JP2005039931A - System-interconnected inverter device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To offer a system-interconnected inverter device which suppresses the occurrence of surplus switching loss within an inverter circuit and a DC/DC converter without causing a distortion in the output current to a commercial power system. <P>SOLUTION: This inverter device is equipped with the DC/DC converter which boosts DC voltage, the inverter circuit, a filter circuit, a boosting control circuit which controls the switching action for the DC/DC converter, and an inverter control circuit which controls the inverter circuit. The boosting control circuit treats a value, where fixed voltage equivalent the amount of voltage drop in a filter circuit and an inverter circuit is added to a voltage value equivalent to the amplitude being computed on the assumption that the waveform is a sine wave based on the effective value of detected system voltage, as a DC output voltage command, when the effective voltage of a commercial power system is within the specified voltage range centering upon its rated voltage, and it controls the DC output voltage of the DC/DC converter so that it may conform to the command value. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a grid-connected inverter device that converts DC power, such as a fuel cell or a solar cell, into AC power, and that is connected to a commercial power system to supply power.

In recent years, a power generation system using a fuel cell, a solar cell, or the like that has little influence on the environment has been actively developed from the viewpoint of protecting the global environment. In such a power generation system, the generated DC power is converted into AC power having a commercial frequency by a grid-connected inverter device and supplied to the commercial power system.
FIG. 19 is a block diagram illustrating a configuration example of a grid-connected inverter device that has been conventionally used. In FIG. 19, the grid-connected inverter device 1 includes a DC / DC converter 3, an inverter circuit 4, a filter circuit 5, a boost control circuit 6, and an inverter control circuit 7.

  The DC / DC converter 3 includes capacitors C1 and C2, a reactor L1, a transistor Q1 as a switching element, and diodes D1 and D6. The DC voltage Vdc1 supplied from the DC power supply 2 is stabilized by a capacitor C1, and then supplied to a boost chopper circuit including a reactor L1, a transistor Q1, and diodes D1 and D6. In the step-up chopper circuit, energy is stored in the reactor L1 when the transistor Q1 is turned on, and when the transistor Q1 is turned off, the stored energy is stored as a voltage in the capacitor C2 connected to the output through the diode D6 and boosted. A DC voltage output Vdc2 is generated. In this case, the boost control circuit 6 detects the DC output voltage Vdc2, and performs PWM control of the ON time of the transistor Q1 so that the value becomes a predetermined value.

  The boosted DC output voltage Vdc2 is applied to the inverter circuit 4 at the next stage. The inverter circuit 4 includes, for example, transistors Q2 to Q5 as switching elements and diodes D2 to D5 connected in antiparallel to the transistors. The circuit configuration is a bridge circuit configuration including a first arm composed of transistors Q2 and Q3 connected in series between positive and negative DC buses and a second arm composed of transistors Q4 and Q5. The interconnection point of the transistors of each arm is connected to the input of the filter circuit 5. The inverter circuit 4 converts the DC power supplied from the DC / DC converter 3 into AC power and supplies it to the filter circuit 5 by the switching operation of the transistors Q2 to Q5. The filter circuit 5 is a low-pass filter including a reactor L2 and a capacitor C3, removes a high-frequency component contained in the alternating current output from the inverter circuit 4, and supplies the sine wave output current Ia to the commercial power system 8.

  In this case, the inverter control circuit 7 monitors the system voltage Vac and the output current Ia supplied from the system interconnection inverter device 1 to the commercial power system 8. Based on these values, power supply to the commercial power system 8 is normally performed with a power factor of 1, that is, the phase of the output current Ia matches the phase of the system voltage Vac of the commercial power system 8. In addition, each ON time of the transistors Q2 to Q5 of the inverter circuit 4 is PWM-controlled. In this way, the grid-connected inverter device 1 is operated such that its output power is synchronized with the commercial power system 8.

By the way, in order for the grid-connected inverter device 1 to supply the output current Ia with a power factor of 1 and a waveform without distortion, the value of the direct-current output voltage Vdc2 that is the input voltage of the inverter circuit 4 is expressed as When ignoring the voltage drop and the conduction loss of the transistors Q2 to Q5, it is necessary that the value be higher than the peak value of the system voltage Vac.
Therefore, in the step-up control circuit 6 described above, the value of the output voltage Vdc2 of the DC / DC converter 3 adds a voltage drop in the realtor L2 and the inverter circuit 4 to the peak value of the maximum rated voltage of the system voltage Vac. The transistor Q1 is PWM controlled to exceed the above value.

  However, the system voltage Vac is not constant and constantly fluctuates. Therefore, when the value of the output voltage Vdc2 of the DC / DC converter 3 is controlled so as to always coincide with the voltage determined in consideration of the maximum value of the system voltage Vac, when the system voltage Vac decreases, The difference between the input voltage Vdc2 of the inverter circuit 4 and the peak value of the system voltage Vac becomes larger than necessary. Thus, if the value of the output voltage Vdc2 of the DC / DC converter 3 becomes unnecessarily high, the switching loss in the transistors Q2 to Q5 of the inverter circuit 4 and the boosting transistor Q1 of the DC / DC converter 3 are increased. This results in increased switching losses.

