JP3910725B2 - Power system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power supply system including a solar cell and a power storage device.
[0002]
[Prior art]
There is a power supply system that includes a solar cell and a power storage device, and reduces the burden on the commercial power supply by supplying the generated power of the solar cell or the stored power of the power storage device to a load. The power storage device is provided to cope with a change in the generated power of the solar cell depending on the amount of solar radiation.
[0003]
In this power supply system, for example, the generated power of the solar cell is supplied to the load during peak load power during the daytime when the amount of power used increases. That is, the peak load power is covered by the power generated by the solar cell, and the power consumption from the commercial AC power supply is reduced accordingly. This is a so-called peak cut. Then, the power storage device is charged with the generated power (surplus power) during off-peak hours when the load's power consumption is low, and the amount of solar radiation is so small that the generated power cannot be obtained from the solar cell. Discharging the power storage device at the time of power shortage, nighttime, power failure, etc. enables continuous operation of the load.
[0004]
The power storage device charges the built-in secondary battery with the generated power (DC voltage) of the solar battery, and converts the charging voltage of the secondary battery into an AC voltage with a bidirectional power converter when discharging. The timing of charging and discharging is set in advance as an operation pattern in consideration of the characteristics of the solar cell.
[0005]
Examples of the load include an air conditioner including a rectifier unit that rectifies the voltage of a commercial AC power source, and an inverter unit that converts the output voltage of the rectifier unit into an AC voltage having a predetermined frequency by turning on and off the switching element. is there. By controlling the output frequency of the inverter unit, variable capacity operation of the compressor is possible.
[0006]
[Problems to be solved by the invention]
In the case where the power storage device is charged / discharged in a preset operation pattern as described above, when an unpredictable peak load power is generated, the load power usage may exceed the contract power.
[0007]
In addition, the power storage device has a problem that power loss occurs when the discharge voltage (DC voltage) is converted to AC voltage.
In an air conditioner that is a load, there is a problem that a large power loss occurs due to conversion from AC voltage to DC voltage (rectification of the rectifier unit) and conversion from DC voltage to AC voltage (switching of the inverter unit). is there.
[0009]
The present invention takes the above circumstances into consideration, and even when an unpredictable peak load power is generated, the operation of the load can be continued without exceeding the contract power, thereby enabling an efficient peak cut. Furthermore, it is an object of the present invention to provide a power supply system with excellent energy saving that can reduce power loss.
[0013]
[Means for Solving the Problems]
The power supply system of the present invention includes an AC power supply line that supplies a voltage of a commercial AC power supply to a rectifier of a load, a solar battery that converts light energy into electric power, and a power generated by the solar battery that is converted into a DC voltage of a predetermined level. Converting means, a DC power supply line for supplying the output voltage of the converting means to the output side of the rectifying means in the load, a power storage device for charging and discharging the DC voltage, and an output voltage of the converting means. Charging means for charging the power storage device; a DC power supply line for supplying the discharge voltage of the power storage device to the output side of the rectifying means in the load; and detection means for detecting the power usage of the load; Control means for controlling voltage supply from the converting means to the output side of the rectifying means or discharging of the power storage device according to the detection result of the detecting means. In particular, the control means reduces the output voltage of the rectifying means when the detection result of the detecting means exceeds a set value in a situation where generated power exceeding a predetermined value is obtained from the solar cell, and the voltage from the converting means to the output side of the rectifying means If the detection result of the detection means exceeds the set value in a situation where the power generated is not obtained from the solar cell and the power storage device is discharged, the output voltage of the rectification means is reduced.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, a load circuit 20 and a load 30 are connected to a commercial AC power supply 1 via an AC power supply line 2, and load power detection means 3 is provided on the AC power supply line 2.
[0015]
The load circuit 20 includes a rectifier unit (rectifier unit) 21 that rectifies the AC voltage of the power supply 1, and an inverter unit (INV unit) 22 that converts an output voltage (DC voltage) of the rectifier unit 21 into an AC voltage having a predetermined frequency by switching. The compressor 23 is driven by the output of the inverter unit 22.
[0016]
The load power detection unit 3 detects the power usage of the load circuit 20 and the load 30.
