JPH11285260A - Method and device for controlling inverter device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control method and its control device for an inverter device, capable of downsizing a device for the connection to a power generating system such as for solar light power generation and a commercial power, and also capable of supplying an AC output current of power factor of 1 to the commercial power side. SOLUTION: In a control method for an inverter device, which converts the DC output of a DC power supply and which is connected to an AC power supply, the phase voltage of a commercial power 4 is detected and used as a command signal, and the output current of an inverter device 2 is detected and used as a feedback signal. Then, the command signal is compared with the feedback signal to generate an error signal. A control signal is formed in such a way as to make the error signal zero, and the inverter 2 is controlled based on this control signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control method and a control device for an inverter device, and more particularly to a method for converting a DC output of a solar cell or the like into an AC output through a current control type inverter device, thereby obtaining an AC commercial power. The present invention relates to a control method and a control device for an inverter device connected to a power system.

[0002]

2. Description of the Related Art In recent years, power generation systems using solar cells have been spreading due to demands for energy saving. In such a power generation system, DC power is generated from photovoltaic power generation, and a device that receives supply of power as a load is often an electric lamp or a motor connected to a commercial AC power supply. For this reason, the DC power generated by the power generation system needs to be converted into AC power having the same frequency, phase, and voltage as the commercial power supply.

[0003] Such a photovoltaic power generation system includes:
Power cannot be generated at night, and the load device needs to be supplied with electric power from a commercial AC power supply. In daylight hours, the load device may exceed the required power. When the generated power exceeds the demand power of the load device, it is preferable that the excess power can be automatically supplied to the commercial AC power supply side. From such a viewpoint, the photovoltaic power generation system often needs to be a system linked to a commercial AC power supply.

As described above, in order to interconnect the photovoltaic power generation system and the commercial AC power supply, it is necessary to convert the DC power of the solar cell into AC power according to the frequency, phase, and voltage of the commercial AC power supply. . FIG. 6 shows interconnection with a commercial AC power source for photovoltaic power generation using a conventional voltage-controlled inverter device. That is, the solar cell 1 is connected to the inverter device 2, and is connected to, for example, a three-phase 200 V AC commercial power supply system 4 via the connection point 3. Here, the switching circuit 5 includes a power transistor, an IGBT, and the like. When a drive signal is input to the base (gate) of the switching circuit 5,
Turns on / off the DC voltage stored in the capacitor 6,
An AC voltage waveform is formed.

[0005] The AC voltage and AC current formed by this switching contain a large amount of harmonic components. Therefore, a filter circuit 7 is provided to remove the harmonic components. The output side of the current filter 7 is connected to the insulating transformer 8 to insulate and separate the commercial power supply side and the inverter device side. And
Interconnected reactor L, magnet switch 9, breaker 1
0 and the like, and connected to the output terminal 3 which is a connection point of the commercial AC power supply system 4.

[0006]

However, in such a voltage-controlled inverter device, when converting the DC output of the solar cell into an AC, the power factor between the output current of the inverter and the commercial power supply voltage is reduced to one. In order to maintain, the commercial power supply voltage is always detected, and based on this commercial power supply voltage,
As shown in FIG. 7, the potential drop e due to the interconnection reactor L
Leading phase output voltage e _I which is the vector sum of _L and system voltage e _C
Was formed by switching the power element. The output power factor of the inverter also fluctuates due to fluctuations in the inverter output current and system voltage due to fluctuations in the amount of solar radiation. Here, the power factor 1 is maintained by controlling the advance angle θ. Therefore, by increasing the interconnection reactor L, the advance angle θ
And control becomes easy. However, since the output voltage of the inverter device is limited by the DC power supply voltage, there is a problem that the control width is narrowed, and a large interconnecting reactor L is disadvantageous for downsizing and cost reduction. there were.

The present invention has been made in view of the above-mentioned circumstances, and can reduce the size and size of a device for interconnecting a power generation system such as a photovoltaic power generation system with a commercial power supply, and have a power factor of 1 unit. It is an object of the present invention to provide a method of controlling an inverter device capable of supplying the AC output current of the present invention to a commercial power supply, and a control device therefor.

