for cleaning the upper surface of the solar cell 5 in a state in which the spray table 20 sprays water 7 on the upper surface of the solar cell 5. Solar cell module with a self-cleaning function.
The method of claim 1,
Solar cell module having a self-cleaning function, characterized in that the upper portion of the reservoir (10) is open.
3. The method according to claim 1 or 2,
Opening opening (10a) is formed on the top of the reservoir (10),
Solar cell module having a self-cleaning function, characterized in that the evaporation suppression plate 50 is provided on the inner upper side of the reservoir in a state located in the lower direction of the opening (10a).
The method of claim 3,
The evaporation suppression plate 50 is a rear inclination plate 510 which is inclined downward from the rear upper portion of the water storage tank 10 toward the front inner circumferential surface of the water storage tank 10 so as to be positioned in a lower direction of the opening 10a;
A solar cell module having a self-cleaning function, characterized in that it comprises a; inclined upward in the direction of the front inner circumferential surface of the reservoir 10 from the lower side of the rear inclined plate (510).
The method of claim 1,
A water level sensor 60 for detecting the water level of the water 7 stored in the reservoir 10;
A non-sensing sensor 70 for detecting outside rain;
A discharge pipe (80) provided at a lower portion of the reservoir (10) to discharge water (7) stored in the reservoir (10);
An opening / closing valve (90) provided in the discharge pipe (80) to open and close the discharge pipe (80);
A control unit (100) for controlling the opening / closing valve (90), the pump (30), and the cleaning unit (40) according to the detection signal of the water level sensor (60) and the detection signal of the non-sensing sensor (70); Solar cell module having a self-cleaning function, characterized in that it is provided.
The method of claim 1,
A temperature sensor 200 for sensing the temperature of the water 7 stored in the reservoir 10;
And a control unit (100) for controlling the pump (30) and the cleaning unit (40) according to the detection signal of the temperature sensor (200).
The method of claim 1,
The cleaning part 40 includes a cleaning member 410 for moving the left and right in contact with the upper surface of the solar cell 5 to clean the upper surface of the solar cell 5;
Solar cell module having a self-cleaning function, characterized in that comprises ;;
8. The method of claim 7,
The left and right moving members 420 may include a driving motor 421 provided on the solar cell 5;
A lead screw 422 axially coupled to the drive motor 421;
A left and right moving body 423 screwed with the lead screw 422 to move left and right with the cleaning member 410;
And a guide rod 424 provided at an upper portion of the solar cell 5 in axially coupled state with the left and right moving bodies 423 to guide left and right movements of the left and right moving bodies 423. Solar cell module with a self-cleaning function.
8. The method of claim 7,
The cleaning member 410 is a solar cell module having a self-cleaning function, characterized in that made of a wiper 411 to move left and right by the left and right moving member 420 in contact with the upper surface of the solar cell (5). .
8. The method of claim 7,
The cleaning member 410 is a solar cell module having a self-cleaning function, characterized in that consisting of a brush 412 to move left and right by the left and right moving member 420 in contact with the upper surface of the solar cell (5). .
The reservoir 10 is provided on the upper portion of the solar cell (5) for storing the water (7) flowing along the upper surface of the solar cell (5), and is provided in the lower portion of the solar cell (5) A spray table 20 for spraying water 7 on the upper surface of the pump 5, a pump 30 for supplying water 7 stored in the water storage tank 10 to the spray table 20, and the spray Sun having a self-cleaning function consisting of; a cleaning unit 40 for cleaning the upper surface of the solar cell 5 in the state in which the base 20 is spraying water (7) on the upper surface of the solar cell (5) A battery module 300;
Street light, characterized in that comprises ;; a luminaire 500 provided in the lower direction of the solar cell module 300.
The reservoir 10 is provided on the upper portion of the solar cell (5) for storing the water (7) flowing along the upper surface of the solar cell (5), and is provided in the lower portion of the solar cell (5) A spray table 20 for spraying water 7 on the upper surface of the pump 5, a pump 30 for supplying water 7 stored in the water storage tank 10 to the spray table 20, and the spray Sun having a self-cleaning function consisting of; a cleaning unit 40 for cleaning the upper surface of the solar cell 5 in the state in which the base 20 is spraying water (7) on the upper surface of the solar cell (5) A battery module 300;
Security camera characterized in that it comprises a; camera unit 700 provided in the lower direction of the solar cell module 300.

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