Since the voltage drop in the real tower L2 changes depending on the value of the output current Ia to the commercial power system 8, the output voltage Vdc2 of the DC / DC converter 3 assumes a rated value as the value of the output current Ia. There is also a problem in determining and controlling the value of.
As a conventional technique for solving such a problem, there is a proposal for determining the output voltage Vdc2 of the DC / DC converter 3 in consideration of, for example, fluctuations in the system voltage Vac (see, for example, Patent Document 1).
JP 2000-152651 A

  The present invention has been made to solve these problems of the prior art, and its purpose is to provide system voltage fluctuation, output current value to the commercial power system, and frequency fluctuation of the commercial power system. Taking into consideration, the output voltage of the DC / DC converter, which is the input voltage of the inverter circuit, is controlled. Accordingly, an object of the present invention is to provide a grid-connected inverter device that can suppress the occurrence of extra switching loss in the inverter circuit and the DC / DC converter without causing distortion in the output current waveform.

In order to achieve the above object, the invention described in claim 1 includes a DC / DC converter (3) for boosting a DC voltage (Vdc1) from a DC power supply (2), and a DC output of the DC / DC converter. An inverter circuit (4) that outputs a PWM-modulated alternating current by switching the voltage (Vdc2), and a high-frequency component contained in the alternating current is removed to convert a sine wave output current (Ia) into a commercial power system (8 ), A step-up control circuit (6) for controlling the DC output voltage by controlling the switching operation of the DC / DC converter, and the switching operation of the inverter circuit for controlling the switching operation of the inverter circuit. A grid-connected inverter device (1) comprising an inverter control circuit (7) for controlling the output current (Ia) of the filter circuit to coincide with a predetermined reference output current (Ir),
When the effective value (Vac) of the system voltage of the commercial power system is within a predetermined voltage range centered on the rated voltage, the boost control circuit (6) has a waveform based on the detected effective value of the system voltage. Is obtained by adding a constant voltage corresponding to the voltage drop in the filter circuit (5) and the inverter circuit (4) to the voltage value corresponding to the amplitude calculated assuming that is a sine wave. ), And the DC output voltage (Vdc2) of the DC / DC converter is controlled so as to coincide with the command value.

  With such a configuration, if the system voltage increases, the DC output voltage of the DC / DC converter increases as the system voltage increases, and if the system voltage decreases, the DC output voltage decreases and the DC of the DC / DC converter decreases. The difference between the output voltage and the peak value of the system voltage is always kept constant. Therefore, it is possible to suppress the occurrence of extra switching loss in the inverter circuit and the DC / DC converter without causing distortion in the output current waveform.

  The invention according to claim 2 is the grid interconnection inverter device according to claim 1, wherein the boosting control circuit replaces the amplitude equivalent voltage value of the system voltage with a peak of the detected system voltage. When the peak value is within a predetermined range, the DC output voltage is obtained by adding a constant voltage corresponding to the voltage drop in the filter circuit (5) and the inverter circuit (4) to the peak value. The system-connected inverter device is characterized in that a command value (Vdc2r) is set and the DC output voltage (Vdc2) of the DC / DC converter is controlled so as to coincide with the command value.

  Since this configuration uses the actually measured peak value of the system voltage instead of the amplitude calculated from the effective value of the system voltage, the same effect as that of the invention described in claim 1 can be obtained.

  The invention according to claim 3 is the grid-connected inverter device according to claim 1 or 2, wherein the step-up control circuit applies a constant voltage corresponding to a voltage drop in the filter circuit and the inverter circuit. Instead of the DC output voltage command value (Vdc2r), the output current (Ia) of the filter circuit is detected, and a value obtained by adding a voltage proportional to the output current in the range where the output current is not more than a predetermined value is output as DC. A system interconnection inverter device characterized in that a voltage command value (Vdc2r) is used and the DC output voltage (Vdc2) of the DC / DC converter is controlled so as to coincide with the command value.

  With such a configuration, the difference between the DC output voltage of the DC / DC converter and the crest value of the system voltage is maintained at a value proportional to the actual output current, causing distortion in the output current waveform. In addition, it is possible to more effectively suppress the occurrence of extra switching loss in the inverter circuit and the DC / DC converter.

  The invention described in claim 4 is the grid-connected inverter device according to claim 3, wherein the boost control circuit further detects the frequency of the system voltage, and the frequency is centered on the rated frequency. In a predetermined frequency range, instead of a value before applying a voltage proportional to the output current (Ia), a value obtained by multiplying the value by a coefficient that increases as the frequency decreases is used. A value obtained by adding a voltage proportional to the output current in a range where the current is equal to or less than a predetermined value is set as a DC output voltage command value (Vdc2r), and the DC output voltage (Vdc2r) of the DC / DC converter is matched with the command value. ) Is a grid-connected inverter device.

  With such a configuration, when the frequency of the system voltage decreases, the DC output voltage of the DC / DC converter is corrected so as to increase, thus preventing the output current from being distorted due to the frequency decrease. can do.

  The invention described in claim 5 is the grid-connected inverter device according to any one of claims 1 to 4, wherein the inverter control circuit is configured such that the system voltage (Vac) of the commercial power system is a predetermined value. Is exceeded, the phase of the output current (Ia) of the filter circuit is controlled to advance from the phase of the system voltage by a phase advance operation amount (Δθ) corresponding to the excess amount, and the step-up voltage is increased. The control circuit makes a correction to reduce the DC output voltage command value (Vdc2r) of the DC / DC converter in response to the increase of the phase advance operation amount so that it matches the corrected DC output voltage command value. The system-connected inverter device controls a DC output voltage (Vdc2) of the DC / DC converter.

