JP4195948B2 - Grid interconnection inverter - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a grid-connected inverter that links DC power, such as solar cells and fuel cells, to a grid and supplies the power as AC power.
[0002]
[Prior art]
Hereinafter, a conventional grid-connected inverter will be described with reference to the drawings. FIG. 11 is a block diagram showing a configuration of an example of a conventional grid-connected inverter.
[0003]
Conventionally, a grid-connected inverter receives DC power from a DC input power supply 1, converts it into AC of 50 Hz or 60 Hz, and supplies AC power to the system 2. The grid interconnection inverter includes a boost converter 3 that boosts the input voltage Vin to a voltage higher than the grid voltage VAC, an intermediate stage capacitor 4 that removes a high frequency component of the boosted voltage, and an inverter that shapes the output current into a sine wave. 5 and a filter 6 that removes high-frequency noise from the output of the inverter 5, and is connected to the system 2. In particular, the boost converter 3 includes a smoothing capacitor 3a for smoothing an input voltage, a DC reactor 3b for energy storage, a boost switching element 3c, and a boost diode 3d. The inverter 5 includes four switching elements Q1 to Q4. It is a full bridge configuration used.
[0004]
The operation in the above configuration will be described with reference to the drawings. FIG. 11 is a waveform diagram showing the operation of the conventional example. In FIG. 11, (a) is a reference wave and a triangular wave, (b) is a gate signal of the switching element Q1, (c) is a gate signal of the switching element Q2, (d) is a gate signal of the switching element Q3, and (e) is The gate signal of the switching element Q4 is shown. The output current io of the grid interconnection inverter is detected by the output current detection means 7 and compared with the command value of the sine waveform output from the current command means 8. The difference is output as a reference wave by the error amplifier 9, and compared with the triangular wave of the triangular wave generating means 11 by the comparator 10, and the on / off state of the switching element Q1 and the switching element Q2 is determined by the magnitude of the triangular wave and the reference wave. . When the system voltage VAC of the system 2 is positive, the switching element Q1 and the switching element Q4 are turned on, so that a current flows through the system 2. Conversely, when the system voltage VAC is negative, the switching element Q2 and the switching element Q3 are Turn on. As shown in FIG. 12, the switching element Q1 and the switching element Q2 perform high-frequency switching, and the switching element Q3 and the switching element Q4 switch at the commercial frequency. The same applies to the case where high frequency switching is simultaneously performed by a combination of the switching element Q1 and the switching element Q4 or a combination of the switching element Q2 and the switching element Q3.
[0005]
Since the triangular wave operates at a constant frequency, for example, when the reference wave is a sine wave, the input voltage of the inverter 5 (here, the voltage of the intermediate stage capacitor 4, that is, the intermediate stage voltage VM) is constant. For example, the average value of the output voltage of the inverter 5 is controlled to be a sine wave. Therefore, the waveform of the output current is determined by selecting the reference wave. At this time, the operating frequency of the inverter 5 matches the operating frequency of the triangular wave. The output voltage of the inverter 5 is removed of a high frequency component by a filter 6 including an output reactor 6a and a filter capacitor 6b.
[0006]
[Problems to be solved by the invention]
In such a conventional grid-connected inverter, when the DC input voltage Vin is lower than the maximum value of the grid voltage VAC, the boost converter 3 is connected to the grid 2 to realize the power factor 1 operation. And the inverter 5 are necessary, and in order to partially limit the operation of the boost converter 3 as a means for further improving the efficiency of the device, the capacity of the intermediate stage capacitor 4 is reduced to several hundred μF or less. Therefore, the intermediate stage voltage VM has a large ripple and is unstable. Further, in the high-speed feedback control in which the PWM method that determines the on / off time of the switching elements Q1 to Q4 by comparing the triangular wave with a constant frequency and the reference wave is detected and the obtained output current io is detected and compared with the command value, It is necessary to compensate for the phase lag of the output current io due to the filter 6, and an accurate active filter is indispensable to realize the compensation. In addition, since the instability of the input voltage (here, the intermediate stage voltage VM) and various fluctuations (voltage, frequency, and phase) of the system 2 are added, stable control is performed and output with little distortion is achieved. It was difficult to generate the current io.
[0007]
The present invention solves the above-described problems. Even when there are fluctuations or ripples in the intermediate stage voltage VM, fluctuations in the system, phase lag due to the filter 6, etc., the command values and filters of special waveforms are not used. An object of the present invention is to provide a grid-connected inverter that can operate stably without being affected by fluctuations and can accurately form a waveform.
