JPH06245392A - Converter for regulating power system energy - Google Patents

Abstract

PURPOSE:To simplify a circuit by stepping down an output of an inverter by a voltage step up/down chopper, charging to a predetermined voltage at the time of initial charging of a zinc-bromine battery, and using the inverter at the time of main charging/discharging, stepping up a battery voltage by chopper to OV in the case of complete discharging, and reversely connecting the chopper to the battery at the time of reverse charging. CONSTITUTION:At the time of initial charging a zinc-bromine battery 1, a power system is transformed by a transformer 17 through a filter 18, and DC is output from an inverter 16. A DC voltage is stepped down by a step up/down chopper 16, and the battery is charged to a predetermined voltage. At the time of main charging/discharging, switches 10, SWN are closed. At the time of complete discharging, the switch 10 is opened, switches SW1-SWN of the copper 12 are closed, and residual energy of the battery is returned to DC of the inverter 16. At the time of reverse charging, the switches SW1, SWN are opened, SW2, SW3 are closed, and the battery 1 is charged to a predetermined negative voltage. Thus, it can be manufactured with a small size and a low cost with a simple circuit configuration.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power system energy adjusting converter that uses a zinc-bromine battery, a power system, and a power converter to perform power storage and reactive power compensation control.

[0002]

2. Description of the Related Art When using a zinc-bromine battery, it is necessary to discharge it periodically and apply a reverse voltage to a predetermined value in order to remove the dendrite accumulated on its electrode. For this reason, when a voltage type converter is used to link with a power system, a current type converter is used for initial charging and complete discharge.

FIG. 5 shows the configuration of a conventional converter for adjusting the energy of a power system, where 1 is a zinc-bromine battery, 2 and 3 are changeover switches, 4 is a capacitor, 5 is a reactor, 6 is a voltage source inverter, and 7 is. Current source inverters 8 and 9 are transformers.

Next, the operation of the above conventional device will be described with reference to the time chart of FIG. First, in the initial charging period (T ₀ -T ₁ ), the changeover switch 2 is turned off and the changeover switch 3 is turned on, and the battery 1 is charged to a voltage V ₁ by a constant current by the operation of the current source inverter 7. next,
During the main charge / discharge period (T ₁ -T ₂ ), the changeover switch 2
Is turned on, the current source inverter 6 is stopped, and the battery 1 is charged and discharged by the voltage source inverter 7. Next, during the complete discharge and reverse charging period (T ₂ −T ₃ ), the changeover switch 2 is turned off, the current source inverter 7 is operated to discharge the battery 1 to 0 V by a constant current, and further the predetermined reverse voltage V Charge up to ₂ .

[0005]

In the above-mentioned conventional apparatus, the main charge / discharge is performed by the voltage source inverter 6, and the constituent elements of the voltage source inverter 6 must be self-extinguishing elements of reverse conduction. Since the element which conducts in the opposite direction is used as described above, the direct current voltage cannot be less than the value obtained by rectifying the alternating current input voltage. Therefore, when the battery 1 is initially charged and completely discharged, it is necessary to use the current source inverter 7 capable of controlling the DC voltage regardless of the AC input voltage, resulting in a complicated and large-sized configuration and high cost. became.

The present invention has been made to solve the above problems, and an object thereof is to obtain a small-sized and inexpensive power system energy adjusting converter.

[0007]

A power system energy adjusting converter according to claim 1 of the present invention converts an AC voltage from a power system into a DC voltage and converts a DC voltage from a battery side into an AC voltage. An inverter that converts, and a buck-boost chopper that boosts or lowers the output of the inverter or battery,
Connect the main switch that connects the inverter to the battery during main charging and discharging of the battery, the battery and buck-boost chopper during initial charging and full discharge of the battery, and reverse the connection between the battery and buck-boost chopper during reverse charging of the battery. It is provided with a polarity changeover switch for changing the polarity.