[0008]

According to a first aspect of the present invention, there is provided a method of controlling an inverter device for converting a DC output of a DC power supply into an AC output and connecting the AC output to an AC commercial power supply.
The phase voltage of the commercial power supply is detected and the phase voltage is set as a command signal, the output current of the inverter device is detected and the output current is set as a feedback signal, and the command signal and the feedback signal are compared to generate an error signal. And generating a control signal to make the error signal zero, and controlling the inverter device based on the control signal.

According to the present invention described above, the inverter device is of a current control type, the voltage waveform of the commercial power source phase is used as a reference signal, the output current of the inverter device is used as a feedback signal, and the output current of the inverter device is controlled by the commercial power source phase. The switching of the power element of the inverter device is controlled so as to match the voltage waveform. This makes it possible to obtain an AC current output waveform of the inverter device that matches the commercial power supply phase voltage waveform. According to this control method, since the phase voltage waveform and the current waveform match in frequency and phase, the AC output of the inverter device having a power factor of 1 is supplied to the commercial power supply.

Since the AC output current of this inverter device has a waveform substantially coincident with the phase voltage of the commercial power supply, the harmonic component is extremely small, and is completely in accordance with the standard for harmonic suppression required on the commercial power supply side. Can be handled. Also, in the filter circuit of the inverter device, it is sufficient to remove the harmonic component of switching by pulse width modulation of the power element, and the switching frequency is generally about 10 kHz or higher, which is higher than the commercial power supply frequency. Can be configured using small and compact inductors and capacitors.

According to a second aspect of the present invention, when the output current is small, the phase between the command signal of the phase voltage and the feedback signal of the output current due to the influence of the reactive current supplied from the commercial power supply to the insulating transformer. In order to correct the deviation, the phase of the phase voltage command signal is advanced.

This makes it possible to correct the phase shift due to the reactive current component (excitation current) flowing into the insulating transformer from the commercial power supply. That is, in the current control type inverter device, the output current of the inverter device is completely in phase with the power supply phase voltage. However, the output current supplied to the power supply system is a vector sum of the output current of the inverter device and the reactive current component flowing into the insulating transformer. For this reason, when the output current of the inverter device is small, the reactive current component becomes relatively large,
Therefore, the phase of the overall output current supplied to the commercial power supply does not match the phase of the phase voltage. That is, the power factor is no longer one. Therefore, by correcting the power supply phase voltage signal so as to advance the phase as described above, the phase difference between the phase voltage and the current on the commercial power supply side can be eliminated.

According to a third aspect of the present invention, in the phase correction of the phase voltage command signal, a command signal obtained by multiplying a phase voltage of another phase by a coefficient k is added to a command signal of a phase voltage of one phase. And
The coefficient k is changed according to the magnitude of the feedback signal of the output current so as to increase as the output current decreases. Thereby, the correction according to the magnitude of the output current of the inverter device can be appropriately performed.

According to a fourth aspect of the present invention, there is provided a control device for an inverter device for converting a DC output of a DC power supply into an AC output and interconnecting the AC power supply with a commercial power supply phase voltage detection circuit, A circuit for detecting an output current of the inverter device, an arithmetic circuit for calculating an error between a phase voltage signal of a commercial power supply detected by both of the detection circuits and an output current signal of the inverter device, and the inverter based on an output of the arithmetic circuit; A driver circuit for controlling switching of the device, wherein the output current of the inverter device is controlled so as to follow a phase voltage signal of the commercial power supply.

According to this, the arithmetic circuit can be realized by a simple analog circuit using an operational amplifier, a microcomputer, or the like, so that the control circuit can be reduced in size and size. In addition, the current control type inverter device eliminates the need for a large reactor and simplifies the control system, so that the overall configuration of the device can be reduced in size and size.

According to a fifth aspect of the present invention, a phase voltage signal of one phase and a signal obtained by multiplying a phase voltage signal of another phase by a coefficient k corresponding to a phase correction amount are added to each other. A phase correction circuit for converting a voltage signal is further provided. Thus, even when the output current of the inverter device is small, an output current with a power factor of 1 can be supplied.

[0017]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a diagram showing a configuration of a current control type inverter device according to an embodiment of the present invention. The output terminal of the solar cell 1 is connected to the current control type inverter device 2, and is further connected to the commercial power system 4 at the interconnection point 3. Then, equipment serving as a load of the power supply can be supplied with electric power from the solar cell 1 and electric power from the commercial power supply system 4.

