KR102501120B1 - Smart washing device and method for three-effect roof-mounted solar panel consisting of micro-nano-bubbles and porous pressure differential spraying for rainwater recycling and washing - Google Patents

Abstract

The present invention relates to a roof-mounted solar panel smart cleaning device of a three-effect type including rainwater recycling, cleaning micro-nano bubbles, and porous pressure differential spray, and to a method thereof, which guarantee profitability and cleaning efficiency. The roof-mounted solar panel smart cleaning device of a three-effect type, comprises: a rainwater receiving unit (100); a rainwater inflow waterway pipe (200); a smart rainwater storage tank unit (400); a twin type suction pump (500); a firefighting suction pump (600); a twin type micro-filter unit (700); and a smart control unit (900b).

Description

Smart washing device and method for three-effect roof-mounted solar panel consisting of micro-nano bubbles for rainwater recycling and porous pressure differential spraying {Smart washing device and method for three-effect roof-mounted solar panel consisting of micro-nano- bubbles and porous pressure differential spraying for rainwater recycling and washing}

The present invention is installed and applied to the roofs of buildings such as homes, schools, and factories. After generation, the roof-mounted photovoltaic panel is washed by porous pressure difference spraying, and it is filtered and stored again in a repeated routine. It relates to a three-effect roof-mounted solar panel smart cleaning device and method.

A solar power generation system essentially includes a solar panel (or solar power module) consisting of photoelectric conversion elements (Solar Cells) that convert light incident from the sun into electrical energy, and the solar panel is It is supported by a base panel installed to have an optimal inclination for the incident angle of sunlight while maintaining a constant height from the ground.

Considering the fact that the amount of power generation/generation efficiency of such a solar panel depends on the cleanliness of its surface, the maximum amount of power generation/generation efficiency can be obtained only when the surface of the solar panel is kept extremely clean.

However, in reality, since the solar panel is installed in a state exposed to the external environment, it is difficult to prevent contamination by soiling, and the amount of power generation / power generation efficiency is highly likely to decrease gradually or rapidly. am.

In other words, the soiling phenomenon on the surface of the solar panel is a continuous process in which scattering dust such as fine dust, yellow dust, algae secretions, foreign substances left during rain or snowfall accumulate on the surface of the panel and are cured by sunlight. It occurs repeatedly, thereby contaminating the surface of the photovoltaic panel, and eventually reducing the amount of power generation / power generation efficiency, resulting in economic loss.

In order to solve this problem, as the prior art, "solar panel cleaning device" of Korean Patent Registration No. 10-1700398 and "solar panel cleaning device" of Korean Patent Registration No. 10-2162964 have been mentioned. , This is used as a time constant as cleaning water, so when the amount of water used increases, water supply costs occur, and above all, water waste increases, and when spraying the nozzle, the spray angle is narrow and the spray length is short, so that the entire solar panel There was a problem in that the washing rate for washing was low, and the washing process had to be performed manually through a separate washing machine.

In addition, a number of workers are required because a worker must manually check the state of foreign matter or dust accumulated on the solar panel and work frequently, resulting in a problem in that labor costs are high.

In addition, in the case of solar panels installed on the roofs of factories or school buildings, in the event of a fire, it is difficult to monitor the fire itself, and it is difficult to supply fire extinguishing water that can extinguish the fire, making it impossible to respond to the initial evolution. There was a problem with watching the entire panel burn down.

1. Korean Patent Registration No. 10-1700398 2. Korean Patent Registration No. 10-2162964

In order to solve the above problems, in the present invention, a repeat routine of filtering and storing rainwater, micro-filtering it, generating micro-nano bubbles for cleaning, washing through a roof-mounted solar panel, and filtering and storing it again Recycling can be controlled to reuse rainwater, and through micro-nano bubble generation control mode for washing, which creates micro-nano bubble for washing while colliding with the force of pressurization and rotation of the screw, the micro-nano bubble for washing is generated in the roof-mounted solar panel. When in contact with the surface, it can generate a cleaning effect according to the bursting of the micro-nano bubbles on the surface, and the porous water flow of the porous pressure differential type washing spray nozzle part spreads to the left and right while washing, forming a wide washing angle and washing radius, so that there is no gap. Above all, washing spray lengths of 50cm, 100cm, 200cm, and 300cm are formed according to the multi-stage pressure difference of 5bar, 10bar, 20bar, and 30bar. Three-effect type roof-mounted solar panel smart cleaning consisting of rainwater recycling, micro-nano bubbles for washing, and porous pressure differential spraying that can create a washing atmosphere so that the surface of the roof-mounted solar panel can be washed Its purpose is to provide an apparatus and method.

In order to achieve the above object, the three-effect roof-mounted solar panel smart cleaning device made of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing according to the present invention

After filtering and storing the rainwater coming down the roof-mounted solar panel, micro-filtering it, generating micro-nano bubbles for cleaning, and washing the roof-mounted solar panel by spraying porous pressure difference, filtering it again and storing it This is achieved by being configured to control rainwater to be reused in a repeating routine.

The three-effect type roof-mounted solar panel smart cleaning device consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing is more specifically,

A rainwater inlet 100 formed along the longitudinal direction at the bottom of the inclined roof-mounted solar panel, receiving rainwater flowing through the roof-mounted solar panel when it rains and conveying it to the water pipe for rainwater inflow;

A water inlet pipe 200 for rainwater inflow, which is located between the rainwater inlet and the cyclone-type rainwater filtration unit, receives rainwater from the rainwater inlet and flows it into the cyclone-type rainwater filtration unit;

Foreign matter contained in the rainwater introduced through the rainwater inlet pipe is filtered by the force of centrifugal force generated by swirling flow and twin (double) upper and lower narrow fine wire mesh, and only the filtered rainwater is smart rainwater. A cyclone-type rainwater filtration unit 300 supplied to the storage tank unit;

A smart rainwater storage tank unit 400 that stores rainwater that has passed through the cyclone-type rainwater filter unit, senses the amount of stored rainwater and transmits it to the smart control unit;

A twin-type suction pump 500 that generates the force of twin (double) pressure, sucks rainwater stored in the smart rainwater storage tank part, and supplies it to the twin-type microfilter part,

A firefighting suction pump 600 that generates the force of one pressure, sucks rainwater stored in the smart rainwater storage tank unit, and supplies it to the porous pressure differential washing spray nozzle unit,

A twin-type microfilter unit that receives rainwater supplied through a twin-type suction pump on one waterway and passes through twin (double) simultaneous microfilters to generate microfiltered filtered rainwater and transfers it to the micro-nano bubble generator for washing. (700),

After receiving the microfiltered rainwater from the twin-type microfilter unit and dissolving it along the zigzag structure so that it dissolves with oxygen, micro-nano bubbles for washing are created while the screw rotates and collides with the force of pressurization to create micro-nano bubbles for washing unit 800;

After sucking in the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generating unit, multi-stage pressure supplying them to the porous pressure differential type washing spray nozzle while giving a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, 30 bar according to the time setting cycle A car discharge pump 900,

Based on the top of the head of the roof-mounted solar panel, a line structure is formed along the longitudinal direction of the X-axis, and a cleaning micro A porous pressure differential type washing spray nozzle unit (900a) for receiving nanobubbles and washing the roof-mounted solar panel;

Connected to cyclone type rainwater filtration unit, smart rainwater storage tank unit, twin type suction pump, firefighting suction pump, twin type micro filter unit, cleaning micro/nano bubble generator unit, multi-stage pressure difference discharge pump, porous pressure differential type washing spray nozzle unit It is characterized in that it consists of a smart control unit (900b) that controls the overall operation while smartly controlling the roof-mounted solar panel to be cleaned by rainwater recycling control, micro-nano bubble generation control for cleaning, and porous pressure differential injection control. do.

In addition, the three-effect roof-mounted solar panel smart cleaning method consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing according to the present invention

Receiving rainwater flowing from the rainwater inlet through the roof-mounted photovoltaic panel and transferring it to the water pipe for rainwater inflow (S10);

A step (S20) of receiving rainwater from the rainwater inlet in the water pipe for inflow of rainwater and introducing it toward the cyclone-type rainwater filtering unit;

In the cyclone-type rainwater filtration unit, the foreign matter contained in the rainwater introduced through the rainwater inlet pipe is filtered by the centrifugal force generated by the swirling flow and the twin (double) upper and lower narrow fine wire mesh. , Supplying only the filtered rainwater to the smart rainwater storage tank unit (S30),

Storing the rainwater that has passed through the cyclone-type rainwater filter in the smart rainwater storage tank unit, sensing the amount of stored rainwater and transmitting it to the smart control unit (S40);

The step of driving the twin-type suction pump according to the control signal of the smart control unit to generate twin (double) pressure, sucking rainwater stored in the smart rainwater storage tank unit, and supplying it to the twin-type microfilter unit (S50 )and,

The fire-fighting suction pump is driven according to the control signal of the smart control unit to generate a force of pressure to suck in the rainwater stored in the smart rainwater storage tank unit and supply it to the porous pressure difference washing spray nozzle unit (S60); ,

In the twin-type microfilter unit, the rainwater supplied through the twin-type suction pump is supplied to one waterway, and through the twin (double) simultaneous microfilter, microfiltered filtered rainwater is generated and transmitted to the micro-nano bubble generator for washing. The step of doing (S70),

In the cleaning micro/nano bubble generating unit, the micro-filtered rainwater is supplied from the twin-type micro filter unit and dissolved along the zigzag structure so that it dissolves with oxygen. Generating step (S80),

After inhaling the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generation unit in the multi-stage pressure differential discharge pump, the multi-stage pressure differential of 5 bar, 10 bar, 20 bar, and 30 bar is applied to the porous pressure differential type washing spray nozzle according to the time setting cycle. Supplying to the side (S90),

In the porous pressure difference type washing spray nozzle part, micro-nano bubbles are supplied for cleaning according to the multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar for each time setting cycle of the multi-stage pressure difference discharge pump, which cleans the roof-mounted solar panel. It consists of step (S100).

As described above, in the present invention

First, rainwater is filtered and stored, micro-filtered, generated micro-nano bubbles for cleaning, washed through a roof-mounted solar panel, and then filtered and stored again to control recycling to reuse rainwater. Through the rainwater recycling control mode, when washing solar panels, water consumption through constant water can be lowered to 90% or less compared to conventional water usage fees, and waterworks usage fees can be reduced to 90% or less.