On the other hand, the solar cell 4 converts sunlight energy into DC power. The electric power generated by the solar cell 4 is supplied to the DC / DC converter 5. The DC / DC converter 5 is a conversion means for converting the electric power generated by the solar cell 4 into a DC voltage of a predetermined level. Specifically, the DC / DC converter 5 once converts the DC voltage supplied from the solar cell 4 into an AC voltage, and the AC The voltage is stepped up (or stepped down) with a transformer and rectified to output a DC voltage of a predetermined level.
[0017]
The output voltage (DC voltage) of the DC / DC converter 5 is supplied to the output side of the rectifier unit 21 in the load circuit 20 via the DC power supply line 6. The DC power supply line 6 is provided with diodes 7 and 8 as backflow prevention means for preventing a backflow of current from the output end of the rectifier unit 21 to the DC / DC converter 5 side.
[0018]
The charger 9 is connected to the output terminal of the DC / DC converter 5, and the power storage device 10 is connected to the output terminal of the charger 9 via the charging line 21. The charger 9 charges the power storage device 10 with the output voltage of the DC / DC converter 5.
[0019]
The power storage device 10 includes a secondary battery capable of charging and discharging a DC voltage. The discharge voltage (DC voltage) of the power storage device 10 is supplied between the connection of the diode 7 and the diode 8 in the DC power supply line 6 through the discharge line 12. That is, the DC power supply line 6 is used both for supplying a voltage from the DC / DC converter 5 to the load circuit 20 and supplying a discharge voltage from the power storage device 10 to the load circuit 20.
[0020]
Reference numeral 40 denotes a control unit that comprehensively controls the power system. The control unit 40 is connected to the load power detection means 3, the DC / DC converter 5, the charger 9, the power storage device 10, and the rectifier unit 21.
[0021]
And the control part 40 is provided with following [1]-[4] as main functional means.
[1] Monitoring means for monitoring the output voltage of the DC / DC converter 5 corresponding to the generated power of the solar cell 4 and the amount of stored power (charge voltage level) of the power storage device 10.
[0022]
[2] Control means for operating the charger 9 to charge the power storage device 7 during off-peak load power.
[3] In a situation where a predetermined amount or more of generated power is obtained from the solar cell 4 (based on the monitoring by the monitoring unit), the DC / DC converter 5 determines whether or not the load power detection unit 3 detects the result (power consumption). Control means for controlling voltage supply to the output side of the rectifier unit 21. Specifically, when the detection result of the load power detection means 3 exceeds the set value, the voltage is supplied from the DC / DC converter 5 to the output side of the rectifier unit 21 by reducing the output voltage of the rectifier unit 21.
[0023]
[4] In a situation where generated electric power of a predetermined level or more cannot be obtained from the solar cell 4 (based on the monitoring of the monitoring unit), the power storage device 10 is configured according to the detection result (power consumption) of the load power detection unit 3. Control means for controlling discharge. Specifically, when the detection result of the load power detection means 3 exceeds the set value, the power storage device 10 is discharged by reducing the output voltage of the rectifier unit 21.
[0024]
Next, the operation of the above configuration will be described.
The AC voltage of the commercial AC power supply 1 is supplied to the load circuit 20 and the load 30 via the AC power supply line 2. Thereby, the operation of the load circuit 20 or the load 30 is executed.
[0025]
During this operation, the power consumption of the load circuit 20 or the load 30 is detected by the load power detection means 3, and the detection result is compared with a predetermined set value.
If the power consumption is less than or equal to the set value, the output voltage of the rectifier unit 21 is allowed as it is, and the load operation using only the output voltage is continued. The power storage device 10 does not discharge. Moreover, the electric power storage apparatus 10 is charged with the electric power generated by the solar cell 4 as surplus electric power.
[0026]
When the power consumption of the load circuit 20 or the load 30 increases and exceeds the set value (when peak power is loaded), the output voltage of the rectifier unit 11 is reduced.
