KR20190016390A - Solar energy management apparatus and management method for solar energy - Google Patents

Abstract

The present invention relates to solar energy management apparatus and method, which calculate an expected charging power amount to be charged tomorrow through weather forecast, calculate an expected use power amount to be used tomorrow by checking a power consumption pattern of a power demand side, and determine a use power load of the power demand side from the expected charging power amount and the expected use power amount, thereby managing solar energy in accordance with weather forecast and consumption pattern of a user to accordingly use power generated from a solar cell efficiently and to stably use power regardless of weather change, and maximizing economic efficiency by establishing plans on efficient charging, discharging and selling of the power.

Description

SOLAR ENERGY MANAGEMENT APPARATUS AND MANAGEMENT METHOD FOR SOLAR ENERGY FIELD OF THE INVENTION [0001]

The present invention relates to a solar energy management apparatus and a solar energy management method, and more particularly, to a solar energy management apparatus and a solar energy management method for managing solar energy according to a weather forecast and a user's consumption pattern .

Generally, electric power is generated by fossil fuel such as oil or gas, but problems such as global warming, air pollution, environmental destruction due to the use of fossil fuel are occurring.

In addition, although nuclear power plants using nuclear power are being used as alternative energy for fossil fuels, there is a risk that nuclear power plants will cause great casualties and environmental destruction in the event of natural disasters such as earthquakes and tsunamis.

The development and use of renewable energy including photovoltaic energy is actively being promoted as a substitute energy for the problems due to fossil fuel and nuclear power generation facilities.

Photovoltaic energy converts the sun's light energy directly into electric energy through a photovoltaic converter called a solar cell, and uses the electric power developed here. By using unlimited solar energy, it can reduce the use of fossil energy and protect the environment. Is increasing.

Generally, the photovoltaic power generation apparatus converts the power generated by the solar cell into an alternating current electricity through an inverter and uses a battery to store the surplus electric power.

That is, the conventional photovoltaic power generation apparatus charges the solar photovoltaic power to the battery when the amount of sunshine is good and discharges the power when necessary.

However, the conventional photovoltaic device has a problem that the capacity of the battery is limited and the power generated through the solar cell can not be efficiently used.

In addition, since the energy stored in the battery is supplied to a power supply organization, for example, a KEPCO or an AC load for self-use, and is provided with a real-time power monitoring function by a timer scheduler, There is a problem that it is not possible to plan charging, discharging, and electric power sales, is dependent on environment, and is limited to monitoring functions.

Patent Document 1: Korean Patent Registration No. 10-1275245 'Solar energy device for simultaneous use of solar and solar heat for apartment house' (registered on June 10, 2013)

It is an object of the present invention to provide a solar energy management apparatus and a solar energy management method that can manage the solar energy according to the weather forecast and the consumption pattern of the user so as to efficiently utilize the power generated by the solar cell.

In order to achieve the above object, a solar energy management apparatus according to the present invention includes a solar battery unit for generating electric power by sunlight, a battery unit for storing electric power generated from the solar battery unit, An expected power consumption calculation unit for calculating a predicted power consumption calculation unit for calculating a predicted power consumption amount for use in the future by confirming a power consumption pattern of a power use destination, And a power supply control unit for determining a used power load of the use place and controlling power supply to the determined power load.

In the present invention, the power supply control unit calculates the remaining amount of electricity F that is the sum of the remaining amount of power B of the battery and the expected amount of used electricity C, and subtracts the remaining amount of electricity F from the estimated use amount of electricity A The absolute value is confirmed as the final remaining power amount (D) of the battery. The remaining power amount (D) of the battery is used to divide the power amount state of the battery into a plurality of modes, and the power load amount of power supplied from the solar battery unit You can decide.

The solar energy management apparatus according to the present invention further includes a solar power switchboard for distributing power generated by the solar power unit to a power load of a power use destination, And may include a plurality of load usage control switches for distributing power generated by the solar battery unit to the power load of the power use place, as power load of the power use place for each mode of the power state of the battery.

In the present invention, the power state of the battery is a first mode when the final residual power amount D of the battery is 95% or more of the maximum charging power amount of the battery, a final residual power amount D of the battery is 70% And the final remaining power amount D of the battery is less than 70% of the maximum charging power amount of the battery in the third mode when the final remaining power amount D of the battery is less than 70% The power supply control unit uses the power generated from the solar battery unit for all the power loads of the power use destination in the first mode, and the power generation controller Only some of the power loads of all the used power loads use the electric power generated from the solar battery unit, and the remaining electric power loads use the electric power supplied from the power supply agency In the third mode, only a part of the power loads of all the power loads used by the power use mode is less than the second mode power, and the remaining power loads are the power supplied from the power supply source Wherein in the fourth mode, only the minimum power load of all the power loads used for power use is less than that of the third mode, and the remaining power load is the power supplied from the power supply source Can be used.

