JP2829237B2 - Inverter device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an inverter device for compensating reactive power of a power system.

[0002]

2. Description of the Related Art FIG. 9 shows the configuration of a conventional inverter device of this kind. In the figure, 1 is a three-phase AC system bus, 2
Is a reference circuit for generating a reference value (predetermined) such as a system voltage and a load current of the three-phase AC system bus 1, and 3 is a current detection for detecting a system voltage and a load current of the three-phase AC system bus 1. (CT), 4 is a reference value output from the reference circuit 2 and a system voltage of the three-phase AC system bus 1 output from the current detector 3,
A current control circuit for comparing and calculating the load current and the like to generate an output voltage reference of the inverter device.
A carrier triangular wave reference for generating a signal serving as a reference for generating a pulse for controlling 0, 6 a comparator for comparing the output voltage reference output from the current control circuit with a reference carrier triangular wave, 7
Is a logic circuit that generates a pulse for controlling the power semiconductor element of the inverter circuit 10 based on the comparison result of the comparator 6, 8 is a pulse amplifier that amplifies the control pulse generated by the logic circuit 7 and drives the inverter circuit 10, 9 is a DC capacitor for storing DC voltage, 10 is GTO
An inverter circuit that is composed of a power semiconductor such as a thyristor and converts the DC voltage stored in the DC capacitor 9 into an AC voltage; 11 is an inverter transformer that supplies the AC voltage converted by the inverter device 10 to the three-phase AC system bus 1 It is.

Next, the operation will be described. The inverter device of FIG. 9 operates so as to compensate for the reactive power when the reactive power is generated in the three-phase AC system bus 1 due to a fluctuation of a load (not shown) or the like. That is, the current detector 3
Detects the system voltage, load current, etc. of the three-phase AC system bus 1,
Output to the current control circuit 4. The current control circuit 4 compares the system voltage, the load current, and the like with a reference value output from the reference circuit 2 to obtain a deviation, thereby obtaining a voltage to be compensated.
A current amount is obtained, and the deviation is multiplied by a predetermined current control gain to generate an output voltage reference of the inverter device.

The output voltage reference of the inverter device generated by the current control circuit 4 is output to a comparator 6. In the comparator 6, the output voltage reference of the inverter device is compared with the reference carrier triangular wave output from the carrier triangular wave reference 5 and converted into a signal serving as a reference for turning on / off the power semiconductor element of the inverter circuit 10. You. The logic circuit 7 generates a predetermined pulse signal based on the output of the comparator 6.
After amplifying the pulse signal, the pulse amplifier 8 supplies the pulse signal to the gate of a power semiconductor element such as a GTO thyristor of the inverter circuit 10.

The inverter circuit 10 turns on / off the output of the DC capacitor 9 based on the output of the pulse amplifier 8,
The DC voltage stored in the DC capacitor 9 is converted into a rectangular-wave AC voltage approximate to the inverter output voltage reference, and supplied to the three-phase AC system bus 1 via the inverter transformer 11. At this time, the output voltage of the inverter transformer 11 becomes 3
If the voltage is higher than the voltage of the phase AC system bus 1, the leading reactive power is compensated. If the voltage is smaller than the voltage of the phase AC system bus 1, the delay reactive power is compensated. Compensate.

[0006]

Since the conventional inverter device is configured as described above, the inverter transformer 11 is excited by the output voltage from the inverter circuit 10 and outputs a predetermined output to the three-phase AC system bus. The output voltage of the inverter transformer 11 is different from the output voltage of each half-wave on the positive side and the negative side of the output voltage,
When the balance is not achieved, or when the output voltage changes suddenly and the balance between the positive and negative polarities cannot be achieved, the drive current of the inverter transformer 11 increases because the inverter transformer 11 is magnetized. In some cases, an overcurrent occurs and stable operation cannot be continued. In particular, when there is a steady magnetization, there is no operating point at the center of the hysteresis characteristic of the iron core of the inverter transformer 11, so that the magnetic flux is apt to be saturated due to a sudden magnetization caused by a load change or the like, and an overcurrent occurs. There was a drawback that it was easy.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and compensates for transient magnetizing of an inverter transformer and compensates for steady magnetizing of an inverter transformer. is there.

[0008]

According to a first aspect of the present invention, there is provided an inverter device for converting a DC voltage into an AC voltage, an inverter transformer receiving the output of the inverter circuit and outputting a compensation power, and the inverter device. A bias detection unit for determining a deviation corresponding to the bias component of the transformer, and a correction signal for a steady component of the deviation detected by the deflection detection unit, and output after delaying the correction signal A first correction circuit, a second correction circuit for generating a correction signal for a transient component of the deviation detected by the demagnetization detection unit, an output of the first correction circuit, An adder that combines the output of the correction circuit; a control circuit that generates a control signal for the inverter circuit based on the output of the adder; and an inverter that drives the inverter circuit based on the output of the control circuit. Those with an amplifier.