[0008]
[Means for Solving the Problems]
The present invention according to claim 1 includes a DC reactor, a boosting switching element, and a boosting diode, and boosts an input voltage from a DC input power supply by high-frequency switching of the boosting switching element, thereby providing a DC intermediate stage voltage. From the intermediate stage voltage by switching of four switching elements configured as a full bridge, an intermediate stage capacitor having a capacity of several hundred μF or less that removes high frequency components in the intermediate stage voltage An inverter that outputs current, a filter that removes high-frequency components in the AC current by an output reactor and a capacitor, and outputs the output current to an AC system as an output current, wherein the input voltage is lower than the absolute value of the system voltage. Only by the boost converter Boosting the intermediate stage voltage so that it is partially convex, In a grid-connected inverter that converts DC power input from the input power source into AC power and outputs the AC power to the grid, a command value upper limit and a command value lower limit with a predetermined hysteresis width with respect to a command value for waveform shaping of the output current The output reactor current is maintained within a hysteresis width between the command value upper limit and the command value lower limit so that an average value of the output reactor current flowing through the output reactor becomes a sine wave. This is a grid-connected inverter in which high-frequency switching of the switching element of the inverter is controlled by hysteresis.
[0009]
According to the present invention, it stably operates against instability of the intermediate stage voltage and various fluctuations of the system voltage, frequency, phase, etc. Therefore, the intermediate stage voltage is convex with a configuration in which the intermediate stage capacitor is reduced in capacity. Thus, it is possible to provide a grid-connected inverter capable of shaping the output current into a sine wave without using a special command value even in a state where there are many ripples.
[0010]
According to a second aspect of the present invention, there is provided a second command value upper limit and a second command value lower limit with a predetermined hysteresis width with respect to a command value for waveform shaping of a DC reactor current flowing through a DC reactor of the boost converter, In the period during which the converter boosts, high-frequency switching of the boost switching element of the boost converter is hysteresis so as to keep the DC reactor current within the hysteresis width between the second command value upper limit and the second command value lower limit. Hysteresis control of high-frequency switching of the switching element of the inverter so that the output reactor current flowing through the output reactor is kept within the hysteresis width between the command value upper limit and the command value lower limit during the period during which the boost converter does not boost This is a grid interconnection inverter according to claim 1.
[0011]
As a result, when the input voltage is lower than the absolute value of the system voltage, the waveform can be shaped by the boost converter. Therefore, each switching element of the four-stone full-bridge inverter only performs a switching operation at a low frequency. It is possible to provide a grid-connected inverter that achieves a reduction in the loss of the inverter and reduces the overall size and weight of the equipment as the efficiency is improved and the size of the heat sink is reduced.
[0012]
The present invention according to claim 3 is configured such that the hysteresis width is variable corresponding to the DC input voltage, the effective value of the system voltage, and the output power. System inverter.
[0013]
As a result, the operating frequency in the hysteresis operation can be kept within a predetermined range corresponding to the DC input voltage, the effective value of the system voltage, and the output power, and the change in the operating frequency becomes small. A grid-connected inverter that can be optimally designed for electrical components such as a switching element, a capacitor, a DC reactor, and an output reactor can be provided.
[0014]
The present invention according to claim 4 is the grid interconnection inverter according to any one of claims 1 to 3, wherein the hysteresis width is variable in the commercial cycle in correspondence with the absolute value of the system voltage. .
[0015]
Thereby, the operating frequency in the hysteresis operation can be made substantially constant within one cycle of the system, and a grid-connected inverter that can be designed to an optimum operating frequency can be provided.
[0016]
The present invention according to claim 5 is provided with an overcurrent upper limit corresponding to an overcurrent and an undercurrent lower limit corresponding to an undercurrent outside the hysteresis width for determining the command value upper limit and the command value lower limit, 5. The grid-connected inverter according to claim 1, wherein an overcurrent exceeding an upper limit and an undercurrent below the undercurrent lower limit are forcibly returned to normal hysteresis control.
[0017]
As a result, even if an overcurrent or undercurrent occurs during the hysteresis operation, it can be forcibly returned to the normal hysteresis operation, and even if a malfunction occurs that deviates from the hysteresis width, the operation can be safely performed after that. A grid interconnection inverter that can be continued can be provided.
[0018]
According to a sixth aspect of the present invention, there is provided on-time detection means for detecting the on-time of all the switching elements constituting the inverter and the boost converter until the on-time of the switching element through which the current flows exceeds a predetermined value. The grid-connected inverter according to any one of claims 1 to 5, wherein an upper limit is set for the operating frequency by not turning off.
[0019]
Thereby, since the operating frequency of the hysteresis operation does not become a predetermined value or more, a malfunction is unlikely to occur, and a grid-connected inverter that operates stably can be provided.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
In the present invention according to claim 1, the output reactor current detecting means is means for detecting a current flowing in a DC reactor provided in the filter, and is constituted by a current transformer or the like. This current shows the change of the current output from the inverter as it is. The command value upper limit generation means is a means for generating a value obtained by adding a predetermined value to a command value for shaping the output current, that is, a command value upper limit. The command value lower limit generation means subtracts the predetermined value from the command value. A means for generating a value, that is, a command value lower limit. In short, the output reactor current gives a limit to repeat increase and decrease within a predetermined range with respect to the command value. Although the width between the command value upper limit and the command value lower limit is referred to as a hysteresis width, it is not limited to a certain width.