According to a second aspect of the present invention, there is provided a power system energy adjusting converter in which the inverter, the step-up / step-down chopper and the main switch are connected to the battery and the step-up / step-down chopper at the time of initial charge and complete discharge of the battery. An auxiliary switch, a reverse charging circuit that converts the AC voltage from the power system into a DC voltage to reverse charge the battery, and a second auxiliary switch that connects the battery and the reverse charging circuit when the battery is reverse charged are provided. It is a thing.

A power system energy adjusting converter according to a third aspect of the present invention is connected between the above-mentioned inverter and main switch, and between the inverter and the battery, and varies the output of the inverter or the battery, and at the time of reverse charging of the battery. The charging / discharging device reversely charges the battery, and the third auxiliary switch which connects the battery and the inverter at the time of main charging / discharging, initial charging and complete discharging of the battery.

[0010]

According to the first aspect of the present invention, the output of the inverter is stepped down by the step-up / step-down chopper and applied to the battery during the initial charging, and the battery is charged to V ₁ . At the time of main charge / discharge, the battery is charged / discharged by the inverter, and at the time of complete discharge, the output of the battery is boosted by the step-up / step-down chopper and applied to the inverter, and the battery becomes 0V. At the time of reverse charging, the connection between the battery and the buck-boost chopper is switched to the reverse polarity, and the battery is reversely charged to V ₂ .

The second aspect differs from the first aspect only in the reverse charging. In the reverse charging, the reverse charging circuit converts the AC voltage from the power system into a DC voltage, and the DC voltage reversely charges the battery.

In the third aspect, the output of the inverter is adjusted by the charger / discharger and applied to the battery at the time of initial charging, and the battery is charged to V ₁ . Main charging / discharging is performed by the inverter, and at the time of complete discharging, the output of the battery is adjusted by the charging / discharging device and applied to the inverter, so that the battery becomes 0V. In addition, reverse charging is performed by the charger / discharger.

[0013]

Embodiment 1 An embodiment of the present invention will be described below with reference to the drawings. Figure 1
Shows the configuration of the power system energy adjusting converter according to the first embodiment, 10 is a main switch, 11 is a switch SW ₁ -S
A polarity changeover switch composed of W ₃ and SWN, 12 is a step-up / down chopper composed of choppers 13 and 14 and a reactor 15, 16 is a voltage source inverter, 17 is a matching transformer, and 18 is an AC filter.

Next, the operation of the above device will be described. First,
In the initial charging, the switches SW ₁ and SWN are turned on. At this time, the AC voltage from the power system is input to the inverter 16 via the AC filter 18 and the matching transformer 17. The inverter 16 operates as a simple rectifier by turning off the self-extinguishing element, the DC voltage from the inverter 16 is stepped down by the chopper 13, and a constant current flows to the battery 1 via the reactor 15 and the switch SW ₁ , and the battery 1 starts from 0V. It is charged to a predetermined voltage V ₁ . Next, in the main charge / discharge period, the main switch 10 is turned on, the chopper 13 is stopped, frequency control and voltage control are performed by the inverter 16, and energy from the power system is supplied to the battery 1 to charge the battery 1. In addition, the direction of the current of the inverter 16 is reversed and the battery 1 is discharged.

Next, during the complete discharge period, the main switch 10 is turned off, and the residual energy of the battery 1 is returned to the DC side of the inverter 16 by the boost control function of the chopper 14.
At this time, the inverter 16 controls the DC voltage to be constant and discharges the electric power to the voltage system side. As a result, the voltage of the battery 1 becomes 0V. Next, in the reverse charging period, the switches SW ₁ and SWN are turned off and the switches SW ₂ and SW ₃ are turned on so that the voltage of the chopper 13 is applied to the battery 1 in the reverse direction. Charge to a predetermined negative voltage V ₂ .

In the first embodiment, one inverter 1
The same function as the conventional one is exhibited by using 6, and one inverter and its transformer can be eliminated,
Can be small and inexpensive.

