JP2008048544A - Solar power generating system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive solar power generating system in which output can be made smooth or timeshifting is possible. <P>SOLUTION: A solar battery string is constituted by including a solar battery and a secondary battery connected to the solar battery in parallel. Output of the solar battery string is inputted to a power conversion device. The system is provided with a detecting part detecting a state of the secondary battery and a control part controlling an output power value of the power conversion device by an output detecting part detecting the output power value of the power conversion device. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

The present invention relates to a solar power generation system having a power storage function for storing the power generation output of a solar battery, and more specifically, the output fluctuation of the solar battery due to solar radiation fluctuation by combining the power of the storage battery and the power of the solar battery as a combined output. The present invention relates to a photovoltaic power generation system that enables smoothing or time shifting of output.
Furthermore, the present invention comprises a plurality of strings comprising a solar cell and a secondary battery that stores the power generation output of the solar cell, and a DC voltage supplied from these strings is converted into a commercial frequency by a power converter (inverter). The present invention relates to a large-scale photovoltaic power generation system that is used to suppress peak power of an existing power system by supplying power with a time shift during a time period when the power demand is locally large, such as daytime.

  The output obtained by converting sunlight into electric power by the solar cell can be supplied to an electric load or can be reversely flowed to the system. However, conventionally, since the power of the solar battery and the storage battery is collectively converted by the power conditioner, the conversion power of the power conditioner must be limited so as to avoid the outflow of power from the storage battery to the system. In addition, if the conversion power of the power conditioner is limited in this way, the generated power of the solar cell is limited, and eventually the output of the solar cell is lowered and the surplus power cannot be sufficiently reversed. .

In order to solve such a problem, the power storage solar power generation system of Patent Document 1 connects a first power conversion unit that performs a grid-connected operation between a solar cell and a system, A photovoltaic power conditioner having a second power conversion unit connected between a storage unit and the first power conversion unit is provided. Then, a load is connected between the power conditioner and the grid, and the received power detection means connected between the load and the grid prevents the received power from falling below a predetermined power when the power is output from the power storage means. Control means for controlling the second power conversion means is provided.
According to Patent Document 1, when the output of the storage battery is adjusted by the second power conversion means, and the power previously stored at midnight is efficiently discharged, the power from the photovoltaic power generation is reversely flowed to the system. It becomes possible to stop the output from the storage battery.

  Further, Patent Document 2 discloses a method of performing maximum power follow-up control operation in order to extract maximum power from a solar cell, connecting a solar cell and a storage battery in parallel, and operating a combined storage battery operation without a complicated switching operation. Yes. That is, the solar power generation device of Patent Document 2 includes a solar battery, a storage battery connected in parallel via the solar battery and charging / discharging means, and another AC power source by converting the output power of the solar battery into AC power. A power converter linked to the solar cell, a maximum power follow-up control means for changing an operation command in a direction in which the output of the solar cell increases, a direct current constant voltage control means for controlling the voltage of the solar battery to be constant, and from the outside There is provided means for performing control by the power command. And it sets so that the voltage of the said storage battery may be set to a value smaller than the DC constant voltage of the said solar battery, and when the voltage of the said storage battery is smaller than the voltage of the said solar battery, it discharges the said storage battery. . According to this system, the power of the storage battery can be output when the amount of power generated by solar power generation is considerably low.

  Patent Document 3 discloses a technique for maximizing the power generation capability of a solar cell, effectively using solar radiation energy, and extending the battery life. That is, an inverter that generates power corresponding to the power output command value is connected to a solar cell, and a bidirectional DC / DC converter block is inserted between the connection point between the solar cell and the inverter and the battery. A switch is connected in parallel to the DC / DC converter block. When the battery discharge / charge command is generated, the switch is turned off and the bidirectional DC / DC converter block is operated to control the voltage at the connection point between the solar cell and the inverter so that the generated power of the solar cell is maximized. When a battery charging command is issued to command charging by the power system, the switch is turned on, the inverter is operated as a converter, and the charging current or charging power to the battery is controlled to be constant.

These systems are designed to operate solar power generation with maximum power and extract the maximum amount of generated power, and focus on maximum power point tracking regardless of output fluctuations due to solar radiation fluctuations. System.
Next, a conventional solar power generation system including a plurality of strings each including a solar battery and a secondary battery will be described with reference to FIGS.

  FIG. 14 is a circuit diagram disclosed in Patent Document 4. In FIG. Patent Document 4 is a photovoltaic power generation that operates in combination with a storage battery and only a solar battery without complicated switching operations, preferentially charges the storage battery during the daytime to keep the storage battery in a fully charged state, and prepares for autonomous operation. Device. This solar power generation device includes a solar battery, a storage battery, a power conversion device, and a control device. By distinguishing day and night from the output voltage of the solar battery and monitoring the storage battery voltage, the storage battery voltage during daytime when the system is normal When the battery voltage drops to the discharge limit voltage, the power conversion device is controlled to charge operation, and at night, the power conversion device is controlled to charge operation whenever the storage battery voltage drops to the lower limit voltage of the charge state higher than the discharge limit voltage. is there.

As shown in FIG. 14, inverters 25a and 25b are provided for each of the strings 20a and 20b. When the sunlight is sufficiently irradiated during the day, the power generation outputs of the solar cells 21a and 21b are supplied to the inverters 25a and 25b. When sunshine is insufficient, electric power is supplied from the secondary batteries 22a and 22b to the inverters 25a and 25b. The inverters 25a and 25b are operated in accordance with the power demand of the load 26 to supply necessary power. Since the inverters 25a and 25b are provided for each string, the input voltage of the inverters 25a and 25b, that is, the voltages of the solar cells 21a and 21b and the secondary batteries 22a and 21b can be set independently for each string.
The secondary batteries 22a and 22b are charged in advance by providing a switch for bypassing the backflow prevention diodes 24a and 24b on the secondary battery 22a and 22b side, and the secondary battery to be charged when there is sufficient sunlight. Is turned on to charge the solar cells 21a and 21b.