Second, through the cleaning micro-nano bubble generation control mode in which micro-nano-bubble for cleaning is generated while colliding with the force of pressurization and the rotation of the screw, when the micro-nano bubble for cleaning comes into contact with the surface of the roof-mounted solar panel, the micro-nano bubble is generated from the surface. A cleaning effect is generated due to bubble bursting, so the cleaning efficiency can be improved by 60% compared to the existing ones, and cleaning can be done in an eco-friendly way without using cleaning solvents.

Third, in the event of a fire in the roof-mounted solar panel, through the fire water automatic supply control mode, the rainwater stored in the smart rainwater storage tank is automatically discharged to the porous pressure difference type washing spray nozzle for fire suppression, through unmanned With the establishment of a fire suppression system, it can be extinguished at an early stage, thereby minimizing the loss of solar panels and factories due to fire.

Fourth, it is possible to wash without gaps by forming a wide washing angle and washing radius that are washed while spreading from side to side through the porous water stream of the porous pressure difference type washing spray nozzle, and above all, it is possible to wash without gaps, and above all, Washing spray lengths of 50cm, 100cm, 200cm, and 300cm are formed according to the length of the roof-mounted solar panel, so that the washing water flowing down the surface of the roof-mounted solar panel flows down like a wave, so that the entire surface of the roof-mounted solar panel is washed. can form, thereby activating the roof-mounted solar panel smart cleaning system market that guarantees economic feasibility, profitability, and cleaning efficiency.

1 is a block diagram showing the components of a three-effect type roof-mounted solar panel smart cleaning device 1 consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing according to the present invention;
Figure 2 is a configuration diagram showing the components of a three-effect type roof-mounted solar panel smart cleaning device 1 consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing according to the present invention;
3 is a flow chart showing the components of a three-effect type roof-mounted solar panel smart cleaning device 1 consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing according to the present invention;
Figure 4 is a perspective view showing the components of the cyclone-type rainwater filter according to the present invention;
5 is an exploded perspective view showing the components of a cyclone-type twin filter unit according to the present invention;
6 is a block diagram showing the components of the smart rainwater storage tank unit according to the present invention;
7 is a perspective view showing the components of the smart rainwater storage tank unit according to the present invention;
8 is a block diagram showing the components of a twin-type suction pump according to the present invention;
9 is a block diagram showing the components of a fire fighting suction pump according to the present invention;
10 is a block diagram showing the components of a twin-type microfilter unit according to the present invention;
11 is an internal configuration diagram showing the components of a first microfilter unit according to the present invention;
12 is an embodiment showing that in the first multi-channel microfilter according to the present invention, rainwater introduced through the first rainwater inlet is microfiltered to generate microfiltered filtered rainwater;
13 is a block diagram showing the components of the cleaning micro/nano bubble generator according to the present invention;
14 is a perspective view showing the components of a micro/nano bubble generator for cleaning according to the present invention;
15 is a perspective view showing the components of the screw rotation collision type micro-nano bubble generator according to the present invention;
16 is a block diagram showing the components of the porous pressure difference type washing spray nozzle unit according to the present invention;
17 is a washing spray length of 50 cm, 100 cm, 200 cm, and 300 cm according to a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar through the porous pressure difference type washing spray nozzle according to the present invention, and a roof-mounted solar panel An embodiment showing that the entire surface of the roof-mounted solar panel is washed by allowing the water flowing down the surface to flow down like a wave,
18 is a circuit diagram showing the components of a smart control unit according to the present invention;
19 is a block diagram showing the components of a smart control unit according to the present invention;
20 is an embodiment showing the components of an on-off automatic valve for foreign material drain according to the present invention;
21 is a repetitive routine of filtering and storing rainwater according to the present invention, micro-filtering it, generating micro-nano bubbles for cleaning, washing it through a roof-mounted solar panel, and filtering and storing it again to reuse rainwater. An embodiment showing washing the solar panel through a rainwater recycling control mode that controls recycling to
22 is a porous pressure differential type washing spray nozzle unit according to the present invention, receiving micro/nano bubbles for washing according to a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar for each time setting cycle of the multi-stage pressure differential discharge pump, and installing the roof An embodiment showing cleaning an expression solar panel,
23 is a flow chart showing a three-effect type roof-mounted solar panel smart cleaning method consisting of micro-nano bubbles and porous pressure difference spraying for rainwater recycling and cleaning according to the present invention.

First, the roof-mounted photovoltaic panel described in the present invention is installed on the roof of a building such as a home, school, or factory, and serves to convert solar thermal energy into electrical energy and generate it.

It is connected to one side, and is configured by forming a power conversion device (PCS), a meter, and a power storage device.

In addition, the roof-mounted solar panel 2 according to the present invention is configured to include a temperature sensor 2a for sensing the temperature of the solar panel on one side of the surface or rear surface.

Next, the micro/nano bubbles for cleaning described in the present invention refer to micro-nano-sized bubbles of 0.05 μm to 50 μm.

Hereinafter, a preferred embodiment according to the present invention will be described with accompanying drawings.

1 relates to a block diagram showing the components of a three-effect type roof-mounted solar panel smart cleaning device 1 composed of micro-nano bubbles for rainwater recycling and washing and porous pressure differential spraying according to the present invention, FIG. 2 relates to a configuration diagram showing the components of a three-effect type roof-mounted solar panel smart cleaning device 1 composed of micro-nano bubbles for rainwater recycling and washing and porous pressure differential spraying according to the present invention, FIG. 3 is a flow chart showing the components of a three-effect type roof-mounted solar panel smart cleaning device 1 consisting of micro-nano bubbles for rainwater recycling and washing and porous pressure differential spraying according to the present invention, which is a roof-mounted type It is a repeated routine of filtering and storing rainwater coming down the solar panel, micro-filtering it, generating micro-nano bubbles for cleaning, washing the roof-mounted solar panel by spraying porous pressure difference, and filtering and storing it again. It is configured to control rainwater to be reused.

More specifically, the three-effect type roof-mounted solar panel smart cleaning device 1 consisting of micro-nano bubbles for rainwater recycling and washing and porous pressure differential spraying includes a rainwater receiving unit 100 and a waterway pipe 200 for rainwater inflow. ), cyclone-type rainwater filtration unit 300, smart rainwater storage tank unit 400, twin-type suction pump 500, fire-fighting suction pump 600, twin-type microfilter unit 700, micro-nano bubble generation for washing It consists of a unit 800, a multi-stage pressure differential discharge pump 900, a porous differential pressure washing spray nozzle unit 900a, and a smart control unit 900b.

First, the rain water receiving unit 100 according to the present invention will be described.

The rain water receiving unit 100 is formed along the longitudinal direction at the bottom of the roof-mounted solar panel having an inclined structure, and receives rainwater flowing through the roof-mounted solar panel when it rains, and transfers it to the waterway pipe for rainwater inflow. play a role

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"의 사각구조로 형성된다.It is made of plastic material

The arc structure of " or "

It is formed in the square structure of ".

Next, the water pipe 200 for inflow of rainwater according to the present invention will be described.

The water pipe 200 for inflow of rainwater is located between the rainwater inlet and the cyclone-type rainwater filtration unit, and serves to receive rainwater from the rainwater inlet and introduce it toward the cyclone-type rainwater filtration unit.

It is formed by connecting one or more of the X-axis longitudinal waterway pipe and the Y-axis longitudinal waterway pipe.

As shown in FIG. 3, the water pipe 200 for inflow of rainwater includes an on-off automatic valve 210 for inflow of rainwater.

Here, the on-off automatic valve 210 for rainwater inflow is driven according to the control signal of the smart control unit and serves as an automatic valve to flow rainwater toward the cyclone-type rainwater filter.

Next, the cyclone-type rainwater filter 300 according to the present invention will be described.

The cyclone-type rainwater filtering unit 300 removes foreign substances contained in rainwater introduced through the rainwater inlet water pipe by the force of centrifugal force generated by swirling flow and twin (double) upper and lower narrow fine wire meshes. After filtering, it serves to supply only filtered rainwater to the smart rainwater storage tank.

As shown in FIG. 4, it consists of a rainwater filtering body 310, a rainwater inlet 320, a cyclone-type twin filter 330, a filtered rainwater supply unit 340, and a foreign matter drain unit 350.

First, the rainwater filtering body 310 according to the present invention will be described.

The rainwater filtering body 310 has a vertical structure of upper and lower sides, and serves to protect and support a rainwater inlet, a cyclone-type twin filter, a filtered rainwater supply, and a foreign matter drain.

It is composed of a vertical structure with a cylindrical shape and a large diameter at the upper end and a smaller diameter at the lower end.

That is, a rainwater inlet is formed on one wall at the top of the interior space, a cyclone-type twin filter unit is formed from the top to the bottom of the interior space, and a filtered rainwater supply unit for supplying filtered rainwater toward the smart rainwater storage tank on one side of the lower middle of the interior space. formed, and a foreign material drain part is formed on the bottom of the lower part of the inner space.

Second, the rainwater inlet 320 according to the present invention will be described.

The rainwater inlet 320 is formed along the longitudinal direction of the X-axis and is connected to a rainwater inflow waterway pipe to receive rainwater and foreign substances contained in rainwater from the rainwater inflow waterway pipe and deliver them to the cyclone-type twin filter unit play a role

This is formed along the longitudinal direction of the X-axis, so that rainwater forms a waterway in the straight direction up to the head of the cyclone-type twin filter unit located in the inner space along the longitudinal direction of the X-axis, and then forms a cylindrical shape from the top to the bottom of the cyclone-type twin filter unit. In addition, it is formed in a vertical structure with a large upper end and a smaller diameter toward the lower end, resulting in centrifugal force due to swirling flow.

Third, the cyclone-type twin filter unit 330 according to the present invention will be described.

The cyclone-type twin filter unit 330 is formed from the upper end to the lower end of the inner space of the rainwater filtering body, and is formed by the centrifugal force generated by the swirling flow and the twin (double) upper and lower narrow fine wire mesh, rainwater It plays a role in filtering the foreign substances contained in it.

As shown in FIG. 5, it is composed of a first cyclone-type fine wire portion 331 and a second cyclone-type fine wire portion 332.

The first cyclone-type fine wire mesh part 331 is formed of a first upper and lower narrow fine wire mesh having a size of 2mm*2mm from the top to the bottom of the inner space, through the force of centrifugal force generated by swirling flow. , it plays a role in primarily filtering foreign substances contained in rainwater.

