JP5895143B2 - Power storage device - Google Patents

Description

The present invention relates to a solar power generation system that uses a power conversion device that converts DC power generated by a solar cell into AC power and superimposes it on a power line of the system. The present invention relates to a power storage device that is connected to a power line and charges and discharges DC power via the DC power line.

Examples of the power storage device include those that are charged from AC power of the system and those that are charged using the generated power of the solar battery, and each of them is discharged to the system or discharged to an independent circuit independent of the system.

When this power storage device discharges and leveles the power demand, when the power storage capacity of the power storage device decreases due to this discharge, the DC power supplied to the power converter is the power required to store the power storage device. When it is larger, charging of the power storage device is started, and when it is smaller, charging of the power storage device is started after stopping the power conversion device. (Patent Document 1)

Japanese Patent No. 3688744

In general, a power storage device discharges for the purpose of maintaining power in the event of a power failure. In such control, the power storage device is controlled from a power converter, and the power converter must always be in an operating state. Accordingly, the power storage device does not start discharging when the system is out of power, and sufficient operation cannot be performed during the power outage.

The present invention provides a power storage device capable of automatically charging / discharging the power storage device without affecting the operation of the power converter in accordance with the amount of power generated even if a power failure occurs in the system. .

The present invention charges DC power supplied to a power converter configured to convert DC power output from a DC power source such as a solar cell into AC power and superimpose it on a system, or DC power is supplied to the power converter. When the power required for charging the power storage device is smaller than the output power of the DC power supply, the power storage device starts charging operation from the voltage of the DC power supply required for the power conversion device to start the superposition operation. The required voltage is set low.

Further, the present invention charges DC power supplied to a power converter configured to convert DC power output from a DC power source such as a solar battery into AC power and supply the AC power to an AC load independent of the system, or In a power storage device that discharges DC power to a power converter, when the power required for the AC load is smaller than the output power of the DC power source, the power converter performs the charging operation of the power storage device from the voltage of the DC power source required for output of AC power. The voltage required to start is set high.

Further, the present invention charges DC power supplied to a power converter configured to convert DC power output from a DC power source such as a solar battery into AC power and supply the AC power to an AC load independent of the system, or In a power storage device that discharges DC power to a power conversion device, when the power required for the AC load is larger than the output power of the DC power source, the power conversion device performs the discharging operation of the power storage device from the voltage of the DC power source required for output of AC power. The voltage required to start is set high.

Further, the present invention charges DC power supplied to a power converter configured to convert DC power output from a DC power source such as a solar battery into AC power and supply the AC power to an AC load independent of the system, or In a power storage device that discharges DC power to a power converter, when the power required for the AC load is smaller than the output power of the DC power source, the power converter performs the charging operation of the power storage device from the voltage of the DC power source required for output of AC power. When the voltage required to start is set high and the power required for the AC load is larger than the output power of the DC power supply, the power converter starts the discharging operation of the power storage device from the voltage of the DC power supply required for the output of AC power. The required voltage is set high.

The power storage device of the present invention can automatically start the power storage device by selecting the charging / discharging operation according to the generated power of the solar cell regardless of the operating state of the power conversion device when the system is out of power. For example, the power storage device can be started before the power conversion device at the time of a power failure of the system, and the power conversion device can be started by the discharge output of the power storage device. To easily add power storage functions to existing solar cell systems
It is something that can be done.

FIG. 1 is a schematic view showing an embodiment of the present invention. FIG. 2 is an explanatory diagram showing the operation of the present invention. FIG. 3 is an explanatory diagram showing another operation of the present invention.

The present invention compares the output of a DC power source such as a solar battery with the power required for a load during a self-sustaining operation, and selects and starts charging and discharging of the power storage device.