  With such a configuration, when the system voltage rises, a large current can be supplied to the commercial power system without increasing the DC output voltage of the DC / DC converter more than necessary. Therefore, it is possible to more effectively suppress the occurrence of extra switching loss in the inverter circuit and the DC / DC converter.

  The invention according to claim 6 is the grid interconnection inverter device according to claim 1, wherein the step-up control circuit detects a peak value of the output current (Ia) of the filter circuit, and When the value is lower than the peak value of the reference output current (Ir), control is performed to increase the DC output voltage (Vdc2) of the DC / DC converter according to the difference. System inverter device.

  With such a configuration, distortion in the output current is prevented and the DC output voltage of the DC / DC converter does not become higher than necessary, so that there is an excess in the inverter circuit and the DC / DC converter. Generation of a large switching loss is effectively suppressed.

  The invention according to claim 7 is the grid-connected inverter device according to any one of claims 1 to 5, wherein the boost control circuit detects a peak value of the output current of the filter circuit, When the peak value is lower than the peak value of the reference output current, a correction is made to increase the DC output voltage command value (Vdc2r) according to the difference, and it matches the corrected DC output voltage command value. In this way, the DC / DC converter controls the DC output voltage (Vdc2).

  With such a configuration, there is an effect that the generation of distortion of the output current is more effectively suppressed.

  The invention described in claim 8 is the grid-connected inverter device according to any one of claims 1 to 7, wherein the step-up control circuit includes a DC output voltage (Vdc2) of the DC / DC converter. Is controlled by proportional integral control to match the DC output voltage command value (Vdc2r). In this case, the value of the proportional constant of the proportional integral control is set to the DC output voltage (Vdc2r) detected by the DC output voltage command value (Vdc2r). When the voltage is lower than Vdc2), the grid-connected inverter device is characterized in that the value is smaller than the opposite case.

  With this configuration, when the system voltage rises, the DC output voltage of the DC / DC converter quickly follows and rises, and when the system voltage falls, it gradually falls and returns. Will do. Therefore, even when the fluctuation of the system voltage Vac is severe, the operation and the output current of the system interconnection inverter device are easily stabilized.

  The invention described in claim 9 is a grid-connected power generation system including the grid-connected inverter device according to any one of claims 1 to 8 and a fuel cell that supplies a DC power to the inverter device. It is.

  Since a fuel cell has a small electromotive force per cell, the number of cells connected in series can be reduced by using the grid-connected inverter device according to any one of claims 1 to 8, and overall efficiency is improved. A good and stable grid-connected power generation system can be constructed.

  The grid-connected inverter device of the present invention is an inverter that takes into account fluctuations in the system voltage at the actual installation location of the inverter device, the value of the output current to the commercial power system, and further the fluctuations in the frequency of the commercial power system. The output voltage of the DC / DC converter that is the input voltage of the circuit is controlled. Therefore, it is possible to suppress the occurrence of excessive switching loss in the inverter circuit and the DC / DC converter without causing distortion in the output current waveform.

  Hereinafter, an embodiment of a grid interconnection inverter device of the present invention will be described with reference to the drawings. FIG. 1 is a configuration block diagram common to various embodiments to be described later, regarding a grid-connected inverter device of the present invention. In the figure, the same or corresponding parts as those in FIG. 19 described in the prior art are denoted by the same reference numerals, and the description thereof will not be repeated.

  In the block diagram shown in FIG. 1, the boost control circuit 6 has an instantaneous value Vac ′ of the system voltage Vac of the commercial power system 8 and an output current Ia flowing out from the filter 5 which is an output current of the system interconnection inverter device 1. The block diagram is the same as FIG. 19 except that the instantaneous value Ia ′ is input and the reference output current Ir of the grid-connected inverter device 1 is input to the inverter control circuit 7. However, the internal circuit configurations of the boost control circuit 6 and the inverter control circuit 7 shown by blocks are different from those of the conventional technique. The configuration of the boost control circuit 6 will be described in each embodiment described later. First, the configuration and operation of the inverter control circuit 7 will be described.

  FIG. 2 shows a block diagram of the inverter control circuit 7. The inverter control circuit 7 includes an instantaneous value Vac ′ of the system voltage Vac (effective value) of the commercial power system 8, an instantaneous value Ia ′ of the output current Ia (effective value) from the filter 5, and a reference for the grid-connected inverter device 1. An output current Ir (effective value) is input. The reference output current Ir is a reference value (target value) of the current supplied from the grid-connected inverter device 1 to the commercial power system 8, and the value is determined by the power supply capability (power generation capability) of the DC power supply 2. Therefore, the value is normally given from a control device (not shown) in the DC power supply 2. The amplitude Ira of the reference output current Ir is calculated by the amplitude calculation circuit 70 and input to the multiplier 73.

  The rising edge of the waveform of the system voltage instantaneous value Vac ′ is detected by the zero-cross detection circuit 71, and the detected rising edge signal is input to the PLL oscillation circuit 72. The PLL oscillation circuit 72 generates a sine wave having an amplitude of 1 and the same as that of the rising edge signal to which the period is input, and a phase advanced from the rising edge signal by a phase advance operation amount Δθ instructed from the outside. That is, when the frequency of the system voltage Vac is f and the instantaneous value Vac ′ is √2 · Vac · sin (2πft), a reference sine wave represented by sin (2πft + Δθ) is generated. Since the output current Ia is normally supplied to the commercial power system 8 at a power factor of 1, the value of Δθ is set to zero. Therefore, the PLL oscillation circuit 72 outputs a reference sine wave having an amplitude of 1 phase-synchronized with the system voltage instantaneous value Vac ′ and is input to the multiplier 73.