It is configured by forming a rainwater impact rounding strip without fine wire mesh at the upper end, and forming a first upper and lower narrow fine wire mesh having a size of 2mm*2mm at the bottom of the rainwater impact rounding strip.

Here, as a rainwater impact rounding band without a fine wire mesh is formed at the upper end, it is possible to create swirling flow by hitting rainwater.

In addition, the size of the first upper and lower narrow fine wire mesh is the horizontal and vertical size of the wire mesh, in addition to the size of 2mm * 2mm, depending on the purpose and shape of use, 2.5mm * 2.5mm size, 3mm * 3mm size is also formed.

The second cyclone-type fine wire mesh part 332 surrounds the first cyclone-type fine wire mesh part and is located at the lower end of the first cyclone-type fine wire mesh part, and has a size of 0.5mm*0.5mm from the top to the bottom of the inner space. It is formed of a lower narrow fine wire mesh, and serves to secondarily filter the remaining foreign matter after filtering in the first cyclone type fine wire mesh unit through the centrifugal force generated by the swirling flow.

It is formed to be 1.1 to 1.5 times larger than the diameter of the first cyclone-type fine wire mesh portion 331 and surrounds the first cyclone-type fine wire mesh portion.

In addition, a rainwater impact rounding strip without fine wire mesh is formed at the upper end, and a first upper and lower narrow fine wire mesh having a size of 2mm*2mm is formed at the bottom of the rainwater impact rounding strip.

Here, as a rainwater impact rounding band without a fine wire mesh is formed at the upper end, it is possible to create swirling flow by hitting rainwater.

In addition, the size of the second upper and lower narrow fine wire mesh is the horizontal and vertical size of the wire mesh, in addition to the size of 0.5mm * 0.5mm, depending on the purpose and shape of use, the size of 0.2mm * 0.2mm, 1mm * 1mm It is also formed in size.

As such, in the cyclone-type twin filter unit 330, the force of the centrifugal force generated by the swirling flow and the upper and lower sides of the twin (double) of the first cyclone-type fine wire mesh unit 331 and the second cyclone-type fine wire mesh unit 332 (上廣下狹) Due to the fine wire mesh, foreign substances contained in rainwater can be filtered 1.5 to 3 times faster than before and with a filtration rate of 80% compared to before.

Fourth, the filtered rainwater supply unit 340 according to the present invention will be described.

The filtered rainwater supply unit 340 is located on one side of the lower side wall of the inner space of the rainwater filtering body, and serves to supply only rainwater that has passed through the first cyclone-type fine wire mesh unit and the second cyclone-type fine wire mesh unit to the smart rainwater storage tank unit. do

This is configured to be located on one side of the lower side wall of the inner space of the rainwater filtering body so that only rainwater passing through the first cyclone-type fine-network unit 331 and the second cyclone-type fine-network unit 332 is supplied.

Fifth, the foreign material drain unit 350 according to the present invention will be described.

The foreign material drain unit 350 is located at the bottom of the cyclone-type twin filter unit and serves to discharge foreign materials filtered from rainwater to the outside.

As shown in FIG. 3, it is configured by including an on-off automatic valve (Auto Valve) 351 for draining foreign matter.

Here, the on/off automatic valve 351 for foreign material drain is driven according to the control signal of the smart controller and serves as an automatic valve to discharge foreign matter to the outside.

As shown in FIG. 20, this includes a foreign material drain valve body 351a, a foreign material drain main valve 351b, a foreign material drain actuator unit 351c, a foreign material drain solenoid valve 351d, and a foreign material drain regulator unit. 351e, and a limit switch box portion 351f for foreign matter drain.

The foreign material drain valve body 351a is formed in an upright vertical structure, and supports a main valve for foreign material drain, an actuator unit for foreign material drain, a solenoid valve for foreign material drain, a regulator unit for foreign material drain, and a limit switch box unit for foreign material drain. plays a role in

It has a main valve for foreign matter drain formed at the lower end, an actuator part for foreign material drain is formed in the upper direction of the main valve for foreign matter drain, a solenoid valve for foreign material drain is formed on one side of the upper end of the actuator part for foreign matter drain, and the foreign matter drain It is configured by forming a limit switch box for foreign matter drain on one side of the solenoid valve.

The foreign material drain main valve 351b is located at the lower end of the foreign material drain valve body and is located on the water channel, and serves to turn on/off the flow of the water channel according to the driving of the foreign material drain actuator unit.

The actuator unit 351c for foreign matter drain is located at one side of the upper end of the main valve for foreign matter drain, and serves to directly drive the main valve for foreign matter drain to turn on/off the flow of the waterway on the waterway.

The solenoid valve 351d for foreign matter drain is located on one side of the upper end of the actuator for foreign material drain, and is driven according to the signal of the limit switch box for foreign material drain to supply or block air transmitted to the actuator for foreign matter drain. do

The foreign material drain regulator part 351e serves to filter the working air and adjust the pressure.

The foreign material drain limit switch box 351f is connected to several contacts of the foreign material drain solenoid valve, and serves to drive and control the foreign material drain solenoid valve according to a control signal of the smart controller.

Next, the smart rainwater storage tank unit 400 according to the present invention will be described.

The smart rainwater storage tank unit 400 serves to sense the amount of stored rainwater and transmit it to the smart control unit while storing rainwater that has passed through the cyclone-type rainwater filtration unit.

As shown in FIG. 6, this includes a rainwater storage tank body 410, a filtered rainwater inlet 420, an overflow portion 430, a time constant water inlet 440, a rainwater level sensor 450, and a microfilter transport. It consists of an inlet 460, a bottom propeller for rotating sediment 470, and a sediment drain 480.

First, the rainwater storage tank body 410 according to the present invention will be described.

The rainwater storage tank body 410 is formed in a square box shape, and protects and supports the filtering rainwater inlet, the overflow portion, the time constant water inlet, the rainwater level sensor, the microfilter conveying inlet, and the bottom propeller for sediment rotation. play a role

It is formed in a square box shape, has a storage capacity of 1 ton to 50 tons or more, and is composed of an integral closed structure.

That is, when viewed from the front direction, the filtered rainwater inlet is formed on one side of the upper surface, the overflow part is formed on one side of the left side, the time constant water inlet is formed on one side of the filtered rainwater inlet, and the rain water flows along the longitudinal direction in the internal space. A water level sensor unit is formed, a microfilter transport inlet unit is formed on one side of the right side, a bottom propeller unit for sediment rotation is formed on the bottom of the inner space, and a sediment drain unit is formed on one side of the bottom of the overflow unit.

Second, the filtered rainwater inlet 420 according to the present invention will be described.

The filtered rainwater inlet 420 is connected to the cyclone-type rainwater filter and serves to introduce rainwater into the inner space of the main body of the rainwater storage tank.

Third, the overflow unit 430 according to the present invention will be described.

The overflow part 430 serves to forcibly discharge the rainwater to the outside when the amount of rainwater stored in the main body of the rainwater storage tank exceeds a reference value.

This is formed on one side of the upper left side of the rainwater storage tank main body.

Fourth, the time constant input unit 440 according to the present invention will be described.

The time constant inlet 440 serves to receive the time constant and introduce it into the inner space of the rainwater storage tank main body when the amount of rainwater stored in the inner space of the rainwater storage tank main body is lower than a reference value.

Here, the time constant refers to water provided by a water supply business.

The time constant water inlet is configured by including an on/off automatic valve (Auto Valve) 441 for time constant water on the waterway.

Here, the on/off automatic valve 441 for the time constant serves as an automatic valve to supply the time constant supplied by being driven according to the control signal of the smart control unit to the inner space of the rainwater storage tank body.

Fifth, the rainwater level sensor unit 450 according to the present invention will be described.

The rainwater level sensor unit 450 serves to sense the level of rainwater stored in the main body of the rainwater storage tank.

It is formed in a vertical longitudinal bar structure and is configured to sense in five stages: lowest, low, middle, high, and highest.

Sixth, the microfilter transfer inlet 460 according to the present invention will be described.

The microfilter transport inlet 460 serves to transport microfiltered filtered rainwater through the twin-type microfilter and store it in the inner space of the rainwater storage tank body.

It is formed and configured on one side of the right side of the rainwater storage tank main body.

Seventh, the bottom propeller unit 470 for rotating the sediment according to the present invention will be described.

The bottom propeller part 470 for rotating the sediment is formed at the center of the bottom surface of the rainwater storage tank body, and serves to rotate the sediment deposited on the bottom surface as the propeller rotates.

As shown in FIG. 7, it is composed of a bottom propeller 471 and a propeller rotation motor 472.

The bottom propeller 471 is formed with a plurality of rotary blades, forms a vortex while rotating, and serves to sink the heavy sediment in the lower direction using the weight difference between water and sediment to separate the layers.

The propeller rotation motor 472 serves to rotate the bottom propeller by generating rotational force.

In this way, as the bottom propeller for rotating the sediment composed of the bottom propeller 471 and the propeller rotation motor 472 is configured, as the propeller rotates, the sediment deposited on the bottom surface is rotated to purify the water circulation and toward the twin-type microfilter. Water circulation Only purified rainwater can be supplied.

Here, the water circulation purification refers to the fact that heavy precipitates sink to the bottom according to the rotation of the propeller, and only pure rainwater is formed to the top.

Eighth, the sediment drain unit 480 according to the present invention will be described.

The sediment drain unit 480 is located on one side of the bottom surface of the main body of the rainwater storage tank and serves to discharge the sediment settled on the floor to the outside through the bottom propeller for rotating the sediment.

As shown in FIG. 3, it is configured by including an on-off automatic valve (Auto Valve) 481 for sediment drain.

Here, the on-off automatic valve 481 for the sediment drain is driven according to the control signal of the smart controller and serves as an automatic valve to discharge the sediment to the outside.

This is configured identically to the components of the on/off automatic valve for foreign matter drain.

Next, the twin type suction pump 500 according to the present invention will be described.

The twin-type suction pump 500 creates a force of twin (double) pressure, sucks rainwater stored in the smart rainwater storage tank unit, and serves to supply it toward the twin-type microfilter unit.

As shown in FIG. 8, it consists of a first suction pump 510 and a second suction pump 520.

That is, as shown in the figure, it is formed together on one waterway to generate the power of twin (double) pressure, quickly sucking in a large amount of rainwater stored in the smart rainwater storage tank to create a twin-type It is configured to supply the microfilter unit.