In this case, if more than a predetermined power is generated from the solar cell 4, the output voltage of the rectifier unit 21 is reduced and the output voltage of the DC / DC converter 5 is supplied to the load circuit 20 through the DC power supply line 6. It is supplied to the inverter unit 22. That is, the peak load power is covered by the generated power of the solar cell 4, and the power consumption from the commercial AC power supply 1 is suppressed by that amount. This is a so-called peak cut.
[0027]
In this case, the output voltage of the rectifier unit 21 is reduced because the output voltage of the DC / DC converter 5 is low unless the electric power exceeding the predetermined level is generated from the solar cell 4 due to a small amount of solar radiation. Accordingly, the charging voltage (DC voltage) of the power storage device 10 is supplied to the inverter unit 22 of the load circuit 20 through the DC power supply line 6. That is, the peak load power is covered by the discharge of the power storage device 10.
[0028]
Thereafter, when the power consumption is reduced to a set value or less, the output voltage of the rectifier unit 21 is increased to a steady value, and the power supply from the solar cell 4 or the discharge of the power storage device 10 is stopped.
[0029]
In this way, when the power usage is below the set value, the load is operated only by the commercial AC power supply 1, and when the power usage exceeds the set value, the power supply from the solar cell 4 or the discharge of the power storage device 10 is performed. The load circuit 20 and the load 30 do not exceed the contract power with the electric power company even when unpredictable peak load power is generated by operating the load with the power supply or discharge and the commercial AC power supply 1. Can continue driving. That is, efficient peak cut can be performed.
[0030]
Moreover, since the power storage device 10 has a simple configuration in which the charging voltage (DC voltage) is discharged as it is when it is necessary, the power loss is lower than that in the conventional case where conversion from DC voltage to AC voltage is performed during discharging. Can be reduced.
[0031]
Further, when the power storage device 10 is discharged, the discharge voltage (DC voltage) is directly supplied to the inverter unit 22 of the load circuit 20 without passing through the rectifier unit 21, so that the power loss in the load circuit 20 is reduced. Decrease.
[0032]
The power loss is reduced, and more efficient peak cut is possible as described above, thereby obtaining an energy saving effect.
In addition, in the said Example, it is good also as a structure which provides the detection means which detects the power failure of the commercial alternating current power supply 1, and discharges the electric power storage apparatus 10 at the time of a power failure.
In addition, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the scope of the invention.
[0034]
【The invention's effect】
As described above, the power supply system of the present invention can continue the operation of the load without exceeding the contract power even when an unpredictable peak load power occurs, thereby enabling an efficient peak cut. In addition, it is excellent in energy saving that can reduce power loss.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Commercial AC power supply 2 ... AC power supply line 3 ... Load electric power detection means 4 ... Solar cell 5 ... DC / DC converter (conversion means)
6 ... DC power supply line 7, 8 ... Diode (backflow prevention means)
DESCRIPTION OF SYMBOLS 9 ... Charger 10 ... Power storage device 11 ... Charge line 12 ... Discharge line 20 ... Load circuit 21 ... Rectifier part (rectifier means)
22 ... Inverter unit 23 ... Compressor 40 ... Control unit

Claims (1)

An AC power line for supplying the voltage of the commercial AC power source to the rectifying means of the load;
A solar cell that converts light energy into electric power;
Conversion means for converting the generated power of the solar cell into a DC voltage of a predetermined level;
A DC power supply line for supplying the output voltage of the converting means to the output side of the rectifying means in the load;
A power storage device for charging and discharging a DC voltage;
Charging means for charging the power storage device with the output voltage of the conversion means;
DC power supply line for supplying the discharge voltage of the power storage device to the output side of the rectifying means in the load;
Detecting means for detecting the power consumption of the load;
Control means for controlling the voltage supply from the conversion means to the output side of the rectification means or the discharge of the power storage device according to the detection result of the detection means;
Comprising
The control means reduces the output voltage of the rectifying means and outputs the output of the rectifying means from the converting means when the detection result of the detecting means exceeds a set value in a situation where the generated electric power of a predetermined value or more is obtained from the solar cell. When the detection result of the detection means exceeds a set value in a situation where a predetermined amount of generated power cannot be obtained from the solar cell, the output voltage of the rectification means is reduced and the power storage device is A power supply system characterized by discharging.

Images