KR102024237B1 - Solar system and operation method thereof - Google Patents

Abstract

The present invention relates to a photovoltaic system which has increased efficiency of photovoltaic power generation, and an operating method thereof. The photovoltaic system of the present invention comprises: a photovoltaic power generation module for producing DC power from sunlight; an inverter for converting the DC power into AC power; a control module provided in a housing; a sensor unit provided in the housing; a communication module for receiving a new pollution condition; and at least one dust removing air sprayer.

Description

SOLAR SYSTEM AND OPERATION METHOD {SOLAR SYSTEM AND OPERATION METHOD THEREOF}

The present invention relates to a solar system and a method of operating the same, and more particularly, to a solar system and an operation method that can prevent a decrease in efficiency caused by dust generation.

Photovoltaic power generation generates electricity by converting solar energy into direct current electricity. Since solar energy is used, there is no fuel cost and no air pollution or waste generation. Therefore, due to the problem of depletion of fossil fuel and environmental pollution, it has long been noticed as a renewable energy that can replace the current power supply.

The photovoltaic module is a collection of solar cells for condensing sunlight. In the case of the most widely used silicon solar cells, the efficiency varies depending on the temperature of the photovoltaic module. Because of these characteristics, the output of solar power is at its peak in spring and autumn, not in the summer when the sun is the longest.

On the other hand, the photovoltaic module is operated in a state of being exposed to the outside because it needs to condense the sunlight, and therefore, the problem of light transmittance deteriorated due to rainwater, algae discharge, pollen, yellow dust, fine dust, etc. have. In particular, it is known that yellow dust and fine dust generated in recent seasons affect not only the efficiency of the solar power module but also the failure or the life of precision machinery and electronic products.

To solve the problem of impeding the efficiency of photovoltaic power generation, solar modules are regularly cleaned by manpower, but this operation requires a great amount of time and labor.

The prior art related to the problem is Korea Patent Registration No. 10-1044713 (efficiency improving equipment for implementing the cleaning of the photovoltaic power generation equipment), the patent proposes a means for injecting cooling water to the solar module. However, the washing of the solar modules using cooling water does not need to be performed so frequently, and since it is necessary to continuously supply a certain level of water, it is not easy to apply this technique in an area where water supply is not smooth.

Therefore, there is a need for a method for maximizing power generation efficiency by protecting a solar power module and various control parts controlling the same from a harmful environment.

The present invention is to solve the above problems, an object of the present invention to provide a solar system and an operation method that can protect the inverter and the control module included in the solar system from dust.

In addition, another object of the present invention is to increase the photovoltaic power generation efficiency by efficiently removing dust that can lower the light transmittance of the photovoltaic module when necessary.

In another aspect, the present invention is to block or remove dust only when a lot of yellow sand or dust is generated, thereby minimizing unnecessary work while efficiently protecting the solar system from dust.

According to an aspect of the present invention, there is provided a photovoltaic system comprising: a photovoltaic module for producing direct current power from sunlight; an inverter provided in a housing; and an inverter configured to convert the direct current power into alternating current power; A control module that controls the operation of the photovoltaic module and the inverter and supplies the AC power to the load, a communication module that receives air quality information from a server through a wired / wireless communication network, and transmits the power information generated by the control module to the terminal. The control module may include an air quality determination unit for identifying an air level using the air quality information. If the air level is identified as satisfying a pollution condition preset in a first period, the control module may include the air quality determination unit. The exhaust circulator installed on one side of the housing is operated to exhaust heat and A pollution mode control unit for stopping the intake circulator installed on the side surface, and when the atmospheric value is identified as satisfying the non-contamination condition preset in the second period, operating the exhaust circulator and the intake circulator in the second period. It characterized in that it comprises a non-contamination mode control unit.

The present invention also provides a photovoltaic module for generating direct current power from sunlight, an inverter for converting the direct current power into alternating current power, a control for controlling the operation of the photovoltaic module and the inverter and supplying the alternating current power to a load. A method of operating a solar system including a module, a housing in which the inverter and the control module are embedded, the method comprising: receiving air quality information from a server, identifying an air value by using the air quality information, and the air If the numerical value is identified as satisfying the pollution condition preset in the first period, the exhaust circulator installed on one side of the housing is operated in the first period to discharge heat, and the intake circulator installed on one side of the housing is discharged. Pollution mode operation step of stopping, the atmospheric value satisfies the non-pollution condition preset in the second period If it is discriminated that is, it comprises a non-polluting operation mode operating the exhaust circulator and the intake air circulator in the second period to an aspect.