[0021]
The upper limit comparator is a means for comparing the value of the output reactor current with the command value upper limit. In the embodiment, when the output reactor current exceeds the command value upper limit, a reset signal is output to the flip-flop. The lower limit comparator is means for comparing the value of the output reactor current with the command value lower limit. In the embodiment, when the output reactor current becomes smaller than the command value lower limit, a set signal is output to the flip-flop. In short, it functions to monitor the output reactor current so that it is between the command value upper limit and the command value lower limit. The flip-flop is a means that is turned on or off in response to the set signal or reset signal, and provides a gate signal that turns on or off the switching element in the inverter. By each of the above means, the inverter performs a hysteresis operation centering on the command value to decrease the current when the command value upper limit is exceeded and to increase the current when the command value is lower than the command value lower limit. DC reactor current with a waveform according to The other components are the same as in the conventional example.
[0022]
In the present invention according to claim 2, the second command value upper limit generating means and the second command value lower limit generating means generate means for generating a second command value upper limit and a second command value lower limit respectively provided for the command value. It is the same as the command value upper limit and the command value lower limit in the first embodiment. The same applies to the second upper limit comparator, the second lower limit comparator, and the second flip-flop. The DC reactor current detection means is means for detecting the current of the DC reactor in the boost converter, shows the change in the current output from the boost converter to the inverter as it is, and is equivalent to the control using the output reactor current in the first embodiment. Served for purpose. In the embodiment, an example is shown in which the waveform of the inverter is not shaped during the boosting period. Therefore, the waveform of the command value for the DC reactor current is the same sine waveform as the waveform of the command value for the output reactor current. Is not to be done.
[0023]
In the present invention according to claim 3, when the output reactor current increases from the command value lower limit toward the command value upper limit, for example, when the switching element Q1 is turned on and current flows, the output voltage Vo (from the intermediate stage voltage VM ( Since the current flows toward the absolute value of the system voltage VAC), the current increases at the rise of (VM-Vo) / L1 via the inductance L1 output reactor, i.e., with respect to the potential difference (VM-Vo). In addition, when the output reactor current decreases from the command value upper limit toward the command value lower limit, for example, when the switching element Q2 is turned on and current flows, the intermediate stage voltage VM is cut off and the output voltage Vo goes to zero potential. Therefore, the current decreases at the fall of Vo / L1, that is, the slope through the inductance L1. Therefore, the transition time from the command value lower limit to the command value upper limit, or from the command value upper limit to the command value lower limit is substantially a value obtained by dividing the hysteresis width by the inclination.
[0024]
In this case, if the reciprocal of the total time of the transition time from the command value lower limit to the command value upper limit at a certain time and the transition time from the next command value upper limit to the command value lower limit is the operating frequency at that time, the intermediate stage voltage The operating frequency depends on VM, the absolute value and effective value of the system voltage VAC, the hysteresis width, and the like. Conversely, by making the hysteresis width variable corresponding to these, the operating frequency can be set to fall within a predetermined range.
[0025]
In the present invention according to claim 4, the rising slope from the command value lower limit of the output reactor current toward the command value upper limit is greater in the vicinity of zero of the system voltage VAC than in the vicinity of the peak. Accordingly, by setting the hysteresis width near the peak to be smaller than the hysteresis width near zero, the operating frequency of the hysteresis operation can be made substantially constant. The same applies to waveform shaping during the boosting operation of the boost converter.
[0026]
In the present invention according to claim 5, the overcurrent detection means detects an overcurrent exceeding the command value upper limit of the output reactor current, and the undercurrent detection means detects an undercurrent of the output reactor current below the command value lower limit. . The overcurrent upper limit comparator compares a predetermined overcurrent upper limit larger than the command value upper limit with the output reactor current, and if it exceeds, outputs a reset signal to the flip-flop. The undercurrent lower limit comparator compares a predetermined undercurrent lower limit that is smaller than the command value lower limit with the output reactor current, and outputs a set signal to the flip-flop if it is lower. Therefore, it functions to forcibly return to normal hysteresis operation. The same can be done when shaping the waveform during the boosting operation of the boost converter.
[0027]
In the present invention according to claim 6, the on-time detecting means is means for detecting the on-time of the switching element of the inverter and continuing the on-state of the switching element if it is less than a predetermined minimum on-time Ton min, In the embodiment, the set signal is output to the flip-flop until Ton min is reached. It functions to prevent a situation where the operating frequency of the hysteresis operation becomes too high. This function is particularly effective when the rising slope of the current is large near the zero voltage of the system voltage.
[0028]
Examples of the present invention will be described below.
[0029]
【Example】
(Example 1)
Hereinafter, Example 1 of the grid interconnection inverter of the present invention will be described with reference to the drawings. This embodiment relates to claim 1.
