JP2021027594A - Leakage current suppression circuit to earth cable in inverter unit and leakage current suppression method to the earth cable in the inverter unit - Google Patents

Abstract

To provide a leakage current suppression circuit to an earth cable in an inverter unit, in which a parallel resonance load is connected to a voltage type inverter device.SOLUTION: A leakage current suppression circuit to an earth cable 206 in an inverter unit 2, in which a parallel resonance load 200 is connected to a voltage type inverter device 10, is structured so that a first inductor 3 and a second inductor 4 are connected, respectively, so that an inductance becomes the same in each rail track connecting the voltage type inverter device 10 and the parallel resonance load 200, and the earth cable 206 is connected to a resonance capacitor 200b structuring the parallel resonance load 200.SELECTED DRAWING: Figure 2

Description

The present invention relates to a leakage current suppression circuit to the ground wire in the inverter unit and a method for suppressing leakage current to the ground wire in the inverter unit.

More specifically, the present invention relates to a circuit for suppressing leakage current to the ground wire in an inverter unit suitable for use in an inverter unit in which a parallel resonance load is connected to a voltage-type inverter device, and a method for suppressing leakage current to the ground wire in the inverter unit. Regarding.

Generally, a voltage type inverter device is known as a power supply device connected to a parallel resonance load such as an induction heating circuit, and when the parallel resonance load is driven by using such a voltage type inverter device, it is used for removing harmonics. It is known that an inductor is connected in series as a filter.

In the following description of the present specification, various alternating currents such as a single-phase alternating current (AC) power supply and a three-phase alternating current (AC) power supply are used in order to simplify the description and illustration and facilitate the understanding of the present invention. In the description when using a power source, a case where a single-phase alternating current (AC) power source is used as an alternating current power source will be described.

Here, FIG. 1 shows a circuit configuration explanatory diagram showing a circuit configuration of a conventional inverter unit that connects a parallel resonant load to a voltage-type inverter device via a transformer.

The inverter unit 1 shown in FIG. 1 includes an inverter device 100 which is a voltage type inverter device, a single-phase alternating current (AC) power supply 102 such as a commercial alternating current power supply, a parallel resonance load 200 such as an induction heating circuit, a transformer 202, and a high frequency. It is configured to have an inductor 204, a ground wire 206, and the like, which are filters for removal.

More specifically, the inverter device 100 converts an alternating voltage supplied from a single-phase alternating current (AC) power supply 102 such as a commercial alternating current power supply into a high-frequency alternating current voltage of a desired voltage, and induces heating circuit via a transformer 202. It is supplied to the parallel resonance load 200 such as.

The parallel resonance circuit constituting the parallel resonance load 200 is composed of a parallel resonance circuit formed by connecting a heating coil 200a for induction heating and a resonance capacitor 200b in parallel.

The inductor 204, which is a filter for removing high frequencies, is connected to one of the two lines connecting the inverter device 100 and the transformer 202.

The ground wire 206 is connected to the resonance capacitor 200b of the parallel resonance load 200, and is used for the purpose of fixing the potential of the parallel resonance load 200 for safety.

As described above, in the circuit configuration of the conventional inverter unit 1, the inductor 204, which is a filter for removing high frequencies, is arranged only on one line of the single phase, and the transformer 202 is used for the resonance circuit. The resonance capacitor 200b of the parallel resonance load 200 connected to the secondary coil side of 202 is grounded by the ground wire 206.

Therefore, according to the circuit configuration of the conventional inverter unit 1, the inductance in each phase is unbalanced.

Due to the imbalance of inductance in each phase, the harmonic voltage with respect to the ground generated on the primary coil side of the transformer 202 passes through the stray capacitance between the primary coil side and the secondary coil side of the transformer 202. There is a problem that a large harmonic ground current may flow as a leakage current to the ground wire 206.

Since the prior art that the applicant of the present application knows at the time of filing the patent application is not an invention related to a document known invention, there is no prior art document information to be described in the specification of the present application.

The present invention has been made in view of the above-mentioned problems in the conventional technique, and an object of the present invention is to use parallel on the load side in an inverter unit in which a parallel resonant load is connected to a voltage type inverter device. It is an object of the present invention to provide a leakage current suppression circuit to the ground wire in an inverter unit and a method for suppressing a leakage current to the ground wire in an inverter unit so as to reduce the leakage current to the ground wire in a resonance load.

In order to achieve the above object, the present invention is to connect inductors having the same inductance to each of the lines connecting the voltage type inverter device and the parallel resonant load.

Therefore, according to the present invention, the inductance imbalance does not occur in each phase, and the leakage of current to the ground wire caused by the inductance imbalance in each phase can be reduced.

That is, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is a leakage current suppression circuit to the ground wire in the inverter unit in which the parallel resonance load is connected to the voltage type inverter device, and is the same as the voltage type inverter device. Inverters are connected to each of the lines connecting the parallel resonance load so that the inductance is the same, and a ground wire is connected to the resonance capacitor constituting the resonance load.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonance load is connected to the voltage type inverter device via a transformer. An inductor is connected to each of the lines connecting the type inverter device and the transformer so that the inductance is the same, and a ground wire is connected to the middle point of the winding on the secondary coil side of the transformer.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonance load is connected to the voltage type inverter device, and is the same as the voltage type inverter device. Inverters are connected to each of the lines connecting the parallel resonance load so that the inductance is the same, and two capacitors with a capacitance smaller than the resonance capacitor of the parallel resonance load are connected to divide the voltage. The ground wire is connected to the midpoint of the above two capacitors.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonance load is connected to the voltage type inverter device via a transformer. Connect the inductors to each of the lines connecting the type inverter device and the transformer so that the inductance is the same, connect the ground wire to the middle point of the winding on the secondary coil side of the transformer, and connect the ground wire. A resistor is connected to.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonance load is connected to the voltage type inverter device, and is the same as the voltage type inverter device. Inverters are connected to each of the lines connecting the parallel resonant load so that the inductance is the same, and a current transformer is connected to the parallel resonant load at the intermediate point on the secondary side of the transformer. The ground wire is connected.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is provided in the ground wire in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, and the current flowing through the ground wire is provided. A current sensor that outputs a ground fault detection signal when a ground fault is detected based on the magnitude, and an operation stop control means that controls to stop the operation of the inverter device when a ground fault detection signal output from the current sensor is input. It is designed to have.