And, the twin-type suction pump 500 is configured to include a pressure sensor unit 530 for the twin-type suction pump.

The pressure sensor unit 530 for the twin-type suction pump is formed on the output channel on the output side of the twin-type suction pump and serves to sense the force of the pressure generated in the twin-type suction pump.

Next, the fire fighting suction pump 600 according to the present invention will be described.

The firefighting suction pump 600 generates a force of one pressure, sucks rainwater stored in the smart rainwater storage tank unit, and serves to supply it toward the porous pressure difference type washing spray nozzle unit.

When a fire occurs due to overheating on one of the roof-mounted solar panels, it is driven according to the control signal of the smart control unit, and the rainwater stored in the smart rainwater storage tank unit is passed through the micro filter of the twin-type micro filter unit, and the porous pressure It is configured to extinguish the fire by rapidly supplying water toward the car type washing spray nozzle part and spraying water through the porous pressure difference type washing spray nozzle part.

As shown in FIG. 9 on the output side waterway of the fire-fighting suction pump, a fire-fighting pressure sensor unit 610, a fire-fighting automatic on-off valve 620, and a micro-filter on-off automatic valve 630 are included and configured.

The pressure sensor unit 610 for firefighting is formed on the output waterway of the output side of the suction pump for firefighting, and serves to sense the force of the pressure generated in the suction pump for firefighting.

The on-off automatic valve 620 for firefighting is driven according to the control signal of the smart control unit to discharge the rainwater stored in the smart rainwater storage tank unit toward the porous pressure difference washing spray nozzle unit for fire suppression through the power of the fire pump. It acts as an automatic valve.

The on/off automatic valve 630 for the microfilter is driven according to the control signal of the smart control unit and serves as an automatic valve to discharge rainwater supplied to the twin-type microfilter unit through the power of the fire pump.

Next, the twin-type microfilter unit 700 according to the present invention will be described.

The twin-type microfilter unit 700 receives rainwater supplied through a twin-type suction pump on one waterway and generates microfiltered filtered rainwater through twin (double) simultaneous microfilters to generate micro-nano bubbles for washing. It plays a role in transmitting to the generation part.

As shown in FIG. 10, this includes a first microfilter unit 710, a second microfilter unit 720, a filtered rainwater inflow sensor unit 730, an on/off automatic valve for transportation 740, and a micro/nano bubble It is composed of an on-off automatic valve 750.

First, the first microfilter unit 710 according to the present invention will be described.

The first microfilter unit 710 is formed in a cylindrical shape having an upright vertical structure, and a plurality of microfilters are formed in the inner space, and a part of the rainwater supplied through one waterway flows into the inner space for microfiltering. After doing it, it serves to create microfiltered filtered rainwater.

As shown in FIG. 11, this includes a first cylindrical body 711, a first rainwater inlet 712, a first microfilter head holder 713, a first multi-channel microfilter 714, a first suction It consists of a pressure generating unit 715 and a first filtering rainwater supply unit 716.

The first cylindrical body 711 is formed in an upright cylindrical shape, and includes a first rainwater inlet, a first microfilter head holder, a first multi-channel microfilter, a first suction pressure generator, and a first filtering rainwater supply. It serves to protect and support wealth.

It is formed in an upright cylindrical shape, a first rainwater inlet is formed on one side of the lower end of the inner space, a first microfilter head holder is formed on the upper head of the inner space, and based on the first microfilter head holder A first multi-channel microfilter is formed along the vertical longitudinal direction of the Y-axis, a first suction pressure generator is formed on one side of the first microfilter head holder, and a first filtering rainwater is formed on one side of the first microfilter head holder in the outer direction. The supply unit is formed and configured.

In addition, an air venturi (air outlet) is included on the upper lid portion.

The first rainwater inlet 712 is located at the lower end of the inner space of the first cylindrical body, and serves to introduce rainwater transmitted through the power of the twin suction pump toward the lower end of the inner space of the first cylindrical body. .

The first microfilter head holder 713 is located on the upper end of the head of the inner space of the first cylindrical body, and serves to detachably mount and mount the first multi-channel microfilter.

The first multi-channel microfilter 714 is detachably mounted on the first microfilter head holder, receives suction pressure from the first suction pressure generator, and microfilters rainwater introduced through the first rainwater inlet. By doing so, it plays a role in generating microfiltered filtered rainwater.

It is formed in a bar shape with an upright longitudinal direction and is composed of a microfilter of 5 to 20 μm having a multi-channel (5 to 20) structure.

Here, as shown in FIG. 11, the microfilter is formed in a form in which a plurality of outer tube rods 714b are surrounded around a center tube rod 714a, and to surround the plurality of outer tube rods and the center tube rod. To this end, the microfilter sheath 714c is wrapped around to form a single microfilter.

The microfilter formed in this way is formed in a multi-channel structure with 5 to 20 pieces.

As shown in FIG. 12, the first multi-channel microfilter 714 having this configuration microfilters rainwater introduced through the first rainwater inlet to generate microfiltered filtered rainwater.

The first suction pressure generator 715 serves to generate suction pressure toward the first microfilter head holder and supply it to the first multi-channel microfilter.

The first filtering rainwater supply unit 716 serves to supply filtered rainwater generated through the first multi-channel microfilter to the cleaning micro-nano bubble generator.

Second, the second microfilter unit 720 according to the present invention will be described.

The second microfilter unit 720 has a cylindrical shape having an upright vertical structure at one side of the first microfilter unit, and a plurality of microfilters are formed in the inner space, and another rainwater supplied through one waterway. After micro-filtering by introducing some of it into the inner space, it serves to create micro-filtered filtered rainwater.

As shown in FIG. 11, this includes a second cylindrical body 721, a second rainwater inlet 722, a second microfilter head holder 723, a second multi-channel microfilter 724, and a second suction It consists of a pressure generating unit 725 and a second filtering rainwater supply unit 726.

The second cylindrical body 721 is formed in an upright cylindrical shape, and includes a second rainwater inlet, a second microfilter head holder, a second multi-channel microfilter, a second suction pressure generator, and a second filtering rainwater supply. It serves to protect and support wealth.

It is formed in an upright cylindrical shape, a first rainwater inlet is formed on one side of the lower end of the inner space, a first microfilter head holder is formed on the upper head of the inner space, and based on the first microfilter head holder A first multi-channel microfilter is formed along the vertical longitudinal direction of the Y-axis, a first suction pressure generator is formed on one side of the first microfilter head holder, and a first filtering rainwater is formed on one side of the first microfilter head holder in the outer direction. The supply unit is formed and configured.

In addition, an air venturi (air outlet) is included on the upper lid portion.

The second rainwater inlet 722 is located at the lower end of the inner space of the second cylindrical body, and serves to introduce rainwater transmitted through the power of the twin suction pump toward the lower end of the inner space of the second cylindrical body. .

The second microfilter head holder 723 is located on the upper end of the head of the inner space of the second cylindrical body, and serves to detachably mount and mount the second multi-channel microfilter.

The second multi-channel microfilter 724 is detachably mounted on the second microfilter head holder, receives suction pressure from the second suction pressure generator, and microfilters rainwater introduced through the second rainwater inlet. By doing so, it plays a role in generating microfiltered filtered rainwater.

It is formed in a bar shape with an upright longitudinal direction and is composed of a microfilter having a multi-channel (5 to 20) structure.

Here, as shown in FIG. 11, the microfilter is formed in a form in which a plurality of outer tube rods are surrounded around a center tube rod, and a microfilter coating is wrapped around the plurality of outer tube rods and the center tube rod to form one microfilter. formed as a filter.

The microfilter formed in this way is formed in a multi-channel structure with 5 to 20 pieces.

As shown in FIG. 12, the second multi-channel microfilter 724 having such a configuration microfilters rainwater introduced through the second rainwater inlet to generate microfiltered filtered rainwater.

The second suction pressure generator 725 serves to generate suction pressure toward the second microfilter head holder and supply it toward the second multi-channel microfilter.

The second filtering rainwater supply unit 726 serves to supply filtered rainwater generated through the second multi-channel microfilter to the cleaning micro-nano bubble generator.

Third, the filtering rainwater inflow sensor unit 730 according to the present invention will be described.

The filtered rainwater inflow sensor unit 730 is formed on the output channel of the output side of the first microfilter unit and the second microfilter unit, and measures the inflow of filtered rainwater generated in the first microfilter unit and the second microfilter unit by a magnetic expression. plays a role in sensing

This is done in m ³ /h unit for the inflow of filtered rainwater.

Fourth, the on/off automatic valve 740 for transportation according to the present invention will be described.

The conveying on/off automatic valve 740 is driven according to the control signal of the smart control unit, and the automatic valve transfers the filtered rainwater microfiltered through the first microfilter unit and the second microfilter unit back to the smart rainwater storage tank unit. fulfill the role of

This is configured identically to the components of the on/off automatic valve for foreign matter drain.

Fifth, the on-off automatic valve 750 for micro-nano bubbles according to the present invention is described.

The on/off automatic valve 750 for micro/nano bubbles is driven according to the control signal of the smart control unit and transfers the micro-filtered filtered rainwater through the first micro filter unit and the second micro filter unit to the micro/nano bubble generator for washing. It plays the role of an automatic valve.

This is configured identically to the components of the on/off automatic valve for foreign matter drain.

Next, the micro/nano bubble generator 800 for cleaning according to the present invention will be described.

The cleaning micro/nano bubble generating unit 800 receives the microfiltered filtered rainwater from the twin-type microfilter unit, dissolves it along the zigzag structure so that it dissolves with oxygen, and then, through the power of pressurization, rotates and collides with the screw for cleaning. It plays a role in generating micro-nano bubbles.

As shown in FIGS. 13 and 14, this includes a dissolution pipe unit 810, an oxygen tank unit 820, a compressor 830, a screw rotation collision type micro-nano bubble generator 840, and a micro-nano bubble storage tank for cleaning. It consists of section 850.

The melting pipe part 810 is formed in a zigzag shape with a length of 1m to 5m, receives microfiltered filtered rainwater from the twin-type microfilter part on one side of the input port, and supplies oxygen from the oxygen tank part on the other side of the input port. It plays the role of dissolving filtered rainwater and oxygen along the zigzag structure.

The oxygen tank unit 820 serves to generate and supply oxygen toward the melting pipe unit.

The compressor 830 serves to accelerate by applying a pressure of 5 bar to 10 bar toward the dissolved oxygen-dissolved filtered rainwater entering the screw rotational collision type micro-nano bubble generator.