  The multiplier 73 multiplies the reference sine wave by the amplitude Ira of the reference output current Ir, and outputs a reference output current instantaneous value Ir ′ represented by Ira · sin (2πft).

  The reference output current instantaneous value Ir ′ is compared with the detected output current instantaneous value Ia ′ by the subtractor 74 to calculate an instantaneous current deviation ΔI ′. The calculated instantaneous current deviation ΔI ′ is subjected to proportional integration calculation by a PI (proportional integration) calculation circuit 75. The proportional-integral calculation result is compared with a high-frequency triangular wave around 20 kHz generated by the triangular wave generation circuit 77 in the PWM comparison circuit 76, and a drive signal for driving the transistors Q2 to Q5 in the inverter circuit 4 is generated. Then, the transistors Q2 to Q5 perform a switching operation according to the drive signal, so that a PWM-modulated sine wave current is supplied to the filter circuit 5, and a high frequency component in the sine wave current is removed, so that the commercial power system 8 is supplied. A sine wave output current Ia is supplied.

  The sine wave output current Ia supplied to the commercial power system 8 becomes equal to the reference output current instantaneous value Ir ′ by PI (proportional integration) control by the subtractor 74 and the PI calculation circuit 75. In this way, the commercial power system 8 is supplied with an output current Ia that is phase-synchronized with the system voltage Vac and whose magnitude is equal to the reference output current Ir.

  The grid-connected inverter device that is the subject of the solution of the present invention, that is, suppressing the occurrence of excessive switching loss in the inverter circuit 4 and the DC / DC converter 3 without causing distortion in the output current waveform. The possible configuration of the grid-connected inverter device 1 is achieved mainly by devising the boost control circuit 6. Next, the configuration and operation of the boost control circuit 6 will be described separately for each embodiment.

(First embodiment)
In order to suppress the occurrence of excessive switching loss in the inverter circuit 4 and the DC / DC converter 3 without causing distortion in the waveform of the output current Ia, the DC output voltage Vdc2 of the DC / DC converter 3 is required. It is important not to make it larger. Therefore, the DC output voltage Vdc2 is controlled so as to coincide with the detected voltage corresponding to the amplitude of the system voltage Vac plus a constant voltage corresponding to the voltage drop due to the switching element in the inverter circuit 4 and the voltage drop in the filter circuit 5. To do.

  For example, as shown in FIG. 3, when the detected system voltage Vac is in an effective value range of 102 to 115 V, a voltage corresponding to an amplitude obtained by multiplying the effective value by √2 assuming that the waveform is a sine wave. Further, a value obtained by adding, for example, 13 to 15 V as an expected voltage drop is set as a DC output voltage command value Vdc2r, and the DC output voltage Vdc2 is controlled so as to coincide with the command value.

  The configuration of the boost control circuit 6 for performing such control is shown in FIG. The instantaneous value Vac ′ of the system voltage of the commercial power system 8 is detected and input to the effective value calculation circuit 61, and the effective voltage Vac of the system voltage is calculated. The calculated effective voltage Vac is led to the DC output voltage command value Vdc2r generating circuit 62, and the DC output voltage command value Vdc2r of the DC / DC converter 3 corresponding to the effective voltage Vac, for example, as shown in the curve of FIG. Generate.

  The generated DC output voltage command value Vdc2r is guided to the subtracter 63, and a deviation ΔVdc2 from the actual DC output voltage Vdc2 of the DC / DC converter 3 is calculated. The calculated deviation ΔVdc2 is input to the PI calculation circuit 64 to perform proportional integration calculation. The calculation result is input to the PWM comparison circuit 65 and compared with the high-frequency triangular wave generated by the triangular wave generation circuit 66, and a drive signal for driving the transistor Q1 in the DC / DC converter 3 is generated. The driving signal causes the transistor Q1 to perform a switching operation. As a result, a DC output voltage Vdc2 is output across the capacitor C2.

The value of the output DC output voltage Vdc2 coincides with the DC output voltage command value Vdc2r as a result of PI control by the subtractor 63 and the PI operation circuit 64.
By such control, the DC output voltage Vdc2 causes waveform distortion in the voltage that is higher than the voltage corresponding to the amplitude of the detected system voltage Vac by the voltage drop in the inverter circuit 4 and the filter circuit 5, that is, in the output current Ia. Not maintained at a minimum voltage. As a result, the occurrence of waveform distortion in the output current Ia supplied to the commercial power system 8 is prevented, and the occurrence of extra switching loss in the inverter circuit 4 and the DC / DC converter 3 is suppressed. .

  Note that the operation and arithmetic processing of each block circuit in the boost control circuit 6 and the inverter control circuit 7 in this embodiment and the embodiments described later are performed periodically using a high-speed arithmetic unit such as a DSP (Digital Signal Processor). Realized by software operation.

(Second Embodiment)
In the first embodiment, a voltage corresponding to the sine wave amplitude of the detected system voltage Vac is calculated, a DC output voltage command value Vdc2r corresponding to the calculated value is determined, and the DC output of the DC / DC converter 3 is determined. The voltage Vdc2 was controlled. Instead of estimating and calculating the amplitude from the effective value in this way, the peak voltage is actually detected from the instantaneous voltage value Vac 'of the system voltage, and the DC output voltage command value Vdc2r is determined corresponding to the peak voltage. Good.