Further, in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, the voltage type inverter device is a voltage type inverter which is PWM controlled. It has an inverter unit connected to the parallel resonance load and driven by an inverter drive signal, and a control means for controlling the operation of the inverter unit. The control means has a resonance frequency of the resonance load. After starting the driving of the inverter section with a pulse signal having a pulse width shorter than the period as the inverter drive signal and starting from a frequency distant from the resonance frequency, the frequency of the inverter drive signal is set to the resonance frequency or the vicinity of the resonance frequency. The frequency is shifted to, and the frequency of the inverter drive signal is controlled so as to substantially match the resonance frequency.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is the above-mentioned leakage current suppression circuit to the ground wire in the inverter unit according to the present invention. The short pulse width allows the output of the inverter section to be output from the outside. The pulse width is set to be the minimum set output value of the set value indicated by the output setting signal of.

Further, the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention is such that the starting point is a frequency lower than the resonance frequency in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention. It was done.

Further, in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, the control unit corrects the voltage phase delay due to the inductor. It is designed to have a delay correction means.

Further, in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, in the leakage current suppression circuit to the ground wire in the inverter unit according to the present invention, in the control unit, the frequency of the inverter drive signal resonates. After controlling so as to substantially match the frequency, the pulse width of the inverter drive signal is widened by PWM control.

Further, the method for suppressing leakage current to the ground wire in the inverter unit according to the present invention is a method for suppressing leakage current to the ground wire in the inverter unit in which a parallel resonance load is connected to the voltage type inductance device, and is the same as the voltage type inverter device. An inductor is connected to each of the lines connecting the parallel resonant load so that the inductance is the same, and the imbalance of the inductance in each phase is suppressed to suppress the leakage of current to the ground wire. is there.

Further, in the method for suppressing leakage current to the ground wire in the inverter unit according to the present invention, in the above method for suppressing leakage current to the ground wire in the inverter unit according to the present invention, the voltage type inverter device is a voltage type inverter which is PWM controlled. A pulse signal having a pulse width shorter than the period of the resonance frequency of the parallel resonance load is used as an inverter drive signal, and after starting driving of the inverter unit from a frequency distant from the resonance frequency, the inverter drive signal The frequency is frequency-shifted to the resonance frequency or the vicinity of the resonance frequency, and the frequency of the inverter drive signal is controlled so as to substantially match the resonance frequency.

Since the present invention is configured as described above, in the inverter unit in which the parallel resonance load is connected to the voltage type inverter device, the leakage current to the ground wire in the parallel resonance load on the load side can be reduced. It has an excellent effect of becoming.

FIG. 1 is a circuit configuration explanatory diagram showing a circuit configuration of a conventional inverter unit that connects a parallel resonant load to a voltage-type inverter device via a transformer. FIG. 2 shows an inverter unit (parallel to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (first embodiment). It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit (inverter unit which connects a resonance load). FIG. 3 is a detailed configuration explanatory view of a control unit in the inverter device (voltage type inverter device) in the inverter unit shown in FIG. FIG. 4 shows an inverter unit (parallel to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (second embodiment). It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit (inverter unit which connects a resonance load). FIG. 5 shows an inverter unit (parallel to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (third embodiment). It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit (inverter unit which connects a resonance load). FIG. 6 shows an inverter unit (parallel to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (fourth embodiment). It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit (inverter unit which connects a resonance load). FIG. 7 shows an inverter unit (parallel to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (fifth embodiment). It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit (inverter unit which connects a resonance load). FIG. 8 shows an inverter unit (parallel to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (sixth embodiment). It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit (inverter unit which connects a resonance load). FIG. 9 shows an inverter unit (a parallel resonance load is applied to a voltage type inverter device via a transformer) when an inverter device having another configuration is used in place of the inverter device shown in FIG. 2 in the inverter unit shown in FIG. It is a circuit configuration explanatory diagram which shows the circuit configuration of the inverter unit to be connected. 10 (a), (b), (c), (d), and (e) are schematic waveform diagrams showing the operation of the inverter device shown in FIG. FIG. 11 shows an inverter unit that connects a voltage-type inverter device and a parallel resonance load without a transformer, to the ground wire in the inverter unit according to an example of the embodiment of the present invention (first embodiment). It is a circuit configuration explanatory diagram which shows the circuit structure of the inverter unit (inverter unit which connects a parallel resonance load to a voltage type inverter device without going through a transformer) provided with the leakage current suppression circuit. FIG. 12 shows an inverter unit that connects a voltage-type inverter device and a parallel resonance load without a transformer, to the ground wire in the inverter unit according to an example of the embodiment of the present invention (third embodiment). It is a circuit configuration explanatory diagram which shows the circuit structure of the inverter unit (inverter unit which connects a parallel resonance load to a voltage type inverter device without going through a transformer) provided with the leakage current suppression circuit.

Hereinafter, with reference to the accompanying drawings, an example of the embodiment of the leakage current suppression circuit to the ground wire in the inverter unit and the leakage current suppression method to the ground wire in the inverter unit will be described in detail. ..

In addition, in the following description of the section of "mode for carrying out the invention", the configuration and operation described above with reference to FIG. 1, or the configuration and operation described with reference to each of the drawings below FIG. The configuration and action that are the same as or equivalent to the action are designated by adding the same reference numerals as those used in FIGS. 1 or 2 and below, and the detailed description of the structure and action will be omitted.

(I) First Embodiment

(I-1) Configuration

FIG. 2 shows an inverter unit (voltage-type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (first embodiment). A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit for connecting the parallel resonant load) is shown.

Further, FIG. 3 shows a detailed configuration explanatory diagram of a control unit in the inverter device (voltage type inverter device) in the inverter unit shown in FIG.

The inverter unit provided with the leakage current suppression circuit to the ground wire in the inverter unit according to the example of the embodiment of the present invention will be described with reference to FIGS. 2 and 3.

The inverter unit 2 shown in FIG. 2 is an inverter unit that connects a parallel resonance load 200 to an inverter device 10 which is a voltage type inverter device via a transformer 202.

