JP2008061308A - Power feeding system and control method of power feeding system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power feeding system using a power generated in a solar cell without losing the generated power. <P>SOLUTION: The system is provided with a power converter having an input connected to the solar cell and a storage battery and an output connected to a load, and operating so as to control a current; and a control section for setting the power feed from the solar cell to the power converter within a range from zero to the current consumption of the load for each predetermined time. With this configuration, if the power feeding to the load can be completely sufficient by the power quantity generated by the solar cell, the power is not fed from the storage battery and only the power output generated by the solar cell can be fed to the load. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power supply system that supplies an output of a solar cell to a load and a control method thereof, and more particularly to a power supply system and a control method that effectively use a power generation output of a solar cell.

For example, Patent Document 1 discloses a power supply system that supplies the output of a solar cell to a load. Patent Document 1 is a system that operates a solar battery and a commercial power system in a linked manner, causes the solar battery to operate independently when the commercial power system is abnormal, and supplies power to the load together with the storage battery. Therefore, the storage battery is connected to the inverter together with the solar battery via the switching circuit, and the switching circuit operates to interrupt the charging / discharging of the storage battery, the state where the discharging current flows via the diode, and the state where the charging / discharging current flows To switch to.
Japanese Patent Laid-Open No. 9-46925

According to Patent Document 1, it is possible to prevent the power of the storage battery from flowing backward, and to operate the power conversion device by the maximum power tracking control.
However, even when there is an amount of solar radiation that can fully cover the power supply to the load by the amount of power generated from the solar battery, the power may be supplied from the storage battery to the load.
In view of the above-described problems, the present invention eliminates the power supply from the storage battery and effectively supplies the output of the solar battery when the power supply to the load can be completely covered by the generated power of the solar battery. A system and a method for controlling the power supply system are provided.

In order to solve the above problems, a power supply system of the present invention connects a solar cell and a storage battery to an input, connects a load to an output, and performs a current control operation, and power from the solar cell to the power conversion device And a control unit that changes supply to any one of zero or less from the power consumption amount of the load every predetermined time.
By providing this configuration, according to the present invention, when the power supply of the load can be completely covered by the power generation output of the solar cell, the power supply from the storage battery is eliminated, and the power is supplied to the load only by the power generation output of the solar cell. can do.

In order to solve the above problems, the power supply system of the present invention connects a solar cell and a storage battery to the input, connects a load to the output, and performs a current control operation, and the solar cell, the storage battery, and the power conversion device And a control unit that periodically turns off the switch.
Thereby, when the power supply of the load can be completely covered by the power generation output of the solar cell, the power consumption of the storage battery can be eliminated, and the power can be supplied to the load only by the power generation output of the solar cell.
Moreover, in this invention, it is preferable to comprise the said power converter device with a DC / DC converter provided with a capacitor. Thereby, the power supply to the load can be continued.

  Further, according to another aspect of the present invention, there is provided a method for controlling a power supply system including a power conversion device that connects a solar cell and a storage battery to an input, connects a load to an output, and performs current control operation, and a control unit, Starting the counting of a timer provided in the control unit, and when the timer counts a predetermined time, the power supply from the solar cell to the power conversion device is set to any one of the load power consumption below and zero And a step of maintaining a period of time from zero to less than the power consumption of the load for a predetermined period, and after the period, the power conversion device is current-controlled to supply a power generation output of the solar cell And a step of resetting the count of the timer.

The present invention also includes a power converter that connects a solar battery and a storage battery to an input, a load that connects to an output, and performs current control operation, a switch that is connected between the solar battery and the storage battery, and the power converter, and a control unit. A control method for a power supply system comprising: starting a count of a timer provided in the control unit; turning the switch off when the timer counts a predetermined time; and the off state Maintaining for a predetermined period;
After the off period has elapsed, the power conversion device is subjected to current control operation to supply a power generation output of a solar cell, and the timer count is reset.

  Since the present invention has the configuration as described above, when the power supply of the load can be completely covered by the power generation output from the solar cell, it is possible to eliminate the power supply from the storage battery and effectively use the power generation output of the solar cell. it can. Furthermore, according to the present invention, the power converter can be controlled easily by performing a current control operation.