FIG. 15 shows another example of a conventional system. By providing the DC / DC converters 27 a and 27 b between the secondary battery 22 and the inverter 25, the discharge power of the secondary batteries 22 a and 22 b can be controlled to match the input voltage of the inverter 25. Although it is necessary to set the voltage of the solar cell 21a and the solar cell 21b to be the same, the voltage of the secondary battery 22a and the secondary battery 22b can be arbitrarily set. The voltage of the secondary battery 22a is stepped up or down to a predetermined input voltage of the inverter 25 by the DC / DC converter 27a. Similarly, the voltage of the secondary battery 22b is stepped up or down to a predetermined input voltage of the inverter 25 by the DC / DC converter 27b. By controlling in this way, since all strings have the same voltage, one secondary battery does not discharge unevenly.
To charge the secondary batteries 22a and 22b, a switch that bypasses the DC / DC converters 27a and 27b is provided in advance, and the bypass switch is turned on for the secondary battery that is to be charged when there is sufficient sunshine. Charge.
JP 2002-171694 A JP 2002-34175 A JP-A-6-266458 JP 2001-224142 A

The current solar power generation system takes out the maximum output generated by the solar cell and operates so that the load connected to the solar power generation system cannot reverse power flow to the grid. As the cost and spread of the system increase, the photovoltaic power generation system becomes larger and the installation density of the system increases. The impact of fluctuations in the output of natural energy on the grid can no longer be ignored, and the output can be smoothed or output. The function to shift is important.
In addition, when the system is increased in size, the battery is also increased in size by arranging several in parallel, and there are many configurations in which one storage battery is provided for the entire solar cell string, and measures such as current control are required.

In the conventional example of FIGS. 14 and 15, inverters 25a and 25b are provided for each string, and DC / DC converters 27a and 27b are used to maximize the power generated by the solar cell. The purpose is to realize the operation, but the number of parts increases and the system becomes expensive.
In order to solve the above-described problems, the present invention provides a photovoltaic power generation system capable of smoothing output or time shifting with an inexpensive system.

In order to solve the above problems, a solar power generation system according to the present invention receives a solar cell, a solar cell string including a secondary battery connected in parallel to the solar cell, and power of the solar cell string. A power converter, a battery state detector that detects the state of the secondary battery, an output detector that detects an output power value of the power converter, and the secondary battery detected by the battery state detector And a control unit that controls an output power value based on the output of the power conversion device detected by the output detection unit.
Since the output power value of the power converter is controlled in this way, output can be smoothed or time-shifted with an inexpensive system.

  Further, another photovoltaic power generation system of the present invention includes a solar cell, a plurality of solar cell strings including secondary cells connected in parallel to the solar cell, and power conversion into which electric power of each solar cell string is input. An apparatus, a battery state detection unit that detects a state of each secondary battery, an output detection unit that detects an output of the power conversion device, and a state of the secondary battery detected by the battery state detection unit, And a control unit that controls an output power value based on the output of the power conversion device detected by the output detection unit. As a result, the output can be adjusted in accordance with the state of charge of the secondary battery, so that the output can be smoothed or time-shifted.

According to the present invention, output can be smoothed and time shifted by an inexpensive system. Further, since the discharge current of the secondary battery does not flow excessively, the system can be stabilized, and further, since the excessive current does not flow through the battery, the life of the secondary battery is extended.
In addition, since a plurality of strings can be connected to one inverter without a DC / DC converter, the system configuration is simple, and capital investment can be suppressed.
Furthermore, according to the present invention, the secondary battery group having a high voltage value can be updated periodically after the system is started, and the number of secondary batteries contributing to discharge can be increased. Can be brought to the state.
In addition, by providing a charge switch for each secondary battery, the secondary battery can be charged from the solar battery during sunshine, and the charge variation state of the secondary battery can be alleviated. Further, since the secondary battery is not discharged by turning off the open / close switch of the secondary battery at night, variations in the secondary battery voltage at the start of early morning can be reduced, and the system can be started more stably and easily.

  In the photovoltaic power generation system of the present invention, a solar cell string is constituted by a solar cell and a secondary battery connected in parallel to the solar cell, and the power conversion device to which electric power of the solar cell string is input; A battery state detection unit that detects a state of the secondary battery and an output detection unit that detects an output power value of the power converter. The output power value is controlled by the state of the secondary battery detected by the battery state detection unit and the output of the power conversion device detected by the output detection unit.

  Here, the battery state detection unit detects any one of the voltage of the secondary battery, the state of charge (SOC), the rate of change of state of charge (SOC) per time, and the like. Furthermore, the present invention includes a data storage unit or a communication unit that receives external data, and from the data storage unit or communication unit, a predicted solar radiation amount based on past solar radiation data, average temperature data, module temperature data, weather forecast, or the like, or One of information such as predicted temperature, predicted module temperature information, and battery deterioration information is acquired, and the control unit controls an operation pattern based on the information.

  In another embodiment of the present invention, a plurality of solar cell strings including a solar cell and a secondary battery connected in parallel to the solar cell are provided. The power of each solar cell string is input to the power converter, and the output power value is controlled by the state of each secondary battery detected by the battery state detector and the output of the power converter detected by the output detector. To do. Therefore, the photovoltaic power generation system of the present invention can adjust the output according to the state of charge of the secondary battery.