According to a second aspect of the present invention, in the inverter device, the demagnetization detecting section detects a primary current output for detecting a primary output of the inverter transformer and a secondary current output of the inverter transformer. And a subtractor for calculating a deviation between the output of the first current detector and the output of the second current detector.

According to a third aspect of the present invention, in the inverter device, the demagnetization detecting section detects a first voltage detector for detecting a primary output of the inverter transformer and a secondary output of the inverter transformer. A second voltage detector, a subtractor for obtaining a deviation between the output of the first voltage detector and the output of the second voltage detector, and extracting a low-frequency component of the deviation output by the subtractor. And a filter circuit that performs the filtering.

According to a fourth aspect of the present invention, in the inverter device, the magnetic flux detecting section includes a magnetic flux detector for detecting a magnetic flux of an iron core of the inverter transformer, and a filter circuit for extracting a low frequency component of the output of the magnetic flux detector. It consists of and.

According to a fifth aspect of the present invention, there is provided an inverter circuit for converting a DC voltage to an AC voltage, an inverter transformer for receiving the output of the inverter circuit and outputting a compensation power, and a bias component of the inverter transformer. Generating a correction signal for a steady-state component of the deviation detected by the first and second polarization detection units; A first correction circuit that outputs a correction signal after delaying the correction signal, a second correction circuit that generates a correction signal for a transient component of the deviation detected by the second magnetic field detection unit, 1
An adder that combines the output of the correction circuit with the output of the second correction circuit; a control circuit that generates a control signal for the inverter circuit based on the output of the adder; And an amplifier for driving an inverter circuit.

According to a sixth aspect of the present invention, in the inverter device, the first demagnetization detecting section includes a first voltage detector for detecting a primary output of the inverter transformer, and a secondary side of the inverter transformer. A second voltage detector for detecting an output;
And a filter circuit for extracting a low frequency component of the deviation output from the subtractor, and a subtractor for obtaining a deviation between the output of the voltage detector and the output of the second voltage detector. A first current detector for detecting a primary side output of the inverter transformer, a second current detector for detecting a secondary side output of the inverter transformer, and the first current detector. And a subtractor for calculating a deviation between the output of the current detector and the output of the second current detector.

According to a seventh aspect of the present invention, in the inverter device, the first magnetic deflector detecting unit detects the magnetic flux of the iron core of the inverter transformer, and extracts a low frequency component of the output of the magnetic flux detector. A first current detector for detecting a primary side output of the inverter transformer, and a secondary side output of the inverter transformer. And a subtractor for calculating a deviation between the output of the first current detector and the output of the second current detector.

The inverter device according to claim 8, wherein the first correction circuit comprises: a comparator for outputting a signal when a deviation output from the magnetic deflector becomes larger than a predetermined value; The pulse generator includes a pulse generator that outputs a pulse signal based on the output of the comparator, and an integrator that integrates the pulse signal output by the pulse generator.

[0016]

According to the first aspect of the present invention, the inverter circuit converts a DC voltage to an AC voltage, the inverter transformer receives the output of the inverter circuit and outputs compensation power, and the magnetic deflector detects the inverter transformer. The first correction circuit generates a correction signal for a steady component of the deviation detected by the magnetic field detection unit, and outputs the correction signal after delaying the correction signal. , A second correction circuit generates a correction signal for a transient component of the deviation detected by the demagnetization detection unit, and an adder outputs the output of the first correction circuit and the output of the second correction circuit. The control circuit generates a control signal for the inverter circuit based on the output of the adder, and the amplifier drives the inverter circuit based on the output of the control circuit.

According to a second aspect of the present invention, the first current detector of the bias detecting section detects the primary output of the inverter transformer, and the second current detector is connected to the second side of the inverter transformer. A secondary output is detected, and a subtractor obtains a deviation corresponding to a magnetic component based on the output of the first current detector and the output of the second current detector.

According to a third aspect of the present invention, the first voltage detector of the demagnetization detector detects the primary output of the inverter transformer, and the second voltage detector detects the primary output of the inverter transformer. A secondary output is detected, and a subtractor obtains a deviation corresponding to a magnetic component based on the output of the first voltage detector and the output of the second voltage detector. The low frequency component of the deviation is extracted.