(Embodiment 1)
FIG. 1 is a block diagram showing the configuration of the first embodiment.
The system of Embodiment 1 is configured by connecting a solar cell 1 and a storage battery 3 via a diode 2 in parallel to the input of the power converter 4 and connecting a load 5 to the output of the power converter 4. The power conversion device 4 is configured by connecting a DC / DC converter 6 and a DC / AC inverter 7 in series.
In addition, the first embodiment includes a control unit 8, and the control unit 8 includes a timer that counts time. The timer sends a control signal for setting the input voltage of the DC / DC converter 6 to zero every minute for t seconds. The control unit 6 itself issues this control signal, but does not receive a signal from the outside in order to generate this control signal. In the present invention, the timer measures an interval between predetermined times, and the timer does not require a strict time counter side as will be described later. Therefore, the timer measures the time using the clock signal provided in the control unit 6. Good.

The load 5 is connected to the commercial power system 10 and can be driven by power supply from the commercial power system 10 when power supply from the solar cell 1 and the storage battery 3 is not received. Although not shown in FIG. 1, a circuit for charging the storage battery 3 by the commercial power system 10 may be formed. Further, the supply from the AC output of the power conversion device to the load may be branched and connected to the storage battery via an AC / DC inverter to charge the storage battery.
Here, the type of the load 5 is not limited, and when the power supply system of the present invention is installed in a general household, for example, the load 5 is a lighting device such as a light bulb, an air conditioner, a vacuum cleaner, a washing machine, a refrigerator, Electric heating appliances, electromagnetic cookers, televisions, videos, personal computers, etc. When the power supply system is installed in an office, it is a lighting fixture, a personal computer, a copier, a printing machine, a facsimile, or the like. When installed in a store, they are lighting fixtures, showcase lighting, refrigerators, refrigerators, and the like.

  Next, the operation of the first embodiment will be described with reference to FIG. FIG. 2 illustrates a method of driving a load with a solar battery and a storage battery when the power supply of the load can be completely covered by the power generation output from the solar battery. The horizontal axis of FIG. 2 shows the output voltage of the solar cell 1, and the vertical axis shows the output power of the solar cell. At the same time, the horizontal axis shows the voltage of the storage battery.

When the solar cell 1 is operated by the power conversion device 4, the output of the solar cell changes as shown by the curve S in FIG. That is, as the amount of solar radiation increases, the voltage and output power of the output of the solar cell increase almost linearly. And if it exceeds the maximum electric power point D2, the output of a solar cell will fall rapidly and will reach the point E of zero output.
Such a characteristic curve can be obtained by performing a current control operation in which the current supply is increased until the power generation output of the solar cell is balanced with the load amount, instead of performing the maximum power point tracking control operation of the solar cell. it can.

On the other hand, the voltage of the storage battery varies somewhat depending on the state of charge and the power consumption of the load, but the voltage change of the storage battery is usually smaller than the voltage change of the solar battery. In the present invention, it is desirable to set the storage battery voltage in the vicinity of the maximum power point voltage in the amount of solar radiation during cloudy weather.
However, the storage battery voltage needs to be determined according to the solar cell installation area and the power generation output of the solar cell. That is, since the movement of the maximum power point is small in an area where there is a relatively large amount of clear sky or an installation location where a stable amount of solar radiation is obtained, the storage battery voltage is in the vicinity of the maximum power point voltage in a clear sky, for example, 3/4 to 1 It is desirable to set the degree.
In addition, the maximum power point shift is large in areas where seasonal fluctuations, temperature changes, and weather changes are large, so the storage battery voltage is about 1/2 to 3/4 of the maximum power point voltage in order to effectively use the power output of the solar cell. May be set. Or you may make it change corresponding to the seasonal fluctuation | variation of a maximum electric power point. The most preferable method is to calculate the storage battery voltage that maximizes the efficiency of the system based on the annual data of the temperature and solar radiation intensity at the installation location of the system, and set the storage battery voltage.
In this manner, the relationship between the current control operation curve S and the storage battery voltage is set in consideration of the solar cell installation area and weather changes.

Hereinafter, in the first embodiment, the operation will be described with reference to FIG. 2 on the assumption that the open voltage of the solar battery is 300 V, the maximum power point voltage is 250 V, and the storage battery voltage is 200 V. The storage battery may be charged with anything such as system power.
When the initial load is no load, that is, 0 W, the solar cell is operating at point E in FIG. 2, and the solar cell 1 and the storage battery 2 do not supply power to the load 5. Next, when the size of the load 5, that is, the amount of power consumption becomes 400 W, the power supply system of the present invention starts supplying current to the load 5. The operating point of the power feeding system of the present invention at this time is point C2. At this operating point C <b> 2, a current that balances the power consumption of the load 5 is supplied to the output of the solar cell. That is, since the power consumption of the load is 400 W, the supply voltage of the solar cell is 280 V, and power is supplied only from the solar cell 1. On the other hand, the storage battery 2 does not supply power because the output voltage is 200V.
Thus, when the output of the maximum power point D2 of the solar battery is 500 W and the power consumption of the load is 400 W, power is supplied only from the solar battery and not supplied from the storage battery. Such an operation state is continued until the load 5 exceeds the generated power 500 W at the maximum power point of the solar cell 1.