In the present invention, the power supply control unit checks the actual charge amount of the battery in a predetermined time unit, compares it with the estimated charge amount to check the deviation, and reflects the deviation? V to the residual power amount F tomorrow, The power supply can be controlled in real time by correcting the remaining power amount D.

According to another aspect of the present invention, there is provided a method for managing solar energy, comprising the steps of: calculating a predicted charge amount that can be charged tomorrow through weather forecast; An expected power usage amount calculating step of calculating an expected power usage amount to be used; and a used power load determining step of determining a used power load of the power use destination from the estimated charging power amount and the expected usage power amount.

In the present invention, the use power load determination step may include calculating a remaining power amount F tomorrow plus the remaining battery power B of the present battery and the estimated used power amount C, calculating a remaining power amount F ) Of the battery is confirmed as the final remaining power amount D of the battery and the final residual power amount D of the battery is determined to divide the power amount state of the battery into a plurality of modes and supplied from the solar battery unit And determining a power load usage of the power.

In the present invention, the process of determining the power load usage may be performed in a first mode when the final remaining power amount D of the battery is 95% or more of the maximum charging power amount of the battery, (D) of the battery is less than 70% and less than 95% of the maximum charging power amount of the battery when the final remaining power amount (D) of the battery is less than 70% The second mode is divided into a fourth mode in which the power consumption of the battery is 15% or more and less than 40% of the maximum charge power of the battery. In the first mode, The power load of some of the power loads of the power use uses only the power generated from the solar cell and the remaining power loads are the power In the third mode, only a part of the power loads of all the power loads used by the power use mode is less than the second mode power, and the remaining power loads are the power supplied from the power supply source In the fourth mode, only the minimum power load of all the power loads used by the power source is less than that of the third mode, and the remaining power load uses the power supplied from the power supply source Can be used.

In the present invention, the step of determining the used power load may further include a step of checking a charge amount of an actual battery in a predetermined time unit and a step of comparing a charge amount of an actual battery with an expected charge amount to check a deviation, The final remaining power amount D of the battery can be corrected in real time by calculating the remaining strategic amount F by reflecting the deviation AV.

The present invention can efficiently utilize the power generated by the solar cell by managing the solar energy according to the weather forecast and the consumption pattern of the user, so that the power can be used stably regardless of the change in the weather.

In addition, the present invention has an effect of maximizing economic efficiency by establishing plans for efficiently charging, discharging, and selling electric power.

1 is a block diagram schematically illustrating a solar energy management apparatus according to the present invention.
2 is a flowchart illustrating a method for managing solar energy according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

FIG. 1 is a block diagram schematically illustrating a solar energy management apparatus according to the present invention. Referring to FIG. 1, an embodiment of a solar energy management apparatus according to the present invention generates power using solar light, 100).

The solar cell module 100 is a solar cell module that can obtain a required voltage and current by connecting a plurality of solar cells in series and in parallel by a photoelectric transducer. The solar cell module 100 is installed facing the sun without any obstacles such as a roof or a roof It is installed in a position where maximum sunshine can be secured during one day.

The solar cell unit 100 generates electric power by using sunlight and supplies electric power to the electric power source so that electric power can be used by the electric power source.

A battery unit 200 for storing electric power generated from the solar battery unit 100 is provided in the corresponding electric power source where the solar battery unit 100 is installed.

The battery unit 200 stores the electric power generated from the solar cell unit 100 and is connected to a PCS (Power Conditioning System) 600 through a BMS (Battery Management System) And when the power to be charged from the solar battery unit 100 is insufficient, the power can be supplied from the power supply agency and charged.

The PCS 600 can supply energy supplied from a power plant of a power supplying organization to the power load or charge the battery through the power grid 800 and supply the power generated by the solar battery 100 to the power load, And supplies the electric power charged in the battery to the electric power load or the electric power supply network 800 of the electric power supply institution to perform power management.

The BMS (Battery Management System) 700 is a system for managing the battery. The BMS (Battery Management System) 700 detects the voltage, current, and temperature of the battery to control the charge / discharge amount of the battery to an appropriate level. And the remaining battery level. In addition, the BMS 700 can protect the battery through emergency operation when a danger is detected.