[0030]
FIG. 1 is a block diagram showing the configuration of this embodiment. Note that the same components as those in FIG. 11 are given the same reference numerals and detailed description thereof is omitted. This embodiment differs from the conventional example in that instead of the output current detection means 7, the filter 6 is provided with an output reactor current detection means 12 for detecting the output current of the inverter 5, and a command value for generating an upper limit of the command value. Upper limit generation means 13, command value lower limit generation means 14 for generating a lower limit of the command value, upper limit comparator 15 for comparing the output of output reactor current detection means 12 and the upper limit of the command value, and output reactor current detection means 12 is provided with a lower limit comparator 16 for comparing the output of 12 with the lower limit of the command value, and a flip-flop 17.
[0031]
The operation in the above configuration will be described with reference to the drawings. FIG. 2 is a waveform diagram showing the operation of this embodiment. 2, (a) is a command value upper limit (hereinafter referred to as command value upper limit) and command value lower limit (hereinafter referred to as command value lower limit), (b) is a gate signal of the switching element Q1, and (c). Is a gate signal of the switching element Q2, (d) is a gate signal of the switching element Q3, and (e) is a gate signal of the switching element Q4.
[0032]
Since the intermediate stage voltage VM must be at least several tens of volts higher than the system voltage VAC in order to inject power into the system 2, for example, when the input voltage Vin is 200V DC and the system voltage VAC is 200V AC, the system voltage The voltage is boosted for a period of 4 to 5 ms around the peak of VAC, and the voltage is not boosted for a period where the absolute value of the other system voltage VAC is sufficiently smaller than the input voltage Vin. Furthermore, since the capacitance of the intermediate stage capacitor 4 is reduced, it does not slip at low frequencies, so that the ON time can be modulated and the difference from the absolute value of the system voltage VAC can be maintained within about several tens of volts. As a result, the intermediate stage voltage VM has a partially convex waveform.
[0033]
In the inverter 5 to which the intermediate stage voltage VM is input, during the half-wave period of the commercial frequency in which the switching element Q4 is on and Q3 is off, the current of the output reactor 6a constituting the filter 6 is approximately sine. When the output reactor current is detected by the output reactor current detecting means 12 and the output reactor current becomes smaller than the command value lower limit, the output of the flip-flop 17 is set and the switching element Q1 is turned on. The switching element Q2 is turned off. As a result, the output reactor current increases. Conversely, when the output reactor current is larger than the upper limit of the command value, the output of the flip-flop 17 is reset, the switching element Q1 is turned off, the switching element Q2 is turned on, and the output reactor current decreases.
[0034]
With the above operation, the output reactor current changes between the command value upper limit and the command value lower limit. Here, by making the command value a sine wave, the average value of the output reactor current becomes a sine wave. The high frequency component of the output reactor current can be removed by the filter capacitor 6b.
[0035]
As described above, according to the present embodiment, in the grid-connected inverter having the intermediate stage capacitor 4 as small as several hundred μF or less, the high-frequency switching in the boost converter 3 is partially performed within one cycle of the system 2 so that the intermediate stage voltage is Even when VM is partially convex, it is possible to provide a grid-connected inverter capable of shaping the output current io into a substantially sine wave.
[0036]
In this embodiment, the inverter 5 is configured to switch the output of the half-bridge inverter that performs high-frequency switching at the commercial frequency. However, the same effect can be obtained even in a configuration in which all of the four stone switching elements Q1 to Q4 perform high-frequency switching. Needless to say.
[0037]
(Example 2)
Hereinafter, Example 2 of the grid interconnection inverter of the present invention will be described with reference to the drawings. This embodiment relates to claim 2.
[0038]
FIG. 3 is a block diagram showing the configuration of this embodiment. Note that the same components as those in FIG. 1 are assigned the same reference numerals and detailed description thereof is omitted. The difference between the present embodiment and the first embodiment is that not all of the waveform shaping of the output current io is performed by the inverter 5, and the boost converter 3 performs a boost operation in a period in which the input voltage Vin is lower than the absolute value of the system voltage VAC. This is because the waveform is shaped by using hysteresis control for the high-frequency switching.
[0039]
In FIG. 3, 18 is a system voltage detecting means for detecting the system voltage VAC of the system 2, 19 is an input voltage detecting means for detecting the input voltage Vin of the input power supply 1, and 20 is an absolute value of the system voltage VAC and the input voltage Vin. Input / output voltage comparator 21, DC reactor current detecting means 21 for detecting DC reactor current iLd of DC reactor 3 b in step-up converter 3, and 22 a second command for generating a second command value upper limit as an upper limit of the command value Value upper limit generating means, 23 is a second command value lower limit generating means for generating a second command value lower limit as a lower limit of the command value, and 24 is a second upper limit comparator for comparing the second command value upper limit with the DC reactor current iLd. , 25 is a second lower limit comparator for comparing the second command value lower limit with the DC reactor current iLd, and 26 is a comparison result of the second upper limit comparator 24 and the comparison result of the second lower limit comparator 25. The second flip-flop 27 is set or reset by the switching of the switching elements Q1 to Q4 by the flip-flop 17, and the switching of the boosting switching element 3c by the second flip-flop 26 is compared by the input / output voltage comparator 20. Switching switching means for switching according to the result.