  Next, when the load 5 increases to 700 W, the power conversion device 4 uses the power consumption amount of the load 5 because the solar cell 1 can only consume 500 W even when operating at the maximum power point D2. The current control operation is performed so as to increase the supply current correspondingly. Here, the difference between the power consumption 700 W of the load and the operating point C1 (400 W) of the solar battery at the storage battery voltage is taken out from the storage battery 2 and operates at the point A.

After the operation at the operating point A as described above, when the load 5 decreases and the power consumption becomes 450 W, the solar cell 1 has an operating point B3 (or B2) below the maximum power point D2. However, nevertheless, the operation is performed stably at the operating point B1 which is an extension of the operating point B3 (or B2).
At this operating point B1, extra power 50W is supplied from the storage battery 2. If the power consumption of the load 5 becomes 500 W, the battery 5 operates at the operating point D1 and the storage battery 2 supplies 100 W.
Contrary to the above, the size of the load 5 does not vary, but when the amount of solar radiation decreases and the maximum power point D2 of the power generation output of the solar cell becomes smaller than the load 5, as described above. Since the load 5 cannot be covered even at the maximum power point D2 of the solar battery 1, the power conversion device 4 takes power from the storage battery 2 in an attempt to increase the supply current of the load 5. Then, even when the maximum power point D2 of the solar cell 1 is restored to the size of the load 5 or more and can be covered by the power generation output of the solar cell 1, the size of the load 5 is the operating point C1. When entering between the operating points D1, the power of the storage battery is consumed as in the above description.

Therefore, the present invention periodically sets the power supply amount from the solar cell 1 to the power conversion device 4 to zero, for example, once a minute. As a result, the operating point is moved to point E as shown in FIG.
The interval at which the output power is made zero can be determined by the fluctuation speed of the load 5 and the control speed of the current control operation. For example, when the fluctuation speed of the load 5 is fast, it is necessary to increase the control speed of the current control operation corresponding to the fluctuation speed, and the interval for setting the output power to zero should be about 10 seconds to 2 minutes. . However, when the fluctuation speed of the load 5 is slow, the control speed of the current control operation may be slow, and the interval at which the output power is made zero is preferably about 30 seconds to 3 minutes. Therefore, about 1 minute is preferable.
The duration of zero output power is determined by the capacity of the capacitor G included in the DC / DC converter 6 constituting the power converter 4, and is usually a short time such as 0.001 to 1 second or less. More preferably, it is 0.001 to 0.1 second. However, when the capacitor G has a large capacity, its operating speed can be slowed, and a time of about several seconds may be set.
That is, when the load 5 is a load that reacts slowly to changes in power supply, such as an electric heater, the time until the charge accumulated in the capacitor G is completely discharged can be set. However, in the case of a load such as a personal computer in which power supply is troublesome even for a moment, the setting is made so that the electric charge accumulated in the capacitor G is recovered before it is completely discharged.

  Embodiment 1 is a case where the solar cell 1, the storage battery 2, and the power conversion device 4 are operating independently, and since there is no power supply from the linkage, the solar cell 1 to the power conversion device 4 periodically as described above. When the power supply amount to zero is set to zero, the current control operation is performed so as to increase the supply current from the power conversion device 4 until it balances with the load size. That is, a current control operation is performed to limit the current to a value determined by the magnitude of the load impedance. As a result, the operation is performed at the point B3 which is the intersection with the maximum power point curve.

In the power supply system of the present invention, when the load has a large amount of power consumption, the power conversion device 4 of the present invention is in current control operation, so the storage battery 2 continues to flow a current according to the load, The current withstand value may be exceeded. Therefore, it is desirable to provide an overcurrent control function for safe operation of the system. The overcurrent control function may be provided anywhere between the storage battery 2 and the load 5. For example, the DC / DC converter 6 and the DC / AC inverter 7 constituting the power converter 4 may be provided with a current limiting resistor. A good overcurrent control function should be connected.
As described above, when the output power of the power conversion device 4 is set to zero for a short time at a predetermined time interval, when the load exceeds the maximum power point of the solar cell and again falls below the maximum power point, an excess from the storage battery 2 is obtained. An event that operates at the operating point B1 that supplies power can be prevented, and the current control operation that operates at the operating point B3 can be changed. Thereby, electric power can be supplied to a load by the power generation output of a solar cell, without consuming the electric power of a storage battery.