The inverter unit 2 includes an inverter device 10, a single-phase alternating current (AC) power supply 102 such as a commercial alternating current power supply, a parallel resonance load 200 such as an inductive heating circuit, a transformer 202, and a first inductor (first inductor) which is a filter for removing high frequencies. It is configured to include a 1 inductor) 3, a second inductor (second inductor) 4, a ground wire 206, and the like.

More specifically, the inverter device 10 is a PWM-controlled voltage-type inverter device connected to the parallel resonant load 200.

That is, the inverter device 10 converts an alternating voltage supplied from a single-phase alternating current (AC) power supply 102 such as a commercial alternating current power supply into a high-frequency alternating voltage of a desired voltage, and is like an induction heating circuit via a transformer 202. It is supplied to the parallel resonance load 200.

The parallel resonance circuit constituting the parallel resonance load 200 is composed of a parallel resonance circuit formed by connecting a heating coil 200a for induction heating and a resonance capacitor 200b in parallel.

The first inductor 3, which is a filter for removing high frequencies, is connected to one of the two lines connecting the inverter device 10 and the transformer 202.

On the other hand, the second inductor 4, which is a filter for removing high frequencies, is connected to the other line of the two lines connecting the inverter device 10 and the transformer 202.

In this way, the first inductor 3 is connected to one of the two lines connecting the inverter device 10 and the transformer 202, and the second inductor 4 is connected to the inverter device 10 and the transformer 202. By connecting to the other line of the book line, a leakage current suppression circuit to the ground line is constructed.

Here, the inductance of the first inductor 3 and the inductance of the second inductor 4 described above are set to the same value.

The inductance value of the first inductor 3 and the inductance value of the second inductor 4 are divided into two, for example, the inductance value of the inductor 204, which is a filter for removing high frequencies in the conventional inverter unit 1 described above. It is preferable to set the value.

That is, assuming that the inductance value of the inductor 204 is "L", it is preferable that the inductance value of the first inductor 3 and the inductance value of the second inductor 4 are "L / 2", respectively.

In other words
Inductor 204 = L
1st inductor 3 = L / 2
2nd inductor 4 = L / 2
Is preferable.

The ground wire 206 is connected to the resonance capacitor 200b of the parallel resonance load 200, and is used for the purpose of fixing the potential of the parallel resonance load 200 for safety.

Next, the inverter device 10 will be described in detail. The inverter device 10 inputs an alternating current voltage supplied from the single-phase alternating current (AC) power supply 102, converts it into a direct current voltage by rectification by a diode, and outputs the converter unit 302. It has.

That is, the converter unit 302 of the inverter device 10 is composed of a diode rectifier circuit that does not use the converter control unit, and an alternating current voltage is input from the single-phase alternating current (AC) power supply 102, and the input alternating current voltage is converted into a DC voltage. It is converted and output to the inverter unit 106.

The inverter unit 106 inputs the DC voltage output from the converter unit 302, converts it back to a high-frequency AC voltage, and outputs the voltage.

In the output stage of the inverter unit 106, the output from the inverter unit 106 (here, the "output" from the inverter unit 106 is the "output voltage Vh" which is the voltage output from the inverter unit 106, or the inverter unit 106. An output sensor 108 is provided that detects the "output current Ih", which is the current output from the inverter, or the "output power", which is the power output from the inverter unit 106, and outputs the detection result as an output sensor signal. Has been done.

The inverter device 10 includes a control unit 12 as a control means for controlling the operation of the inverter unit 106.

As shown in FIG. 3, the control unit 12 includes a PWM control unit 12a and a frequency shift control unit 12b.

The control unit 12 feedback-controls the inverter unit 106 based on the output setting signal, which is a signal for setting the output of the inverter unit 106 from the outside, and the output sensor signal output from the output sensor 108.

That is, the control unit 12 drives the transistor of the voltage type inverter constituting the inverter unit 106 by the PWM control of the PWM control unit 12a so that the output from the inverter unit 106 becomes the output set value indicated by the output setting signal. The pulse widths of the rectangular wave inverter drive signals Q and NQ, which are the inverter drive signals, are changed to change the output of the high frequency AC voltage converted by the inverter unit 106.

The output from the inverter unit 106 is input to the parallel resonance load 200 via the output sensor 108.

(I-2) Operation

In the above configuration, in the circuit configuration of the inverter unit 2 described above, when the inductor is connected in series to the parallel resonance load 200 as a filter for removing harmonics, the two lines connecting the inverter device 10 and the transformer 202 are connected. The first inductor 3 is connected to one of the lines, and the second inductor 4 is connected to the other line of the two lines connecting the inverter device 10 and the transformer 202 to leak to the ground line. We are constructing a current suppression circuit.

By providing the leakage current suppression circuit to the ground wire, the inductance becomes equal in each phase, and the imbalance of the inductance in each phase is suppressed, so that the current leakage to the ground wire 206 occurs. Can be suppressed and the leakage current to the ground wire 206 can be reduced.

Next, the operation executed by the control unit 12 of the inverter device 10 will be described in detail below.

That is, at the start of driving (starting) when the output from the inverter device 10 is started, the pulse width is sufficiently shorter than the resonance frequency period, for example, the minimum set output value (output voltage) of the set value indicated by the output setting signal from the outside. Alternatively, the pulse width that becomes the output current or the output power (in the present specification and the present patent claim, the “pulse width that becomes the minimum set output value of the set value indicated by the output setting signal from the outside” is the “minimum pulse”. The drive is started (started) by the rectangular wave inverter drive signals Q and NQ starting from a frequency distant from the resonance frequency of the parallel resonance load 200.

As a result, even if the resonance frequency of the parallel resonance load 200 fluctuates, the frequencies of the rectangular wave inverter drive signals Q and NQ by the frequency shift control unit 12b of the control unit 12 are shifted to the resonance frequency from the start of driving (start). The frequency shift enables automatic tracking to fluctuating resonance frequencies.

Then, in the inverter device 10, the PWM control unit 12a of the control unit 12 sends an output setting signal from the outside after the frequencies of the square wave inverter drive signals Q and NQ are close to the resonance frequency (resonance point) or the resonance frequency. The pulse width of the square wave inverter drive signals Q and NQ is widened by PWM control so that the output of the set value indicated by is obtained.