In the present invention, the voltage comparison unit numbers the secondary batteries detected by the battery state detection unit in descending order of voltage. And the high voltage secondary battery group which belongs to the numbered high voltage is determined, and when the photovoltaic power generation system is started, the output of the power converter is calculated based on the total output power allowed from the high voltage secondary battery group. Is further provided with an activation control unit for controlling the power conversion device so as to be small.
As a result, when the solar power generation system is large-scale, even if the initial specifications are the same, depending on where the solar cells are installed, there are large output solar cells and small solar cells, Even when a secondary battery with a large output and a secondary battery with a small output are generated depending on the installation conditions and the ambient temperature, the photovoltaic power generation system of the present invention is used in order of the output voltage of the secondary battery, so the secondary battery with a good charge state The battery can contribute to the output, and all solar cells and secondary batteries can be leveled.

In addition, the SOC comparison unit of the present invention numbers each secondary battery detected by the battery state detection unit in descending order of the state of charge (SOC), and the SOCs belonging to the numbered group of large state of charge (SOC). Startup that determines the secondary battery group and controls the power converter so that the output of the power converter is smaller than the total output power allowed from the SOC secondary battery group when starting the photovoltaic power generation system A control unit is further provided.
For this reason, when the photovoltaic power generation system is large-scale, even if the initial specifications are the same, a secondary battery having a large output and a secondary battery having a small output are generated depending on the installation state of the secondary battery and the ambient temperature. However, since the present invention is used in the descending order of the state of charge (SOC) of the secondary batteries, all the secondary batteries can be leveled.

Also, assuming that the number of strings is n, the internal resistance of the secondary battery is r, the margin of the output current of the secondary battery from the absolute maximum rating Imax is ΔImax, and the efficiency of the power converter is η, the second of each string at system startup is The secondary batteries are SB1, SB2,..., SBn in descending order of voltage, the electromotive force of each secondary battery is E1, E2,..., En, the current is I1, I2,. When
(E1-Ei) / r <ΔImax
The number of strings satisfying the following condition is examined for k, and the output P of the power converter is
P <(E1−r × Imax) × (Imax + I2max +... + Ikmax) × η
(Where Iimax = Imax × (Ei− (E1−r × Imax)) / (E1−r × Imax), i = 2, 3,..., K)
The output is controlled so that Thereby, the output which does not flow overcurrent from a secondary battery can be calculated | required.

Furthermore, the voltage of each secondary battery is periodically monitored from the time of start-up, the above determination is repeated, and when k increases, the output of the power converter is increased accordingly, thereby providing a stable and reliable system. Can be started. In this way, it is possible to update the secondary battery group with a high voltage value periodically after system startup and increase the number of secondary batteries that contribute to discharging, so that the system can be stably maintained in a minimum amount of time. Can take it to.
In addition, a charge switch is provided for each secondary battery of each string, and when the amount of charge of the secondary battery is small and the electromotive voltage is small during sunshine, the secondary battery is charged by turning on the charge switch and using a solar battery. When the battery is charged and the electromotive voltage becomes high, the charging switch is turned off, so that the secondary battery with a small amount of charge can be easily charged.
In addition, an open / close switch that disconnects each secondary battery from the system is provided, and the secondary battery is opened when the system is stopped at night, etc., thus suppressing the secondary battery's natural discharge and reducing the variation in the state of charge of the secondary battery. be able to.

Next, each component of the present invention will be described in detail.
《Solar cell module》
The solar cell module used in the present invention is a crystalline solar cell module produced by connecting a plurality of crystalline solar cells, or a silicon-based semiconductor or compound system formed on a glass substrate by a method such as CVD. Examples include a solar cell module using cells obtained by processing semiconductor thin film solar cells so that they are connected in series, and a solar cell module using a tandem solar cell in which crystalline silicon and amorphous silicon are stacked. .

  In ordinary solar power generation, the maximum power point that changes according to the sunlight conditions and the temperature of the solar cell module is tracked, and the operating point voltage is controlled so that the output power becomes maximum. However, in this invention, it operates so that the voltage of the storage battery module connected may become the operating point voltage of a solar cell module. Therefore, the operating point voltage of the solar cell module is limited to the voltage range in which the storage battery module operates.

In general, the output of a solar cell decreases as its module temperature increases, and the maximum power operating point has a linear relationship with a negative slope (temperature coefficient) with respect to temperature. Usually, the temperature coefficient of crystalline silicon is about −0.45 to −0.5% / ° C. The amorphous silicon thin film solar cell is about -0.17 to -0.2%. In addition, amorphous silicon laminated with crystalline silicon and compound semiconductor solar cells such as GaAs have been developed and put into practical use with a temperature coefficient suppressed to -0.2 to -0.3% / ° C. .
On the other hand, the operating voltage of the storage battery module is not significantly affected by temperature. Therefore, it is desirable to select a solar cell having excellent temperature characteristics that is less susceptible to change in output voltage depending on temperature.

As described above, it is desirable to select a solar cell module having a temperature coefficient of −0.42% / ° C. or lower, more preferably −0.3% / ° C. or lower. Thereby, high system efficiency can be obtained. Although this depends on the type of the storage battery device to be connected, the fluctuation range due to the temperature change of the operating voltage of the storage battery device is about 20 to 30%, while the operating temperature range of the solar cell module is about 60 ° C. It is calculated considering this.
In particular, a change in charging voltage due to temperature is very small in a lithium ion battery, and when a lithium ion battery is selected as a storage battery device of a storage battery module, it is preferable to combine a solar battery having an excellent temperature coefficient.