[0040]
The operation in the above configuration will be described with reference to the drawings. FIG. 4 is a waveform diagram showing the operation of this embodiment. 4, (a) is a command value, command value upper limit and command value lower limit, (b) is a gate signal of switching element Q1 in inverter 5, (c) is a gate signal of switching element Q2, and (d) is switching. The gate signal of the element Q3, (e) is the gate signal of the switching element Q4, (f) is the gate signal of the transistor QF in the step-up switching element 3c, and (g) is the input voltage Vin and the absolute value of the system voltage VAC. .
[0041]
The grid interconnection inverter controls the output reactor current to a sine wave using the command value upper limit and the command value lower limit during a period when the absolute value of the system voltage VAC is lower than the input voltage Vin. Further, a DC reactor current detecting means 21 is provided, and the detected DC reactor current is input to the second upper limit comparator 24 and the second lower limit comparator 25, and compared with the second command value upper limit and the second command value lower limit, respectively. Thus, the second flip-flop 26 generates a gate signal for driving the boosting switching element. The input / output voltage comparator 20 compares the system voltage VAC from the system voltage detection means 18 with the input voltage Vin from the input voltage detection means 19, and the input voltage Vin is generally higher than the absolute value of the system voltage VAC. When the inverter 5 is selected by the switching switching means 27, hysteresis control is performed by the command value upper limit and the command value lower limit, and when the absolute value of the system voltage VAC is substantially lower than the input voltage Vin, the boost converter 3 And hysteresis control is performed by the second command value upper limit and the second command value lower limit.
[0042]
When the boost converter 3 performs hysteresis control, the direct current reactor current is detected by the direct current reactor current detecting means 21, and when the direct current reactor current becomes smaller than the command value lower limit of the second command value lower limit generating means 23, The output of the flip-flop 26 is set, and the transistor QF of the boosting switching element 3c is turned on. As a result, the DC reactor current increases. Conversely, when the DC reactor current is larger than the second command value upper limit of the second command value upper limit generating means 22, the output of the second flip-flop 26 is reset, the transistor QF is turned off, and the DC reactor current decreases. To do. At this time, the output current decreases. With these operations, the DC reactor current during the period in which the boost converter 3 performs the boost operation is maintained between the second command value upper limit and the second command value lower limit, and is output to the inverter 5.
[0043]
By the above operations, the command value upper limit, the command value lower limit, the second command value upper limit, and the second command value lower limit are appropriately set, and the average value of the output current io is shaped into a sine wave. A high frequency component accompanying the transition of the DC reactor current and the output reactor current is removed by the intermediate stage capacitor 4 and the filter 6.
[0044]
As described above, according to this embodiment, by controlling the DC reactor current of the boost converter 3, the boost converter 3 can perform waveform shaping when the input voltage Vin is substantially lower than the absolute value of the system voltage VAC. In some cases, the inverter 5 can be switched only at a low frequency, so that the loss can be reduced, and the entire device can be reduced in size and weight as the heat sink becomes smaller and the efficiency is reduced.
[0045]
(Example 3)
Hereinafter, Example 3 of the grid interconnection inverter of the present invention will be described with reference to the drawings. This embodiment relates to claim 3. In addition, if the structure of a present Example is shown with a block diagram, it will become the same as FIG. 1, and drawing is abbreviate | omitted.
[0046]
The operation in the above configuration will be described. FIG. 5 is a waveform diagram showing the operation of this embodiment. When trying to obtain a certain output current, the voltage hysteresis width between the command value upper limit and command value lower limit for the command value of the output reactor current is VH1, the intermediate stage voltage is VM, the output voltage is Vo, and the output reactor inductance is L1. Then, the output reactor current iL1 increases with a slope of (VM -Vo) / L1. Here, when the intermediate stage voltage VM or Vo changes, the ON time of the step-up switching element 3c is kept constant while keeping the output reactor current iL1 constant by changing the hysteresis width and newly setting VH2. Is possible. For example, when the intermediate stage voltage VM increases, the hysteresis width is widened, and when the intermediate stage voltage VM decreases, the hysteresis width is reduced, thereby changing the hysteresis width in response to the change in the slope and keeping the on time constant. Can keep. Further, since the current decreases with a slope of Vo / L1 during the off time, the off time can also be made substantially constant.
[0047]
As described above, according to this embodiment, the range of the operating frequency can be limited by adjusting the hysteresis width with respect to changes in the input voltage Vin, the system voltage VAC, and the output power, and a malfunction occurs accordingly. Thus, it is possible to provide a grid-connected inverter that can waveform-shape the output current io into a sine wave while reducing the possibility of doing so.