According to the present invention as described above, the inverter and the control module included in the solar system can be protected from dust.

Moreover, according to this invention, dust which can lower the light transmittance of a photovoltaic module can be removed efficiently when needed, and there exists an effect that a photovoltaic power generation efficiency becomes high.

In addition, the present invention can block or remove dust only when a lot of yellow sand or dust is generated, it is possible to efficiently protect the solar system from dust while minimizing unnecessary work.

1 is a view for explaining a solar system according to an embodiment of the present invention,
2 is a view showing a rotation state of the intake circulator according to an embodiment of the present invention;
3 is a view illustrating a stopped state of an intake circulator according to an embodiment of the present invention;
4 is a block diagram illustrating a control module according to an embodiment of the present invention;
5 is a flowchart illustrating a method of operating a solar system according to an embodiment of the present invention.

The above objects, features, and advantages will be described in detail with reference to the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals in the drawings are used to indicate the same or similar components, all combinations described in the specification and claims may be combined in any way. And unless specified otherwise, reference to the singular may include one or more, and reference to the singular may also include the plural expression.

1 is a view for explaining a solar system according to an embodiment of the present invention. 1, a solar system according to an embodiment of the present invention includes a solar power generation module 100, an inverter 210, a control module 230, a sensor unit 260, and a communication module 290. The remaining components except for the solar power generation module 100 may be provided in the housing 200. The housing 200 may include an exhaust circulator 250 and an intake circulator 270 in a component provided in the housing. It can be installed for the purpose of cooling the generated heat.

In a broad sense, a solar system according to an embodiment of the present invention may include a terminal 500. The terminal 500 may include a manager terminal, that is, an administrator, for monitoring a photovoltaic system 100, 200. Means a computing device to be used. The terminal 500 may be installed with an application program for monitoring and controlling the photovoltaic systems 100 and 200 in consultation, and the administrator uses the application program to control the photovoltaic module 100 and the inverter 210. The module 230 may be controlled.

The photovoltaic module 100 generates direct current power from sunlight. The solar power module 100 may be understood as a solar panel composed of one or more solar cells. In addition, the photovoltaic module 100 described herein includes a solar cell array (PV Array) to which a plurality of PV modules are connected.

The photovoltaic module 100 according to an embodiment of the present invention may include one or more dust remover air emitters 130 installed at equal intervals on both sides of the photovoltaic module 100. As shown in FIG. 1, the air radiator 130 may be installed at equal intervals d on both sides of the photovoltaic module 100 and may include one or more air injection holes 131. One or more air injection holes 131 are formed to face in different directions, and the injected air may have a pressure level capable of removing dust accumulated in a semicircular area having a radius d as shown in FIG. 1. .

According to an embodiment of the present invention, the housing 200 including the configuration of the inverter 210, the control module 230, etc. may be connected to each of the photovoltaic modules 100 and used, a plurality of photovoltaic power generation It may be used as a solar panel to collect the power output from the module 100.

The inverter 210 is provided in the housing 200 to convert DC power into AC power. The AC power converted by the inverter 210 is boosted by a separate AC switchboard and transmitted to the grid system or supplied to a load.

The operation of the photovoltaic module 100 and the inverter 210 may be controlled by the control module 230. The control module 230 transmits the DC power output from the photovoltaic module 100 to the inverter 210 and transmits the AC power converted by the inverter 210 to a grid system or a load. In addition, the control module 230 controls the components in the housing 200-the sensor unit 260, the communication module 290, etc., the exhaust circulator 250 and the intake circulator 270 installed in the housing 200 By controlling the operation of the) keeps the temperature of the housing 200 to an appropriate temperature and protects each component from dust.

The control module 230 may include an air quality determination unit 231, a pollution mode controller 233, a non-pollution mode controller 235, and a state information generator 237 (see FIG. 4).