According to a fourth aspect of the present invention, the magnetic flux detector of the magnetic deflector detecting part detects the magnetic flux of the iron core corresponding to the magnetic deflector of the inverter transformer, and the filter circuit detects the low frequency of the output of the magnetic flux detector. Extract the components.

According to a fifth aspect of the present invention, the inverter circuit converts a DC voltage into an AC voltage, and the inverter transformer receives the output of the inverter circuit and outputs compensation power.
A first magnetic deflector detecting section and a second magnetic deflector detecting section obtain a deviation corresponding to a magnetic deflected component of the inverter transformer, and a first correction circuit calculates a deviation of the deviation detected by the first magnetic deflector detecting section. The second correction circuit generates a correction signal for the stationary component among the above and outputs the correction signal after delaying the correction signal, and the second correction circuit corrects the transient component of the deviation detected by the second magnetic field detection unit. A correction signal is generated, an adder combines an output of the first correction circuit and an output of the second correction circuit, and a control circuit generates a control signal of the inverter circuit based on an output of the adder. An amplifier drives the inverter circuit based on the output of the control circuit.

According to a sixth aspect of the present invention, the first voltage detector of the first demagnetization detector detects the primary output of the inverter transformer, and the second voltage detector detects the primary transformer output. The output of the first voltage detector and the output of the second voltage detector are determined by a subtractor, and the filter circuit detects a low deviation of the output from the subtractor. Extracting a frequency component, a first current detector of the second magnetic field detecting unit detects a primary output of the inverter transformer,
A second current detector detects a secondary output of the inverter transformer, and a subtractor determines a deviation between the output of the first current detector and the output of the second current detector.

According to a seventh aspect of the present invention, the magnetic flux detector of the first magnetic deflector detecting part detects a magnetic flux corresponding to the demagnetization of the iron core of the inverter transformer, and the filter circuit outputs the output of the magnetic flux detector. , The first current detector of the second bias detection unit detects the primary output of the inverter transformer, and the second current detector detects the primary output of the inverter transformer. A secondary output is detected, and a subtractor obtains a deviation between the output of the first current detector and the output of the second current detector.

In a preferred embodiment of the present invention, the comparator of the first correction circuit outputs a signal when the deviation output from the magnetic deflector becomes larger than a predetermined value, and a pulse generator is provided. Outputs a pulse signal based on the output of the comparator, and the integrator integrates the pulse signal output by the pulse generator.

[0024]

【Example】

Embodiment 1 FIG. Hereinafter, an inverter device according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of the inverter device according to the first embodiment. In the figure, 1 is a three-phase AC system bus, and 2 is a predetermined three-phase AC system bus 1
A reference circuit for generating reference values such as system voltage and load current of the
Reference numeral 3 denotes a system voltage of the three-phase AC system bus 1, a current detector (CT) for detecting a load current, 4 denotes a reference value output by the reference circuit 2 and a system voltage of the three-phase AC system bus 1 output by CT3,
A current control circuit for comparing and calculating the load current and the like to generate an output voltage reference of the inverter device.
A carrier triangular wave reference for generating a signal serving as a reference for generating a pulse for controlling 0, a comparator 6 for comparing the output voltage reference of the inverter device with a reference carrier triangular wave, and 7 based on a comparison result of the comparator 6 A logic circuit that generates a pulse for controlling the power semiconductor element of the inverter circuit 10, a pulse amplifier 8 that amplifies the control pulse generated by the logic circuit 7 to drive the inverter circuit 10, and a DC amplifier 9 that stores a DC voltage The capacitor 10 is composed of a power semiconductor such as a GTO thyristor, and an inverter circuit for converting the DC voltage stored in the DC capacitor 9 into an AC voltage.
An inverter transformer to be supplied to the phase AC system bus 1.

Reference numeral 12 denotes a current detector (DCCT) for measuring and outputting a secondary current of the inverter transformer 11;
Is a subtractor for calculating the difference between the output of the CT3 and the output of the DCCT 12, 14 is an amplifier for amplifying the output of the subtractor 13, 15
Is a DC bias generator for adjusting the offset output of the amplifier 14 during normal operation, 16 is an adder for adding the output of the amplifier 14 and the output of the DC bias generator 15, and 17 is based on the output of the adder 16. A comparator for determining whether or not the bias current exceeds a predetermined value;
18 is an inverter transformer 11 based on the output of the comparator 17.
When the imbalance between the positive and negative portions of the output voltage of the output voltage is greater than a predetermined reference, a pulse generator that outputs a pulse having a predetermined positive or negative constant amplitude and a constant duration, 19 An integrator that integrates the output of the pulse generator 18 to convert it into a DC signal, delays the DC signal, and outputs the delayed DC signal;
Reference numeral 20 denotes a filter circuit for extracting a steep / transient component of the demagnetized component from the output of the adder 16, and 21 denotes an integrator 19
Adder for adding the output of the filter circuit 20 and the output of the filter circuit 20;
An adder 22 adds the output of the current control circuit 4 and the output of the adder 21.