FIG. 1 is a schematic diagram showing one embodiment of the present invention. In this figure, 1 is a solar cell module (DC power supply), and DC power generated by the solar cell module 1 passes through a DC power line 3 via a connection box 2 (including at least a diode and an opening / closing contact piece). Power conversion device 4
Supplied to. When there are a plurality of solar cell modules, the junction box 2 connects a series circuit composed of a diode and an opening / closing contact piece to each solar cell and combines the outputs of the plurality of solar cell modules into one. is there. The power converter 4 boosts the DC power obtained via the DC power line 3 by the booster circuit 5, and then synchronizes with the AC power of the power system 40 by the single-phase / three-phase bridge circuit 6 and converts it to AC power having the same frequency. This is converted and superimposed on the electric power system 40.

As the booster circuit 5 that boosts the DC voltage supplied from the DC power line 3 to a predetermined voltage, a general-purpose booster chopper circuit can be used if it is composed of a reactor, a switching element, a diode, and a capacitor. The boost ratio of the booster circuit 5 changes depending on the magnitude of the power superimposed on the power system 40, and increases as the superimposed power increases, and is feedback controlled so that this power becomes the target power. is there.

The bridge circuit 6 is composed of four switching elements in a single phase (six switching elements in a three-phase) connected in a single-phase or three-phase bridge shape, and a PWM (pulse) that modulates a predetermined carrier waveform with a sine wave. Switching elements that form bridges are ON / OFF controlled using switching signals based on (width modulation). This switching signal may be directly modulated using a comparator or may be obtained by calculation on a program. The sine wave is synchronized with the frequency of the power system 40 and has the same frequency, but the amount of feedback and correction for power failure detection are added to the waveform.

The AC power converted from DC power by the bridge circuit 6 is connected to the system linkage relays 7a and 7b and the distribution board 30 (the power conversion device 4 and the power system 40 are connected to the dedicated breaker 31, the main circuit breaker 3).
2, and power is supplied to the individual circuits in the house via the breaker 33.
) Are sequentially superimposed on the power system 40, and the AC power output from the bridge circuit 6 is supplied to a specific load 11 via a self-sustained operation relay 8 and a self-sustained operation outlet (or a self-sustained operation terminal) 9. To be supplied. System linkage relays 7a and 7b and independent operation relay 8
Means that either one is closed and the supply of AC power can be switched. When the power system 40 is normal, the system linkage relays 7a and 7b are closed at the time of startup, and when the power system 40 is in a power failure state, the self-sustaining operation relay 8 is closed.

Reference numeral 20 denotes a power storage device that is connected to the DC power line 3 and charges DC power from the DC power line 3 and discharges DC power to the DC power line 3. The power storage device 20 is a bidirectional DC /
A DC converter 23 and a storage battery 24 are included. For example, the DC / DC converter 23 connects the AC side of an inverter circuit in which at least four switching elements are connected in a single-phase bridge to terminals on the DC power line side and storage battery side of the insulation transformer. Are connected to the DC power line 3 and the storage battery 24, respectively. Note that diodes are connected in parallel to the switching elements in opposite directions, and when all the switching elements are OFF, four diodes act as a full-wave rectification diode bridge. A smoothing capacitor is connected to the DC input side of each inverter circuit.

When charging the storage battery 24, each switching element of the inverter circuit is turned on / off based on PWM (pulse width modulation) to convert the DC power of the DC power line 3 into AC power using a pseudo sine wave. This pseudo sine wave is induced from the DC power line side of the insulating transformer to the storage battery side, and is supplied to the inverter circuit as predetermined AC power. In this inverter circuit, the switching element is in an OFF state, and the attached diode functions as a full-wave rectifier circuit, and is converted into DC power through a smoothing capacitor. The voltage of the DC power is controlled by changing the ON duty of the pseudo sine wave supplied to the DC power line side of the insulation transformer.

Accordingly, when charging the storage battery 24, for example, when performing multi-stage charging, the terminal voltage of the storage battery 24 is detected, and the ON duty is feedback-controlled so that this terminal voltage becomes the first target voltage. When the charging current to the storage battery 24 at this time becomes equal to or less than a predetermined value, the target voltage is changed to the second target voltage (> first target voltage) and charging is continued. The charging power required for charging can be obtained by detecting the voltage and current on the DC power line side of the insulation transformer (or the voltage and current of DC power supplied from the direct power line 3).