The screw rotational collision type micro/nano bubble generator 840 has a screw rotational collision structure formed in the internal space in addition to the capsule in the longitudinal direction, and the oxygen-dissolved filtered rainwater accelerated through the compressor is rotated and collided with the screw to generate micro/nano bubbles for cleaning. plays a role in generating

As shown in FIG. 15, it is composed of a capsule body 841 in the longitudinal direction, and a plurality of screw rotation collision type mesh protrusions 842 are formed in the inner space of the capsule body.

Here, the screw rotation collision type mesh protrusion 842 is formed in a screw screw frame structure, and causes the inflowing oxygen-dissolved filtered rainwater to screw rotation collision.

In addition, a venturi tube 843 is formed at the end of the screw rotation collision type mesh protrusion, and a fine filter network 844 of 0.01 to 0.1 mm is formed at the output end of the venturi tube.

The cleaning micro/nano bubble storage tank unit 850 serves to store micro/nano bubbles for cleaning generated through the screw rotation collision type micro/nano bubble generator.

Next, the multi-stage pressure differential discharge pump 900 according to the present invention will be described.

The multi-stage pressure differential discharge pump 900 sucks in the cleaning micro-nano bubbles generated from the cleaning micro-nano bubble generation unit, and then applies a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar according to the time setting cycle to the porous pressure. It plays a role in supplying to the car type washing spray nozzle part.

This is configured by including an on/off automatic valve for a discharge pump on one side of a supply pipe to which micro/nano bubbles for washing generated from the micro/nano bubble generator for washing are supplied.

The on/off automatic valve for the discharge pump is driven according to the control signal of the smart control unit, and the role of the automatic valve is to transfer the micro-nano bubbles for cleaning generated through the micro-nano-bubble generation unit for cleaning to the input port of the multi-stage pressure differential discharge pump. Do it.

Here, giving a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar according to the time setting cycle means that micro-nano bubbles for washing are directed toward the porous pressure difference type washing spray nozzle for 1 minute (set the setting range according to the operation selection condition, eg 1 minute 2 minutes or 10 minutes, etc.), pressure of 5bar, 10bar, 20bar, 30bar is given in order, and the porous pressure difference type washing spray nozzle cleans the roof-mounted solar panel, and at the pressure of 5bar, the roof-mounted solar panel To create a 50cm-long washing spray length sprayed toward the photovoltaic panel, at a pressure of 10 bar, to create a 100 cm long washing spray length sprayed toward the roof-mounted solar panel at a pressure of 20 bar, and at a pressure of 20 bar, a roof-mounted solar It means to create a 200cm long washing spray length sprayed toward the photovoltaic panel, and to create a 300cm long washing spray length sprayed toward the roof-mounted solar panel at a pressure of 30 bar.

The multi-stage pressure difference discharge pump 900 includes an on-off automatic valve 910 for multi-stage pressure difference and an on-off automatic valve 920 for return on one side of the output side.

Next, the porous pressure difference type washing spray nozzle unit 900a according to the present invention will be described.

The porous pressure difference type washing spray nozzle part 900a is formed in a line structure along the X-axis longitudinal direction based on the top of the head of the roof-mounted solar panel, and 5 bar, 10 bar, It is supplied with micro-nano bubbles for cleaning according to the multi-stage pressure difference of 20 bar and 30 bar, and serves to clean the roof-mounted solar panel.

As shown in FIG. 16, this includes a spray nozzle holder (900a-1), a cleaning micro-nano bubble supply pipe (900a-2), a porous pressure difference type washing spray nozzle (900a-3), and a flame detection sensor (900a-4). ) is composed of

The spray nozzle holder (900a-1) is positioned at a height of 30 cm to 50 cm based on the top of the head of the roof-mounted solar panel, and the micro-nano bubble supply pipe for washing and the porous pressure difference type washing spray nozzle are upright. It serves as a structural support.

The cleaning micro/nano bubble supply pipe (900a-2) is formed in a row structure along the X-axis longitudinal direction on the spray nozzle holder, and multi-stage pressure of 5 bar, 10 bar, 20 bar, and 30 bar for each time setting cycle of the multi-stage pressure difference discharge pump It plays the role of receiving the micro/nano bubbles for washing according to the difference and supplying them to the porous pressure difference type washing spray nozzle.

The porous pressure difference-type washing spray nozzles (900a-3) are composed of a plurality on the micro-nano bubble supply pipe for washing, and 50 cm according to the multi-stage pressure difference of 1 to 10 porous water streams and 5 bar, 10 bar, 20 bar, and 30 bar. , 100cm, 200cm, and 300cm of washing spray length, and it serves to wash the roof-mounted solar panel with a porous pressure differential method.

It consists of a rod-shaped body, and is constituted by forming 1 to 10 porous holes on the head surface of the body.

In addition, the internal space is widened and narrowed towards the end of the nozzle, so that the internal pressure is lowered and the flow rate is increased.

The reason why 1 to 10 porous holes are formed on the head surface of the body according to the present invention is that when washing the roof-mounted solar panel, the washing angle is widened and the washing radius is also widened accordingly, so that there is no gap. to induce washing.

In addition, as shown in FIG. 17, washing spray lengths of 50 cm, 100 cm, 200 cm, and 300 cm are formed according to the multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar, so that the water flowing down the surface of the roof-mounted solar panel It can flow like a wave so that the entire surface of the roof-mounted solar panel can be washed.

In addition, when the micro-nano bubbles for cleaning according to the present invention come into contact with the surface of the roof-mounted solar panel, a cleaning effect occurs due to bubble bursting on the surface, and the cleaning efficiency can be improved by 60% compared to the conventional one.

The flame detection sensor 900a-4 is located on one side of the spray nozzle holder and serves to sense a flame generated in the event of a fire in the roof-mounted solar panel.

Next, the smart control unit 900b according to the present invention will be described.

The smart control unit (900b) includes a cyclone-type rainwater filtration unit, a smart rainwater storage tank unit, a twin-type suction pump, a fire-fighting suction pump, a twin-type microfilter unit, a micro-nano bubble generator unit for washing, a multi-stage pressure difference discharge pump, and a porous pressure It is connected to the car-type washing spray nozzle part and controls the overall operation, and plays a role of smart control to wash the roof-mounted solar panel by rainwater recycling control, micro-nano bubble generation control for washing, and porous pressure difference spraying control.

It is configured by selecting one of PLC (Programmable Logic Controller), PIC one-chip microcomputer, microcomputer, and microprocessor.

In the present invention, it is composed of a microprocessor.

That is, as shown in FIG. 18, the temperature sensor 2a is connected to one side of the input terminal, and a sensing signal for sensing the temperature of the solar panel is input to one side of the surface or rear surface of the roof-mounted solar panel, and A rainwater level sensor unit 450 is connected to one side of the other input terminal, and a sensing signal for sensing the level of rainwater stored in the rainwater storage tank body is input. ) is connected, formed on the output waterway on the output side of the twin-type suction pump, and a sensing signal for sensing the force of pressure generated in the twin-type suction pump is input, and another input terminal on one side of the firefighting pressure sensor unit 610 Is connected, formed on the output waterway on the output side of the fire suction pump, a sensing signal for sensing the force of pressure generated in the fire suction pump is input, and a filtering rainwater inflow sensor unit 730 is connected to one side of another input terminal. Then, a sensing signal for magnetically sensing the inflow of filtered rainwater generated in the first microfilter unit and the second microfilter unit is input, and a flame detection sensor 900a-4 is connected to one side of another input terminal, A sensing signal for sensing flames generated in the event of a fire in a roof-mounted solar panel is input, and an on-off automatic valve (210) for rainwater inflow is connected to one side of the output terminal to filter rainwater into a cyclone-type rainwater filter. An output signal is output so as to flow into the outside, and an on-off automatic valve (Auto Valve) 351 for foreign material drain is connected to one side of another output terminal to output an output signal to discharge foreign matter to the outside, and another output An on/off automatic valve (441) for time constant is connected to one side of the terminal to output an output signal to supply the supplied time constant to the inner space of the rainwater storage tank body, and to one side of another output terminal for sediment rotation. A propeller rotation motor (472) of the bottom propeller is formed, generates rotational force, outputs an output signal to rotate the bottom propeller, and an on-off automatic valve (481) for sediment drain on one side of another output terminal is connected, the output to discharge the sediment to the outside A signal is output, and a twin-type suction pump 500 is connected to one side of another output terminal to create a twin (double) pressure force to suck rainwater stored in the smart rainwater storage tank, and a twin-type microfilter An output signal is output to be supplied to the side, and a firefighting suction pump 600 is connected to one side of another output terminal to generate a force of pressure, sucking rainwater stored in the smart rainwater storage tank unit, and porous pressure An output signal is output so that it is supplied to the car washing spray nozzle part, and an on-off automatic valve 620 for firefighting is connected to one side of another output terminal, and through the power of the fire pump, rainwater stored in the smart rainwater storage tank part is discharged. For suppression, an output signal is output so that it is discharged to the porous pressure difference type washing spray nozzle part, and an on-off automatic valve 630 for microfilter is connected to one side of another output terminal, through the power of the fire pump, supplied rainwater is output toward the twin-type microfilter unit, and the first suction pressure generating unit 715 of the first microfilter unit is connected to one side of another output terminal to generate suction pressure, thereby generating a first multi-channel An output signal is output so as to be supplied to the microfilter, and a second suction pressure generator 725 of the second microfilter unit is connected to one side of another output terminal to generate suction pressure and supply it to the second multi-channel microfilter. An output signal is output so as to output, and an on-off automatic valve 740 for conveyance is connected to one side of another output terminal, and the filtered rainwater microfiltered through the first microfilter unit and the second microfilter unit is again smart rainwater storage tank An output signal is output to be transmitted to the negative side, and an on-off automatic valve 750 for micro-nano bubbles is connected to one side of another output terminal, so that the filtered rainwater microfiltered through the first microfilter unit and the second microfilter unit is An output signal is output to be transmitted to the cleaning micro-nano bubble generating unit, and an oxygen tank unit 820 is connected to one side of another output terminal to generate and supply oxygen to the zigzag melting pipe unit. , compression on one side of another output terminal The machine 830 is connected to output an output signal that accelerates by applying a pressure of 5 bar to 10 bar toward the oxygen-dissolved filtered rainwater entering the screw rotation collision type micro-nano bubble generator, and outputs a multi-stage pressure difference on one side of another output terminal The discharge pump 900 is connected, sucks the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generating unit, and then provides a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar according to the time setting cycle to form a porous pressure differential It is configured to output an output signal so as to supply toward the washing spray nozzle part.