That is, the inverter device 10 has the minimum set output value (output voltage, output current, or output power) of the set value indicated by the output setting signal from the outside as the rectangular wave inverter drive signals Q and NQ which are the inverter drive signals. Is output and a pulse signal (narrow pulse signal) having a pulse width sufficiently shorter than the resonance frequency period (for example, the minimum pulse width described above) is used, and the narrow pulse signal is set to a frequency far from the resonance frequency. After starting from the starting point and shifting the frequency to the resonance frequency or the vicinity of the resonance frequency, the frequency is controlled to the resonance frequency.

After that, the inverter device 10 widens the pulse width of the narrow pulse signal by PWM control, and becomes an output (output voltage or output current or output power) of a set value indicated by an output setting signal from the outside. To do so.

(I-3) Action effect

In the inverter unit 2 described above, since the leakage current suppression circuit to the ground wire is constructed, when the parallel resonance load 200 is connected to the inverter device 10 which is a voltage type inverter device and used, the load side It becomes possible to reduce the leakage current to the ground wire 206 in a certain parallel resonance load 200.

Further, according to the inverter device 10 of the inverter unit 2 described above, the output frequency of the inverter unit does not deviate from the resonance frequency even if the output is controlled, and the tracking characteristic for a load in which the resonance frequency fluctuates. Can be improved.

Further, in the inverter device 10 of the inverter unit 2 described above, since the output can be controlled by the inverter unit 106, the thyristor rectifier circuit and the chopper circuit are not used as the converter circuit of the converter unit as in the conventional technique. ..

Therefore, the inverter device 10 of the inverter unit 2 described above has an improvement in power factor and a significant improvement in output response speed as compared with the conventional technique using a thyristor rectifier circuit or a chopper circuit (the inventor of the present application). According to the experiment, the response speed has been greatly improved from 100 ms in the conventional technique to 10 ms), and the cost can be reduced and the reliability can be improved by drastically reducing the number of parts.

Further, in the inverter device 10 of the inverter unit 2 described above, the start frequency, which is the frequency at the start (start) of driving the inverter drive signal, is set to a frequency far from the resonance frequency, and then the frequency of the inverter drive signal is set to the resonance frequency. Since the frequency is shifted so that the frequencies are closer to each other, the tracking characteristics for the parallel resonance load 200 whose resonance frequency fluctuates are greatly improved, and there is no problem when switching and connecting a plurality of parallel resonance loads 200 having different resonance frequencies. can do.

Here, it is preferable that the region (frequency shift region) in which the frequency is shifted by the frequency shift control unit 12b is determined to be an inductive region in consideration of the diode reverse recovery characteristic that is optimal for the inverter circuit.

In other words, the start frequency is preferably determined so that the frequency shift region is an inductive region based on the diode reverse recovery characteristic of the inverter circuit.

According to the experiment by the inventor of the present application, the start frequency, which is the frequency at the start (start) of driving the inverter drive signal, is a frequency 5% or more away from the frequency of the resonance frequency (for example, the resonance frequency is 20 kHz). Then, a frequency 5% or more away from the frequency of the resonance frequency is a frequency of 19 kHz or less or a frequency of 21 kHz or more), and good results are obtained.

When the start frequency is set to a frequency 5% or more away from the frequency of the resonance frequency, that is, when the start frequency is separated from the frequency of the resonance frequency by 5% or more, the low frequency side of the resonance frequency (from the resonance frequency). (For example, if the resonance frequency is 20 kHz, the frequency 5% or more away from the low frequency side of the resonance frequency is the frequency of 19 kHz or less), or the resonance frequency. It may be separated to the high frequency side (frequency direction higher than the resonance frequency) (for example, if the resonance frequency is 20 kHz, the frequency 5% or more away from the high frequency side of the resonance frequency becomes the frequency of 21 kHz or more. .).

According to the knowledge of the inventor of the present application, the start frequency should be separated from the frequency of the resonance frequency (for example, 5% or more with respect to the frequency of the resonance frequency) as in the inverter device 10 according to the present invention described above. After starting the driving of the inverter section by the narrow pulse signal from the start frequency, the narrow pulse signal is frequency-shifted to the resonance frequency, and then the pulse width of the narrow pulse signal is widened at the resonance frequency. There is no conventional technique for initiating PWM control.

(II) Second Embodiment

FIG. 4 shows an inverter unit (with respect to a voltage type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (second embodiment). A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit for connecting the parallel resonant load) is shown.

Comparing the inverter unit 5 shown in FIG. 4 with the inverter unit 2 shown in FIG. 2, the inverter unit 2 connects the ground wire 206 to the resonance capacitor 200b of the parallel resonance load 200 and grounds the inverter unit 2. The inverter unit 5 and the inverter unit 2 are different from each other in that the unit 5 connects the ground wire 207 directly to the middle point of the winding on the secondary coil side of the transformer 202 and grounds it.

That is, the inverter unit 5 is such that the midpoint of the winding on the secondary coil side of the transformer 202 connected to the parallel resonance load 200 is directly grounded.

By setting the grounding point as the midpoint of the winding on the secondary coil side of the transformer 202 in this way, it is possible to suppress the leakage current due to the imbalance of the ground potential on the secondary coil side of the transformer 202.

That is, by providing the above configuration, in the inverter unit 5, it is possible to cancel the ground current flowing through the stray capacitance between the primary coil side and the secondary coil side of the transformer 202, and as a result, it is on the load side. It becomes possible to reduce the leakage current to the ground wire 207 in the parallel resonance load 200.

(III) Third Embodiment

FIG. 5 shows an inverter unit (with respect to a voltage-type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (third embodiment). A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit for connecting the parallel resonant load) is shown.

Comparing the inverter unit 6 shown in FIG. 5 with the inverter unit 2 shown in FIG. 2, the inverter unit 2 connects the ground wire 206 to the resonance capacitor 200b of the parallel resonance load 200 and grounds the inverter unit 2. The unit 6 connects the ground wire 208 to the midpoint between the two first inverters for voltage division (first inverter for voltage division) 209 and the second inverter (second inverter for voltage division) 210 and grounds them. In that respect, the inverter unit 6 and the inverter unit 2 are different.