The switching circuit 5 constituting the main circuit of the inverter device 2 turns on / off a DC voltage by a control signal of a pulse width modulation (PWM) method so that the pulse width modulation follows a voltage waveform of a commercial power supply. The generated pseudo sine wave alternating current is generated. In the inverter device 2, current detection circuits 18u and 18w are connected to the output lines of the switching circuit 5 to detect U-phase and W-phase output currents. The current filter 7 is a filter for removing harmonic components included in the output current of the switching circuit 5,
The frequency band of, for example, 10 kHz or more, which is the carrier switching frequency of the switching circuit 5, is removed. Therefore, as the current filter 7, a small and compact inductance element and a capacitance element having relatively small inductance and capacitance values can be used.

The output current of the switching circuit 5 passing through the current filter 7 is insulated and separated from the commercial power supply and the inverter by the insulating transformer 8. Further, an interconnection magnet switch 9 and a breaker 10 are provided on the output side of the inverter device 2, and a commercial power system 4 is connected to the output terminal 3 of the inverter device 2 which is an interconnection point. It should be noted that the interconnection reactor required for the conventional voltage-controlled inverter device has been eliminated. This is because in the current control type inverter device, the power supply phase voltage is used as a reference signal, and the output current follows the reference signal as a feedback signal, so that the interconnection reactor is not required. As a result, the control system is simplified, and the size and size of the device can be reduced.

A signal transformer 11 is connected to an output line of the breaker 10, and the signal transformer 11 is a circuit for detecting a phase voltage waveform of a commercial power supply. That is, the commercial power supply phase voltage is induced to the output side, and in the case shown in the figure, when the breaker 10 is in the ON state, the U-phase and W-phase phase voltages are detected by the detection circuits 11u and 11w. In the detection circuits 11u and 11w, they are converted into phase voltage signals, and the phase voltage signals Vu and Vw are respectively converted into multipliers 12u and 1w.
2w is input. The multiplier 12 has a maximum power tracking circuit 2
0 is input, whereby phase voltage signals Vu ′ and Vw ′ multiplied by the coefficient Sd corresponding to the output of the maximum power tracking circuit 20 are input as reference signals to one terminal of the error integrators 13u and 13w. Is done.

The other terminals of the error integrators 13u and 13w are connected to a detection circuit 18u of the output current of the switching circuit 5 and
The current signals Iu and Iw detected by 18w are input as feedback signals. Error integrators 13u, 13
w is a proportional-integral (PI) control circuit that outputs a control signal that makes the difference between the power supply phase voltage signal that is a reference signal and the output current signal of the switching circuit 5 that is a feedback signal zero. The control signal outputs of the error integrators 13u and 13w are input to a two-phase / three-phase conversion circuit 14, which generates respective control signals for the U, V, and W phases. The control signals for each of the U, V, and W phases are input to the PWM modulation circuit 15, where they are subjected to pulse width modulation. The pulse width modulated control signal switches the power element of the switching circuit 5 via the driver circuit 16.

Accordingly, the phase voltage signal of the commercial power supply is detected by the signal transformer 11, and this is input to the multipliers 12u and 12w.
Are input to the error integrators 13u and 13w as reference signals. Then, the output current of the switching circuit 5 is detected by the detectors 18u and 18w, and is input to the error integrator 13 as a feedback signal. Then, the error integrators 13u and 13w generate a control signal so that the error signal becomes zero.
The switching circuit 5 performs a DC voltage switching operation via the WM modulator 15. Therefore, the output current of the switching circuit 5 is controlled so that its waveform follows the power supply phase voltage waveform, thereby forming an AC output current of a system power supply frequency in which the frequency and the phase of the power factor 1 exactly match. . This output current waveform is shown in FIG. A small harmonic component contained in the output current is
, And a clean alternating current of only the fundamental wave component is output from the interconnection point 3 to the commercial power supply 4 side. Since the current waveform has the same frequency and phase as the power supply phase voltage waveform, extremely high-quality AC power having a power factor of 1 and containing almost no harmonic components is transmitted to the commercial power supply system. When an inductive load such as a motor is connected to the grid, the reactive current supplied to this load is supplied from the grid power supply.