  FIG. 5 shows an example of the relationship between the peak voltage of the system voltage Vac thus detected and the DC output voltage command value Vdc2r determined correspondingly. In the figure, when the peak voltage of the system voltage Vac is in the range of 144 to 163 V, a value obtained by adding 12 to 16 V as a voltage drop equivalent in the inverter circuit 4 and the filter circuit 5 is set as the DC output voltage command value Vdc2r. .

  The configuration of the boost control circuit 6 according to this idea is shown in FIG. The difference from the configuration of FIG. 4 in the case of the first embodiment is that the effective value calculation circuit 61 is replaced with a peak voltage detection circuit 67. Based on the peak value of the system voltage Vac detected by the peak voltage detection circuit 67, the DC output voltage command value Vdc2r generation circuit 62 outputs the DC output voltage command value Vdc2r having the relationship as shown in FIG. As in the case of the first embodiment, the direct-current output voltage Vdc2 is controlled to match the value by PI control.

(Third embodiment)
In the first and second embodiments, the DC output voltage command value Vdc2r is a value obtained by adding a voltage drop equivalent in the inverter circuit 4 and the filter circuit 5 to the amplitude equivalent voltage of the system voltage Vac or the detected peak voltage. . The voltage drop equivalent in this case needs to be set to a value corresponding to the voltage drop when the rated output current is supplied from the viewpoint of preventing distortion in the output current waveform. When the value of the voltage drop is determined in this way, the DC output voltage Vdc2 becomes too high when the output current is less than the rated value. In order to avoid this, the value corresponding to the voltage drop may be proportional to the actual output current value.

  For example, as shown in FIG. 7, if the output current Ia is in the range of 30 to 100% of the rated value and the value of the voltage drop α is proportional to the output current Ia, at least in the current range, It becomes possible to reduce switching loss without causing current waveform distortion.

  FIG. 8 is a configuration example of the boost control circuit 6 for realizing such an idea. In FIG. 8, based on the detected output current instantaneous value Ia ′, the voltage drop generation circuit 68 generates, for example, a voltage drop α according to FIG. This voltage drop α and the peak voltage detected by the peak voltage detection circuit 61 based on the system voltage instantaneous value Vac ′ are added by an adder 69 to obtain a DC output voltage command value Vdc2r. The configuration for performing PI control so that the DC output voltage Vdc2 matches the command value is the same as in the first and second embodiments.

  It is to be noted that, instead of the peak voltage detection circuit 61, the effective value calculation circuit 61 used in FIG. 4 is used, and a sine wave amplitude equivalent voltage obtained by multiplying the calculated effective value by √2 is used instead of the peak voltage. Result is obtained.

(Fourth embodiment)
In the present embodiment, the DC output voltage command value Vdc2r is determined in consideration of the change in the frequency of the system voltage Vac in addition to the configuration of the previous embodiments. When the frequency of the system voltage Vac is reduced, a waveform distortion in which the current waveform in the vicinity of the peak value of the output current Ia is crushed or conversely tends to occur. This is because when the frequency is lowered, the time for maintaining a high current is long. Therefore, in order not to cause distortion in the current waveform even when the frequency is lowered, it is necessary to raise the DC output voltage Vdc2 as the frequency is lowered.

  When the frequency drops when the rated frequency is 50 Hz, for example, a coefficient β larger than 1 as shown in FIG. 9 is multiplied by the peak voltage value of the detected system voltage Vac, and the value is the peak voltage so far. Use it instead.

  FIG. 10 is a configuration example of the boost control circuit 6 based on such an idea. A frequency f of the system voltage Vac is detected by a circuit to be described later, and a coefficient β as shown in FIG. A multiplier 611 multiplies the generated coefficient β by the peak voltage detected by the peak voltage detection circuit 61. As in the case of the third embodiment, the voltage drop α generated by the voltage drop generation circuit 68 is added to the obtained value by the adder 69 and used as the DC output voltage command value Vdc2r.

  As the frequency f of the system voltage Vac, the frequency detected inside the inverter control circuit 7 shown in FIG. 2 is used. That is, in FIG. 2, the rising signal detected by the zero cross detection circuit 71 is input to the period detection circuit 78 to detect the period, and the inverse of the detected period is calculated by the frequency calculation circuit 79 to obtain the frequency f.

  In place of the peak voltage detection circuit 61 of FIG. 10, the effective value calculation circuit 61 used in FIG. 4 is used, and a sine wave amplitude equivalent voltage obtained by multiplying the calculated effective value by √2 is used instead of the peak voltage. Almost the same result is obtained.

(Fifth embodiment)
The grid-connected inverter device 1 generally outputs a power factor of 1, that is, an output current Ia that is in phase with the grid voltage Vac in many cases. However, in some cases, it is better to have a power factor adjustment function (advance compensation) to suppress an increase in the DC output voltage Vdc2 as the system voltage Vac increases. This function is to control the phase of the output current Ia of the grid-connected inverter device 1 to advance with respect to the system voltage Vac according to the excess voltage value when the system voltage Vac exceeds a predetermined value, for example, 107V. is there.

  In this way, since the peak value phase of the output current Ia advances more than the peak value phase of the system voltage Vac, the current to be actually generated passes the peak in the vicinity of the system voltage peak value phase where current control itself becomes severe. The direction is decreasing. Therefore, even if the difference between the DC output voltage Vdc2 of the DC / DC converter 3 and the peak value of the system voltage Vac is small or reversed, the influence is small, and as a result, the influence on the current distortion is reduced. In other words, when the control is performed with the leading phase, even if the value of the DC output voltage Vdc2 is decreased from the value in the case of the power factor 1, no actual harm (a significant increase in current distortion) occurs.