[0048]
Example 4
Hereinafter, Example 4 of the grid interconnection inverter of the present invention will be described with reference to the drawings. This embodiment relates to claim 4. In addition, if the structure of a present Example is shown with a block diagram, it will become the same as FIG. 3, and drawing is abbreviate | omitted.
[0049]
The operation in the above configuration will be described. FIG. 6 is a waveform diagram showing the operation of this embodiment. 6A shows the command value, the command value upper limit, and the command value lower limit, FIG. 6B shows the details near the peak of the system voltage VAC, and FIG. 6C shows the details near the zero of the system voltage VAC.
[0050]
When the hysteresis width is constant, the potential difference between the intermediate stage voltage VM and the output voltage Vo increases near zero of the absolute value of the system voltage VAC, so the slope of the increase in the output reactor current increases, and the peak of the system voltage VAC The operating frequency is higher than in the vicinity. Therefore, as shown in FIG. 6A, the operating frequency can be made constant in one cycle of the sine wave by decreasing the hysteresis width near the peak and increasing it near zero.
[0051]
As described above, according to this embodiment, by changing the hysteresis width of the output reactor current according to the absolute value of the system voltage VAC, the operating frequency becomes substantially constant, and the design is made with the optimum operating frequency of the inverter. In addition, it is possible to provide a grid-connected inverter that further achieves noise reduction.
[0052]
In the present embodiment, the case of waveform shaping using the output reactor current of the inverter 5 has been described. Needless to say, the same applies to the case of waveform shaping using the DC reactor current of the boost converter 3.
[0053]
(Example 5)
Hereinafter, Example 5 of the grid interconnection inverter of the present invention will be described with reference to the drawings. This embodiment relates to claim 5.
[0054]
FIG. 7 is a block diagram showing the configuration of this embodiment. Note that the same components as those in FIG. 1 are assigned the same reference numerals and detailed description thereof is omitted. The present embodiment is different from the first embodiment in that an overcurrent detection means 28 and an undercurrent detection means 29 are provided for the output reactor current, and an overcurrent upper limit comparator 30 for comparing with the output reactor current and an undercurrent lower limit. The comparator 31 is provided. The overcurrent detection means 28 detects an overcurrent of the output reactor current that exceeds the command value upper limit, and the undercurrent detection means 29 detects an undercurrent of the output reactor current that falls below the command value lower limit.
[0055]
The operation in the above configuration will be described. FIG. 8 is a waveform diagram showing the operation of this embodiment. In FIG. 8, (a) shows a command value upper limit, command value lower limit, command value, overcurrent upper limit, and undercurrent lower limit, and (b) shows details in the vicinity of the peak.
[0056]
Normally, the output reactor current transitions in the hysteresis width VH1, but when the switching element Q1 has to be turned off, for example, when the upper limit of the command value is reached and the switching device Q1 has to be turned off for some reason, In the present embodiment, the overcurrent detection means 28 detects the overcurrent of the output reactor current, and the overcurrent upper limit comparator 30 includes an overcurrent upper limit having a width of VHL provided outside the hysteresis width, an output reactor current, and And a reset signal is output to the flip-flop 17 to forcibly turn off the switching element Q1. On the other hand, if the output reactor current deviates from the hysteresis width of the command value lower limit and remains off, the undercurrent detection means 29 and the undercurrent lower limit comparator 31 determine that the abnormality is below the undercurrent lower limit, and the forced Thus, the switching element Q1 is turned on.
[0057]
As described above, according to this embodiment, it is possible to provide a grid-connected inverter that can continue to operate safely even if a malfunction occurs in the hysteresis control of the output reactor current.
[0058]
In the present embodiment, the operation of the switching element Q1 of the inverter 5 has been described. However, the same applies to the case of waveform shaping by the boost converter 3.
[0059]
(Example 6)
Hereinafter, Example 6 of the grid interconnection inverter of the present invention will be described with reference to the drawings. This embodiment relates to claim 6.
[0060]
FIG. 9 is a block diagram showing the configuration of this embodiment. Note that the same components as those in FIG. 1 are assigned the same reference numerals and detailed description thereof is omitted. This embodiment is different from the first embodiment in that an on-time detecting means 32 for detecting the on-time of the switching element Q1 or Q3 of the inverter 5 is provided.
[0061]
The operation in the above configuration will be described. FIG. 10 is a waveform diagram showing the operation of this embodiment. 10, (a) shows a command value upper limit, a command value lower limit, and a command value, and (b) shows details in the vicinity of the peak. In FIG. 10, the output reactor current normally transitions within the hysteresis width VH1, but the ON time corresponding to the hysteresis width corresponding to the conditions such as the input voltage Vin, the intermediate stage voltage VM, the system voltage VAC, and the output power. Even if it is set, if the ON time detected by the ON time detection means 32 has not reached the predetermined minimum ON time Ton min, a set signal is output to the flip-flop 17 and the Ton min is calculated. The switching element Q1 is kept in the ON state until the value is exceeded. This prevents a situation where the operating frequency of the hysteresis operation becomes very high.