<Setting the voltage range>
In charging / discharging using a storage battery module, the upper limit of the voltage is the end-of-charge voltage, and the lower limit of the voltage is defined as the end-of-discharge voltage. The voltage range determined by the upper limit and the lower limit may be fixed, or the set value may be sequentially changed according to the deterioration state of the secondary battery.
In the voltage range, the lower limit value is preferably 65% or more, more preferably 70% or more, and further preferably 75% or more of the voltage determined by the discharge end voltage. The higher this lower limit, the higher the efficiency of the system. In order to further increase the efficiency, it is preferable to select an electric storage device in which voltage fluctuation due to charging / discharging is small.
This range can also be changed depending on the assumed solar radiation conditions of the installation location, and the lower limit value can be set to 80% or more in an area where the solar radiation is stable.
In general, as the storage battery deteriorates, the internal resistance increases, so that the end-of-charge voltage can be set in advance within the above range, and the end-of-discharge voltage can be set in advance so as to decrease. Is also possible.

<Power storage module>
In the present invention, the power storage module is one in which one or more power storage devices are connected to a protection circuit or the like as necessary. As the electricity storage device, a secondary battery using a chemical reaction such as a lithium ion battery, a nickel hydride battery, or a lead storage battery, an electric double layer capacitor, or the like can be used. As described above, as much capacity as possible can be obtained in a narrow voltage range, and a secondary battery using a chemical reaction is preferable. Among them, a battery system that basically does not involve a side reaction in the charge / discharge reaction is more preferable because of high power efficiency by charge / discharge. A typical example is a lithium ion battery.

Furthermore, lead-acid batteries that have been used as power storage devices until now are subject to capacity deterioration if they continue to be insufficiently charged. Although an effect etc. are seen, a lithium ion battery does not have cycle deterioration or memory effect due to insufficient charging, and can be suitably used as a battery for constituting the power storage module of the present invention. Furthermore, since the lithium ion battery is less susceptible to changes in the charging voltage due to the ambient temperature, it is very effective as the power storage system of the present invention.
Various materials for the positive electrode material and the negative electrode material have been proposed for the lithium ion battery, and all of them can be used. Among them, a lithium ion battery using LiFePO4 as the positive electrode has a flat charge / discharge curve and is particularly preferable.
Examples of the protection circuit include an overcharge prevention circuit, an overdischarge prevention circuit, an overcurrent prevention circuit, a voltage monitoring circuit for each cell of the storage battery device, and a balance circuit for adjusting the voltage of each cell.

《Solar cell string》
In the present invention, the solar cell string refers to a solar cell module and a power storage module connected in parallel. More specifically, a backflow prevention diode connected to the solar battery, a backflow prevention diode connected to the secondary battery, a switch that bypasses the backflow prevention diode connected to the secondary battery, and a current that detects the charging or discharging current of the secondary battery. A sensor and a voltage sensor for detecting the output voltage of the secondary battery may be included.
The solar cell module is preferably installed in a sunny place such as a roof or a rooftop. It is desirable to install the storage battery module in a part of the solar cell base that is shaded by the solar battery module, in a wiring box that collects wiring, or indoors or in a place not exposed to rain and wind. Then, the plurality of solar cell modules that are set and connected so that the power storage module is in the above voltage range and the power storage modules are connected to each other by electric wiring so as to form a pair.

<Charging control method>
In the present invention, it is possible to control charging of the storage battery module by controlling the output from the DC / AC converter. That is, charging power is obtained by subtracting the output of the DC / AC converter from the power generated by solar power generation. Thereby, the output of a solar cell module is smoothed and charge control can be performed.
The output may be constant in order to absorb the output fluctuation from the solar cell module, or the output of the DC / AC converter may be controlled so that the charging current is constant.
Further, it is preferable to monitor the charging voltage so that the current charged to the secondary battery gradually decreases as the end of charging is approached. Such control can be realized by gradually increasing the output of the DC / AC converter when the output from the solar cell is constant.

  The control for reducing the charging current at the end of charging as described above is usually not so much, but if the solar power generation system of the present invention is operated in accordance with the general change of solar radiation, the amount of solar radiation gradually approaches the evening. And the current value also decreases, so there is an effect of gradually decreasing the current value (an effect like CV charging), and it is also possible to control based on that effect.

<Balance of capacity>
When the output of the solar cell module is P1 (W) and the storage capacity of the storage module is W1 (Wh), it is preferable that the capacity balance of both is about P1 × 0.3 hours <W1 <P1 × 5 hours. By setting both capacities in this way, it is possible to achieve both leveling of output at fine time intervals and power shift (leveling) in a large time for time shifting power. In the solar cell module, the maximum current is limited by the number of cells, internal resistance, and wiring resistance, and inherently has a current limiting function. For this reason, when the capacity balance between the solar cell module and the power storage module is adjusted as described above, the normally-required current limiting circuit during charging becomes unnecessary. Accordingly, the capacity balance is preferably P1 × 0.5 hours <W1, and more preferably P1 × 1 hour <W1.

There is no particular problem even if the maximum capacity value of the power storage module is large, but it may be determined from the viewpoints of equipment size, cost, equipment availability, etc. For example, P1 × 10 hours <W1, more preferably P1 X 5 hours <W1.
In addition, since the maximum output current of a solar cell is determined depending on the device, the capacity ratio determines the maximum charging current for the power storage module. For this reason, the capacity balance between the solar cell and the battery is important.