  As shown in FIG. 3, the DC / DC converter 6 includes a capacitor C. For this reason, the electric charge stored in the capacitor G is supplied to the load 5 until the output power of the DC / DC converter 6 becomes zero as described above for a short time until the power supply from the DC / DC converter 6 is started again. Therefore, an instantaneous power supply stop to the load 5 is eliminated and continuous power supply is enabled. Generally, a capacitor G having a capacitance value corresponding to the power capacity of the DC / DC converter 6 and the power consumption of the load is used, so that continuous power supply to the load 5 is possible.

After the output power of the DC / DC converter 6 is reduced to zero for a short time, the time t (s) until the total output of the solar cell and storage battery and the load amount are balanced is the time of the capacitor G built in the DC / DC converter 6. When the capacity Q (Wh) and the rated load amount are X (W),
t ≦ 3600Q / X
It is desirable to satisfy.

  A circuit diagram of the DC / DC converter 6 is shown in FIG. The circuit diagram shown in FIG. 3 is a general boost chopper circuit, and the DC / DC converter 6 of the present invention can use all circuits that perform a boost chopper type operation. The capacitor G indicates a capacitor G connected to the output end as shown in FIG.

FIG. 6 shows a flowchart of this embodiment.
As shown in FIG. 6, when the power generation system of the present invention causes the power generation output of the solar cell 1 to be current controlled by the power conversion device 4 and starts operating in a state where power is supplied to the load 5, step S <b> 1 is performed. Thus, a timer provided in the control unit 8 starts counting. If it is determined in step S2 that the timer has not passed 1 minute, the DC / DC converter 6 supplies power according to the size of the load 5 in step S3. If the timer has passed 1 minute in step S2, the process proceeds to step S4, and the DC / DC converter 6 sets the output power to zero. The time for setting the output power to zero is counted in step S5, for example, for t seconds. After t seconds, the DC / DC converter 6 supplies power corresponding to the load 5 in step S6. In step S7, the timer count is reset, and the process returns to the first step S1.

As shown in the flowchart of FIG. 6, according to the present invention, the DC / DC converter 6 supplies power by performing current control according to the size of the load 5, but when the timer counts 1 minute, t seconds The output power of the DC / DC converter 6 becomes zero, and then a current control operation is performed to limit the current according to the size of the load 5.
In the first embodiment, the operation of the DC / DC converter 6 may be stopped in order to zero the power supply from the solar cell 1 to the power converter 4 every predetermined time.
In the first embodiment, the power supply from the solar cell 1 to the power conversion device 4 is zeroed every predetermined time. However, it is not always necessary to zero, for example, after the power consumption of the load 5 increases, When it falls, it may be any one from the operating point C1 or less shown in FIG. Further, the power at the point C1 with respect to the power at the point D2 does not fall below 50% except during extremely low solar radiation. Therefore, the power supply from the solar cell 1 to the power conversion device 4 may be 50% of the point D2 every predetermined time. By doing so, the capacity of the capacitor can be reduced, the size of the system can be reduced, and the cost can be reduced. Thus, in order to make it any one from C1 or less to zero, it can achieve by adjusting the internal impedance of the power converter device 4.

The above explanation is a case where the solar cell to the load are operating in a self-supporting manner. However, in the case of the linkage type in which the power can be supplied from the commercial AC power source to the load, the power conversion device is as long as the storage battery is allowed. Since the electric charge is discharged, if the operation of the present invention is to be performed in the case of the linkage type, it is necessary to stop the discharge of the storage battery at a constant value.
As described above, the power feeding system of the present invention can be implemented by setting the output power amount of the solar battery and the output voltage value of the storage battery as in the present invention and performing the current control operation of the power conversion device 4. In addition, complicated control such as maximum power point tracking control is unnecessary, and the control unit 8 only needs to zero the power supply from the solar cell 1 to the power conversion device 4 every predetermined time. The configuration is simple.

(Embodiment 2)
FIG. 4 is a block diagram showing the configuration of the second embodiment.
A second embodiment will be described with reference to FIG. In this system, a solar cell 1 and a storage battery 2 via a diode 3 are connected in parallel to the input of the power conversion device 4, and a DC load 5 is connected to the output of the power conversion device 4. In the second embodiment, the power conversion device 4 is configured by only the DC / DC converter 9.
Other configurations are the same as those of the first embodiment, and the flowchart of FIG. 6 is executed.