The PCS 600 is connected to the power supply control unit 500 to perform power management and the power supply control unit 500 compares the estimated charging power amount charged through the solar battery unit 100 and the expected use power amount of the corresponding power usage destination Determines the use power load of the power usage destination, and controls the power supply to the determined power load.

The estimated charging power calculation unit 300 calculates the estimated charging power amount, and the estimated charging amount calculation unit 300 receives the weather forecast of the area where the power usage place is located and receives the weather forecast Calculate the estimated charging power.

That is, the predicted charge amount calculation unit 300 estimates the amount of sunshine tomorrow through the weather forecast and calculates the estimated amount of charge electric power to be charged through the solar battery unit 100 through the predicted amount of sunshine.

The expected power usage amount is calculated by the expected power usage amount calculation unit 400, and the expected power usage amount calculation unit 400 checks the power consumption pattern of the power usage destination to calculate the expected used power amount for tomorrow.

The power consumption pattern of the power use destination can be confirmed by receiving the power use information of the power use destination stored in the main server of the power supply organization and can be used for initializing the data of the average power use value per region stored in the main server of the power supply agency, It is noted that the data can be updated by accumulating data on the power usage value of the user from the set reference time after setting the reference as the power consumption pattern value.

The power supply control unit 500 identifies the residual power amount of the current battery, divides the power amount state into the plurality of modes from the estimated charging power amount and the estimated usage power amount, and calculates the power load of the power supplied from the solar cell unit 100 Determine usage.

More specifically, the power supply control unit 500 calculates a remaining amount of electricity F that is the sum of the remaining amount of electricity B of the battery and the expected amount of used electricity C, Is subtracted from the final residual power amount D of the battery.

Then, the final remaining power amount D of the battery is checked to divide the power amount state of the battery into a plurality of modes, and the power load usage of the power supplied from the solar battery unit 100 is determined for each mode.

That is, tomorrow's remaining power amount F can be expressed by the following equation (1).

Further, the final remaining power amount D of the battery can be expressed by the following equation (2).

When the final remaining power amount D of the battery is 95% or more of the maximum charging power amount of the battery, the first mode is selected when the final remaining power amount D of the battery is 70% or more and less than 95% (D) of the battery is 40% or more and less than 70% of the maximum charging power amount of the battery, and the third mode is when the final remaining power amount (D) of the battery is less than 40% , It is divided into the fourth mode.

In the first mode, the power supply control unit 500 allows the power generated from the solar battery unit 100 to be used for all the power loads of the power use destination, and in the second mode, some of the power loads Only the load uses the electric power generated from the solar battery unit 100, the remaining electric power load uses the electric power supplied from the electric power supply agency, and in the third mode, Only the power load uses the electric power generated from the solar battery unit 100, the remaining electric power load uses the electric power supplied from the electric power supply agency, and in the fourth mode, Only the power load of the solar cell unit 100 is used, and the remaining power load uses the power supplied from the power supply agency The.

The solar energy management apparatus further includes a solar power switchboard for distributing the power generated by the solar battery unit 100 to a power load used by the power source.

The solar power switchboard uses power generated by the solar battery unit 100 as a power load for each power mode of the battery classified into a plurality of modes and uses a plurality of loads And a control switch.

The load usage control switch allows the power load usage to be controlled for each mode of battery power state.

For example, the load use control switch may include a first switch for the first mode, a second switch for the second mode, a fourth switch for the third mode, and a fourth switch for the fourth mode.

That is, when the first switch is connected in a state where the second to fourth switches are short-circuited, it is possible to use the electric power generated from the solar battery unit 100 for all the electric power loads of the electric power source.

When the second switch is connected in a state in which the first switch, the third switch, and the fourth switch are short-circuited, only some of the power loads of the power use destination use power generated from the solar cell unit 100 The remaining power loads allow power to be supplied from the power grid's power grid 800.

When the third switch is connected in a state in which the first switch, the second switch, and the fourth switch are short-circuited, only a part of the power load of all the power loads of the power use destination is supplied from the solar battery unit 100 And the remaining power loads use the electric power supplied from the electric power grid 800 of the electric power supply company.

When the fourth switch is connected in a state in which the first switch, the second switch, and the third switch are short-circuited, only the minimum power load of all the power loads of the power use destination And the remaining power loads use the electric power supplied from the electric power grid 800 of the electric power supply company.

A part of the power load capable of using the power generated in the solar cell unit 100 from the second switch is preset and a part of the power load capable of using the power generated in the solar cell unit 100 from the third switch is And the minimum power load that can use the power generated in the solar cell unit 100 from the fourth switch is preset.