That is, the inverter unit 6 has two capacitors (first capacitor 209 for voltage division and second capacitor 210 for voltage division) having a capacitance smaller than that of the resonance capacitor 200b of the parallel resonance load 200 so as not to affect the resonance. The voltage is divided by connecting, and the ground wire 208 is connected to the ground at the midpoint between the first capacitor 209 for dividing pressure and the second capacitor 210 for dividing pressure.

By providing the above configuration, the leakage current to the ground wire 208 can be reduced also in the inverter unit 6.

(IV) Fourth Embodiment

FIG. 6 shows an inverter unit (voltage-type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (fourth embodiment). A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit for connecting the parallel resonant load) is shown.

Comparing the inverter unit 7 shown in FIG. 6 with the inverter unit 5 shown in FIG. 4, the inverter unit 7 and the inverter unit 5 are different in that the inverter unit 7 connects the resistor 211 to the ground wire 207.

That is, the inverter unit 7 connects the resistor 211 to the ground wire 207 that grounds the midpoint of the winding on the secondary coil side of the transformer 202 connected to the parallel resonance load 200, and connects the transformer 202 to the parallel resonance load 200. The midpoint of the winding on the secondary coil side of is grounded by resistance.

By providing the above-described configuration, the inverter unit 7 can have the same effect as that of the inverter unit 5, and can suppress the current flowing through the ground wire 207 at the time of a ground fault by the resistance grounding.

(V) Fifth Embodiment

FIG. 7 shows an inverter unit (voltage-type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (fifth embodiment). A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit for connecting the parallel resonant load) is shown.

Comparing the inverter unit 8 shown in FIG. 7 and the inverter unit 2 shown in FIG. 2, the inverter unit 2 connects the ground wire 206 to the resonance capacitor 200b of the parallel resonance load 200 and grounds the inverter unit 2. The inverter unit 8 and the inverter unit 2 are different in that the unit 8 connects the ground wire 212 to the intermediate point on the secondary side of the transformer 213 and grounds the ground wire 212.

That is, the inverter unit 8 is grounded by connecting the current transformer 213 to the parallel resonance load 200 and connecting the ground wire 212 to the intermediate point on the secondary side of the current transformer 213.

By providing the above configuration, the leakage current to the ground wire 212 can be reduced also in the inverter unit 8.

(VI) Sixth Embodiment

FIG. 8 shows an inverter unit (voltage-type inverter device via a transformer) provided with a leakage current suppression circuit to the ground wire in the inverter unit according to an example of the embodiment of the present invention (sixth embodiment). A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit for connecting the parallel resonant load) is shown.

Comparing the inverter unit 9 shown in FIG. 8 and the inverter unit 5 shown in FIG. 4, the inverter unit 9 provides the current sensor 214 on the ground wire 207, and the signal output from the current sensor 214 (ground fault detection signal). The inverter unit 9 and the inverter unit 5 are different from each other in that the operation stop control unit 215 for stopping the operation of the inverter device 10 is provided based on the above.

That is, the inverter unit 9 is provided with a current sensor 214 on the ground wire 207, monitors the magnitude of the current flowing through the ground wire 207 by the current sensor 214, and uses the current sensor 214 based on the magnitude of the current flowing through the ground wire 207. It is designed to detect ground faults.

When the current sensor 214 detects a ground fault, the current sensor 214 outputs a ground fault detection signal to the operation stop control unit 215. The operation stop control unit 215 that has input the ground fault detection signal controls to stop the operation of the inverter device 10 instantly, thereby preventing the inverter unit 9 from malfunctioning due to the ground fault and protecting the power supply.

Further, also in this inverter unit 9, the leakage current to the ground wire 207 can be reduced.

The inverter units 2, 6, 7, and 8 also have the same configuration as the inverter unit 9, that is, the current sensors 214 are provided on the ground wires 206, 207, 208, and 212, and are output from the current sensor 214. The operation stop control unit 215 that stops the operation of the inverter device 10 based on the signal (ground fault detection signal) may be provided.

In this way, the inverter units 2, 6, 7, and 8 can prevent malfunctions due to ground faults and protect the power supply as well as the inverter units 9.

(VII) Description of Other Embodiments and Modifications

It should be noted that the above-described embodiment is merely an example, and the present invention can be implemented in various other embodiments. That is, the present invention is not limited to the above-described embodiment, and various omissions, replacements, and changes can be made without departing from the gist of the present invention.

For example, the above-described embodiment may be modified as shown in (VII-1) to (VII-7) below.

(VII-1) Inverter units 2, 5, 6, 7, described above as an inverter unit provided with a leakage current suppression circuit to the ground wire in the inverter unit according to the first to sixth embodiments. In 8 and 9, as illustrated in FIG. 9, the inverter device 20 may be used instead of the inverter device 10.

Note that FIG. 9 shows an inverter unit (parallel to the voltage type inverter device via a transformer) when an inverter device having another configuration is used in place of the inverter device shown in FIG. 2 in the inverter unit shown in FIG. A circuit configuration explanatory diagram showing the circuit configuration of the inverter unit (inverter unit to which the resonance load is connected) is shown.

Further, FIGS. 10 (a), (b), (c), (d), and (e) show a schematic waveform diagram showing the operation of the inverter device shown in FIG.

Explaining the inverter device 20 of the inverter unit 2'with reference to FIGS. 9 and 10, the inverter device 20 is connected to the parallel resonance load 200 via the transformer 202.

By the way, the parallel resonance load 200 has a characteristic of being inductive in a range lower than the resonance frequency, while the voltage type inverter is induced by the reverse recovery characteristic of the current of the diode connected in parallel with the inverter element. It has been found that the switching operation in sex is more stable than that in capacitance.

Therefore, the inverter device 20 sets a frequency lower than the resonance frequency of the parallel resonance circuit 200 (for example, a frequency 5% or more lower than the resonance frequency) as the start frequency of the inverter drive signal, and shifts the frequency from this start frequency. The frequency of the inverter drive signal is raised to the resonance frequency, and the frequency of the inverter drive signal is locked by the resonance frequency.

The inverter device 20 will be described below. Reference numeral 26 is a voltage sensor, and reference numeral 28 is a control unit.