In FIG. 1, portions surrounded by a chain line, namely, a DC current detector 12, a subtractor 13, an amplifier 14,
The DC bias generator 15, the adder 16, the comparator 17, the pulse generator 18, the integrator 19, the filter circuit 20, the adder 21, and the adder 22 represent a demagnetizing compensator. Further, the comparator 17, the pulse generator 18, and the integrator 19 are a first correction circuit for generating a correction signal of a stationary component of the magnetic bias, and the filter circuit 20 includes a transient component of the magnetic bias. Is a second correction circuit for generating the correction signal of FIG.

Next, the operation will be described. 1 includes a comparator 17, a pulse generator 18, an integrator 1
9 to detect the steady magnetization, while the filter circuit 2
0 is used to detect transitional magnetization. For both the steady magnetic polarization and the transient magnetic polarization, magnetic polarization compensation is performed based on the signal added by the adder 21.

First, the operation in the case of compensating for the steady magnetization is described. As a prerequisite for operation, the inverter device shown in FIG. 1 has a deviation between the primary current and the secondary current of the inverter transformer 11 obtained as the output of the amplifier 14 in a normal (non-magnetized) operation state. It is assumed that the correction has been made. That is, in the normal state, the subtractor 1
3. The DC bias generator 15 is adjusted so that the deviation between the primary current and the secondary current obtained by the amplifier 14 becomes zero at the output of the adder 16.

In this case, when a steady magnetization occurs, as shown in FIG. 2, an imbalance occurs between the positive peak value and the negative peak value in the output corresponding to the current deviation of the adder 16. This occurs (in the figure, the magnetic field gradually deviates to the negative side). This figure shows the waveform when there is no bias correction, and since the bias increases and increases, even if a slight steady bias occurs, it cannot be ignored.

Then, the comparator 17 detects that the imbalance between the positive peak value and the negative peak value of the output of the adder 16 has become larger than a predetermined value due to the steady magnetization, Then, the pulse generator 18 receives the output of the comparator 17 and generates a pulse having a predetermined constant level and a predetermined width so as to balance the positive and negative voltage-time products and correct the magnetic bias. The output of the inverter circuit 10 is controlled slowly. That is, the pulse generator 18, when the deviation current is the output of the adder 16 Ip, the peak current is a predetermined threshold value for determining that steady magnetic bias has occurred was I _1, A constant pulse is generated by the following equations (1) to (3).

[0031] Ip> pulse generating levels A ₁ when _{I 1} (pulse width time T) (1) Ip <pulse generating levels -A ₁ when -I ₁ (pulse width time T) (2) - When I ₁ ≦ Ip ≦ I _{1 No} pulse is generated (3) However, the pulse amplitude A ₁ and the pulse width T are predetermined.

The output pulse of the pulse generator 18 is integrated and delayed by an integrator 19 and converted into a constant value.
Is output to Here, the delay is performed for a time corresponding to several tens of cycles of the signal.

Here, the comparator 17, the pulse generator 18,
The reason why the integrator 19 calculates the steady-state magnetization correction amount is as follows. In the case of steady magnetic demagnetization caused by the imbalance of the positive and negative voltage products of the output voltage, the magnetic flux gradually saturates over a plurality of cycles according to the hysteresis characteristic of the inverter transformer 11. In such a case, it is necessary to detect a sign of steady magnetization (a gradual change in the center of the hysteresis cycle) and correct the magnetization before the magnetic flux is saturated. Further, at this time, if the magnetic field demagnetization correction is performed abruptly, the control cannot be stabilized due to excessive correction, so that it is necessary to delay the control. Therefore, as shown in FIG. 1, by a combination of the pulse generator 18 and the integrator 19, if the magnetic field is slightly demagnetized, a small correction is made. If is not found, control is performed to further increase the amount of correction (to generate a pulse). In this way, even if the magnetic field is once demagnetized, the stepwise control is performed with a delay of about several seconds (about several tens of cycles of the signal) to gradually correct the demagnetization.