[0062]
As described above, according to the present embodiment, since the operating frequency does not exceed the predetermined value when performing the hysteresis control of the output reactor current, the malfunction is unlikely to occur, and the grid-connected inverter that continues to operate safely Can be provided.
[0063]
【The invention's effect】
The present invention according to claim 1 includes a DC reactor, a boosting switching element, and a boosting diode, and boosts an input voltage from a DC input power supply by high-frequency switching of the boosting switching element, thereby providing a DC intermediate stage voltage. From the intermediate stage voltage by switching of four switching elements configured as a full bridge, an intermediate stage capacitor having a capacity of several hundred μF or less that removes high frequency components in the intermediate stage voltage, An inverter that outputs current, a filter that removes high-frequency components in the AC current by an output reactor and a capacitor, and outputs the output current to an AC system as an output current, and the input voltage is lower than the absolute value of the system voltage DC voltage boosted by the boost converter and input from the input power source only In a grid-connected inverter that converts AC power into AC power and outputs it to the grid, a command value upper limit and a command value lower limit are provided with a predetermined hysteresis width for a command value for shaping the output current, and the output reactor is By using a grid-connected inverter in which high-frequency switching of the switching element of the inverter is controlled so as to maintain a flowing output reactor current within a hysteresis width between the command value upper limit and the command value lower limit, In a grid-connected inverter that operates stably against instability of the intermediate stage voltage and various fluctuations of the system voltage, frequency, phase, etc., and thus the capacity of the intermediate stage capacitor is reduced to several hundred μF or less. Even when the intermediate stage voltage is partially convex, command a sine wave without using a special waveform for the command value. It may be substantially sinusoidal output current by the.
[0064]
According to a second aspect of the present invention, there is provided a second command value upper limit and a second command value lower limit with a predetermined hysteresis width with respect to a command value for waveform shaping of a DC reactor current flowing through a DC reactor of the boost converter, In the period during which the converter boosts, high-frequency switching of the boost switching element of the boost converter is hysteresis so as to keep the DC reactor current within the hysteresis width between the second command value upper limit and the second command value lower limit. Hysteresis control of high-frequency switching of the switching element of the inverter so that the output reactor current flowing through the output reactor is kept within the hysteresis width between the command value upper limit and the command value lower limit during the period during which the boost converter does not boost In order to provide a grid-connected inverter according to claim 1 Ri, can reduce the loss in the inverter, therefore, enables miniaturization of the heat sink, it is possible to provide a system interconnection inverter small and light.
[0065]
The present invention according to claim 3 is configured such that the hysteresis width is variable corresponding to the DC input voltage, the effective value of the system voltage, and the output power. By using a system inverter, the operating frequency in the hysteresis operation can be kept within a predetermined range corresponding to the DC input voltage, the effective value of the system voltage, and the output power, and the change in the operating frequency is reduced. It is possible to provide a grid-connected inverter that can be designed optimally for simplification and electrical components such as a switching element, a capacitor, a DC reactor, and an output reactor.
[0066]
The present invention according to claim 4 is a grid-connected inverter according to any one of claims 1 to 3, wherein the hysteresis width is variable in a commercial cycle corresponding to the absolute value of the system voltage. Thus, the operating frequency in the hysteresis operation can be made substantially constant within one cycle of the system, and a grid-connected inverter that can be designed to an optimal operating frequency can be provided.
[0067]
The present invention according to claim 5 is provided with an overcurrent upper limit corresponding to an overcurrent and an undercurrent lower limit corresponding to an undercurrent outside the hysteresis width for determining the command value upper limit and the command value lower limit, By setting the grid interconnection inverter according to any one of claims 1 to 4 to forcibly return to normal hysteresis control for an overcurrent exceeding an upper limit and an undercurrent below the undercurrent lower limit, Even if an overcurrent or undercurrent occurs during the hysteresis operation, the system can be forcibly returned to normal hysteresis operation, and even if a malfunction occurs that falls outside the hysteresis width, the system can continue to operate safely after that. A connected inverter can be provided.
[0068]
According to a sixth aspect of the present invention, there is provided on-time detection means for detecting the on-time of all the switching elements constituting the inverter and the boost converter, and until the on-time of the switching element through which the current flows exceeds a predetermined value. Since the operating frequency of the hysteresis operation does not exceed a predetermined value by using the grid-connected inverter according to any one of claims 1 to 5 in which an upper limit is set on the operating frequency by not turning off, malfunction is prevented. Therefore, it is possible to provide a grid-connected inverter that is less likely to occur and operates stably.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a first embodiment of a grid-connected inverter according to the present invention.
FIG. 2 is a waveform diagram showing the operation of the embodiment.
FIG. 3 is a block diagram showing a configuration of a second embodiment of a grid-connected inverter according to the present invention.