When discharging from the storage battery 24, the inverter circuit is operated based on PWM to change the DC power to pseudo sine wave AC power and supply it to the storage battery side of the insulation transformer, and to the DC power line side of the insulation transformer. Is output. This AC power is supplied to the DC power line after the inverter circuit functions as a full-wave rectifier circuit and is converted into DC power through a smoothing capacitor, as in the case of charging the storage battery. At this time, the current supplied to the DC power line is detected by the current detector, and the ON duty of the switching element constituting the inverter circuit on the storage battery side of the insulation transformer is feedback controlled so that the detected value becomes the target current value. Is. Therefore,
By changing the target current value, the amount of discharge from the storage battery to the DC power line can be controlled.

A power failure detector 25 detects the voltage of the AC power line connecting the power converter 4 and the distribution board 30. The distribution board 30 is connected to the power system 40 (commercial power supply) via the main breaker 32, and the power failure detector 25 substantially detects the voltage of the power system 40, and if this voltage is an AC waveform, the normal state is obtained. If a substantial DC waveform or ground potential is determined, a power failure of the power system 40 is determined. Further, the power conversion device 4 has a built-in power failure detector different from the power failure detector, and automatically stops operation when a power failure of the power system 40 is determined. Therefore, when the power system 40 reaches a power failure, the power converter 4 first detects the power failure and stops operation. At this time, since the AC power is output until the power conversion device 4 stops operation, the power failure detector 25 cannot detect this AC power and determine the power failure of the power system 40. A power outage is determined by the absence of AC power output after 4 stops operation. When a power failure occurs in the power system 40 with the power conversion device 4 stopped operating,
A power failure is immediately determined by the power failure detector 25.

Reference numeral 26 denotes a power detector, which detects DC power before the DC power generated by the solar battery is branched to the power storage device 20 after being supplied to the DC power line 3, and is substantially generated by the solar battery. Can be detected. This power detector 26 can obtain DC power from the product of the current value and voltage detected by DC CT (current transformer). The direct current may be obtained from a voltage drop by inserting a shunt resistor in the direct current power line 3.

Hereinafter, operation | movement of the power converter device 4 is demonstrated. (1) As shown in the explanatory diagram of FIG. 2, when the power system 40 is not a power failure, that is, when the power failure detector 25 has not detected a power failure of the power system 40, the operation start voltage Vs of the power storage device 20 is set. A voltage lower than the operation start voltage Vp of the power converter 4 is set. The power storage device 20 starts operation according to the power generated by the solar cell 1. That is, when the generated power of the solar battery 1 is low, the power required to charge the storage battery 24 is insufficient, so the charging operation is not performed. However, when the voltage corresponding to this power is detected and this voltage is equal to or higher than the operation start voltage. In addition, the storage battery 24 can be charged. Similarly, the power conversion device 4 also has power required to start operation, and the power generation voltage of the solar cell 1 corresponding to this power is calculated as the operation start voltage V
Compared with p, whether or not driving is possible is determined. The operation start voltage of the power converter 4 is normally a fixed value, and is set to a DC voltage of 70 V to 400 V (which varies depending on the configuration of the solar cell system, but is a value in a general household power converter). Has been. Therefore, the operation start voltage Vs is set to a voltage lower than this voltage. Although the operation start voltage Vs can be fixed and the operation start voltage Vp can be increased, in this case, communication is established between the power conversion device and the power storage device to exchange data.

Next, the generated power of the solar battery 1 is compared with the power required for charging the power storage device 20, and when the generated power of the solar battery 1 is greater than the power required for charging the storage battery 24, the storage battery 24 is charged by the multistage charging described above. Is what you do. This charging is performed until the storage battery 24 is fully charged,
Further, when the storage battery 24 is already fully charged or nearly full, this charging operation is not performed, or the charging end process is performed. By operating in this way, the power storage device 20 is preferentially charged as the operation start voltage is lower than that of the power conversion device 4.