Embodiment 2 FIG. 2 shows the construction of a power system energy adjusting converter according to Embodiment 2, 19 is a reverse charging circuit, 20 is a transformer, 21 is a rectifier, 22 is a current limiting resistor, and 23 is a first. 2 is an auxiliary switch, and 24 is a first auxiliary switch. Other configurations are similar to those of the first embodiment.

Next, the operation of the second embodiment will be described. First,
At the time of initial charging, the first auxiliary switch 24 is turned on. At this time, the AC voltage from the electric power system is input to the inverter 16 via the matching transformer 17, the inverter 16 functions as a rectifier, and the DC voltage from the inverter 16 is stepped down by the chopper 13 and the reactor 15 and the first auxiliary. A constant current flows in the battery 1 via the switch 24, and the battery 1 is charged from 0V to a predetermined voltage V ₁ .

Next, the main switch 10 is turned on to perform main charging / discharging, and then the main switch 10 is turned off to completely discharge the battery 1, as in the first embodiment.

During the reverse charging period after the voltage of the battery 1 becomes 0 V, the first auxiliary switch 24 is turned off to stop the step-up / down chopper 12 and the second auxiliary switch 23 is turned on. Then, the reverse charging circuit 19 is connected to the battery 1. As a result, the AC voltage from the power system is rectified by the rectifier 21 via the transformer 20 and the current limiting resistor 22 is applied to the battery 1.
A direct current flows through the battery 1, and the battery 1 is reversely charged to a predetermined negative voltage V ₂ .

In the second embodiment, the voltage source inverter 16, the transformer 17, the step-up / down chopper 12, the reverse charging circuit 19 and the switches 10, 23 and 24 are used. The reverse charging circuit 19 is the conventional current source inverter 7. compared to need only pass a current only in one direction opposite charge, becomes the voltage control range the conventional V ₁ + V ₂ V ₂ only 1 / 15-1 / 2
When it becomes 750V class, it becomes as narrow as 0,
The capacity may be about 1/15 to 1/20. Further, the current flowing through the reverse charging circuit 19 becomes about 1/100 to 1/200 of the main current, and the capacity of the second auxiliary switch 23 may be small. Therefore, a compact and inexpensive device as a whole can be obtained.

Third Embodiment FIG. 3 shows a reverse charging circuit according to a third embodiment.
0, a second auxiliary switch 23, a current source inverter 32, and a reactor 33. Also in this case, the capacity of the current source inverter 32 and the second auxiliary switch 23 may be small, and the size and cost can be reduced.

Fourth Embodiment FIG. 4 shows the configuration of a power system energy adjusting converter according to a fourth embodiment. Reference numeral 25 is a charger / discharger, which is semiconductor switches 26 to 28 of reverse conduction, a diode 29, and a reactor 30.
It consists of Reference numeral 31 is a third auxiliary switch.

Next, the operation of the fourth embodiment will be described. First,
At the time of initial charging, the main switch 10 is turned off and the third
The auxiliary switch 31 is turned on. At this time, the charger / discharger 2
ON / OFF of the semiconductor switch 26 of 5 and the semiconductor switch 2
Voltage source inverter with 7 flywheel diode action 1
The DC voltage output from 6 is changed to set the voltage of battery 1 to 0.
Charge from V to a predetermined voltage V ₁ . Inverter 16 acts simply as a rectifier. Next, during the main charge / discharge of the battery 1, the main switch 10 is turned on to stop the operation of the charge / discharge device 25, and the battery 1 is charged / discharged by the frequency control and the voltage control of the inverter 16.

Next, when the battery 1 is completely discharged, the main switch 10 is turned off, and the output voltage of the battery 1 is controlled by the on / off operation of the semiconductor switch 27 and the flywheel diode operation of the semiconductor switch 26. Is discharged to 0V. At this time, the inverter 16 performs control such that the DC voltage is constant, and discharges power to the power system side. Next, when the battery 1 is reversely charged, the third auxiliary switch 31 is turned off, the on / off operation of the semiconductor switches 27 and 28, the flywheel diode action of the semiconductor switch 26, and the action of the diode 29 cause the output of the inverter 16. The voltage is controlled and the battery 1 is reversely charged to a predetermined negative voltage V ₂ .