FIG. 4 is a waveform diagram showing the operation of the embodiment.
FIG. 5 is a waveform diagram showing the operation of the third embodiment of the grid interconnection inverter of the present invention.
FIG. 6 is a waveform diagram showing the operation of the system interconnection inverter according to the fourth embodiment of the present invention.
FIG. 7 is a block diagram showing a configuration of a fifth embodiment of a grid-connected inverter according to the present invention.
FIG. 8 is a waveform diagram showing the operation of the embodiment.
FIG. 9 is a block diagram showing a configuration of a grid-connected inverter according to a sixth embodiment of the present invention.
FIG. 10 is a waveform diagram showing the operation of the embodiment.
FIG. 11 is a block diagram showing the configuration of a conventional grid-connected inverter
FIG. 12 is a waveform diagram showing the operation of the conventional example.
[Explanation of symbols]
1 Input power
2 lines
3 Boost converter
3a Smoothing capacitor
3b DC reactor
3c Boosting switching element
3d boost diode
4 Intermediate stage capacitor
5 Inverter
6 Filter
6a Output reactor
6b Filter capacitor
7 Output current detection means
8 Current command means
9 Error amplifier
10 comparator
11 Triangular wave generation means
12 Output reactor current detection means
13 Command value upper limit generation means
14 Command value lower limit generation means
15 Upper limit comparator
16 Lower limit comparator
17 Flip-flop
18 System voltage detection means
19 Input voltage detection means
20 I / O voltage comparator
21 DC reactor current detection means
22 Second command value upper limit generation means
23 Second command value lower limit generation means
24 Second upper limit comparator
25 Second lower limit comparator
26 Second flip-flop
27 Switching switching means
28 Overcurrent detection means
29 Undercurrent detection means
30 Overcurrent upper limit comparator
31 Undercurrent lower limit comparator
32 On-time detection means
Vin input voltage
VM intermediate stage voltage
Vo output voltage
VAC system voltage
VH1, VH2 Hysteresis width
io output current
iL1 output reactor current
iLd DC reactor current
Q1, Q2, Q3, Q4 switching element
QF transistor

Claims (6)

A step-up converter comprising a DC reactor, a step-up switching element, and a step-up diode, and stepping up an input voltage from a DC input power supply by high-frequency switching of the step-up switching element and outputting a DC intermediate stage voltage; An intermediate stage capacitor having a capacity of several hundred μF or less that removes a high frequency component in the stage voltage, an inverter that outputs an alternating current from the intermediate stage voltage by switching of four switching elements configured in a full bridge, and an output reactor And a capacitor that removes a high-frequency component in the alternating current and outputs the output current to an alternating current system as an output current, and the intermediate stage voltage is output by the boost converter only during a period when the input voltage is lower than the absolute value of the system voltage. There is boosted so as to be partially convex, input from the input power source In the grid-connected inverter that converts the direct current power into alternating current power and outputs it to the system, a command value upper limit and a command value lower limit are provided with a predetermined hysteresis width with respect to a command value for shaping the output current, The switching reactor of the inverter is configured to keep the output reactor current within a hysteresis width between the command value upper limit and the command value lower limit so that an average value of the output reactor current flowing through the output reactor becomes a sine wave. A grid-connected inverter with hysteresis control for high-frequency switching.   A second command value upper limit and a second command value lower limit are provided with a predetermined hysteresis width with respect to a command value for waveform shaping of a DC reactor current flowing through a DC reactor of the boost converter, and during the period during which the boost converter boosts the DC Hysteresis control is performed on the high-frequency switching of the boosting switching element of the boost converter so as to keep the reactor current within the hysteresis width between the second command value upper limit and the second command value lower limit, and the boost converter does not boost The high frequency switching of the switching element of the inverter is subjected to hysteresis control so that the output reactor current flowing through the output reactor is maintained within a hysteresis width between a command value upper limit and a command value lower limit during the period. Grid-connected inverter.   3. The grid interconnection inverter according to claim 1, wherein the hysteresis width is variable corresponding to the DC input voltage, the effective value of the grid voltage, and the output power.   The grid interconnection inverter according to any one of claims 1 to 3, wherein the hysteresis width is variable in a commercial cycle corresponding to an absolute value of the system voltage.   An overcurrent upper limit corresponding to overcurrent and an undercurrent lower limit corresponding to undercurrent are provided outside the hysteresis width for determining the command value upper limit and the command value lower limit, and the overcurrent and the undercurrent exceeding the overcurrent upper limit are provided. The grid interconnection inverter according to any one of claims 1 to 4, wherein a normal hysteresis control is forcibly returned to an insufficient current below a lower limit.   On-time detection means is provided to detect the on-time of all switching elements that constitute the inverter and boost converter, and the operating frequency is not limited until the on-time of the switching element that is carrying current exceeds a predetermined value. The grid connection inverter in any one of Claims 1 thru | or 5 which provided.

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