(2) As shown in the explanatory diagram of FIG. 3, when the power system 40 fails and the power conversion device 4 is in a stopped state, the operation start voltage Vs of the power storage device 20 is set to the operation start voltage Vp of the power conversion device 4. Set to a higher voltage. Next, when the generated power of the solar cell 1 is larger than a specific load, the charging operation of the storage battery 24 is performed. The specific load 11 is supplied with power when the self-sustained operation relay is closed again when a power failure of the power system 40 is detected again at the time of manual or automatic re-operation after the power conversion device 4 is stopped due to a power failure of the power system 40. Is the load. In the present embodiment, the rated output value of the independent operation performed when the autonomous operation relay 8 is closed is the magnitude of the rated load. In addition, when the value of the electric power actually supplied to the load is obtained in the self-sustaining operation, it can be replaced with this value.
Therefore, if the solar cell is sufficiently generating power, the power supply from the power conversion device 4 to the specific load is preferentially performed by the amount that the operation start voltage Vp of the power conversion device 4 is lower than the startup voltage Vs of the power storage device. It will be.

In the state (2), when the power generated by the solar cell 1 is smaller than a specific load, the power storage device 4 performs a discharging operation. This discharge is a constant output discharge of 150 V or 3 A, for example, and is continued until the charge capacity of the storage battery 24 reaches a certain value or below. Solar cell 1
In order to determine the magnitude of the generated power and the specific load, a differential is appropriately set to suppress chattering when the charging device 20 is switched between charging and discharging.

The power storage device can be connected to a DC power line connecting the solar cell and the power conversion device, and an existing power storage function can be easily added to an existing solar cell system.

DESCRIPTION OF SYMBOLS 1 Solar cell 3 DC power line 4 Power converter 20 Power storage device 30 Distribution board 40 Electric power system

Claims (4)

The DC power of a system in which a solar cell and a power converter configured to boost the DC power output from the solar cell and then convert it to AC power and superimpose it on the grid are connected by a DC power line.
The electric storage device capable of discharging the DC power to be and before <br/> Symbol DC power line charges the DC power supplied from the DC power can be connected to the power line wire,
When power required for the charging of said power storage device from the output power of the solar cell is small, the power converter starts the charging operation of the electric storage device than the voltage of the solar cell required to initiate the superposition operation The power storage device is characterized in that the voltage required for is set low. A DC power line connects a solar cell and a power converter configured to boost the DC power output from the solar cell and then convert it to AC power and supply it to an AC load independent of the grid.
In the power storage device that can be connected to the DC power line of the stem and can charge the DC power supplied from the DC power line and discharge the DC power to the DC power line ,
When power required for the AC load from the output power of the solar cell is small, the voltage required for the power converter starts the charging operation of the electric storage device than the voltage of the solar cell required for the output of the AC power A power storage device characterized by being set high. A DC power line connects a solar cell and a power converter configured to boost the DC power output from the solar cell and then convert it to AC power and supply it to an AC load independent of the grid.
In the power storage device that can be connected to the DC power line of the stem and can charge the DC power supplied from the DC power line and discharge the DC power to the DC power line ,
When power required for the AC load from the output power of the solar battery is large, the voltage required for the power converter starts the discharge operation of the electric storage device than the voltage of the solar cell required for the output of the AC power A power storage device characterized by being set high. A DC power line connects a solar cell and a power converter configured to boost the DC power output from the solar cell and then convert it to AC power and supply it to an AC load independent of the grid.
In a power storage device that can be connected to the DC power line of the stem and can charge the DC power supplied from the DC power line and discharge the DC power to the power converter,
When power required for the AC load from the output power of the solar cell is small, the voltage required for the power converter starts the charging operation of the electric storage device than the voltage of the solar cell required for the output of the AC power When the power required for the AC load is larger than the output power of the solar battery , the power conversion device starts the discharging operation of the power storage device from the voltage of the solar battery required for the output of the AC power. The power storage device is characterized in that the voltage required for is set high.

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