  In order to implement such an idea, the phase advance Δθ with respect to the system voltage Vac is manipulated as shown in FIG. 11, for example. Then, the DC output voltage Vdc2 is corrected by the correction amount X as shown in FIG. 12, for example, corresponding to the phase advance operation amount Δθ. In FIG. 12, the limit value of the lead phase is set to about 37 °, and when the value exceeds about 18 °, the reduction of the DC output voltage Vdc2 is started.

  FIG. 13 shows the configuration of the inverter control circuit 7 of this embodiment for implementing such control, and FIG. 14 shows the configuration of the boost control circuit 6. The inverter control circuit 7 in FIG. 13 is obtained by adding an effective value calculation circuit 710 that calculates an effective value of the instantaneous value Vac ′ of the system voltage and a phase advance amount generation circuit 711 to the circuit configuration in FIG. .

  The phase advance amount generation circuit 711 generates a phase advance operation amount Δθ according to, for example, the relationship shown in FIG. 11 corresponding to the effective value Vac of the system voltage calculated by the effective value calculation circuit 710 and supplies the phase advance operation amount Δθ to the PLL oscillation circuit 72. To do. The PLL oscillation circuit 72 generates a reference sine wave having an amplitude 1 with the same frequency as the instantaneous value Vac ′ of the system voltage and a phase advanced by the phase advance operation amount Δθ and supplies the generated reference sine wave to the multiplier 73. As a result, the grid-connected inverter device 1 supplies the commercial power system 8 with a current whose magnitude is equal to the reference output current Ir and whose phase is advanced by Δθ from the system voltage Vac.

  On the other hand, the boost control circuit 14 receives the phase advance operation amount Δθ generated by the phase advance amount generation circuit 711 in FIG. 13, and sets the correction amount γ of the DC output voltage Vdc2 corresponding to the value as shown in FIG. Generated according to the relationship. The generated correction amount γ is input to the adder 69 to correct the value of the DC output voltage command value Vdc2r of the DC / DC converter 3.

  By controlling in this way, when the system voltage Vac rises above a predetermined value, the commercial power system 8 is supplied with the output current Ia having a phase advanced from the system voltage Vac. Then, in a state where the phase has advanced by a predetermined value or more, correction in the direction of decreasing to the DC output voltage command value Vdc2r is added. As a result, the DC output voltage Vdc2 of the DC / DC converter 3 is lower than the voltage when the power factor is 1, but the output current Ia without waveform distortion is supplied to the commercial power system 8. Thus, since the DC output voltage Vdc2 can be lower than in the case of control with a power factor of 1, an effect of further reducing switching loss in the inverter circuit 4 and the DC / DC converter 3 is brought about.

(Sixth embodiment)
When the DC output voltage Vdc2 of the DC / DC converter 3 is insufficient, the current waveform in the vicinity of the peak value of the output current Ia is crushed or dropped and distortion increases. Therefore, by monitoring the peak value of the output current Ia and controlling the DC output voltage Vdc2 so that the value is exactly equal to the amplitude of the reference output current Ir, distortion of the waveform of the output current Ia can be prevented and at the same time It is possible to suppress the occurrence of excessive switching loss in the circuit 4 and the DC / DC converter 3.

The present embodiment is an embodiment based on such an idea, and FIG. 15 shows the configuration of the boost control circuit 6 in this case. The inverter control circuit 7 uses the circuit configuration shown in FIG.
A reference output current Ir (effective value) to be supplied to the commercial power system 8 is input to the boost control circuit 6, and the amplitude calculation circuit 613 calculates the amplitude of the sine wave and supplies it to the subtracter 63. On the other hand, the output current instantaneous value Ia ′ is input to the peak value detection circuit 614, and the peak value is detected. In the subtractor 63, the difference ΔIp between the amplitude of the reference output current Ir and the peak value of the output current instantaneous value Ia ′ is calculated, and the direct current of the DC / DC converter 3 is controlled by PI control so that the difference ΔIp becomes zero. Controls the output voltage Vdc2.

  With such control, when the peak current value of the output current Ia is smaller than the value of the sine wave amplitude calculated from the reference output current Ir, the DC output voltage Vdc2 of the DC / DC converter 3 starts to rise. The increase stops when the peak current value of the output current Ia becomes equal to the amplitude of the reference output current Ir. In this way, distortion of the waveform of the output current Ia is prevented, and generation of extra switching loss in the inverter circuit 4 and the DC / DC converter 3 is suppressed.

(Seventh embodiment)
In the sixth embodiment, the peak value of the output current Ia is detected, so that the value matches the amplitude of the reference output current Ir, that is, the output current waveform is not distorted. The DC output voltage Vdc2 of the DC converter 3 was controlled. Instead of controlling only depending on the peak value of the output current Ia in this way, the amplitude of the reference output current Ir and the DC output voltage command value Vdc2r of the DC / DC converter 3 in the first to fifth embodiments are A value obtained by multiplying the difference from the peak value of the output current Ia by a certain coefficient may be added as a correction value, and the DC output voltage Vdc2 may be controlled using the added value as a new DC output voltage command value Vdc2r.