Next, the adder 21 adds the stationary demagnetization compensation signal output from the integrator 19 and the demagnetization compensation signal at the time of a transient change output from the filter circuit 20 to be described later. 22. The adder 22 shifts the voltage reference output by the current control circuit 4 to a polarity that can compensate for the demagnetization by adding the demagnetization compensation signal of the adder 21 and the output of the current control circuit 4 ( (Fig. 4). That is, when compensating for the steady magnetization, the adder 2
Reference numeral 2 denotes a normal voltage reference signal (FIG. 4A)
9 offsetting corresponds to the output (s ₁₎ in (Fig (b)). The dotted line in FIG. 3B is a voltage reference signal when no correction is made.

The output voltage reference output from the adder 22 is output to the comparator 6 as in the case of the conventional example. In the comparator 6, the inverter output voltage reference is compared with the reference carrier triangular wave output from the carrier triangular wave reference 5 and converted into a signal serving as a reference for turning on / off the power semiconductor element of the inverter circuit 10. The logic circuit 7 generates a predetermined pulse signal based on the output of the comparator 6. After amplifying the pulse signal, the pulse amplifier 8 supplies the pulse signal to the gate of a power semiconductor element such as a GTO thyristor of the inverter circuit 10.

The inverter circuit 10 turns on / off the output of the DC capacitor 9 based on the output of the pulse amplifier 8,
The DC voltage stored in the DC capacitor 9 is converted into a rectangular-wave AC voltage approximate to the inverter output voltage reference, and supplied to the three-phase AC system bus 1 via the inverter transformer 11. At this time, the output voltage of the inverter transformer 11 becomes 3
When the voltage is higher than the voltage of the phase AC system bus 1, the reactive power is compensated for, and when the voltage is smaller than the voltage of the bus 1, the reactive power is compensated for. Can compensate,
Peak value of the output of the adder 16 as shown in FIG. 3 is -I ₁
Since the exciting current of the inverter transformer 11 is controlled so as to be within the range from + I ₁ to + I ₁ , steady magnetization can be compensated.

Next, the operation of transient magnetic bias compensation will be described. When magnetizing is caused by a sudden change in load or the like, the exciting impedance rapidly decreases, so that a sudden magnetizing current flows through the output of the DC current detector 12 as shown in FIG. Then, an attempt is made to compensate for the sudden magnetic bias current, and the device becomes in an overcurrent state, so that normal operation cannot be performed. Therefore, we compensate immediately for this transient magnetic bias,
It is necessary to compensate for the magnetization before an overcurrent occurs.

In the case where the magnetization is generated due to the transient change, the filter circuit 20 detects only the instantaneous magnetization current component (transient magnetization current component) from the output of the adder 16. The adder 21 adds the transient magnetizing current component output from the filter circuit 20 and the steady magnetizing current component output from the integrator 19, and outputs the result to the adder 22. The output of the adder 22 is, for example, as shown in FIG.
A part of one cycle of the signal is corrected so as to be able to compensate for a sudden magnetization. The operation of the comparator 6 and thereafter is the same as that of the case where the steady demagnetization is compensated.
The description is omitted.

As described above, according to the first embodiment, the comparator 17, the pulse generator 18, and the integrator 19 gradually compensate for the steady magnetization, and the filter circuit 2
0 compensates for transient magnetization, so steady magnetization,
More effective compensation can be performed for any of the transient magnetic bias, and the operation can be stably continued without generating an overcurrent. In addition, the steady magnetization can be compensated slowly, and the operating point in the hysteresis curve can be set almost at the center. Even in this case, the saturation of the magnetic flux of the inverter transformer hardly occurs, and the overcurrent of the inverter device does not occur.

Embodiment 2 FIG. In the first embodiment, the primary side current and the secondary side current of the inverter transformer 11 are used to determine the deviation due to the magnetic bias. However, the present invention is not limited to this. The secondary voltage may be used. FIG. 5 shows the configuration of the second embodiment.

In the figure, reference numeral 23 denotes an inverter transformer 1
1 is a voltage detector (PT) for detecting the primary voltage, 24 is a voltage detector (DCPT) for detecting the secondary voltage of the inverter transformer 11, and 25 is a low frequency component extracted from the output of the subtractor 13. Filter circuit. .., And the adder 22 are the same as those shown in FIG. The operation waveform of each unit is the same as that of the first embodiment.

The operation of the inverter of FIG. 5 is the same as that of the inverter of FIG. 1, except that the difference between the primary voltage and the secondary voltage of the inverter transformer 11 is used as the deviation. That is, the PT 23 obtains the voltage on the three-phase AC system bus 1 side, the DCPT 24 obtains the voltage on the inverter circuit 10 side, obtains the deviation by the subtractor 13, and further uses the filter circuit 25 to obtain the low frequency component of the deviation. To detect. The deviation output from the filter circuit 25 is output to the amplifier 14.

In the inverter device, when the exciting voltage of the inverter transformer 11 has a DC component (DC component),
By accumulating this DC component, the operating point on the hysteresis curve moves from the center, and a steady magnetic bias occurs. By the way, according to the configuration of FIG. 5, the DC component of the voltage of the inverter transformer 11 can be measured more accurately than in the case of the first embodiment, so that the sign of the steady magnetization can be detected earlier. By controlling the DC component so as not to flow, it is possible to control the bias current and the overcurrent caused by the bias before they flow.

As described above, according to the second embodiment, since the accuracy of the detection of the DC component of the steady deviation is improved, the steady demagnetization compensation is more effectively performed than in the first embodiment. I can do it.

Embodiment 3 FIG. In the second embodiment, the voltage detector is used for measuring the voltage for obtaining the deviation. However, the present invention is not limited to this, and a search coil may be used. FIG. 6 shows the configuration of the third embodiment.

In the figure, reference numeral 26 denotes an inverter transformer 1
1 is a search coil that is provided on the iron core and detects a magnetic flux of the iron core. .., And the adder 22 are the same as those shown in FIG. The operation waveform of each unit is the same as that of the first embodiment.

The operation of the inverter device of FIG. 6 is the same as that of the inverter device of FIG. 5 except that the magnetic flux of the iron core of the inverter transformer 11 detected by the search coil 26 is used as the deviation. That is, the search coil 26 outputs a voltage corresponding to the magnetic flux of the iron core of the inverter transformer 11, and the filter circuit 25 detects a low frequency component of the output of the search coil 26. The deviation output from the filter circuit 25 is output to the amplifier 14.

As described above, according to the third embodiment, the search coil 2 provided on the iron core in the inverter transformer 11
6, the accuracy can be improved by controlling based on the actual magnetic flux level, and the current detector and the voltage detector required in the first and second embodiments become unnecessary, and the size of the device can be reduced. Can be achieved.

Embodiment 4 FIG. In the above-described first to third embodiments, the comparator 17, the pulse generator 18, and the integrator 19 for correcting the steady magnetic polarization, and the filter circuit 20 for correcting the transient magnetic polarization are provided. Have been supplied with a common signal, but these signals may be signals by different means. FIG. 7 shows the configuration of the fourth embodiment.

In the figure, a three-phase AC system bus 1,...
The filter circuit 25 is the same as that shown in FIGS. The operation of the inverter device of FIG. 7 is to input a deviation between the PT23 and the DCPT24 to the comparator 17 via the filter circuit 25 in order to correct a steady magnetic polarization, while correcting a transient magnetic polarization. For CT3 and D
The operation is the same as that of the inverter device shown in FIGS. 1 and 5 except that the deviation from the CCT 12 is input to the filter circuit 20 via the amplifier 14b (not through the filter circuit 25).

As described above, according to the fourth embodiment, the steady magnetization compensation is performed based on the output of the voltage detector capable of accurately detecting the DC component of the voltage, and the transient magnetization compensation is performed. Since the correction is performed based on the output of the current detector, it is possible to improve the compensation accuracy for the steady magnetization while providing effective compensation even when a transiently changing magnetization current flows.

Embodiment 5 FIG. Although the fourth embodiment is a combination of the first and second embodiments, the fourth embodiment may be a combination of the first and third embodiments. FIG. 7 shows the configuration of the fifth embodiment.

In the figure, a three-phase alternating current system bus 1,...
The filter circuit 25 is the same as that shown in FIGS. The operation of the inverter device of FIG. 8 is to input a magnetic flux signal from the search coil 16 to the comparator 17 via the filter circuit 25 in order to correct steady magnetic demagnetization.
On the other hand, CT3 and DCC
The operation is the same as that of the inverter device of FIGS. 1 and 6 except that the deviation due to T12 is input to the filter circuit 20 via the amplifier 14b (not through the filter circuit 25).

As described above, according to the fifth embodiment, the steady magnetization is compensated based on the output of the search coil which can accurately detect the DC component of the voltage, and the transient magnetization is compensated for by the current. Since the correction is performed based on the output of the detector, it is possible to improve the compensation accuracy for the steady magnetization while providing effective compensation even when a transiently changing magnetization current flows. Further, compared to the fourth embodiment, the components of the voltage detector are not required, the number of components can be reduced, and the device can be downsized.

[0055]

As described above, according to the first aspect of the present invention, there is provided a magnetic field detecting unit for obtaining a deviation corresponding to a magnetic component of the inverter transformer, A first correction circuit that generates a correction signal for a stationary component and outputs the correction signal after delaying the correction signal;
A second correction circuit for generating a correction signal for a transient component of the deviation detected by the magnetic field detection unit;
An adder that combines the output of the correction circuit with the output of the second correction circuit; a control circuit that generates a control signal for the inverter circuit based on the output of the adder; Since it is equipped with an amplifier that drives the inverter circuit, it is possible to compensate for both steady and transient magnetic polarization, prevent overcurrent due to the magnetic polarization of the inverter transformer, and maintain a stable Driving can be performed.

According to the second aspect of the present invention, the demagnetization detecting section includes a first current detector for detecting a primary output of the inverter transformer, and a secondary output of the inverter transformer. , And a subtractor for calculating a deviation between the output of the first current detector and the output of the second current detector. Compensation can be performed for both magnetic polarization and transient magnetic polarization.

Further, according to the third aspect of the present invention, the demagnetization detecting unit includes a first voltage detector for detecting a primary output of the inverter transformer, and a secondary output of the inverter transformer. A second voltage detector for detecting an output of the first voltage detector, a subtractor for obtaining a deviation between the output of the first voltage detector and the output of the second voltage detector, and a low-frequency component of the deviation output by the subtractor. , A sign of steady magnetic demagnetization can be quickly detected, and steady magnetic compensation can be more effectively performed.

According to the fourth aspect of the present invention, the magnetic flux detector detects the magnetic flux of the iron core of the inverter transformer, and extracts a low frequency component of the output of the magnetic flux detector. Since it is composed of the filter circuit, the measurement accuracy of the magnetic polarization is improved, the magnetic polarization can be accurately compensated, and the device can be downsized.

According to the fifth aspect of the present invention, the first and second magnetic field detecting sections for obtaining the deviation corresponding to the magnetic field component of the inverter transformer, and the first magnetic field detecting section. A first correction circuit that generates a correction signal for a stationary component of the deviation detected by the detection unit and outputs the correction signal after delaying the correction signal, and a deviation correction unit that detects the deviation detected by the second magnetization detection unit. A second correction circuit for generating a correction signal for the transient component, an adder for combining an output of the first correction circuit and an output of the second correction circuit, and an output of the adder. A control circuit for generating a control signal for the inverter circuit based on the output of the control circuit, and an amplifier for driving the inverter circuit based on the output of the control circuit. Compensation can be performed accurately

According to the sixth aspect of the present invention, the first
A first voltage detector for detecting a primary side output of the inverter transformer, a second voltage detector for detecting a secondary side output of the inverter transformer, and the first And a filter circuit for extracting a low frequency component of the deviation output from the subtractor, and a subtractor for obtaining a deviation between the output of the voltage detector and the output of the second voltage detector. A first current detector for detecting a primary side output of the inverter transformer, a second current detector for detecting a secondary side output of the inverter transformer, and the first current detector. And the subtractor for calculating the deviation between the output of the current detector and the output of the second current detector.
In addition to being able to accurately perform demagnetization compensation for both steady and transient demagnetization, it is also possible to detect signs of steady demagnetization earlier, making steady demagnetization compensation more effective. Can be done

According to the seventh aspect of the present invention, the first
A magnetic flux detector for detecting the magnetic flux of the iron core of the inverter transformer, and a filter circuit for extracting a low frequency component of the output of the magnetic flux detector,
A second current detector for detecting a secondary output of the inverter transformer, a first current detector for detecting a primary output of the inverter transformer, a second current detector for detecting a secondary output of the inverter transformer, Since it is composed of a subtractor for calculating a deviation between the output of the first current detector and the output of the second current detector, the magnetic field is compensated for both the steady magnetization and the transient magnetization. In addition to accurate measurement, the measurement accuracy of the magnetization is improved, and the magnetization compensation can be performed accurately, and the device can be downsized.

According to the eighth aspect of the present invention, the first
A correction circuit, a comparator that outputs a signal when the deviation output by the magnetic deflector detection unit becomes larger than a predetermined value, and a pulse generator that outputs a pulse signal based on the output of the comparator. And an integrator for integrating the pulse signal output from the pulse generator, so that accurate correction can be performed with a simple configuration.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an inverter device according to a first embodiment of the present invention.

FIG. 2 is a waveform chart for explaining an operation of the inverter device according to the first embodiment of the present invention.

FIG. 3 is a waveform chart for explaining an operation of the inverter device according to the first embodiment of the present invention.

FIG. 4 is an example of a voltage reference according to the first embodiment of the present invention.