The voltage sensor 26 is a component corresponding to the output sensor 108 described above, detects a voltage, and outputs a signal indicating the detected voltage as an output sensor signal.

The control unit 28 includes a frequency shift circuit 30, a voltage control oscillator (VCO: Voltage-control oscillator) circuit 32, a narrow pulse signal generation circuit 34, an output circuit 36, a phase comparison circuit 38, and a delay setting circuit 40. The lock complete circuit 42, the detection circuit 44, the error amplifier filter 46, the triangular wave generation circuit 48, and the PWM circuit 50 are included.

Here, the inverter device 20 applies a conventionally known technique of the inverter device, except that the control unit 28 includes a frequency shift circuit 30 to shift the frequency of the inverter drive signal and a signal switching point. Therefore, detailed description of other configurations except for the point of frequency shifting the frequency of the inverter drive signal and the point of signal switching will be omitted.

In the above configuration, the operation of the inverter device 20 of the inverter unit 2'will be described focusing on the operation of the control unit 28.

In the control unit 28, an output ON (ON) signal from the outside is input to the frequency shift circuit 30, and the frequency is lower than the resonance frequency of the parallel resonance load 22 (for example, the frequency is 5% or more lower than the resonance frequency). A signal is output to the VCO circuit 32 so as to start driving the inverter unit 106, a frequency signal from the output of the VCO circuit 32 is input to the narrow pulse signal generation circuit 34, and the frequency of the output of the VCO circuit 32 is narrow. The pulse signal is generated by the narrow pulse signal generation circuit 34 and output to the output circuit 36. The output circuit 36 switches from the signal of the narrow pulse signal generation circuit 34 to the signal of the PWM circuit 50 according to the signal of the lock completion circuit 42.

Here, the pulse width of the narrow pulse signal generated by the narrow pulse signal generation circuit 34 is such that the output value output from the inverter unit 106 is the minimum set output value of the set value indicated by the output setting signal from the outside ( It is preferable to set the output voltage, output current, or output power).

10 (a), (b), (c), (d), and (e) show waveform diagrams schematically showing the operation of the inverter device 20.

In FIGS. 10 (a), (b), (c), (d), and (e), the waveform D, the waveform E, the waveform F, the waveform G, and the waveform H are the voltages (capacitor voltage Vc) detected by the voltage sensor 26. It is a waveform.

FIG. 10A shows a voltage (capacitor voltage Vc) waveform (waveform D) detected by the voltage sensor 26 as an output of the inverter unit 106 at the start frequency at the start of driving (starting) and a narrow pulse as an inverter drive signal. Indicates the phase difference from the signal.

When the parallel resonance load 200 is connected to the inverter device 20, it is known that the phase of the inverter drive signal lags the phase of the capacitor voltage Vc in the frequency region below the resonance frequency.

Here, in the phase comparison circuit 38, the point A, which is a position delayed by 1/4 of the pulse cycle of the inverter drive signal, is set as the pulse position of the phase detection pulse, and the zero cross point of the capacitor voltage Vc phase waveform (waveform E) to be compared is set. As point B (see FIG. 10B), compare the phase difference between point A and point B and lock at a frequency where the phase difference is zero (0) or a preset phase difference. (See FIG. 10 (c).).

On the other hand, the waveform signal from the voltage sensor 26 and the frequency signal from the VCO circuit 32 are input to the phase comparison circuit 16 to compare their respective phases, and the frequency of the VCO circuit 32 is controlled so as to be a resonance frequency.

Specifically, the inverter unit 106 is started to be driven by the inverter drive signal of the narrow pulse signal having a frequency away from the resonance frequency, for example, a frequency 5% or more lower than the resonance frequency as the start frequency (FIG. 10A). ), The frequency of the inverter signal is frequency-shifted and raised (see FIG. 10B).

Then, the phase comparison circuit 38 locks the frequency of the inverter drive signal at the resonance frequency (see FIG. 10C), and the lock completion circuit 42 detects the lock completion and outputs a signal to the output circuit 36. By this signal, the output circuit 36 outputs an inverter drive signal in which the pulse width tw is widened by PWM control from the narrow pulse signal, and the output of the inverter unit 106 rises to the output of the set value set by the output setting signal. (See FIGS. 10 (d) and 10 (e)).

That is, the inverter device 20 connects the parallel resonance load 200, and as the rectangular wave inverter drive signals Q and NQ which are the inverter drive signals, the minimum set output value (output voltage or output) of the set value indicated by the output setting signal from the outside. Use a pulse signal (narrow pulse signal) with a pulse width sufficiently shorter than the resonance frequency period that outputs current or output power, and use the narrow pulse signal at a frequency farther than the resonance frequency (for example, than the resonance frequency). The frequency of the inverter drive signal is controlled to the resonance frequency by performing frequency control by a frequency shift that raises the frequency to the resonance frequency or the vicinity of the resonance frequency after starting from the starting point (which is a frequency lower than 5%).

After that, the inverter device 20 widens the pulse width of the narrow pulse signal by PWM control, and becomes an output (output voltage or output current or output power) of the set value indicated by the output setting signal from the outside. To do so.

Therefore, also in the inverter device 20, the same operation and effect as described above with respect to the inverter device 10 can be obtained.

In the inverter unit 2', similarly to the inverter unit 2, a first inductor 3 and a second inductor 4 for preventing harmonic currents are connected between the inverter device and the transformer 202.

That is, in the inverter device 20 of the inverter unit 2', when the inverter unit 106, which is a voltage type inverter, is connected to the parallel resonance load 200, a harmonic current flows due to the voltage of the harmonic component of the rectangular wave voltage. The first inductor 3 and the second inductor 4 are connected in series to the output stage of the inverter unit 106 in order to prevent the above.

The output voltage of the inverter unit 106 becomes a square wave, but it is generally known that the square wave consists of a composite waveform of a sine wave and an odd harmonic, and if the rectangular wave is connected to the parallel resonance load 200 as it is, it is odd. Since the harmonic component has a high frequency, the reactivity of the capacitor becomes small, the harmonic current increases, causing current waveform distortion, and the loss of the transistor, which is the switching element of the inverter unit 106, deteriorates.