  The present embodiment is an embodiment based on such an idea, and FIG. 16 shows the configuration of the boost control circuit 6 for performing the control. The difference from the configuration of the boost control circuit 6 of FIG. 14 described above is that the amplitude value of the reference output current Ir calculated by the amplitude calculation circuit 613 and the peak of the output current instantaneous value Ia ′ detected by the peak value detection circuit 614 are different. The difference is calculated by a subtraction circuit 615, and a value obtained by multiplying the difference by a constant coefficient by a coefficient unit 616 is added as a correction value to the DC output voltage command value Vdc2r so far. In this case, the previously described circuit configuration of FIG. 13 is used as the inverter control circuit 7.

(Eighth embodiment)
In the grid-connected inverter device 1 described so far, the DC output voltage Vdc2 of the DC / DC converter 3 is controlled to follow the DC output voltage command value Vdc2r by PI control. Therefore, for example, when the voltage of the system voltage Vac rises in a short time and then returns to the original value again in a short time, the gradient when the DC output voltage Vdc2 rises and the gradient when the DC output voltage Vdc2 falls and decreases and returns. It became basically the same.

  Thus, when the voltage of the system voltage Vac rises in a relatively short time and then recovers, the direction in which the DC output voltage Vdc2 rises is prevented from flowing out the low-order harmonic current to the commercial power system 8. It is necessary to ascend as quickly as possible from the viewpoint. However, the return (decrease) direction does not necessarily have to follow in a short time. Rather, it can be said that it is more convenient to make the recovery time slightly longer from the viewpoint of stabilizing the operation of the grid-connected inverter device 1 and stabilizing the output when the fluctuation of the grid voltage Vac is severe.

  The present embodiment is an embodiment based on such a concept. When the DC output voltage Vdc2 of the DC / DC converter 3 is increased, the PI control responsiveness in the boost control circuit 6 is increased quickly. It is controlled so as to be slow. Specifically, a non-linear amplifier circuit 617 is inserted as shown in FIG. 17 before the PI operation circuit 64 in the boost control circuit 6 shown in FIGS. 4, 6, 8, 10, 14, 15, and 16 described above. To do.

  The input / output characteristics of the inserted nonlinear amplifier circuit 617 are as shown in FIG. 18, and the gain when the difference voltage ΔVdc2 between the DC output voltage command value Vdc2r and the DC output voltage Vdc2 is positive is negative. It is larger than the gain. As a result, the PI control performed by the subtractor 63, the non-linear amplifier circuit 617, and the PI operation circuit 64 is performed when the value when the proportional constant increases the DC output voltage Vdc2 of the DC / DC converter 3 is decreased. Larger than the value. Therefore, when the DC output voltage command value Vdc2r rises stepwise and returns to a stepped state, the follow-up speed of the DC output voltage Vdc2 is slower in the return case than in the rise case, thereby achieving the purpose of the control. Is done.

(Ninth embodiment)
The present embodiment is a form in which a grid-connected power generation system is constructed by combining the grid-connected inverter device 1 of each of the embodiments described above with a fuel cell as a DC power supply 2. Since the fuel cell has a low voltage per cell of about 700 to 800 mV, it must be connected in series in order to supply about 175 V, which is a DC voltage that can supply the system voltage Va of the commercial power system 8. The number of cells becomes enormous. Theoretically, it is possible to increase the number of cells connected in series, but it is difficult to supply fuel cell fuel (hydrogen gas or methanol) and oxygen (air, etc.) in a balanced manner to all series cells. It is.

  Therefore, since the output voltage Vdc1 of the fuel cell is usually lower than the input voltage required by the inverter circuit 4 to secure the system voltage Va, the input voltage required by the inverter circuit 4 is ensured. In addition, a boosting DC / DC converter 3 is required. In particular, in consideration of normal power generation operation, there is an operation method called DSS operation that is generally operated outside the bedtime at midnight. In this case, the system voltage Va fluctuates drastically in order to operate in a time zone in which people are active. Therefore, the time for holding the value of the DC output voltage Vdc2 at an optimum value increases, and the grid-connected inverter device 1 described in the first to eighth embodiments is effective in improving the operation efficiency. An efficient grid-connected power generation system can be constructed by combining the fuel cell and the grid-connected inverter device described so far.

It is a block diagram which shows the whole circuit structure of the grid connection inverter apparatus of this invention. It is a block diagram of the inverter control circuit in FIG. It is an example of the relationship between the system voltage effective value which concerns on 1st Embodiment, and the DC output voltage command value of a DC / DC converter. 1 is a block diagram of a boost control circuit according to a first embodiment. FIG. It is an example of the relationship between the system voltage peak value which concerns on 2nd Embodiment, and the DC output voltage command value of a DC / DC converter. 6 is a block diagram of a boost control circuit according to a second embodiment. FIG. It is an example of the relationship between the output current concerning 3rd Embodiment, and a voltage drop part. FIG. 10 is a block diagram of a boost control circuit according to a third embodiment. It is an example of the relationship between the frequency of the system voltage which concerns on 4th Embodiment, and coefficient (beta). FIG. 10 is a block diagram of a boost control circuit according to a fourth embodiment. It is an example of the relationship between the system voltage and phase advance operation amount which concern on 5th Embodiment. It is an example of the relationship between the amount of phase advance operations which concerns on 5th Embodiment, and correction amount (gamma). It is a block diagram of the inverter control circuit which concerns on 5th Embodiment. FIG. 10 is a block diagram of a boost control circuit according to a fifth embodiment. FIG. 10 is a block diagram of a boost control circuit according to a sixth embodiment. FIG. 10 is a block diagram of a boost control circuit according to a seventh embodiment. It is a block diagram of the PI control part in the step-up control circuit according to the eighth embodiment. It is a figure which shows the input-output characteristic of the nonlinear amplifier circuit in FIG. FIG. 2 is a view corresponding to FIG.