(Embodiment 3)
FIG. 5 is a block diagram showing the configuration of the third embodiment.
The third embodiment will be described with reference to FIG. This system is characterized in that a switch 10 is connected between a connection point between the solar cell 1 and the storage battery 2 and an input of the power conversion device 4. The rest is the same as in the first embodiment.
The operation of the third embodiment will be described. In the first embodiment, the output power of the DC / DC converter 6 is set to either zero or less than the magnitude of the reduced load every predetermined time. Then, the switch 10 is turned off every predetermined time for t seconds. The rest is the same as in the first embodiment.

(Embodiment 4)
In the first to third embodiments, the power supply from the solar cell 1 to the power conversion device 4 is periodically changed from one below the power consumption amount of the load 5 to zero, or connected to the input of the power conversion device 4 The switch was to be turned off. The fourth embodiment does not perform a regular operation, but monitors the output power amount of the solar cell and the power consumption amount of the load, and performs the operation of the present invention corresponding to the fluctuations.
Therefore, the fourth embodiment includes a voltmeter or a wattmeter that measures the output power of the solar cell 1, and an ammeter or wattmeter that detects a change in the load 5. Other configurations are the same as those shown in FIG. 1, FIG. 4 or FIG.
In the fourth embodiment, the control unit 8 monitors whether the output power of the solar cell 1 is larger than the load power amount, and determines whether the operating point is on the maximum power point curve. While this state is maintained, the control unit does not change the control. However, if the load 5 increases and sufficient power cannot be supplied to the load 5 even if the load 5 is operated at the maximum power point D2 of the solar battery 1, power is supplied from the storage battery 2. The power supply control from the storage battery 2 is naturally performed by the output voltage of the solar battery 1 and the output voltage of the storage battery 2 without special control by the control unit 8.

  Next, when the load 5 drops below the maximum output power of the solar cell 1, an ammeter or wattmeter provided in the load 5 detects this. When the control unit 8 receives this detection output, the power supply from the solar cell 1 to the power conversion device 4 is changed from the power consumption amount of the load 5 to zero or the switch is turned off. When the load is zero or the switch is turned off, the operating point moves to point E on the maximum power point curve. After maintaining point E for a predetermined time, the control unit 8 restores the output of the power conversion device 4 or turns on the switch. As a result, a current control operation in which the current is limited by the impedance of the load can be performed and operated on the maximum power point curve.

1 is a block diagram illustrating a configuration of a first embodiment. It is a figure explaining operation | movement of this invention. It is a circuit diagram of a DC / DC converter. 6 is a block diagram showing a configuration of Embodiment 2. FIG. 10 is a block diagram showing a configuration of Embodiment 3. FIG. 3 is a flowchart of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Solar cell 2 Storage battery 4 Power converter 5 Load 8 Control part 10 Commercial power system

Claims (6)

A power converter that connects a solar battery and a storage battery to the input, connects a load to the output, and performs current control operation;
A power supply system comprising: a control unit configured to set power supply from the solar cell to the power conversion device at any predetermined time from zero to less than the power consumption amount of the load. When the power consumption of the load becomes equal to or higher than the maximum power point of the solar cell and then becomes equal to or lower than the maximum power point again, the control unit causes the power conversion device from the solar cell to perform current control operation. 2. The power supply system according to claim 1, wherein power supply to the power supply is set to any one of a power consumption amount of the load and less than zero every predetermined time. A power converter that connects a solar cell and a storage battery to the input, connects a load to the output, and performs current control operation; and
A switch connected between the solar cell and the storage battery and a power converter;
And a controller that periodically turns off the switch.   The power supply system according to claim 1, wherein the power conversion device is configured by a DC / DC converter including a capacitor. A power conversion device that connects a solar battery and a storage battery to an input, connects a load to an output, and performs current control operation, and a control method of a power feeding system including a control unit,
Starting a count of a timer provided in the control unit;
When the timer counts a predetermined time, the power supply from the solar cell to the power conversion device is set to any one of zero or less power consumption of the load;
Maintaining a period of time from zero power consumption of the load to zero to a predetermined period;
After the period, the power conversion device is current-controlled to supply a power generation output of a solar cell;
Resetting the count of the timer. A power conversion device including a solar battery and a storage battery connected to an input, a load connected to an output, a current control operation, a switch connected between the solar battery and the storage battery and the power conversion device, and a control unit. A control method,
Starting a count of a timer provided in the control unit;
Turning the switch off when the timer counts a predetermined time; and
Maintaining the off state for a predetermined period;
After the off period has elapsed, the power conversion device is current-controlled to supply a power generation output of a solar cell;
Resetting the count of the timer.

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