The power supply controller 500 checks the actual charge amount of the battery in a predetermined time unit, compares the charge amount with the expected charge amount, confirms the deviation, and reflects the deviation? V to the remaining power amount F tomorrow, (D) and controls power supply in real time.

The remaining amount of electricity F that is reflected in real time tomorrow is expressed by the following equation (3).

FIG. 2 is a flowchart illustrating a solar energy management method according to an embodiment of the present invention. Referring to FIG. 2, an embodiment of a solar energy management method according to the present invention includes estimating An estimated power consumption calculation step S200 for calculating an estimated power consumption amount for use tomorrow by confirming a power consumption pattern of a power use destination, a step of calculating an estimated power consumption amount And a used power load determining step (S300) for determining a used power load of the place of use.

The estimated charging amount calculation step S100 receives the weather forecast of the area where the power user is located and calculates the estimated charging power amount that can be charged tomorrow through the received weather forecast.

That is, the predicted charge amount calculation step S100 predicts the sunrise amount of tomorrow through the weather forecast, and calculates the estimated charge amount C to be charged through the solar battery unit 100 through the estimated sunlight amount.

In addition, the expected power consumption calculation step (S200) checks the power consumption pattern of the power use destination and calculates the expected used power amount A of tomorrow.

The power consumption pattern of the power use destination can be confirmed by receiving the power use information of the power use destination stored in the main server of the power supply organization and can be used for initializing the data of the average power use value per region stored in the main server of the power supply agency, It is noted that the data can be updated by accumulating data on the power usage value of the user from the set reference time after setting the reference as the power consumption pattern value.

The use power load determination step S300 includes a step S330 of calculating a remaining amount of electricity F that is obtained by adding the remaining amount of electricity B of the battery and the estimated amount of used electricity C, (S340) of confirming an absolute value obtained by subtracting the final residual power amount (D) of the battery from the final residual power amount (D) of the battery And a process of determining a power load usage amount of electric power supplied from the battery unit 100 (S350).

That is, tomorrow's remaining power amount F can be calculated by the following equation (4).

Further, the final remaining power amount D of the battery can be expressed by the following equation (5).

The used power load determining step S300 is a step of determining a power amount state of the battery by a first mode when the final remaining power amount D of the battery is 95% or more of the maximum charging power amount of the battery, A third mode when the final remaining power amount D of the battery is less than 70% of the maximum charging power amount of the battery is 70% to less than 95% of the power amount, If it is 15% or more but less than 40% of the maximum charging power, it is classified into the fourth mode.

The power usage load determination step S300 may be such that, in the first mode, the power generated from the solar cell unit 100 is used for all the power loads of the power usage destination. In the second mode, Only the power load of the solar cell unit 100 uses the power generated from the solar cell unit 100 and the remaining power load uses the power supplied from the power supply agency and in the third mode, Only a part of the power load uses the electric power generated from the solar battery unit 100 and the remaining electric power load uses the electric power supplied from the electric power supply agency and in the fourth mode, Only the smallest electric power load uses the electric power generated from the solar battery 100, and the remaining electric power load uses the electric power supplied from the electric power supply agency .

Some of the power loads that can use the power generated in the solar cell 100 in the second mode are predetermined and some power loads that can use the power generated in the solar cell 100 in the third mode And the minimum power load capable of using the power generated in the solar battery unit 100 in the fourth mode is preset.

The used power load determining step S300 further includes a step S310 of checking the actual battery charge amount in a predetermined time unit, a step S320 of comparing the actual battery charge amount with the estimated charge amount to confirm the deviation, The final remaining power amount D of the battery is corrected in real time by calculating the remaining strategic amount F by reflecting the deviation V in the process of calculating the remaining power amount F in step S330, do.

The remaining amount of electricity F that is reflected in real time tomorrow is calculated by the following equation (6).

The present invention can efficiently utilize the power generated by the solar cell by managing the solar energy according to the weather forecast and the consumption pattern of the user, so that the power can be used stably regardless of the change of the weather.