<< Explanation of output control to output specified capacity >>
A general photovoltaic power generation system is controlled to output all the power that can be output while following the maximum power point that the solar cell can output with the amount of solar radiation.
In the self-supporting type, the output is controlled in accordance with the load capacity of the device connected to the DC / AC converter. Since the output of the solar cell in this case is regulated by the load size, the power generation output of the solar cell may not be used effectively.

In the present invention, such conventional control is not performed, and control is performed so as to maintain a constant output for a certain period of time, output is maintained in accordance with solar radiation intensity, and output is output while absorbing short-term output fluctuations. Perform smoothing output. In the present invention, that the solar cell module and the power storage module are directly connected means that the power of solar power generation is directly connected to the storage battery so that it can be charged and discharged.
By adjusting the output width and output amount, it is possible to control the charge / discharge amount to the storage module, and gradually shift the storage module to the full charge direction, or conversely gradually shift to the end of discharge. It is possible to make full charge → discharge end stage → full charge end stage → discharge end stage periodically.

When the voltage range of the storage module is set as described in << Setting the voltage range >> above, the voltage on the fully charged side is closer to the maximum power point. If the output fluctuation is absorbed on the fully charged side, higher system efficiency can be obtained. In this way, it is also possible to control the charge / discharge amount by judging from which season, the solar radiation conditions, the temperature, the module temperature, etc., which efficiency is higher to control in the operating voltage range of the storage battery Thus, the system efficiency can be further increased by such operation.
In addition, the method of determining the output amount and time width of the above-mentioned constant output depending on the state of charge of the battery, or a method of selecting a preset pattern with reference to weather information or separately measured solar radiation amount, etc. .
For such control, the present invention includes a data storage unit or a communication unit that receives external data. From the data storage unit or communication unit, the present invention is based on past solar radiation data, average temperature data, module temperature data, or weather forecasts. Any one information including the predicted solar radiation amount or predicted temperature, predicted module temperature information, and battery deterioration information is acquired. Based on this information, the control unit controls the operation pattern.

  Further, as the smoothing operation, for example, the charging power for the first 10 minutes from the start of power generation is measured, the average power generation amount per minute is calculated from the integrated power generation amount, and the value is calculated for the first minute of the 11th minute. Output. Next, the average generated power per minute is calculated from the integrated power generation amount from the 1st minute to the 11th minute, and the value is set as the 12th minute generated power. In this way, by performing output control by advancing by 1 minute while averaging with a delay of 10 minutes, it is possible to output while absorbing fine output fluctuations.

<< Voltage Comparison Unit, High Voltage Secondary Battery Group Generation Unit, Startup Control Unit, SOC Comparison Unit, SOC Secondary Battery Group Generation Unit, >>
Each of these parts is provided in the control unit of the present invention, and uses a RAM that is a temporary information storage unit to number secondary batteries in order of increasing voltage or in descending order of SOC, and its upper group. Is generated. The upper group is preferably determined according to the condition 1 described below. In addition, the number is not particularly limited, but the number may be set in advance such as half or 1/3 of all the storage batteries. Then, the activation control unit performs control so as to supply power to the power conversion device using the upper group battery group at the time of activation.

(Embodiment 1)
"System configuration"
FIG. 1 is a block diagram showing an example of the configuration of the photovoltaic power generation system of the present invention.
The solar cell module 1 is configured by connecting 12 thin-film crystal solar cell panels (Vpm = 51V, Isc = 2A, 85W) in a 4 × 3 series connection, and outputs 1 kW. The storage battery module 2 includes 48 9.5 Ah lithium ion batteries in series, and includes a circuit unit having a protection circuit and a power counter.
The solar cell module 1 and the storage battery module 2 are connected in parallel to the DC / AC converter 7 via a backflow prevention element 3 provided so that the power of the storage battery does not flow back to the solar cell. A current sensor 6 that measures the current of the string is connected to the DC / AC converter 7. Further, the DC / AC conversion device 7 can detect the state of the storage battery by the signal line 8 from the storage battery module 2.
The solar cell string 10 configured as described above is connected to the DC / AC converter 7 and linked to the system power by the output of the DC / AC converter 7.

<Operating voltage range of storage battery>
In the case of charging and discharging the entire power of the lithium ion battery, the voltage range is 202V to 144V, but in the first embodiment, SOC (state of charge) 20% to SOC 80% obtained by cutting 20% at the top and bottom, It was decided to use 60% of the total capacity. The lower limit voltage during discharging is 174V, and the upper limit voltage during charging is 199V.
FIG. 2 is a diagram for explaining the SOC 20% to SOC 80%. FIG. 2 shows the relationship between the output power P and the output voltage V of the solar cell module, and the PV curve A of the solar cell module is shown in FIG. It is shown. In this PV curve A, the operating voltage range of the storage battery module 2 is SOC 20% to SOC 80%. The SOC indicates the state of charge of the storage battery module, where SOC 100% is fully charged, and SOC 0% is the state of completion of discharge. The efficiency at the maximum power point voltage (Pmax) in the range of SOC 20% to SOC 80% is 103% to 105% from the right vertical scale and the curve B representing the efficiency.

FIG. 3 shows the relationship between the charge capacity and the charge / discharge voltage, and explains the voltage range when charging / discharging the storage battery module. The storage battery is charged as indicated by a charging curve C and discharged as indicated by a discharging curve D. In such a charge / discharge curve, the charge end voltage is set as the upper limit voltage value during charging, and the discharge end voltage is set as the lower limit voltage value during discharge, and the voltage range from the charge end voltage to the discharge end voltage is arbitrary. Can be set to In the first embodiment, the voltage range is 60% of the central portion between SOC 20% and SOC 80%.
Therefore, the maximum electric power point pressure (Vpm) of the solar cell module at 1000 mW / m 2 and 25 ° C. is 204 V, and the generated power at that time is 85 W. Under the same conditions, the output power at the lower limit voltage 174 V and the upper limit voltage 199 V of the battery is 78.2 W (92%) and 83.7 W (98.5%), respectively.