In addition, the smart control unit 900b according to the present invention is configured to control the transmission of the operating state and sensing signal of each device to the solar panel control server along with fire monitoring control.

As shown in FIG. 19, the smart control unit 900b has a rainwater recycling control mode (900b-1), a micro-nano bubble generation control mode for washing (900b-2), and a porous pressure difference injection control mode (900b-3). , the fire fighting water automatic supply control mode (900b-4) is programmed and configured.

The rainwater recycling control mode (900b-1) is a repetitive routine of filtering and storing rainwater, micro-filtering it, generating micro-nano bubbles for washing, washing it through a roof-mounted solar panel, and filtering and storing it again. It plays a role in controlling recycling so that rainwater can be reused.

Through this, when washing solar panels, water consumption through constant water can be lowered to 90% or less compared to the existing ones, and water supply fees can be reduced to 90% or less, activating an economical roof-mounted solar panel smart cleaning system. can make it

The washing micro/nano bubble generation control mode (900b-2) drives the washing micro/nano bubble generating unit to receive the microfiltered filtered rainwater from the twin-type microfilter unit and dissolve it along the zigzag structure so that it dissolves with oxygen. , It plays a role of controlling to generate micro-nano bubbles for cleaning while colliding with the rotation of the screw through the force of pressurization.

Through this, when micro-nano bubbles for cleaning come into contact with the surface of a roof-mounted solar panel, a cleaning effect occurs due to the bursting of micro-nano bubbles on the surface, and the cleaning efficiency can be improved by 60% compared to the previous one, and the use of cleaning solvents Without it, it can be cleaned in an environmentally friendly way.

The porous pressure difference injection control mode (900b-3) drives the multi-stage pressure difference discharge pump to supply a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar to the porous pressure difference type washing spray nozzle part according to the time setting cycle , Roof installation with a porous pressure difference method consisting of 1 to 10 porous water streams of porous pressure differential type washing spray nozzles and 50 cm, 100 cm, 200 cm, and 300 cm of washing spray length according to multi-stage pressure differences of 5 bar, 10 bar, 20 bar, and 30 bar. It plays a role in controlling the cleaning of the solar panel.

Due to this, the washing angle and washing radius are widened while spreading from side to side through the porous water stream, so that it can be washed without gaps, and above all, 50cm, 100cm, 200cm according to the multi-stage pressure difference of 5bar, 10bar, 20bar, and 30bar , a washing spray length of 300 cm is formed, so that the washing water flowing down the surface of the roof-mounted solar panel flows down like a wave, thereby forming a washing atmosphere so that the entire surface of the roof-mounted solar panel is washed.

The automatic firefighting water supply control mode (900b-4) drives a suction pump for firefighting when a fire is detected through a temperature sensor and a flame sensor, and through the power of the firefighting pump, the rainwater stored in the smart rainwater storage tank is used to extinguish the fire. It serves to control the discharge toward the porous pressure differential type washing spray nozzle.

As a result, in the event of a fire in the roof-mounted solar panel, the rainwater stored in the smart rainwater storage tank is automatically discharged to the porous pressure differential type washing spray nozzle for fire suppression through the automatic firefighting water supply control mode. With the establishment of a fire suppression system through fire suppression system, it can be extinguished at an early stage, thereby minimizing solar panel loss due to fire.

Hereinafter, the specific process of the three-effect roof-mounted solar panel smart cleaning method consisting of micro-nano bubbles for rainwater recycling and cleaning and porous pressure differential spraying according to the present invention will be described.

23 is a flow chart showing a three-effect type roof-mounted solar panel smart cleaning method consisting of micro/nano bubbles/porous pressure differential spraying for rainwater recycling/cleaning according to the present invention.

First, rainwater flowing through the roof-mounted photovoltaic panel is received from the rainwater receiving unit and transferred to the water pipe for rainwater inflow (S10).

At this time, in addition to the rainwater, the washing water for washing the roof-mounted solar panel is received and transferred to the water pipe for rainwater inflow.

Next, rainwater is received from the rainwater inlet in the water pipe for rainwater inflow and introduced into the cyclone-type rainwater filter (S20).

Next, in the cyclone-type rainwater filtration unit, the foreign matter contained in the rainwater introduced through the rainwater inlet pipe is transferred to the centrifugal force generated by the swirling flow and the twin (double) upper and lower narrow fine wire mesh. After filtering, only filtered rainwater is supplied to the smart rainwater storage tank (S30).

Next, while storing the rainwater that has passed through the cyclone-type rainwater filtration unit in the smart rainwater storage tank unit, the amount of stored rainwater is sensed and transmitted to the smart control unit (S40).

Next, the twin-type suction pump is driven according to the control signal of the smart control unit to generate twin (double) pressure force to suck in the rainwater stored in the smart rainwater storage tank unit and supply it to the twin-type microfilter unit. (S50).

Next, the firefighting suction pump is driven according to the control signal of the smart control unit to generate a force of one pressure to suck in the rainwater stored in the smart rainwater storage tank unit and supply it to the porous pressure difference washing spray nozzle unit (S60). ).

Next, in the twin-type microfilter unit, rainwater supplied through the twin-type suction pump is supplied to one waterway, and micro-filtered rainwater is generated through twin (double) simultaneous microfilters to generate micro-nano bubbles for washing It is transmitted to the negative side (S70).

Next, in the cleaning micro-nano bubble generating unit, microfiltered rainwater is supplied from the twin-type microfilter unit and dissolved along the zigzag structure so that it dissolves with oxygen. Generates nanobubbles (S80).

Next, after suctioning the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generation unit in the multi-stage pressure difference discharge pump, the porous pressure differential type is applied while giving a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar according to the time setting cycle. It is supplied toward the washing spray nozzle part (S90).

Finally, as shown in FIG. 22, in the porous pressure differential type washing spray nozzle unit, micro/nano bubbles for washing are supplied according to the multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar for each time setting cycle of the multi-stage pressure differential discharge pump. Receive and wash the roof-mounted solar panel (S100).

Through this, when micro-nano bubbles for cleaning come into contact with the surface of a roof-mounted solar panel, a cleaning effect occurs due to the bursting of micro-nano bubbles on the surface, and the cleaning efficiency can be improved by 60% compared to the previous one, and the use of cleaning solvents Without it, it can be cleaned in an environmentally friendly way.

In addition, as shown in FIG. 21, a repeated routine of filtering and storing rainwater, micro-filtering it, generating micro-nano bubbles for washing, washing through a roof-mounted solar panel, and filtering and storing it again Through the rainwater recycling control mode that controls recycling to reuse rainwater, when washing solar panels, water consumption through constant water can be lowered to 90% or less, and waterworks usage fees can be reduced to 90% or less.

In addition, the three-effect roof-mounted solar panel smart cleaning device and method consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing according to the present invention are installed and applied to the roofs of buildings such as homes, schools, and factories In addition to that, it can be extended and applied to solar panels installed on the floor or inclined slopes by configuring a rainwater inlet and a waterway pipe for rainwater inflow.

1: Three-effect roof-mounted solar panel smart cleaning device
100: rain water inlet
200: water pipe for rainwater inflow
300: cyclone type rainwater filter
310: rainwater filtering body
320: rainwater inlet
330: cyclone type twin filter unit
340: filtered rainwater supply unit
350: foreign matter drain
400: smart rainwater storage tank
410: rainwater storage tank body
420: filtered rainwater inlet
430: overflow part
440: time constant inlet
450: rainwater level sensor unit
460: microfilter transfer inlet
470: bottom propeller for sediment rotation
480: sediment drain unit
500: twin suction pump
600: fire suction pump
700: twin type micro filter unit
710: first microfilter unit
720: second microfilter unit
730: filtering rainwater inflow sensor unit
740: on-off automatic valve for transport
750: on-off automatic valve for micro-nano bubbles
800: micro-nano bubble generating unit for cleaning
900: multi-stage pressure differential discharge pump
900a: Porous pressure difference washing spray nozzle part
900b: smart control unit

Claims (15)