In the fourth embodiment, the voltage source inverter 16, the charger / discharger 25, and the switches 10 and 31 are used, and the conventional current source inverter 7 and transformer 9 are no longer required.
Can be small and inexpensive.

Although the voltage source inverter 16 is used in each of the above embodiments, a current source inverter may be used instead.

[0028]

As described above, according to claim 1 of the present invention, a single inverter and a step-up / down chopper are used to perform the same function as the conventional one, and one inverter and its transformer are provided. It can be omitted, and it can be made small and inexpensive.

According to a second aspect of the present invention, the inverter, the step-up / down chopper, the reverse charging circuit, and the switch are included. Particularly, in the reverse charging circuit, the current and voltage control range is narrow and the capacity may be small. Since the capacity of the switch can be small, it can be made small and inexpensive.

Further, according to the third aspect of the present invention, the inverter and the charger / discharger are used, and the inverter and its transformer can be omitted for one unit, and the size and cost can be reduced.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a power system energy adjusting converter according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a power system energy adjusting converter according to a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a reverse charging circuit according to a third embodiment of the present invention.

FIG. 4 is a configuration diagram of a power system energy adjusting converter according to a fourth embodiment of the present invention.

FIG. 5 is a configuration diagram of a conventional power system energy adjusting converter.

FIG. 6 is a time chart showing the operation of a conventional power system energy adjusting converter.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Zinc-bromine battery 10 ... Main switch 11 ... Polarity changeover switch 12 ... Buck-boost chopper 16 ... Voltage source inverter 19 ... Reverse charging circuit 23, 24, 31 ... Auxiliary switch 25 ... Charge / discharge device

Claims (3)

[Claims] 1. A zinc-bromine battery, an inverter for converting an AC voltage from a power system into a DC voltage when the battery is charged, and an inverter for converting a DC voltage from the battery side into an AC voltage when the battery is discharged, an inverter or A buck-boost chopper that boosts and lowers the output of the battery, a main switch that connects the inverter and the battery when the battery is mainly charged and discharged, and stops the buck-boost chopper, and a battery and the buck-boost chopper when the battery is initially charged and fully discharged. And a polarity changeover switch for connecting the battery and the buck-boost chopper in reverse polarity when the battery is reversely charged. 2. A zinc-bromine battery, an inverter that converts an AC voltage from a power system into a DC voltage when the battery is charged, and an inverter that converts a DC voltage from the battery side into an AC voltage when the battery is discharged, an inverter, or A buck-boost chopper that boosts and lowers the output of the battery, a main switch that connects the inverter and the battery when the battery is mainly charged and discharged, and stops the buck-boost chopper, and a battery and the buck-boost chopper when the battery is initially charged and fully discharged. A first auxiliary switch that connects the battery, a reverse charging circuit that reversely charges the battery by converting an AC voltage from the power system into a DC voltage, and a second charging circuit that connects the battery and the reverse charging circuit when the battery is reversely charged. A power system energy adjustment conversion device comprising an auxiliary switch. 3. A zinc-bromine battery, an inverter that converts an AC voltage from a power system into a DC voltage when the battery is charged, and an inverter that converts a DC voltage from the battery side into an AC voltage when the battery is discharged, and an inverter. Connected between the batteries to change the output of the inverter or the battery, and to connect the inverter and the battery during the main charging of the battery and the charger / discharger that reverse-charges the battery during the reverse charging of the battery and to operate the charger / discharger. A third switch that connects the inverter with the main switch to be stopped and the main charge / discharge of the battery, the initial charge and the complete discharge
A converter for adjusting power system energy, comprising the auxiliary switch.