《Output control method》
In the first embodiment, the output control is performed under the following conditions. The SOC is an abbreviation for the state of charge, and in the first embodiment, it is expressed as a ratio to the capacity actually used (60% capacity of the electricity storage device) defined above.
(1) If the SOC is less than 10%, output is stopped.
(2) SOC 10% or more and less than 20%, 200W output (3) SOC 20% or more and less than 40%, 300W output (4) SOC 40% or more and less than 95%, 700W output (5) SOC 95% or more, 1000W output (6) 17: When it reaches 00, 500W output is performed.
However, once the conditions are changed, the conditions are not changed for 20 minutes.

"result"
FIG. 4 shows the daily operation data of the first embodiment. As shown by the lines that change drastically and greatly, the output of the solar cell fluctuates drastically with fluctuations in solar radiation. However, as shown by the straight line, the output from the DC / AC converter is smoothed. And after 17:00, it can be seen that the daytime generated power can be peak shifted.
FIG. 5 shows the maximum power point power by comparing the power generation amount at the maximum power point calculated from the solar radiation intensity and module temperature at each power generation and the power generation amount at the voltage where the battery is actually connected. The ratio of how much generated power is obtained is shown. In this figure, the efficiency with the accumulated power for one day was 99%.
It can be seen that the first embodiment makes it possible to smooth the output and time shift the power with high efficiency.

(Embodiment 2)
The system configuration of the second embodiment is the same as that of the first embodiment except that the solar cell capacity is 3 kW and the storage battery capacity is 15 Ah, and only the control method is set as follows to perform control.
《Output control method》
(1) Calculate the amount of power generated by solar power generation for the past 30 minutes from the integrated value of the SOC change amount of the battery and the determined output amount. (2) Calculate the average power generation amount per minute from the calculated power generation amount. The next one minute output.

"result"
As shown in FIG. 6, an output smoothed with a delay of 30 minutes can be obtained. FIG. 7 shows the power generation amount at the maximum power point calculated from the solar radiation intensity and the module temperature at the time of each power generation, and the voltage at which the battery is actually connected when performing such smoothed output. The ratio of how much generated power is obtained with respect to the maximum power point power is shown by comparison of the amount of power generated at. Moreover, the efficiency in the integrated electric power for 1 day was 97.8%.

The amount of solar power generation may be calculated by measuring the amount of solar radiation and calculating the amount of solar radiation. However, in the system according to the present invention, power generation in the past is determined from the SOC of the battery and the output amount controlled by the system itself. The amount can be calculated, and a smoothed output can be obtained without measuring solar radiation.
Measuring the SOC after a lapse of a certain time is equivalent to measuring the integrated power amount of the charge / discharge amount to the battery for a certain time. Further, the controlled output is basically an output determined by the system itself, and the amount can be known without measurement. Therefore, the amount of power generated by solar power generation in the past, which is necessary for smoothing, is relatively simple, without the need for a highly accurate measuring instrument that has been required to follow the fluctuations in solar radiation. It can be obtained accurately by measurement.

(Embodiment 3)
FIG. 8 is a block diagram of the third embodiment.
The configuration of the solar cell 1, the secondary battery 2, the inverter 7 and the string 10 is the same as that of FIG. 1 shown in the first embodiment, except that a backflow prevention diode 9 is connected to each string 10. is there. In the third embodiment, a voltmeter (not shown) is attached to the secondary battery of each string, and the output voltage value of each secondary battery is monitored by the control circuit 11 of the inverter 7 through the signal line 8. It has a configuration that can.
In FIG. 8, the number of strings is 2, but in the following description, the number of strings is n, the internal resistance of the secondary battery is r, the set voltage of the secondary battery is E0, the set current of the secondary battery is I0, Let Δimax be the current margin from the set current of the battery to the maximum rated current Imax. If the efficiency of the power converter is η and the maximum output is Pmax,
n × (E0−r × I0) × I0 × η = Pmax
That is, the relationship is such that the maximum power can be output when the secondary batteries of all strings output at the set voltage / set current.

This is true when the system is stable and all the secondary batteries are in the same state of charge. However, if the secondary battery voltage varies depending on the state of charge of the secondary battery at system startup, etc., set Pmax. When trying to output, too much current is taken from the secondary battery with a high voltage, so the output is limited as follows.
When the system is started, first, the voltage of the secondary battery of each string is measured, and the voltage is set to SB1, SB2,..., SBn in descending order, and the electromotive force of each secondary battery is E1, E2,. When En and current are I1, I2,..., In, the voltage Ei of each secondary battery is sequentially from i = 2.
(E1-Ei) / r <ΔImax (Condition 1)
Check whether the conditions of the above are satisfied.

For example, FIG. 9 is a diagram for schematically explaining the relationship between the voltage E and the current I of the secondary battery. In the case of i = 2, assuming that (E1−E2) / r> ΔImax, SB1 and SB2 Even if it tries to flow current at the same time, since the voltage E1 of SB1 is too high for other secondary batteries, the current I1 from SB1 increases and the voltage drop due to the internal resistance r increases, and the voltage at the junction S However, I1 exceeds Imax and becomes an overcurrent before the voltage drops to the voltage E2 of SB2. That is, since current can be taken only from SB1, only the output for one string is P <(E1-r × Imax) × Imax × η.
Restrict to.