Therefore, for the purpose of suppressing such harmonic currents, the inverter device 20 also has the first inductor 3 and the second inductor 4 connected to the output stage of the inverter unit 106, similarly to the inverter device 10.

Further, the control unit 28 of the inverter device 20 is provided with a delay setting circuit 40 for setting a signal delay time when the output signal from the VCO circuit 32 is input to the phase comparison circuit 38 to perform phase comparison. There is.

That is, in the inductor device 20, when the inverter unit 106, which is a voltage type inductor, is connected to the parallel resonant load 200, a harmonic current flows due to the voltage of the harmonic component of the rectangular wave voltage, so in order to prevent this. The first inductor 3 and the second inductor 4 are connected in series, but the voltage phase at the time of resonance is delayed due to the inductor component due to the series connection between the first inductor 3 and the second inductor 4.

In the control unit 28 of the inverter device 20, in order to correct this voltage phase delay, a delay setting circuit 40 for delaying the pulse phase on the drive side input to the phase comparison circuit 38 is provided to perform the delay correction.

(VII-2) In the above-described embodiment, when the start frequency is separated from the resonance frequency, specifically, it is exemplified that the start frequency is separated from the resonance frequency by 5% or more.

However, the start frequency is not limited to being separated from the resonance frequency by 5% or more, and may be separated from the resonance frequency by less than 5%.

That is, although the value of "5%" is a suitable value empirically obtained by the inventor of the present application through experiments, the value of "5%" is not limited to the value when the start frequency is separated from the resonance frequency. It suffices if the start frequency is far from the resonance frequency.

By separating the start frequency from the resonance frequency, it is possible to automatically find the resonance frequency by frequency shift, no matter how the resonance frequency on the parallel resonance load side deviates.

Here, the frequency shift region (frequency shift region) is preferably determined to be an inductive region in consideration of the diode reverse recovery characteristic that is optimal for the inverter circuit, and according to an experiment by the inventor of the present application, 5% or more from the resonance frequency. Was the area of.

(VII-3) In the above-described embodiment, the specific circuit configuration and the like in each configuration are omitted, but it goes without saying that a conventionally known circuit configuration corresponding to each configuration may be used.

(VII-4) In the above-described embodiment, the description of specific circuit constants and the like in each configuration is omitted, but it goes without saying that conventionally known circuit constants corresponding to each configuration may be used.

(VII-5) Inverter units 2, 2', 5, 6 described above as an inverter unit provided with a leakage current suppression circuit to the ground wire in the inverter unit according to the first to sixth embodiments. , 7, 8 and 9 are inverter units 2, 2', 5, 6, 7, 8 in which a voltage type inverter device (inverter device 10, inverter device 20) and a parallel resonance load 200 are connected via a transformer 202. , 9 has been described, but it goes without saying that the description is not limited to this.

For example, the inverter unit may be provided with a leakage current suppression circuit to the ground wire in the inverter unit, and an inverter unit for connecting the inverter device 10 and the parallel resonance load 200 without going through a transformer 202 may be constructed.

Specifically, as illustrated in FIG. 11, the inverter unit according to the first embodiment is provided with a leakage current suppression circuit to the ground wire, and the inverter device 10 and the parallel resonance load 200 are provided without going through the transformer 202. Inverter unit 2 ”that connects the above may be constructed.

However, in this case, it is preferable to insulate the single-phase alternating current (AC) power supply 102 side with the power transformer 400 to keep the entire circuit in a floating state.

Note that FIG. 11 shows an inverter unit that connects a voltage-type inverter device and a parallel resonance load without a transformer, and is an inverter unit according to an example of the embodiment of the present invention (first embodiment). A circuit configuration explanatory diagram showing the circuit configuration of an inverter unit (inverter unit that connects a parallel resonance load to a voltage-type inverter device without a transformer) provided with a leakage current suppression circuit to the ground wire is shown.

Alternatively, as illustrated in FIG. 12, the inverter unit according to the third embodiment is provided with a leakage current suppression circuit to the ground wire, and the inverter device 10 and the parallel resonance load 200 are connected without going through the transformer 202. The inverter unit 6'may be constructed.

In this case, by reducing the capacitance of the two capacitors (first capacitor for voltage division 209 and second capacitor for voltage division 210), the current of the commercial frequency component becomes smaller, so that single-phase alternating current (AC) is used. It is not necessary to provide a power transformer on the power supply 102 side.

Note that FIG. 12 shows an inverter unit that connects a voltage-type inverter device and a parallel resonance load without a transformer, and is an inverter unit according to an example of the embodiment of the present invention (third embodiment). A circuit configuration explanatory diagram showing the circuit configuration of an inverter unit (inverter unit that connects a parallel resonance load to a voltage-type inverter device without a transformer) provided with a leakage current suppression circuit to the ground wire is shown.

(VII-6) In the above embodiment, the case where a single-phase alternating current (AC) power supply is used as the alternating current power supply has been described, but it goes without saying that the alternating current power supply is not limited to this, and the alternating current power supply is not limited to this. For example, a three-phase AC power supply may be used. That is, in the present invention, any AC power source may be used, and if the inductors are connected to each of the lines connecting the voltage type inverter device and the parallel resonant load so that the inductances are the same. Good.

(VII-7) Of course, the above-described embodiments and the above-described embodiments (VII-1) to (VII-6) may be combined as appropriate.

The present invention can be used for an inverter unit in which a parallel resonant load is connected to a voltage-type inverter device.