The air quality determination unit 231 may identify the air value for each period by using the air quality information received by the communication module 290 from the server. The air quality information may include at least one of fine dust, ultrafine dust, ozone, or yellow dust values, and may include an identifier indicating a type of each atmospheric value and a value corresponding to the numerical value. The air quality determination unit 231 may identify the degree of fine dust, ultra fine dust, ozone, or yellow dust by period using the identifier.

Furthermore, the air quality determination unit 231 determines whether each air level satisfies a preset pollution condition. The pollution condition is set in advance to protect the solar system. For example, the air quality determination unit 231 determines that the pollution condition is satisfied when the fine dust value is greater than or equal to a preset threshold, and the fine dust value is determined. If it is less than the preset threshold, it may be determined that the contamination condition is not satisfied.

In another embodiment, the contamination condition may be set by combining two or more atmospheric values, for example, when the fine dust value is greater than or equal to the threshold A and the yellow dust value is greater than or equal to the threshold B. In this case, the air quality determination unit 231 may determine whether the fine dust value received from the server is A or more, and the yellow dust value is B or more. If both criteria are satisfied, the air quality determination unit 231 may determine that the pollution condition is satisfied.

The air quality identification and determination of the air quality determination unit 231 may be performed for each period. Here, the term "period" means a predetermined unit time, and the air value may be determined by the unit of time, the unit of time, or the unit of day to control the solar system for each unit time. For example, suppose that the server 300 provides, as air quality information, the fine dust and ultra-fine dust values predicted in units of 30 minutes for 24 hours from the present. If the solar system according to an embodiment of the present invention sets the unit time to three hours, the air quality determination unit 231 calculates an average value of the fine dust value and the ultra fine dust value for three hours, respectively. For example, by determining whether the average value of the fine dust value for 3 hours is A or more and the average value of the ultrafine dust value is B or more, it can be determined as shown in Table 1 whether the contamination condition is satisfied for each period. Table 1 is an example of the case that A is 150μg / m ^2, B is 100μg / m ^2.

term 3 hour average value of fine dust
(Threshold 150 μg / m ²⁾ Ultrafine dust 3 hours average value
(Threshold 100 μg / m ²⁾ Pollution conditions
Satisfaction 1 (09: 00 ~ 12: 00) 153 103 ㅇ 2 (12: 00 ~ 15: 00) 156 83 x 3 (15: 00-18: 00) 143 90 x 4 (18: 00 ~ 21: 00) 131 105 x

If it is determined that the air value satisfies the pollution condition set in the first period, the pollution mode controller 233 operates the exhaust circulator 250 installed at one side of the housing in the first period to discharge heat and It is possible to stop the intake circulator 270 provided on one side. This state is referred to herein as a contamination mode. As described above, if the air value satisfies the contamination condition, it means that the air condition is poor. The pollution mode control unit 233 stops the intake circulator 270 in the contamination mode, thereby entering the housing 200. To prevent outside air from entering.

In particular, the intake circulator 270 according to an embodiment of the present invention is formed so as to completely block the inside and outside of the housing 200 when stopped as shown in Figs. In a very bad state that satisfies the condition, only the exhaust circulator 250 operates, so that outside air cannot enter the housing 200.

2 is a view illustrating a rotation state of the intake circulator according to an embodiment of the present invention, and FIG. 3 is a view illustrating a stopped state of the intake circulator according to an embodiment of the present invention. 2 to 3, the intake circulator 270 is coupled to the rotating member 271 and the rotating member connected to the motor, and the angle is adjusted according to the rotational speed to stop the intake circulator. In one state, all one side may include a pitch control blade 273 controlled to face the front surface of the intake circulator.

The pitch control blade 273 is a blade having a variable angle with the front surface of the rotating member. When rotating, the angle formed with the front surface of the rotating member has a value within 20 ° to 90 °. The resulting angle is controlled to have a value within 0 ° to 10 °. At rest, each blade may be arranged in such a way that a left or right portion of the blade overlaps an adjacent blade. The pitch control blade 273 of the present invention is not limited to a specific method of controlling the pitch, and the angle at the time of rotation and the angle at the stop are set differently, and at the time of stopping, the pitch control blade 273 is arranged to form the same direction as the front surface of the rotating member. In addition, the intake circulator 270 is characterized in that it acts as a barrier to block the outside and the inside of the housing 200.