If (E1-E2) / r <ΔImax, the current I2 can also flow from SB2. When I1 is Imax, I2 is
I2max = Imax * (E2- (E1-r * Imax)) / (E1-r * Imax)
So,
P <(E1−r × Imax) × (Imax + I2max) × η
Can output up to.

Similarly, if condition 1 is satisfied until i = k,
P <(E1−r × Imax) × (Imax + I2max +... + Ikmax) × η (Condition 2)
(Here, Ikmax = Imax × (Ek− (E1−r × Imax)) / (E1−r × Imax)).
By controlling the output of the inverter in this way, it is possible to start up the system without flowing an overcurrent from each secondary battery.
As described above, the secondary battery can be leveled by measuring the voltage of the secondary battery and controlling the secondary battery satisfying the condition 1 up to the condition 2. Such control can be realized by providing the control circuit 11 with a voltage comparison unit, a high-voltage secondary battery group generation unit, and an activation control unit, and operating these parts.
In the third embodiment, the voltage of the secondary battery is measured, but the SOC of the secondary battery is measured, numbered in descending order of the SOC, and the SOC secondary battery group belonging to the group with the large SOC is generated. Depending on the SOC secondary battery group, the output of the power conversion device may be made smaller than the total output allowed for the SOC secondary battery group. In this case, it is realizable by providing an SOC comparison part, an SOC secondary battery production | generation part, and a starting control part.
In addition, here, the voltage or SOC of the secondary battery is measured and numbered in the descending order. However, the same result is obtained even if the voltage or SOC is measured and grouped according to whether or not the condition 1 is satisfied. Obtainable.

  As described above, once the system is started, the voltage of the discharged secondary battery becomes gradually lower. In the photovoltaic power generation system of the present invention, it is desirable to provide the control circuit 11 with a timer, and periodically monitor the voltage of each secondary battery from the time of startup to confirm the above conditions. When measuring that a certain amount of time has passed by the timer, if k increases, the output of the power converter is increased accordingly, so that all secondary batteries can be output eventually. it can.

(Embodiment 4)
FIG. 10 shows another embodiment. Compared to the first embodiment shown in FIG. 1, a difference is that a backflow prevention diode 15 and a charge switch 16 that bypasses the backflow prevention diode 15 are added to each secondary battery. The other configuration is the same.
According to this configuration, when the solar cell has sufficient electromotive force during normal sunshine, and when the secondary battery is in an empty state, the charging switch 16 is turned on so that the solar cell 1 The secondary battery 2 can be directly charged. If the switch 16 is turned off, the maximum power point control can be performed and only the solar cell can be operated.
Moreover, the amount of spontaneous discharge can be reduced by turning off the switch 16 when the system is stopped at night or the like to disconnect the secondary batteries for all strings, and the variation state of the charge amount can be alleviated when the system is started. .

  In the block diagram shown in FIG. 10, the backflow prevention diode 15 and the charge switch 16 are provided. However, the backflow prevention diode 15 can be eliminated and the backflow prevention diode 15 can be configured by a simple open / close switch. In the case where only the switch is configured as described above, the same operation and effect can be obtained by performing the same operation as in the fourth embodiment even when the switch element such as FET or IGBT is provided.

  As another control method of the present invention, control as shown in FIG. 11 is performed so as to maintain a constant output for a certain time width, not maximum power point tracking control or output power control in accordance with load capacity. It is possible. In FIG. 11, (a) shows the charge state of a storage battery module. (B) shows the amount of solar radiation. (C) shows the output of the solar cell string.

As shown in FIG. 11, it is possible to control the charge / discharge amount to the storage battery module by adjusting the output width and output amount, and gradually shift the storage battery module in the full charge direction, or gradually. It is possible to shift in the direction of the end of discharge or periodically in the order of full charge → near end of discharge → full charge → near end of discharge.
That is, as is clear from the operation result shown in FIG. 11, the power generation output obtained by the operation by tracking the maximum power point in the morning is time-shifted from 12: 00 to 14:00 and discharged, and from 14: 00 to 00: The power generation output obtained by the maximum power point tracking operation at 17:00 is time-shifted from 17:00 to 8:00 the next day to charge the secondary battery.

FIG. 12 shows a control method when emphasizing output smoothing. One day, the generated power E of the solar cell module from 16:00 to 17:00, the output F of the DC / AC converter, and the charging of the storage battery module Electric power G and SOC (charged state) H are shown. As the amount of solar radiation decreases as the evening approaches, the generated power E gradually decreases. However, since the output F from the DC / AC converter is controlled to be constant, the amount of solar radiation decreases. Therefore, a constant output can be obtained. Further, the charging power G of the storage battery module gradually decreases, and two controls are achieved simultaneously. When such a control is used at the end of charging of the storage battery module, the same drop as the constant current / constant voltage charging often used in the charging control of the storage battery module is obtained, which is very effective.
Normally, when the battery is almost fully charged by the charge control device, control is performed to reduce the charging power. However, in the solar power generation system of the present invention, control is performed to reduce the charging power near the full charge. The charging control can be achieved simultaneously only by the output control of the DC / AC converter.