1 Inverter unit 2 Inverter unit 2'Inverter unit 2 "Inverter unit 3 1st inductor 4 2nd inductor 5 Inverter unit 6 Inverter unit 6'Inverter unit 7 Inverter unit 8 Inverter unit 9 Inverter unit 10 Inverter device 12 Control unit (control means) )
12a PWM control unit (control means)
12b Frequency shift control unit (control means)
20 Inverter device 26 Voltage sensor 28 Control unit (control means)
30 Frequency shift circuit 32 Voltage control oscillator (VCO: Voltage-capacitor oscillator) circuit 34 Narrow pulse signal generation circuit 36 Output circuit 38 Phase comparison circuit 40 Delay setting circuit 42 Lock completion circuit 44 Detection circuit 46 Error amplifier filter 48 Triangular wave generation circuit 50 PWM circuit 100 Inverter device 102 Single-phase AC (AC) power supply 106 Inverter unit 108 Output sensor 200 Parallel resonance load 200a Heating coil 200b Resonance capacitor 202 Transformer 204 Inlet 206 Earth wire 207 Earth wire 208 Earth wire 209 First capacitor for voltage division 210 Second capacitor for voltage division 211 Resistance 212 Earth wire 213 Fluctuating device 214 Current sensor 215 Operation stop control unit (operation stop control means)
302 Converter unit 400 Power transformer Vh Output voltage Ih Output current Q Rectangular wave inverter drive signal NQ Rectangular wave inverter drive signal T 1 cycle of the fundamental wave component of the inverter unit output (output voltage or output current) T / 4 Inverter unit output 1/4 period of the fundamental wave component of (output voltage or output current) tw Rectangular wave Inverter drive signal Q, NQ pulse width

Claims (13)

It is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonant load is connected to the voltage type inverter device.
Inductors are connected to each of the lines connecting the voltage type inverter device and the parallel resonant load so that the inductance is the same.
A circuit for suppressing leakage current to the ground wire in an inverter unit, which comprises connecting a ground wire to a resonant capacitor constituting the resonant load. It is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonant load is connected to the voltage type inverter device via a transformer.
Inductors are connected to each of the lines connecting the voltage type inverter device and the transformer so that the inductance is the same.
A circuit for suppressing leakage current to the ground wire in an inverter unit, wherein the ground wire is connected to the midpoint of the winding on the secondary coil side of the transformer. It is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonant load is connected to the voltage type inverter device.
Inductors are connected to each of the lines connecting the voltage type inverter device and the parallel resonant load so that the inductance is the same.
To the ground wire in the inverter unit, which is characterized in that two capacitors having a capacitance smaller than the resonance capacitor of the parallel resonant load are connected to divide the voltage, and the ground wire is connected to the midpoint of the two capacitors. Leakage current suppression circuit. It is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonant load is connected to the voltage type inverter device via a transformer.
Inductors are connected to each of the lines connecting the voltage type inverter device and the transformer so that the inductance is the same.
Connect the ground wire to the midpoint of the winding on the secondary coil side of the transformer.
A leakage current suppression circuit to the ground wire in an inverter unit, which comprises connecting a resistor to the ground wire. It is a leakage current suppression circuit to the ground wire in the inverter unit in which a parallel resonant load is connected to the voltage type inverter device.
Inductors are connected to each of the lines connecting the voltage type inverter device and the parallel resonant load so that the inductance is the same.
A leakage current suppression circuit to the ground wire in an inverter unit, characterized in that a current transformer is connected to the parallel resonant load and a ground wire is connected to an intermediate point on the secondary side of the current transformer. In the leakage current suppression circuit to the ground wire in the inverter unit according to any one of claims 1, 2, 3, 4 or 5.
A current sensor provided on the ground wire and outputting a ground fault detection signal when a ground fault is detected based on the magnitude of the current flowing through the ground wire.
A circuit for suppressing leakage current to the ground wire in an inverter unit, which comprises an operation stop control means for controlling the operation of the inverter device when a ground fault detection signal output from the current sensor is input. In the leakage current suppression circuit to the ground wire in the inverter unit according to any one of claims 1, 2, 3, 4, 5 or 6.
The voltage type inverter device is a PWM-controlled voltage type inverter.
An inverter unit connected to the parallel resonant load and driven by an inverter drive signal,
It has a control means for controlling the operation of the inverter unit.
The control means uses a pulse signal having a pulse width shorter than the period of the resonance frequency of the resonance load as the inverter drive signal, starts driving the inverter portion from a frequency distant from the resonance frequency, and then drives the inverter. Leakage current to the ground wire in the inverter unit, characterized in that the frequency of the signal is frequency-shifted to the resonance frequency or the vicinity of the resonance frequency, and the frequency of the inverter drive signal is controlled so as to substantially match the resonance frequency. Suppression circuit. In the leakage current suppression circuit to the ground wire in the inverter unit according to claim 7.
The short pulse width is a pulse width at which the output of the inverter unit becomes the minimum set output value of the set value indicated by the output setting signal from the outside. The leakage current suppression circuit to the ground wire in the inverter unit. In the leakage current suppression circuit to the ground wire in the inverter unit according to any one of claims 7 or 8.
The starting point is a leakage current suppression circuit to the ground wire in the inverter unit, which is characterized in that the frequency is lower than the resonance frequency. In the leakage current suppression circuit to the ground wire in the inverter unit according to any one of claims 7, 8 or 9.
The control unit is a leakage current suppression circuit to the ground wire in an inverter unit, which comprises a delay correction means for correcting a voltage phase delay due to the inductor. In the leakage current suppression circuit to the ground wire in the inverter unit according to any one of claims 7, 8, 9 or 10.
The control unit controls the frequency of the inverter drive signal so as to substantially match the resonance frequency, and then widens the pulse width of the inverter drive signal by PWM control to the ground wire in the inverter unit. Leakage current suppression circuit. This is a method of suppressing leakage current to the ground wire in an inverter unit in which a parallel resonant load is connected to a voltage-type inverter device.
Inductors are connected to each of the lines connecting the voltage type inverter device and the parallel resonant load so that the inductance is the same.
A method for suppressing leakage current to the ground wire in an inverter unit, which is characterized in that leakage of current to the ground wire is suppressed by suppressing an inductance imbalance in each phase. In the method for suppressing leakage current to the ground wire in an inverter unit in which a parallel resonant load is connected to the voltage type inverter device according to claim 12.
The voltage type inverter device is a PWM-controlled voltage type inverter.
A pulse signal having a pulse width shorter than the period of the resonance frequency of the parallel resonance load is used as an inverter drive signal, and after starting driving of the inverter unit from a frequency distant from the resonance frequency, the frequency of the inverter drive signal is used as the resonance. A method for suppressing leakage current to the ground wire in an inverter unit, which comprises controlling the frequency of the inverter drive signal so as to substantially match the resonance frequency by shifting the frequency to the frequency or the vicinity of the resonance frequency.

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