After filtering and storing the rainwater coming down the roof-mounted solar panel, micro-filtering it, generating micro-nano bubbles for cleaning, and washing the roof-mounted solar panel by spraying porous pressure difference, filtering it again and storing it In the three-effect type roof-mounted solar panel smart cleaning device that controls rainwater to be reused in a repetitive routine,
The three-effect type roof-mounted solar panel smart cleaning device
A rainwater inlet 100 formed along the longitudinal direction at the bottom of the inclined roof-mounted solar panel, receiving rainwater flowing through the roof-mounted solar panel when it rains and conveying it to the water pipe for rainwater inflow;
A water inlet pipe 200 for rainwater inflow, which is located between the rainwater inlet and the cyclone-type rainwater filtration unit, receives rainwater from the rainwater inlet and flows it into the cyclone-type rainwater filtration unit;
Foreign matter contained in the rainwater introduced through the rainwater inlet pipe is filtered by the force of centrifugal force generated by swirling flow and twin (double) upper and lower narrow fine wire mesh, and only the filtered rainwater is smart rainwater. A cyclone-type rainwater filtration unit 300 supplied to the storage tank unit;
A smart rainwater storage tank unit 400 that stores rainwater that has passed through the cyclone-type rainwater filter unit, senses the amount of stored rainwater and transmits it to the smart control unit;
A twin-type suction pump 500 that generates the force of twin (double) pressure, sucks rainwater stored in the smart rainwater storage tank part, and supplies it to the twin-type microfilter part,
A firefighting suction pump 600 that generates the force of one pressure, sucks rainwater stored in the smart rainwater storage tank unit, and supplies it to the porous pressure differential washing spray nozzle unit,
A twin-type microfilter unit that receives rainwater supplied through a twin-type suction pump on one waterway and passes through twin (double) simultaneous microfilters to generate microfiltered filtered rainwater and transfers it to the micro-nano bubble generator for washing. (700),
After receiving the microfiltered rainwater from the twin-type microfilter unit and dissolving it along the zigzag structure so that it dissolves with oxygen, micro-nano bubbles for washing are created while the screw rotates and collides with the force of pressurization to create micro-nano bubbles for washing unit 800;
After sucking in the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generating unit, multi-stage pressure supplying them to the porous pressure differential type washing spray nozzle while giving a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, 30 bar according to the time setting cycle A car discharge pump 900,
Based on the top of the head of the roof-mounted solar panel, a line structure is formed along the longitudinal direction of the X-axis, and a cleaning micro A porous pressure differential type washing spray nozzle unit (900a) for receiving nanobubbles and washing the roof-mounted solar panel;
Connected to cyclone type rainwater filtration unit, smart rainwater storage tank unit, twin type suction pump, firefighting suction pump, twin type micro filter unit, cleaning micro/nano bubble generator unit, multi-stage pressure difference discharge pump, porous pressure differential type washing spray nozzle unit It is composed of a smart control unit (900b) that controls the overall operation while smartly controlling the roof-mounted photovoltaic panel to be cleaned by rainwater recycling control, cleaning micro-nano bubble generation control, and porous pressure differential injection control. It is a three-effect type roof-mounted solar panel smart cleaning device consisting of micro-nano bubbles for rainwater recycling, cleaning, and porous pressure differential spraying.
delete According to claim 1, wherein the cyclone type rainwater filter 300
A rainwater filtering main body 310 consisting of a vertical structure of upper and lower sides, protecting and supporting a rainwater inlet, a cyclone-type twin filter, a filtered rainwater supply, and a foreign matter drain;
A rainwater inlet 320 formed along the longitudinal direction of the X-axis and connected to the rainwater inlet pipe to receive rainwater and foreign matter contained in the rainwater from the rainwater inlet pipe and deliver them to the cyclone twin filter unit;
It is formed from the top to the bottom of the inner space of the rainwater filtering body, and the centrifugal force generated by the swirling flow and the twin (double) upper and lower narrow fine wire nets filter foreign substances contained in the rainwater. With the filter unit 330,
A filtered rainwater supply unit 340 that is located on one side of the sidewall of the lower middle of the inner space of the rainwater filtering body and supplies only rainwater that has passed through the first cyclone-type fine wire mesh unit and the second cyclone-type fine wire mesh unit toward the smart rainwater storage tank unit,
It is located at the bottom of the cyclone-type twin filter unit and consists of a foreign matter drain unit 350 for discharging foreign matters filtered from rainwater to the outside, characterized in that it is composed of micro-nano bubbles for rainwater recycling, cleaning, and porous pressure differential spraying. Three-effect roof-mounted solar panel smart cleaning device.
The method of claim 3, wherein the cyclone-type twin filter unit 330
It is formed of the first upper and lower narrow fine wire mesh having a size of 2mm*2mm from the top to the bottom of the inner space, and filters foreign substances contained in rainwater primarily through the centrifugal force generated by the swirling flow. 1 cyclone-type fine wire mesh unit 331;
It is located at the bottom of the first cyclone-type fine wire mesh while surrounding the first cyclone-type fine wire mesh, and is formed of a second upper and lower narrow fine wire mesh having a size of 0.5mm * 0.5mm from the top to the bottom of the inner space. Rainwater recycling and washing, characterized in that it consists of a second cyclone-type fine-wire mesh unit 332 that secondarily filters the remaining foreign substances after filtering in the first cyclone-type fine wire unit through the centrifugal force generated by the swirling flow. A three-effect type roof-mounted solar panel smart cleaning device composed of micro-nano bubbles and porous pressure differential spraying.
According to claim 4, the foreign material drain unit 350 is driven according to the control signal of the smart control unit to discharge the foreign material to the outside, performing the role of an automatic valve (Auto Valve) for foreign material drain (Auto Valve) (351) ) A three-effect type roof-mounted solar panel smart cleaning device consisting of micro-nano bubbles for rainwater recycling and cleaning and porous pressure differential spraying, characterized in that it is composed of.
The method of claim 5, wherein the on-off automatic valve (351) for the foreign material drain
Formed in an upright vertical structure, the main valve for foreign matter drain, the actuator part for foreign matter drain, the solenoid valve for foreign matter drain, the regulator part for foreign matter drain, and the foreign matter drain valve body 351a supporting the limit switch box part for foreign matter drain ,
A foreign material drain main valve 351b located at the lower end of the valve body for foreign matter drain and located on the waterway to turn on or off the flow of the waterway according to the driving of the actuator for foreign material drain;
An actuator unit 351c for foreign matter drain, which is located on one side of the upper end of the main valve for foreign matter drain, and directly drives the main valve for foreign matter drain to turn on/off the flow of the waterway on the waterway;
A solenoid valve (351d) for foreign material drain, which is located on one side of the upper end of the actuator for foreign material drain, is driven according to the signal of the limit switch box for foreign material drain, and supplies or blocks air transmitted to the actuator for foreign material drain,
A foreign material drain regulator unit 351e for filtering the working air and adjusting the pressure;
It is connected to several contacts of the solenoid valve for foreign matter drain, and it is composed of a limit switch box part (351f) for foreign matter drain that drives and controls the solenoid valve for foreign matter drain according to the control signal of the smart control unit. A three-effect type roof-mounted solar panel smart cleaning device consisting of micro-nano bubble and porous pressure differential spraying.
The method of claim 1, wherein the smart rainwater storage tank unit 400
A rainwater storage tank main body 410 formed in a square box shape to protect and support the filtering rainwater inlet, the overflow portion, the time constant water inlet, the rainwater level sensor, the microfilter conveying inlet, and the bottom propeller for rotating the sediment;
A filtered rainwater inlet 410 connected to the cyclone-type rainwater filter and introduced into the inner space of the rainwater storage tank body;
An overflow unit 430 forcibly discharged to the outside when the amount of rainwater stored in the rainwater storage tank body exceeds the reference value;
When the amount of rainwater stored in the inner space of the rainwater storage tank main body is lower than a reference value, a time constant water inlet 440 for receiving the time constant and introducing it into the inner space of the rainwater storage tank main body;
A rainwater level sensor unit 450 for sensing the level of rainwater stored in the rainwater storage tank body;
A microfilter conveying inlet 460 for conveying the microfiltered filtered rainwater through the twin-type microfilter unit and storing it in the inner space of the rainwater storage tank body;
A bottom propeller part 470 for rotating sediment formed at the center of the bottom surface of the main body of the rainwater storage tank and rotating the sediment deposited on the bottom surface as the propeller rotates;
Located on one side of the bottom surface of the main body of the rainwater storage tank, micro-nano bubbles for recycling and washing rainwater, characterized in that it consists of a sediment drain unit 480 for discharging sediment settled on the floor to the outside through a bottom propeller for sediment rotation. ·Three-effect roof-mounted solar panel smart cleaning device consisting of porous pressure differential spraying.
The method of claim 1, wherein the firefighting suction pump (600)
A firefighting pressure sensor unit 610 formed on the output waterway on the output side of the firefighting suction pump and sensing the force of pressure generated by the firefighting suction pump;
It is driven by the control signal of the smart control unit and through the power of the fire pump, the rainwater stored in the smart rainwater storage tank unit is discharged toward the porous pressure difference type washing spray nozzle unit for fire suppression. an automatic valve 620;
It is driven according to the control signal of the smart control unit and consists of an on-off automatic valve 630 for microfilter that plays the role of an automatic valve to discharge rainwater supplied to the twin-type microfilter unit through the power of the fire pump. A three-effect type roof-mounted solar panel smart cleaning device consisting of rainwater recycling, cleaning micro-nano bubbles, and porous pressure differential spraying.
The method of claim 1, wherein the twin-type microfilter unit 700
A cylindrical shape having an upright vertical structure is formed, a plurality of microfilters are formed in the inner space, and a part of the rainwater supplied through one waterway is introduced into the inner space for microfiltering, and then microfiltered filtered rainwater is generated. A first microfilter unit 710 to make,
A cylindrical shape having an upright vertical structure is formed on one side of the first microfilter unit, a plurality of microfilters are formed in the inner space, and a portion of rainwater supplied through one waterway is introduced into the inner space for microfiltering Then, a second microfilter unit 720 for generating microfiltered filtered rainwater;
A filtering rainwater inflow sensor unit (730) formed on the output channel of the output side of the first microfilter unit and the second microfilter unit to magnetically sense the inflow amount of filtered rainwater generated in the first microfilter unit and the second microfilter unit. )and,
An on-off automatic valve for conveyance that is driven according to the control signal of the smart control unit and serves as an automatic valve to transfer the filtered rainwater microfiltered through the first microfilter unit and the second microfilter unit back to the smart rainwater storage tank unit. (740) and
Turn-on for micro-nano bubbles that act as an automatic valve to deliver filtered rainwater that is driven according to the control signal of the smart control unit and is micro-filtered through the first micro-filter unit and the second micro-filter unit toward the micro-nano bubble generator for washing. A three-effect type roof-mounted solar panel smart cleaning device consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing, characterized in that it consists of an off automatic valve (750).
10. The method of claim 9, wherein the first microfilter unit 710
A first cylindrical body formed in an upright cylindrical shape to protect and support the first rainwater inlet, the first microfilter head holder, the first multi-channel microfilter, the first suction pressure generator, and the first filtering rainwater supply unit (711),
A first rainwater inlet 712 located at the lower end of the inner space of the first cylindrical body and introducing rainwater transmitted through the power of the twin suction pump toward the lower end of the inner space of the first cylindrical body;
A first microfilter head holder 713 located on the upper end of the head of the inner space of the first cylindrical body and detachably mounting and holding the first multi-channel microfilter;