The inverter device 2 is operated such that the inverter device operates at its maximum output point. FIG.
Shows an example of the output characteristics of the solar cell. That is, the output voltage is substantially constant until the load current reaches the maximum output point (about 10 A), and when the load current exceeds the maximum output point M, the output voltage drops rapidly. The position of the maximum output point M varies depending on conditions such as sunshine.

For this reason, in the inverter device 2,
First, a DC voltage detection circuit 19v and a DC current detection circuit 19i are provided, and a maximum power tracking circuit 20 calculates a DC output based on the output results. If the DC output is equal to or lower than the maximum output point M in FIG. 3, a control signal Sd for increasing the inverter AC output current is generated. The control signal output Sd is used as a multiplier 12u,
By inputting to 12w, each power supply phase voltage signal is multiplied by a coefficient. Therefore, the output current signal should follow,
The multiplication circuits 12u and 12w change the reference power supply phase voltage signal according to the difference from the maximum point M of the solar cell output. Thereby, the inverter device 2 is operated so as to always operate at the maximum output point M of the inverter device.

When the power generation capacity of the solar cell is reduced due to the sunshine or the like, the state in which power cannot be transmitted is detected by the AC side detection circuits 18u and 18w and the DC side detection circuits 19v and 19i. By opening the switch 9 under the control of the power tracking circuit 20, etc., the power transmission from the solar cell 1 to the commercial power supply ends.

FIGS. 4 and 5 show the outline of the phase correction circuit. When the output current of the inverter is small, the phase difference between the output current of the inverter and the phase voltage of the commercial power cannot be maintained at zero due to the effect of the reactive current supplied from the commercial power system 4 to the insulating transformer 8. . Due to the reactive current of the insulating transformer 8, the output current of the inverter device has a certain phase delay from the commercial power supply phase voltage. Therefore, in order to maintain the phase difference between the output current of the commercial power supply and the phase voltage of the commercial power supply at zero, it is necessary to correct the phase of the command signal of the inverter device.

FIG. 4 shows the commercial power phase voltage signals U _S , V _S , W
_Shows a vector representation of _S. These are commercial power phase voltage signals output from the signal transformer 11. To advance the phase of the power supply phase voltage signal U _S, so it may be added to a portion of the power supply phase voltage signals W _S, the power supply phase voltage signal vector U _S
The sum vector of k · W _S, to form a corrected supply phase voltage signal vector U _G. Here, k is a coefficient smaller than 1 and is a coefficient determined according to the output current of the inverter device. That is, when the output current of the inverter device decreases, k increases. When the output current increases, k decreases. When the output current increases beyond a certain level, k becomes zero. That is, when the output current of the inverter device is large, the ratio of the reactive current component supplied to the insulating transformer becomes small, so that phase correction is unnecessary at this time. Conversely, when the output current of the inverter device is small, the ratio of the reactive current component supplied to the insulating transformer increases, so that phase correction is necessary at this time. By adding the vector k · V _S in the same manner as the power supply phase voltage signals W _S, to form a corrected phase voltage signal vectors W _G. W _G, to the vector supply phase voltage signals W _S, is corrected so as proceeds amount corresponding phase of the vector k · V _S.

FIG. 5 is a circuit example for realizing such a phase correction. The signal transformer output signal U _S is multiplied by a multiplier 12u by a maximum power command signal Sd for maintaining the operating point of the solar cell at the maximum power, and its amplitude is corrected.
Then, the power supply voltage signal U corrected by the maximum power command
Adding k · W _S is a phase correction signal by the adder 22 to _S '. This power supply voltage signal is corrected in phase advance is formed by a U _G is formed, is input to the error integrator 13u. The correction signal k · W _S is obtained by multiplying the power supply voltage signal W _S , which is the output of the signal transformer, by the coefficient k by the multiplier 23. Here, although not shown, the coefficient k becomes larger in a range smaller than 1 when the output current is small, approaches zero when the output current is large, and becomes zero when the output current becomes a certain value or more by comparing with the output current. As described above, it is formed by calculation using an error amplifier or the like.