  FIG. 13 is a diagram for explaining the control of the charging current. The generated power I of the solar cell module from 10:00 to 11:00 on a certain day, the output J of the DC / AC converter, and the charging power K to the storage battery module are shown. Although the generated electric power I of the solar cell module changes steeply with the variation of the amount of solar radiation, the present invention does not perform the follow-up control but controls the output according to the flow of the large amount of solar radiation. Therefore, the output J from the DC / AC converter can be smoothed. Further, the charging power K is controlled at the same time so that the charging power K is always equal to or lower than a certain level, although it varies. In battery control, controlling not to charge more than the rated charge power is important for extending the life of the battery. Normally, such control is performed by a dedicated charger. In the invention, the output from the DC / AC converter is smoothed, and at the same time, the charging power is controlled.

3 is a block diagram of the first embodiment. FIG. It is a figure which shows the relationship between the output voltage of a solar cell module, and output electric power. It is a figure which shows the relationship between the charging capacity of a solar cell module, and charging / discharging voltage. FIG. 4 is a diagram illustrating operation data for one day according to the first embodiment. It is a figure which shows the relationship between solar radiation intensity, the electric power generation amount of a solar cell module, and efficiency. FIG. 10 is a diagram illustrating one-day operation data according to the second embodiment. It is a figure which shows the relationship between the solar radiation intensity of Embodiment 2, the electric power generation amount of a solar cell module, and efficiency. FIG. 10 is a block diagram of a third embodiment. It is a figure which illustrates typically the relation between voltage E and current I of a rechargeable battery. FIG. 10 is a block diagram of a fourth embodiment. It is a figure explaining the control method of a solar power generation system, and is an explanatory view in the case of controlling to maintain a fixed output for a certain time width. It is explanatory drawing of the control method which attaches importance to the output smoothing of a solar cell module. It is explanatory drawing of the control method which controls the rechargeable battery of a solar cell module. It is a block diagram of the conventional 1st photovoltaic power generation system. It is a block diagram of the conventional 2nd photovoltaic power generation system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solar cell 2 Secondary battery 3 Backflow prevention diode 4 Switch 6 Current sensor 7 Power converter 5 Load 10 Solar cell string

Claims (10)

A solar cell string including a solar cell and a secondary battery connected in parallel to the solar cell;
A power conversion device to which power of the solar cell string is input;
A battery state detector for detecting the state of the secondary battery;
An output detector that detects an output power value of the power converter;
A control unit that controls an output power value based on the state of the secondary battery detected by the battery state detection unit and the output of the power conversion device detected by the output detection unit;
A photovoltaic power generation system comprising:   The battery state detection unit detects at least one of a voltage of a secondary battery, a state of charge (SOC), and a rate of change of the state of charge (SOC) per time. Solar power system.   Further, a data storage unit or a communication unit for receiving external data is provided, and the predicted solar radiation amount or predicted temperature based on past solar radiation data, average temperature data, module temperature data, weather forecast, etc. from the data storage unit or communication unit, prediction The photovoltaic power generation according to claim 1 or 2, wherein any one information including module temperature information and battery deterioration information is acquired, and the control unit controls an operation pattern based on the information. system. A plurality of solar cell strings including a solar cell and a secondary battery connected in parallel to the solar cell;
A power conversion device to which the power of each solar cell string is input;
A battery state detector for detecting the state of each of the secondary batteries;
An output detector for detecting the output of the power converter;
A control unit that controls an output power value based on the state of the secondary battery detected by the battery state detection unit and the output of the power conversion device detected by the output detection unit;
A photovoltaic power generation system comprising:   A voltage comparison unit that numbers the secondary batteries detected by the battery state detection unit in descending order of voltage, and a high-voltage second unit that determines a group of secondary batteries belonging to the high voltage numbered by the voltage comparison unit. The secondary battery group generation unit and the startup that controls the power converter so that the output of the power converter is smaller than the total output power allowed from the high-voltage secondary battery group when the solar power generation system is started. The solar power generation system according to claim 4, further comprising a control unit.   An SOC comparison unit that numbers the secondary batteries detected by the battery state detection unit in descending order of state of charge (SOC) and a group of large charge states (SOC) numbered by the SOC comparison unit An SOC secondary battery group generation unit that determines an SOC secondary battery group, and an output of the power converter is made smaller than the total output power allowed from the SOC secondary battery group when the photovoltaic power generation system is activated. The solar power generation system according to claim 4, further comprising an activation control unit that controls the power conversion device. When the photovoltaic power generation system is started up, assuming that the number of strings is n, the internal resistance of the secondary battery is r, the margin of the output current of the secondary battery from the absolute maximum rating Imax is ΔImax, and the efficiency of the power converter is η SBn, SB2,..., SBn in order of increasing voltage, the electromotive force of each secondary battery is E1, E2,..., En, and the current is I1, I2,. When In,
(E1-Ei) / r <ΔImax
The number of strings satisfying the following condition is examined for k, and the output P of the power converter is
P <(E1−r × Imax) × (Imax + I2max +... + Ikmax) × η
(Where Iimax = Imax × (Ei− (E1−r × Imax)) / (EI−r × Imax),
i = 2, 3,..., k)
The photovoltaic power generation system according to any one of claims 4 to 6, wherein the output is controlled so as to satisfy the relational expression:   The voltage of each secondary battery is periodically monitored from the start of the photovoltaic power generation system, and when the k increases, the output allowable value of the power converter is increased corresponding to the increase of k. The solar power generation system according to claim 7.   A charge switch is provided for each secondary battery of each string, and when the amount of charge of the secondary battery is small during sunshine, the secondary battery is charged by turning on the charge switch and charging the secondary battery with the solar battery. The photovoltaic power generation system according to any one of claims 1 to 8, wherein when the electromotive voltage becomes high, the charge switch is turned off.   The solar power generation system according to any one of claims 1 to 9, wherein a switch is provided in the secondary battery, and the secondary battery is opened during a system suspension such as at night.

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