An agent that is detachably mounted on the first microfilter head holder, receives suction pressure from the first suction pressure generating unit, microfilters rainwater introduced through the first rainwater inlet, and generates microfiltered filtered rainwater. 1 multi-channel microfilter 714;
A first suction pressure generating unit 715 that generates suction pressure toward the first microfilter head holder and supplies it to the first multi-channel microfilter;
Micro/nano bubble/porous pressure differential spraying for rainwater recycling/washing, characterized in that it consists of a first filtering rainwater supply unit 716 for supplying the filtered rainwater generated through the first multi-channel microfilter to the micro/nano bubble generator for cleaning. A three-effect type roof-mounted solar panel smart cleaning device consisting of
The method of claim 1, wherein the washing micro-nano bubble generator 800
It is formed in a zigzag shape with a length of 1m to 5m, receives microfiltered filtered rainwater from the twin-type microfilter on one side of the input port, and receives oxygen from the oxygen tank on the other side of the input port. A melting pipe part 810 for dissolving oxygen;
An oxygen tank unit 820 for generating and supplying oxygen toward the melting pipe unit;
A compressor 830 that accelerates by applying a pressure of 5 bar to 10 bar toward the oxygen-dissolved filtered rainwater entering the screw rotational collision type micro-nano bubble generator;
In addition to the longitudinal capsule, a screw rotation collision structure is formed in the internal space, and a screw rotation collision type micro/nano bubble generator (840 )and,
It is characterized in that it consists of a micro-nano bubble storage tank for cleaning (850) for storing the micro-nano bubble for cleaning generated by the screw rotation collision type micro-nano bubble generator. A three-effect roof-mounted solar panel smart cleaning device consisting of spraying.
According to claim 1, wherein the porous pressure difference type washing spray nozzle (900a)
Based on the top of the head of the roof-mounted solar panel, it is positioned at a height of 30 cm to 50 cm, and the spray nozzle holder (900a- 1) and,
A line structure is formed along the longitudinal direction of the X-axis on the spray nozzle holder, and micro/nano bubbles for cleaning are delivered according to the multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar for each time setting cycle of the multi-stage pressure differential discharge pump, and the porous pressure differential type A cleaning micro/nano bubble supply pipe 900a-2 supplied toward the cleaning spray nozzle;
It consists of a plurality of micro-nano bubble supply pipes for cleaning, and consists of 1 to 10 porous water streams and a washing spray length of 50cm, 100cm, 200cm, and 300cm according to the multi-stage pressure difference of 5bar, 10bar, 20bar, and 30bar. A porous pressure difference-type washing spray nozzle (900a-3) for washing the roof-mounted solar panel by a pressure difference method,
It is located on one side of the spray nozzle holder and consists of a flame detection sensor (900a-4) that senses a flame generated in the event of a fire in a roof-mounted solar panel. A three-effect roof-mounted solar panel smart cleaning device consisting of spraying.
The method of claim 1, wherein the smart control unit (900b)
A temperature sensor 2a is connected to one side of the input terminal, and a sensing signal for sensing the temperature of the solar panel is input to one side of the surface or rear surface of the roof-mounted solar panel, and a rainwater level sensor unit ( 450) is connected, a sensing signal for sensing the level of rainwater stored in the rainwater storage tank body is input, and a pressure sensor unit 530 for a twin-type suction pump is connected to one side of another input terminal, so that the twin-type suction pump It is formed on the output water line on the output side, and a sensing signal for sensing the force of pressure generated by the twin-type suction pump is input, and a pressure sensor unit 610 for fire fighting is connected to one side of another input terminal, so that the output side of the suction pump for fire fighting is connected. Formed on the waterway, a sensing signal for sensing the force of pressure generated by the firefighting suction pump is input, and a filtering rainwater inflow sensor unit 730 is connected to one side of another input terminal, so that the first microfilter unit and the second microfilter unit A sensing signal for magnetically sensing the inflow of filtered rainwater generated in the microfilter unit is input, and a flame detection sensor (900a-4) is connected to one side of another input terminal, located on one side of the spray nozzle holder, and installed on the roof. A sensing signal that senses the flame generated in the event of a fire in the solar panel is input, and an on-off automatic valve (210) for rainwater inflow is connected to one side of the output terminal, so that rainwater flows into the cyclone-type rainwater filtration unit. An output signal is output to discharge the foreign matter to the outside, and an on-off automatic valve (Auto Valve) 351 for foreign material drain is connected to one side of another output terminal, and an output signal is output to discharge foreign matter to the outside, and another output terminal An on-off automatic valve 441 for time constant is connected to, outputting an output signal so that the supplied time constant is supplied to the inner space of the rainwater storage tank body, and a bottom propeller for sediment rotation on one side of another output terminal A negative propeller rotation motor 472 is formed to generate rotational force and output an output signal to rotate the bottom propeller, and an on-off automatic valve 481 for sediment drain is connected to one side of another output terminal. and an output signal to discharge the sediment to the outside output, and a twin-type suction pump 500 is connected to one side of another output terminal to create a twin (double) pressure force to suck rainwater stored in the smart rainwater storage tank unit, toward the twin-type microfilter unit An output signal is output to supply, and a suction pump 600 for firefighting is connected to one side of another output terminal to generate a force of pressure to suck in rainwater stored in the smart rainwater storage tank to clean the porous pressure difference type An output signal is output so as to be supplied to the spray nozzle part, and an on-off automatic valve 620 for firefighting is connected to one side of another output terminal, and through the power of the fire pump, the rainwater stored in the smart rainwater storage tank part is extinguished. In order to do so, an output signal is output to be discharged to the porous pressure difference type washing spray nozzle part, and an on-off automatic valve 630 for microfilter is connected to one side of another output terminal, and through the power of the fire pump, supplied rainwater is turned into a twin An output signal is output to be discharged to the type microfilter unit, and the first suction pressure generating unit 715 of the first microfilter unit is connected to one side of another output terminal to generate suction pressure, thereby generating a first multi-channel microfilter. The second suction pressure generator 725 of the second microfilter unit is connected to one side of the other output terminal to generate suction pressure and supply it to the second multi-channel microfilter. An output signal is output, and an on-off automatic valve 740 for transport is connected to one side of another output terminal, and the filtered rainwater microfiltered through the first microfilter unit and the second microfilter unit is returned to the smart rainwater storage tank unit. An output signal is output to transfer, and an on-off automatic valve 750 for micro-nano bubbles is connected to one side of another output terminal, and is used for washing the filtered rainwater microfiltered through the first microfilter unit and the second microfilter unit. An output signal is output to be transmitted to the micro-nano bubble generator, and an oxygen tank unit 820 is connected to one side of another output terminal, and an output signal is output to generate and supply oxygen to the zigzag melting pipe unit. Compressor (83) on one side of the other output terminal 0) is connected to produce an output signal that accelerates by applying a pressure of 5 bar to 10 bar toward the oxygen-dissolved filtered rainwater entering the screw rotation collision type micro-nano bubble generator, and outputs a multi-stage pressure differential discharge pump on one side of another output terminal. (900) is connected to suck in the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generation unit, and then spray the porous pressure differential type washing while giving a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar according to the time setting cycle. A three-effect type roof-mounted solar panel smart cleaning device consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and washing, characterized in that it is configured to output an output signal so as to be supplied toward the nozzle part.
The method of claim 1, wherein the smart control unit (900b)
Rainwater recycling that recycles and controls rainwater to be reused in a repeating routine of filtering and storing rainwater, micro-filtering it, generating micro-nano bubbles for washing, washing it through a roof-mounted solar panel, and filtering and storing it again a control mode (900b-1),
By driving the micro-nano bubble generator for cleaning, micro-filtered filtered rainwater is supplied from the twin-type micro-filter and dissolved along the zigzag structure so that it dissolves with oxygen. A micro-nano bubble generation control mode for washing (900b-2) for controlling to generate bubbles;
By driving the multi-stage pressure difference discharge pump, while giving a multi-stage pressure difference of 5 bar, 10 bar, 20 bar, 30 bar according to the time setting cycle, it is supplied to the porous pressure difference type washing spray nozzle part, and 1 to 10 of the porous pressure difference type washing spray nozzle A porous pressure difference that controls the washing of a roof-mounted photovoltaic panel by a porous pressure difference method consisting of a porous water stream and a washing jet length of 50cm, 100cm, 200cm, and 300cm according to a multi-stage pressure difference of 5bar, 10bar, 20bar, and 30bar. An injection control mode (900b-3),
When a fire is detected through the temperature sensor and the flame sensor, the fire-fighting suction pump is driven, and through the power of the fire-fighting pump, the rainwater stored in the smart rainwater storage tank is controlled to be discharged toward the porous pressure differential washing spray nozzle for fire suppression. A three-effect roof-mounted solar panel smart washing device consisting of rainwater recycling, washing micro-nano bubbles, and porous pressure differential spraying, characterized in that it consists of a fire-fighting water automatic supply control mode (900b-4).
Receiving rainwater flowing from the rainwater inlet through the roof-mounted photovoltaic panel and transferring it to the water pipe for rainwater inflow (S10);
A step (S20) of receiving rainwater from the rainwater inlet in the water pipe for inflow of rainwater and introducing it toward the cyclone-type rainwater filtering unit;
In the cyclone-type rainwater filtration unit, the foreign matter contained in the rainwater introduced through the rainwater inlet pipe is filtered by the centrifugal force generated by the swirling flow and the twin (double) upper and lower narrow fine wire mesh. , Supplying only the filtered rainwater to the smart rainwater storage tank unit (S30),
Storing the rainwater that has passed through the cyclone-type rainwater filter in the smart rainwater storage tank unit, sensing the amount of stored rainwater and transmitting it to the smart control unit (S40);
The step of driving the twin-type suction pump according to the control signal of the smart control unit to generate twin (double) pressure, sucking rainwater stored in the smart rainwater storage tank unit, and supplying it to the twin-type microfilter unit (S50 )and,
The fire-fighting suction pump is driven according to the control signal of the smart control unit to generate a force of pressure to suck in the rainwater stored in the smart rainwater storage tank unit and supply it to the porous pressure difference washing spray nozzle unit (S60); ,
In the twin-type microfilter unit, the rainwater supplied through the twin-type suction pump is supplied to one waterway, and through the twin (double) simultaneous microfilter, microfiltered filtered rainwater is generated and transmitted to the micro-nano bubble generator for washing. The step of doing (S70),
In the cleaning micro/nano bubble generating unit, the micro-filtered rainwater is supplied from the twin-type micro filter unit and dissolved along the zigzag structure so that it dissolves with oxygen. Generating step (S80),
After inhaling the cleaning micro/nano bubbles generated from the cleaning micro/nano bubble generation unit in the multi-stage pressure differential discharge pump, the multi-stage pressure differential of 5 bar, 10 bar, 20 bar, and 30 bar is applied to the porous pressure differential type washing spray nozzle according to the time setting cycle. Supplying to the side (S90),
In the porous pressure difference type washing spray nozzle part, micro-nano bubbles are supplied for cleaning according to the multi-stage pressure difference of 5 bar, 10 bar, 20 bar, and 30 bar for each time setting cycle of the multi-stage pressure difference discharge pump, which cleans the roof-mounted solar panel. A three-effect type roof-mounted solar panel smart cleaning method consisting of micro-nano bubbles and porous pressure differential spraying for rainwater recycling and cleaning, characterized in that it consists of step (S100).

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