The present invention maximizes economic efficiency by establishing plans such as efficient charging, discharging and power sale of electric power.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

100: solar battery part 200: battery part
300: Estimated charge amount calculation unit 400: Estimated usage amount calculation unit
500: power supply control unit 600: PCS
700: BMS 800: Power grid
S100: Expected charge calculation step
S200: Estimated power consumption calculation step
S300: Power usage load determination step
S310: Process of determining power load usage of power
S320: The process of checking deviations
S330: Process of calculating the remaining amount of electricity (F) tomorrow
S340: The process of confirming with the final remaining power amount (D)
S350: Process of determining power load usage of power

Claims (9)

Generating solar power by solar power;
A battery unit for storing electric power generated from the solar cell unit;
An estimated charging amount calculation unit for calculating an estimated charging power amount that can be charged tomorrow through the weather forecast;
An expected use power calculation unit for calculating a predicted use power amount to be used tomorrow by confirming a power consumption pattern of the power use place; And
And a power supply control unit for determining a used power load of the power use destination from the estimated charging power amount and the expected use power amount and controlling power supply to the determined power load. The method according to claim 1,
The power supply control unit calculates the remaining amount of electricity F for the present day plus the remaining amount of power B of the battery and the expected amount of used electricity C and calculates an absolute value obtained by subtracting the remaining amount of electricity F from the estimated use amount of electricity A The final remaining power amount D of the battery and the final remaining power amount D of the battery to divide the power amount state of the battery into a plurality of modes and determine the power load usage of the power supplied from the solar battery unit for each mode A solar energy management device characterized by. The method of claim 2,
Further comprising a solar power switchboard for distributing power generated by the solar battery unit to a power load used by the power source,
The solar power distribution board includes a plurality of load usage control units for distributing power generated by the solar battery unit to a power load of a power usage destination, Wherein the switch comprises a switch. The method of claim 2,
The first mode is a mode in which the final remaining power amount D of the battery is equal to or more than 70% and less than 95% of the maximum charging power amount of the battery when the final remaining power amount D of the battery is 95% (D) of the battery is less than or equal to 40% and less than 70% of the maximum charging power amount of the battery. In a third mode, if the final remaining power amount (D) %, It is divided into the fourth mode,
Wherein the power supply control unit allows the power generated from the solar battery unit to be used for all the power loads of the power use destination in the first mode, and only the power loads of all the power loads of the power use destination in the second mode, Wherein the first mode uses power supplied from a power source and the remaining power load uses power supplied from a power supply source, and in the third mode, And the remaining power load uses the power supplied from the power supply source, and in the fourth mode, only the minimum power load of all the power loads used for power use is smaller than the minimum power load of the third mode Use the power generated from the solar panel and the remaining power Wherein the control unit uses the power to be supplied to the solar cell. The method of claim 2,
The power supply control unit checks the actual charge amount of the battery in a predetermined time unit, compares the charge amount with the expected charge amount, confirms the deviation, and reflects the deviation? V to the residual power amount F tomorrow to calculate the final remaining power amount D) of the photovoltaic power generation unit to control power supply in real time. An estimated charging amount calculating step of calculating an estimated charging power amount that can be charged tomorrow through the weather forecast;
An estimated power consumption calculation step of calculating a predicted power consumption amount to be used tomorrow by confirming the power consumption pattern of the power use destination; And
And a use power load determining step of determining a use power load of the power use destination from the estimated charging power amount and the expected use power amount. The method of claim 6,
Calculating a remaining power amount (F) tomorrow by adding the residual power amount (B) of the present battery and the expected use amount of electricity (C);
Confirming an absolute value obtained by subtracting the remaining power amount F from the expected used power amount A by the final remaining power amount D of the battery; And
Determining a final remaining power amount (D) of the battery to divide the power amount state of the battery into a plurality of modes, and determining a power load usage amount of power supplied from the solar battery unit for each mode, How to manage. The method of claim 7,
The process of determining the power load usage may be performed by a first mode when the final remaining power amount D of the battery is 95% or more of the maximum charging power amount of the battery, a final remaining power amount D of the battery is the maximum charging amount of the battery A third mode when the final remaining power amount D of the battery is less than 70% of the maximum charging power amount of the battery is 70% to less than 95% of the power amount, In the first mode, the power generated from the solar battery unit is used for all the power loads of the power use destination, and when the power mode is the second mode, Only the power load of some of the power loads of the solar cell uses the power generated from the solar battery, the remaining power loads use the power supplied from the power supply agency, In the third mode, only a part of the power load of all the power loads used by the power use is generated from the solar battery unit, and the remaining power loads use the power supplied from the power supply agency, In the fourth mode, only the minimum power load of all the power loads of the power use destination is smaller than that of the third mode, and the remaining power loads use the power supplied from the power supply agency Wherein the photovoltaic energy management method comprises the steps of: The method of claim 7,
Wherein the used power load determination step comprises:
Checking a charge amount of an actual battery in a predetermined time unit; And
Comparing the actual charge amount of the battery with the expected charge amount to confirm the deviation,
The final remaining power amount D of the battery is corrected in real time by calculating the remaining strategic amount F by reflecting the deviation? V in the course of calculating the remaining power amount F of tomorrow How to manage solar energy.

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