Explanation of symbols

In the figure, 1 is a grid-connected inverter device, 2 is a DC power supply (fuel cell), 3 is a DC / DC converter, 4 is an inverter circuit, 5 is a filter circuit, 6 is a boost control circuit, 7 is an inverter control circuit, 8 is the commercial power system, f is the frequency of the system voltage, Ia is the output current (effective value), Ia 'is the output current (instantaneous value), Ir is the reference output current (effective value), and Vac is the system voltage (effective value). , Vac ′ is a system voltage (instantaneous value), Vdc2 is a DC output voltage, Vdc2r is a DC output voltage command value, and Δθ is a phase advance operation amount.

Claims (9)

A DC / DC converter (3) that boosts the DC voltage (Vdc1) from the DC power supply (2) and the DC output voltage (Vdc2) of the DC / DC converter are switched to output PWM-modulated AC current An inverter circuit (4), a filter circuit (5) for removing a high-frequency component contained in the alternating current and outputting a sine wave output current (Ia) to the commercial power system (8), and the DC / DC conversion A step-up control circuit (6) for controlling the switching operation of the converter and controlling its DC output voltage, and controlling the switching operation of the inverter circuit to match the output current of the filter circuit with a predetermined reference output current (Ir) A grid interconnection inverter device (1) comprising an inverter control circuit (7) for controlling
When the effective value (Vac) of the system voltage of the commercial power system is within a predetermined voltage range centered on the rated voltage, the boost control circuit (6) has a waveform based on the detected effective value of the system voltage. Is obtained by adding a constant voltage corresponding to the voltage drop in the filter circuit (5) and the inverter circuit (4) to the voltage value corresponding to the amplitude calculated assuming that is a sine wave. And the DC output voltage (Vdc2) of the DC / DC converter is controlled so as to coincide with the command value.   2. The grid-connected inverter device according to claim 1, wherein the boost control circuit (6) uses a peak value of the detected system voltage instead of an amplitude equivalent voltage value of the system voltage, and the peak value Is within a predetermined range, a value obtained by adding a constant voltage corresponding to a voltage drop in the filter circuit and the inverter circuit to the peak value is set as a DC output voltage command value (Vdc2r), and the value is matched with the command value. A grid-connected inverter device that controls a DC output voltage (Vdc2) of a DC / DC converter.   3. The grid-connected inverter device according to claim 1, wherein the step-up control circuit is replaced with a DC output voltage command value (Vdc2r) obtained by adding a constant voltage corresponding to a voltage drop in the filter circuit and the inverter circuit. The output current (Ia) of the filter circuit is detected, and a value obtained by adding a voltage proportional to the output current in a range where the output current is equal to or less than a predetermined value is defined as a DC output voltage command value (Vdc2r). And a DC output voltage (Vdc2) of the DC / DC converter is controlled so as to agree with the above.   4. The grid-connected inverter device according to claim 3, wherein the step-up control circuit detects a frequency of the system voltage, and the output current (in a range of a predetermined frequency centered on a rated frequency). Instead of the value before applying the voltage proportional to Ia), a value obtained by multiplying the value by a coefficient that increases as the frequency decreases is used, and the output current is within the range where the output current is not more than a predetermined value. A value obtained by adding a voltage proportional to is set as a DC output voltage command value (Vdc2r), and the DC output voltage (Vdc2) of the DC / DC converter is controlled so as to coincide with the command value. System inverter device.   5. The grid-connected inverter device according to claim 1, wherein when the system voltage (Vac) of the commercial power system exceeds a predetermined value, the inverter control circuit The phase of the output current (Ia) is controlled to be advanced from the phase of the system voltage by the phase advance operation amount (Δθ) corresponding to the excess amount, and the boost control circuit responds to the increase of the phase advance operation amount. Then, the DC output voltage command value (Vdc2r) of the DC / DC converter is corrected to be lowered, and the DC output voltage (Vdc2r) of the DC / DC converter is matched with the corrected DC output voltage command value. ) To control a grid-connected inverter device.   2. The grid-connected inverter device according to claim 1, wherein the boost control circuit detects a peak value of the output current (Ia) of the filter circuit, and the peak value is a wave of the reference output current (Ir). A grid-connected inverter device characterized in that, when the value is lower than a high value, control is performed so as to increase the DC output voltage (Vdc2) of the DC / DC converter according to the difference.   6. The grid-connected inverter device according to claim 1, wherein the step-up control circuit detects a peak value of an output current (Ia) of the filter circuit, and the peak value is the reference output current. If it is lower than the peak value of (Ir), a correction is made to increase the DC output voltage command value (Vdc2r) according to the difference, so that it matches the corrected DC output voltage command value (Vdc2r). A grid-connected inverter device that controls a DC output voltage (Vdc2) of the DC / DC converter.   The grid-connected inverter device according to any one of claims 1 to 7, wherein the step-up control circuit converts a DC output voltage (Vdc2) of the DC / DC converter to the DC output voltage command value (Vdc2r). In this case, when the DC output voltage command value (Vdc2r) is lower than the detected DC output voltage (Vdc2), the reverse is performed. A grid-connected inverter device characterized in that the value is smaller than the case. A grid-connected power generation system comprising the grid-connected inverter device according to any one of claims 1 to 8 and a fuel cell that supplies a DC power to the inverter device.

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