FIG. 5 is a configuration diagram of an inverter device according to a second embodiment of the present invention.

FIG. 6 is a configuration diagram of an inverter device according to a third embodiment of the present invention.

FIG. 7 is a configuration diagram of an inverter device according to a fourth embodiment of the present invention.

FIG. 8 is a configuration diagram of an inverter device according to a fifth embodiment of the present invention.

FIG. 9 is a configuration diagram of a conventional inverter device.

[Explanation of symbols]

3 Current detector (CT), 11 Inverter transformer, 1
2 DC current detector (DCCT), 13 Subtractor, 14
Amplifier, 17 comparator, 18 pulse generator, 19
Integrator, 20 filter circuit, 21 adder, 22 adder, 23 voltage detector (PT), 24 DC voltage detector (DCPT), 25 filter circuit, 26 search coil.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) H02M 7/42-7/98 G05F 1/12-1/445 G05F 1/70 H02J 3/00-5 / 00

Claims (8)

(57) [Claims] 1. An inverter circuit for converting a DC voltage to an AC voltage, an inverter transformer receiving an output of the inverter circuit and outputting a compensation power, and a bias for obtaining a deviation corresponding to a magnetic component of the inverter transformer. A magnetic detection unit, a first correction circuit that generates a correction signal for a steady component of the deviation detected by the magnetic polarization detection unit, and outputs the correction signal after delaying the correction signal; A second correction circuit for generating a correction signal for a transient component of the deviation detected by the adder, an adder for combining an output of the first correction circuit and an output of the second correction circuit, An inverter device comprising: a control circuit that generates a control signal for the inverter circuit based on an output of an adder; and an amplifier that drives the inverter circuit based on an output of the control circuit. A first current detector for detecting a primary output of the inverter transformer; and a second current detector for detecting a secondary output of the inverter transformer. 2. The inverter device according to claim 1, further comprising: a subtractor for calculating a difference between an output of the first current detector and an output of the second current detector. A first voltage detector for detecting a primary output of the inverter transformer; and a second voltage detector for detecting a secondary output of the inverter transformer. A subtractor for calculating a deviation between the output of the first voltage detector and the output of the second voltage detector; and a filter circuit for extracting a low-frequency component of the deviation output by the subtractor. The inverter device according to claim 1, wherein 4. A magnetic flux detector comprising: a magnetic flux detector for detecting a magnetic flux of an iron core of the inverter transformer; and a filter circuit for extracting a low frequency component of an output of the magnetic flux detector. The inverter device according to claim 1, wherein: 5. An inverter circuit for converting a DC voltage to an AC voltage, an inverter transformer for receiving an output of the inverter circuit and outputting a compensation power, and determining a deviation corresponding to a magnetic component of the inverter transformer. Generating a correction signal for a steady component of the deviation detected by the first and second magnetic field detection units and the first magnetic field detection unit, and delaying the correction signal A first correction circuit for outputting, a second correction circuit for generating a correction signal for a transient component of the deviation detected by the second magnetic field detection unit, and an output of the first correction circuit. An adder that combines the output of the second correction circuit; a control circuit that generates a control signal for the inverter circuit based on the output of the adder; and an amplifier that drives the inverter circuit based on the output of the control circuit When Inverter device equipped with 6. A first voltage detector for detecting a primary side output of the inverter transformer, wherein the first magnetic field detector comprises:
A second voltage detector for detecting a secondary output of the inverter transformer, a subtractor for obtaining a difference between an output of the first voltage detector and an output of the second voltage detector, And a filter circuit for extracting a low-frequency component of the deviation output from the detector.
A first current detector for detecting a primary output of the inverter transformer, a second current detector for detecting a secondary output of the inverter transformer, and an output of the first current detector. 6. The inverter device according to claim 5, further comprising a subtractor for calculating a deviation from an output of the second current detector. 7. The first magnetic deflector detecting unit includes a magnetic flux detector for detecting a magnetic flux of an iron core of the inverter transformer, and a filter circuit for extracting a low-frequency component of an output of the magnetic flux detector. And a second current detector for detecting a primary output of the inverter transformer, and a second current detector for detecting a secondary output of the inverter transformer. 6. The inverter device according to claim 5, wherein the inverter device comprises: a subtractor for calculating a deviation between an output of the first current detector and an output of the second current detector. 8. The first correction circuit includes: a comparator that outputs a signal when a deviation output from the demagnetization detection unit becomes larger than a predetermined value; and a pulse based on an output of the comparator. The inverter device according to any one of claims 1 to 7, further comprising a pulse generator that outputs a signal, and an integrator that integrates a pulse signal output by the pulse generator.