That is, the intake circulator according to an embodiment of the present invention is not only limited in operation by the air quality information received from the server 300, but also completely blocking external air that may enter the housing 200. In addition, the dusty atmosphere may serve as a barrier to prevent air from entering the housing 200.

In the contamination mode, the intake circulator 270 not only stops its operation but also blocks the housing 200 from the outside air, making it difficult to cool the outside air. Therefore, the solar system according to an embodiment of the present invention can lower the internal temperature by operating a cooler (not shown) provided in the housing. The air cooled by the cooler may maintain a constant temperature of the components provided in the housing 200, and the air having a high temperature may be discharged to the outside through the exhaust circulator 250.

Meanwhile, in the pollution mode, the pollution mode controller 233 may control the one or more dust removing air radiators 130 installed at equal intervals on both sides of the photovoltaic module 100 to inject air. The air radiator 130 may remove dust accumulated on the surface of the photovoltaic module 100 in a preset area around the air radiator 130 and inject air at a pressure that can cover the area. Can be. Therefore, air is periodically sprayed on the surface of the photovoltaic module 100 in a dusty pollution mode period in the air, and dust does not accumulate on the photovoltaic module 100.

As another embodiment, when it is determined that the first period is the pollution mode, the pollution mode controller 233 may control the air emitter 130 to inject air for a preset time of the next period of the first period. For example, when the 9:00 to 12 o'clock (first period) is the contamination mode, the contamination mode control unit 233 may control to inject air for 15 minutes from 12 to 12:15. By removing the dust in this way, the dust can be removed efficiently in a short time. Since there is a lot of dust in the atmosphere during the pollution period, it may be difficult to improve the light transmittance simply by removing the dust present on the surface, which maximizes the efficiency of the dust-free period by removing the dust after it has accumulated. You can take a strategy.

On the other hand, the non-pollution mode control unit 235 may operate the exhaust circulator 250 and the intake circulator 270 in the second period when it is determined that the air value does not satisfy the pollution condition in the second period. . Note that the first period and the second period herein are expressions for specifying the period, and may be different or the same. The solar system operates in non-pollution mode when the air level does not meet the pollution condition. In the non-pollution mode, the general method-exhaust circulator 250 and the intake circulator 270 are used to It is possible to maintain the temperature inside the housing 200 in such a way as to circulate.

The exhaust circulator 250 is installed at one side of the housing 200 to exhaust the air inside the housing 200 to the outside to discharge heat therein, and the intake circulator 270 sucks the outside air to the inside. The inside of the housing 200 is cooled. The intake and exhaust circulators 250 and 270 may be made by control signals of the control module 230.

The sensor unit 260 may include one or more sensors, and may include a temperature sensor, a humidity sensor, a smoke detection sensor, a dust sensor, a gas detection sensor, and the like. The sensor unit 260 may transmit sensing information collected from each sensor to the control module 230.

For example, the sensor unit 260 may include a temperature sensor. When the temperature inside the housing 200 measured by the temperature sensor is transmitted to the control module 230, the state information generator 237 may measure the measured temperature and exhaust. The state information of the housing 200 may be generated using the operation data of the circulator and the operation data of the intake circulator, and the generated state information may be transmitted to the terminal 500 and used for monitoring a solar system. .

Upon receiving the status information, the manager can check the state of the housing 200 of the solar system in real time, whether excessive heat is generated therein, whether the exhaust circulator 250 and the intake circulator 270 operate well, That is, you can check whether cooling and dust removal are performed properly.

In addition, when the dust sensor is included in the sensor unit 260, the state information may include the amount of dust measured by the dust sensor, the terminal 500 is performed by the air quality information using the received state information By comparing the amount of dust in the housing 200 with the actual amount of dust in the housing 200, the correlation between the air quality information and the control operation transmitted from the server and the amount of dust in the housing 200 may be determined.