The reference signal input of the error integrator 13u is fast phase-corrected power supply phase voltage signal U _G is input, since the AC output current Iu is input as a feedback signal, the error integrator 13u are both The control command U is output so that the difference becomes zero. As a result, the AC output current Iu
Since the follow corrected supply phase voltage signal U _G to fast, to correct the phase shift caused by the reactive current component power factor therebetween is supplied from the 1, and the commercial power supply side of the insulating transformer 8 it can. That is, even when the output current of the inverter device is smaller than the reactive component current of the power transformer 8, the phase of the power phase voltage and the AC output current can be matched on the commercial power side of the insulating transformer 8, and It can approach the rate 1. Although the phase correction circuit shown in FIG. 5 is for the power supply phase voltage signal U _S ,
The same circuit can be used for the W phase.

In the above-described embodiment, an example has been described in which DC power generated by a solar cell is converted to AC power. It goes without saying that the system to be linked can be similarly applied.

[0032]

According to the present invention as described above,
An output current containing almost no harmonic component having a power factor of 1 can be supplied to the commercial power supply, and the device can be made compact and compact. Further, even when the AC output current is small, it is possible to correct the phase shift due to the inflow of the exciting current of the insulating transformer and maintain the power factor of 1 at the output end.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing an outline of a control device of an inverter device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a waveform of an output current of the inverter device of FIG.

FIG. 3 is a diagram illustrating an example of output characteristics of a photovoltaic power generation system.

FIG. 4 is an explanatory diagram of a power supply voltage signal vector.

FIG. 5 is an explanatory diagram of a phase correction circuit.

FIG. 6 is an explanatory diagram showing an outline of a conventional control device for an inverter device.

FIG. 7 is an explanatory diagram of an output voltage vector in the device of FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Solar cell 2 Inverter device 3 Interconnection point 4 Commercial power system 5 Switching circuit 6 Capacitor 7 Filter circuit 8 Insulation transformer 9,10 Switch 11 Signal transformer 12u, 12w Multiplier circuit 13u, 13w Error amplifier 14 Two-phase / 3-phase conversion Circuit 15 PWM modulation circuit 16 Driver circuit 18u, 18w Output current detection circuit 20 Maximum power tracking circuit 21 Phase correction circuit

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Hiroshi Nambu 11-1 Haneda Asahimachi, Ota-ku, Tokyo Inside Ebara Works Co., Ltd. (72) Inventor Hiroshi Okazaki 11-1 Haneda Asahi-cho, Ota-ku, Tokyo Co., Ltd. EBARA CORPORATION

Claims (5)

[Claims] 1. A method for controlling an inverter device for converting a DC output of a DC power supply into an AC output and interconnecting the AC power supply, wherein a phase voltage of the commercial power supply is detected and the phase voltage is set as a command signal. Detecting the output current of the inverter device and using the output current as a feedback signal, comparing the command signal and the feedback signal to generate an error signal, and forming a control signal that makes the error signal zero, A method for controlling an inverter device, comprising controlling the inverter device based on the control signal. 2. A method for correcting a phase shift between a command signal of the phase voltage and a feedback signal of the output current due to an influence of a reactive current supplied from the commercial power supply to an insulating transformer when the output current is small. 2. The method according to claim 1, wherein the phase of the phase voltage command signal is advanced. 3. The method of correcting the phase of a phase voltage command signal, comprising:
The phase voltage command signal of one phase is converted to the phase voltage of the other phase by a coefficient k.
3. The inverter device according to claim 2, wherein the command signal obtained by multiplying the output current is added and the coefficient k is changed according to the magnitude of the feedback signal of the output current so as to increase as the output current decreases. Control method. 4. A control device for an inverter device for converting a DC output of a DC power supply into an AC output and connecting the AC power to a commercial power supply, comprising: a circuit for detecting a phase voltage of the commercial power supply; A detection circuit, an arithmetic circuit for calculating an error between a phase voltage signal of a commercial power supply detected by the two detection circuits and an output current signal of the inverter device, and a driver for controlling switching of the inverter device based on an output of the arithmetic circuit A control circuit for controlling an output current of the inverter device so as to follow a phase voltage signal of the commercial power supply. 5. A phase correction circuit for adding a signal obtained by multiplying a phase voltage signal of one phase by a coefficient k corresponding to a phase correction amount to a phase voltage signal of another phase to obtain a phase voltage signal of the commercial power supply. The control device for an inverter device according to claim 4, further comprising: