JPH09121561A - Method of treating regenerative energy of inverter and regenerative energy treating apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To treat the regenerative energy of an inverter without increasing the cost of whole inverter equipment by a method wherein the regenerative energy is consumed by the switching loss of a switching device. SOLUTION: A voltage/frequency converter 17 which monitors the DC voltage E of an inverter 1 and, when the DC voltage E is excessively elevated by a regenerative energy, increases the switching frequency of the inverter 1 is added to the switching controller 7 of the inverter 1. The lower limit and upper limit of the detected DC voltage E are defined by a limiter circuit 16 and, if the DC voltage E is in a normal range, the inverter 1 is operated with a normal switching frequency and, if the DC voltage E is excessively elevated over the normal range by the regenerative energy, the switching frequency of the inverter 1 is increased in accordance with the elevated value and a switching loss in the inverter 1 is increased. The regenerative energy can be consumed by the switching loss.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for processing regenerative energy in an inverter that converts a rated DC voltage into an AC voltage and outputs the AC voltage to a load or the like.

[0002]

2. Description of the Related Art A self-excited var compensator (VSVC), a variable voltage variable frequency power supply (VVVF), a pulse width modulation (PWM) type inverter used in a grid interconnection system of a photovoltaic power generation system, etc. By turning on / off each of the plurality of bridge-connected switching elements at a predetermined switching frequency, the DC power from the DC power supply unit is converted into AC power and supplied to a load such as a motor or a system power supply. Depending on the load that receives power supply from the inverter and the conditions on the system side, regenerative energy (electric power) may flow into the inverter from the side that receives the power, and the DC power supply unit of the inverter may enter an overvoltage state.

For example, when the load supplied with electric power by the inverter is a motor, when the operating mode of the motor shifts from the power running mode to the regenerative mode, the motor load becomes a generator and regenerative energy of electric power flows into the inverter. ,
This regenerative energy may cause the DC voltage of the DC power supply unit of the inverter to rise excessively above the rating, and damage the DC power supply unit. Therefore, the inverter is equipped with a means for heating and consuming the regenerative energy that flows in, and a means for supplying the regenerative energy that flows in to another power supply system to protect the DC power supply unit. A specific example of the above will be described with reference to FIG.

FIG. 2 shows a power conversion system using the inverter 1. Inverter 1 in this system
Converts the DC voltage E of the DC power supply unit 2 into AC and supplies the AC voltage E to the load 3 such as a motor. The DC power supply unit 2 has a configuration in which, for example, the AC voltage of the commercial AC power supply 4 is rectified by the rectifier 5 and the DC capacitor 6 is charged, and the DC voltage E of the DC capacitor 6 is maintained at the rated value, which is AC-converted by the inverter 1. Is output to the load 3.

The inverter 1 is of a PWM type in which a plurality of switching elements are connected in a full bridge, and a switching control circuit 7 controls ON / OFF of each switching element. The switching control circuit 7 includes a triangular wave generating circuit 8 that generates a triangular wave having a fixed frequency, and a PWM circuit 9. The triangular wave generating circuit 8 PWMs the triangular wave based on the reference clock signal CLK having a fixed frequency.
The PWM circuit 9 outputs the output voltage command signal V _REF that determines a desired output voltage of the inverter 1 and the gate pulse signal P having a predetermined frequency that determines the pulse width at the crossing point of the triangular wave from the triangular wave generating circuit 8. It outputs to the inverter 1, and the switching element of the inverter 1 is on / off controlled at a predetermined switching frequency.

When the operation mode of the load 3 which is supplied with power by the inverter 1 is changed to the regenerative mode, regenerative energy flows from the load 3 into the inverter 1. Therefore, in the power conversion system of FIG. 2, the discharge circuit in which the discharge switch 10 and the discharge resistor 11 are connected in series is connected in parallel to the DC capacitor 6, and the discharge switch 10 is turned on only when the regenerative energy flows. In this case, by turning on the discharge switch 10, the regenerative energy is discharged to the discharge resistor 11
To suppress the DC voltage E from exceeding the rated value due to regenerative energy.

On / off control of the discharge switch 10 is performed by the DC voltage detection circuit 12 and the voltage determination circuit 13. The DC voltage detection circuit 12 detects the DC voltage E and outputs it to the voltage determination circuit 13. The voltage determination circuit 13 compares the input DC voltage E with a preset reference voltage V _S ,
When the DC voltage E exceeds the reference voltage V _S , a signal for turning on the discharge switch 10 is output, and the DC voltage E is changed to the reference voltage V _S.
When it is smaller than _{S, the} discharge switch 10 is kept off. That is, the DC voltage E detected by the DC voltage detection circuit 12 is equal to 10 of the AC power supply 4 of the DC power supply unit 2 of the inverter 1.
%, The reference voltage V _S is set to a predetermined value of about 10% or more of the rated DC voltage E in consideration of the steady fluctuation of the AC power source 4, and the detected DC voltage E is detected. Exceeds the reference voltage V _S , it is determined that the regenerative energy has caused the DC voltage E to exceed the rated value, and the discharge switch 10 is turned on.

[0008]

In the case of the method for treating regenerative energy in the inverter 1 of FIG. 2, excessive rise of the DC voltage E due to regenerative energy is suppressed, and damage due to overvoltage of the DC power supply unit 2 is suppressed. A large and expensive discharge circuit component such as a discharge switch 10 and a discharge resistor 11 for energy consumption needs a large capacity, which increases the installation space of inverter equipment such as an inverter-specific power conversion system, and the entire equipment. Was expensive.

Further, instead of the rectifier 5 of the DC power supply unit 2 of the inverter 1, a bidirectional converter (PWM converter or the like), that is, a bidirectional converter capable of flowing power in and out in both input and output directions is used. Then, the regenerative energy of the inverter 1 is transferred from the bidirectional converter to the AC power supply 4
There is a regenerative energy processing method and a processing apparatus that consumes the regenerative energy by supplying the regenerative energy to the side.
In this case, a discharging means for processing regenerative energy, a DC voltage detecting means, etc. are unnecessary, and the number of constituent parts of the entire inverter equipment is smaller than that in the case of FIG. 2, but a bidirectional converter requires a complicated structure and is expensive. Therefore, there was a problem that the cost of the entire inverter equipment increased.

An object of the present invention is to provide a method and apparatus for treating regenerative energy of an inverter without increasing the cost of the entire inverter equipment.

[0011]

SUMMARY OF THE INVENTION A regenerative energy processing method for achieving the above object of the present invention is a fluctuation amount of the direct current voltage due to regenerative energy in a pulse width modulation type inverter for converting a rated direct current voltage into an alternating current and outputting it. In accordance with the above, variably control the switching frequency of the inverter,
It is characterized in that regenerative energy is consumed by switching loss due to the switching element of the inverter.

Here, the switching frequency of the inverter and the switching loss are in a proportional relationship, and if the regenerative energy flowing from the output side of the inverter increases, the switching frequency of the inverter is raised in accordance with the increase to regenerate the energy. Energy is consumed by heat generated by switching loss.

The regenerative energy consuming device for achieving the above object of the present invention is characterized in that a switching control circuit of a pulse width modulation type inverter for converting a rated direct current voltage into an alternating current and outputting the converted direct current voltage changes depending on the regenerative energy of the inverter. Based on a control signal that frequency-converts the DC voltage, the switching frequency of the inverter is variably controlled within the allowable range of the switching element, and a voltage-frequency conversion circuit that suppresses fluctuations in the DC voltage of the inverter due to regenerative energy is added. Characterize.

Here, the voltage / frequency conversion circuit is
When the DC voltage of the inverter excessively rises due to the regenerative energy, the switching frequency of the inverter is raised corresponding to this increase in voltage, and the regenerative energy is consumed by the switching loss due to the switching element of the inverter.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an embodiment in which the present invention is applied to the inverter-type power conversion system of FIG. 2, and hereinafter, with reference to FIG. 1, the regenerative energy processing method and processing apparatus of the present invention. Will be explained. The same or corresponding portions as those in FIG. 2 of FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted.

The regenerative energy processing device 15 of the embodiment of the present invention shown in FIG. 1 outputs a signal for variably controlling the switching frequency of the inverter 1 to the switching control circuit 7 based on the detection signal of the DC voltage E of the inverter 1. The voltage / frequency conversion circuit 17 is added. Specifically, the regenerative energy processing device 15 includes a DC voltage detection circuit 12 similar to that shown in FIG. 2, a limiter circuit 16 that sets and outputs the lower and upper limits of the detected DC voltage E, and an output voltage of the limiter circuit 16. A voltage / frequency conversion circuit 17 for frequency conversion is provided.

The DC voltage detection circuit 12 detects the DC voltage E of the inverter 1 and outputs it to the limiter circuit 16. The limiter circuit 16 outputs a signal within a range of a preset lower limit value and an upper limit value of the voltage signal corresponding to the detected DC voltage E to the voltage / frequency conversion circuit 17. For example, when the DC voltage E is within the steady fluctuation range due to the steady fluctuation of about 10% of the AC power supply 4, the limiter circuit 1
6 outputs a voltage signal of a constant voltage value settled by the lower limit value to the voltage / frequency conversion circuit 17. Further, when the DC voltage E increases beyond the steady fluctuation range, the limiter circuit 16 outputs the increased voltage signal to the voltage / frequency conversion circuit 17 to increase the switching frequency of the inverter 1 as described later. The upper limit of the increase of the switching frequency is limited to the upper limit switching frequency of the switching element of the inverter 1, and the limit is set by the upper limit value set in the limiter circuit 16.

The voltage / frequency conversion circuit 17 uses a DC voltage E
The input voltage signal from the limiter circuit 16 is converted into a reference clock signal CLK having a desired frequency in proportion to the voltage value, and the reference clock signal CLK is supplied to the triangular wave generation circuit 8 of the switching control circuit 7. Output.
The switching control circuit 7 includes a voltage / frequency conversion circuit 17
The switching frequency of the inverter 1 is variably controlled in proportion to the frequency of the reference clock signal CLK.

That is, when there is no regenerative energy flowing into the inverter 1 and the DC voltage E is in the steady fluctuation range, a constant voltage signal is output from the limiter circuit 16 to the voltage / frequency conversion circuit 1.
7, and the voltage / frequency conversion circuit 17 outputs a reference clock signal CLK having a predetermined reference frequency to the triangular wave generation circuit 8. In this case, the triangular wave generation circuit 8 outputs a triangular wave having a predetermined reference frequency to the PWM circuit 9 to perform PWM.
The circuit 9 controls ON / OFF of the switching element of the inverter 1 at a constant switching frequency corresponding to the input triangular wave frequency (the same frequency as in FIG. 2).

Further, when the DC voltage E of the inverter 1 increases beyond the steady fluctuation range due to the regenerative energy flowing into the inverter 1, the voltage / frequency conversion circuit 17 outputs the increased voltage of the fluctuation voltage signal from the voltage / frequency conversion circuit 17. The frequency of the reference clock signal CLK is increased. Then, the frequency of the triangular wave generated by the triangular wave generation circuit 8 to which the reference clock signal CLK is input increases corresponding to the increase in the frequency of the reference clock signal CLK, and the switching frequency of the inverter 1 increases corresponding to this increase. As a result, the switching loss of the switching element of the inverter 1 increases.

Therefore, the correlation between the increase in the DC voltage E due to the regenerative energy and the switching frequency of the inverter 1 is preset so that the regenerative energy flowing into the inverter 1 is consumed by the heat generated by the switching loss of the inverter 1. deep. Then, the regenerative energy that flows into the inverter 1 is consumed only by the switching loss of the inverter 1, and the excessive rise of the DC voltage E is suppressed, and the DC power supply unit 2 is protected from the regenerative energy.

[0022]

According to the regenerative energy processing method of the present invention, the regenerative energy of the inverter is consumed by the switching loss of the existing switching element of the inverter, so that the regenerative energy is exclusively consumed by a special discharge circuit or the like that consumes the regenerative energy. Since the parts can be omitted, the number of parts of the inverter equipment can be reduced and the cost can be easily reduced.

The voltage / frequency conversion circuit used in the regenerative energy processing device of the present invention has a function of variably controlling the output frequency of the switching control circuit of the inverter to variably control the switching frequency of the inverter. Therefore, it can be configured with low-cost, small-sized, and space-saving components, which facilitates cost reduction and small-sized space saving of inverter equipment such as an inverter-specific power conversion system.

[Brief description of the drawings]

FIG. 1 is a block circuit diagram of inverter equipment showing an embodiment of the present invention.

FIG. 2 is a block circuit diagram of inverter equipment for explaining a conventional method and a processing device for regenerative energy of an inverter.

[Explanation of symbols]

 1 Inverter E DC voltage 7 Switching control circuit 15 Regenerative energy processing device 17 Voltage / frequency conversion circuit

Claims (2)

[Claims] 1. A switching frequency of the inverter is variably controlled corresponding to a variation of the DC voltage due to the regenerative energy in a pulse width modulation type inverter that converts a rated DC voltage to an AC and outputs the regenerative energy. A method for processing regenerative energy of an inverter, characterized in that the switching element consumes the switching loss. 2. A switching control circuit of a pulse width modulation type inverter which converts a rated DC voltage into an AC voltage and outputs the AC voltage, based on a control signal obtained by frequency-converting the DC voltage which fluctuates due to regenerative energy of the inverter. A regenerative energy processing device for an inverter, characterized in that a voltage / frequency conversion circuit is added to control the frequency variably within the allowable range of the switching element to suppress fluctuations in the DC voltage of the inverter due to regenerative energy.