In addition, the terminal 500 performs unsupervised learning as an input value of the air value for each period included in the air quality information, the operation of the exhaust circulator for each period, the operation of the intake circulator for each period, and the actual amount of dust inside the housing 200. By performing the operation, the operating conditions of the exhaust circulator 250 for each atmospheric value and the operating condition of the intake circulator 270 for each atmospheric value can be calculated to minimize the actual amount of dust. In addition, the terminal 500 may calculate a new pollution condition using the terminal 500.

That is, if the preset pollution condition is a linear condition for determining whether the air value is above or below the threshold value, the new pollution condition may be a nonlinear condition generated by learning. The nonlinear new pollution condition is transmitted to the control module 230 through the communication module 290, the control module 230 may update the pollution condition using the new pollution condition.

5 is a flowchart illustrating a method of operating a solar system according to an embodiment of the present invention.

Referring to FIG. 5, a photovoltaic module for generating direct current power from sunlight, an inverter for converting the direct current power into alternating current power, controlling the operation of the photovoltaic module and the inverter and supplying the alternating current power to a load In a method of operating a control module of a solar system including a control module, a housing in which the inverter and the control module is built, the control module receives the air quality information from the server (S100), the air quality information The air value for each period is identified by using (S200). Next, the control module determines whether the air level satisfies a preset pollution condition (S300). If it is determined that the air level satisfies a pollution condition preset in a first period, the control unit determines the housing in the first period. When the exhaust circulator installed on one side of the operation to discharge heat and stop the intake circulator installed on one side of the housing (S350), if it is determined that the atmospheric value does not satisfy the pollution condition in the second period In operation S370, the exhaust circulator and the intake circulator may be operated in the second period.

The solar system according to an embodiment of the present invention efficiently performs dust cleaning and reduction in the photovoltaic module 100 and the housing 200, and may minimize efficiency degradation that may occur due to dust.

Some embodiments omitted in the present specification may be equally applicable to the same subject matter. In addition, the above-described present invention can be variously substituted, modified, and changed within the scope without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains to the above-described embodiments and attached It is not limited by the drawings.

100: solar power module
200: housing
300: server
500: terminal

Claims (4)

In the solar system,
A photovoltaic module for generating direct current power from sunlight;
An inverter provided in the housing to convert the DC power into AC power;
A control module provided in the housing to control operations of the photovoltaic module and the inverter, supply the AC power to a load, and generate state information inside the housing;
A sensor unit provided in the housing to measure at least one of a temperature and an amount of dust in the housing;
Receives air quality information from a server through a wired / wireless communication network, transmits power information and the state information generated by the control module to a terminal at predetermined intervals, and receives a new pollution condition calculated using the state information from the terminal. A communication module;
At least one dust removing air emitter installed at equal intervals on both sides of the photovoltaic module,
The control module
An air quality determination unit identifying an air level by period using the air quality information, and determining whether an average value of the air level during the period satisfies a preset pollution condition;
If it is determined that the average value of the atmospheric values satisfies the pollution condition preset in the first period, the exhaust circulator installed on one side of the housing is operated in the first period to discharge heat and to one side of the housing. A pollution mode control unit for stopping the installed intake circulator and controlling the air emitter to inject air for a preset time of a next period of the first period;
A non-pollution mode controller configured to operate the exhaust circulator and the intake circulator in the second period when it is determined that the average value of the atmospheric values does not satisfy the pollution condition in the second period;
And a state information generator for generating the state information including the operation data for each period of the exhaust circulator, the operation data for each period of the intake circulator, the atmospheric value for each period, the average temperature for each period, and the amount of dust.
The new pollution condition is calculated using the operating condition of the exhaust circulator for each atmospheric value and the operating condition of the intake circulator for each atmospheric value calculated by performing unsupervised learning with the state information as an input value,
The pollution condition is updated using the new pollution condition.
The method of claim 1
The pollution mode control unit
And operating the cooler provided in the housing during the first period to lower the temperature in the housing.
The method of claim 1,
The air quality information includes at least one of fine dust, ultra fine dust, ozone or yellow dust.
The method of claim 1,
The intake circulator
A rotating member connected to the motor and rotating;
And a pitch control blade coupled to the pivot member, the angle of which is controlled according to a rotational speed so that all of one side is directed toward the front surface of the intake circulator when the intake circulator is stopped.

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