JP4468372B2 - Photovoltaic power generation system and its boosting unit - Google Patents

Description

  The present invention relates to a photovoltaic power generation system and a boosting unit thereof, and in particular, increases the power generation voltage of a solar cell circuit within an input operation range of a power conditioner, and converts the DC power of the solar cell circuit into AC power. The present invention relates to a photovoltaic power generation system interconnected with commercial power and a booster unit thereof.

  The solar power generation system converts the DC power generated by the solar cell circuit into AC power by the power conditioner and links it with general commercial power supplied from the power company, so that surplus power is regenerated to the grid side. However, the insufficient power is a power generation system that is supplied from the grid side. Conventionally, as a general configuration of this type of photovoltaic power generation system, for example, there is a configuration shown in Patent Document 1 below. FIG. 4 is a diagram illustrating an example of a boosting unit of the photovoltaic power generation system disclosed in Patent Document 1.

  In FIG. 4, the boost unit 101 includes a standard input unit 110 to which a solar cell circuit 100 a that is one unit (hereinafter referred to as “solar cell circuit”) configured by connecting a plurality of solar cell modules in series, A boost input unit 112 to which the battery circuit 100b is connected. The standard input unit 110 is an input unit that does not include a booster circuit, and is an input unit that requires the number of series connected solar cell circuits that can be supplied without boosting the voltage within the input operation range of the power conditioner 102. . On the other hand, the boost input unit 112 is an input unit including a booster circuit, and is an input unit that boosts the voltage of the solar cell circuit to the operation range of the power conditioner by the booster circuit. The standard input unit 110 and the boost input unit 112 are each provided with a switch at each input stage, and the outputs are connected in the boost unit 101 to be grouped together and output to the power conditioner 102. In the power conditioner 102, the DC power of the solar cell circuit output from the boost unit 101 is converted into AC power and connected to the commercial power system 104 to perform grid connection. In the boosting unit shown in the figure, only two solar cell circuits (100a, 100b) are shown for simplification of the drawing, but usually more solar cell circuits may be inputted. Further, since the grid connection of the photovoltaic power generation system is an existing technology, detailed description thereof is omitted.

  The boost input unit 112 to which the solar cell circuit 100b is connected receives a control signal Sg2 to the main circuit composed of a reactor, a switching element, a diode, a capacitor, and the like, and to the switching element of the main circuit based on the input voltage Vs2 and the output voltage Vo2. A control circuit 114 to be supplied, and a trip signal generating unit 116 that generates and outputs a trip signal for tripping the switch of the input unit in the event of an abnormality based on the output voltage Vo2 and the temperature T2 of the switching element detected by the temperature sensor. Is provided.

The booster circuit of the booster input unit 112 sets the ratio of the number of series connection (n1) of solar cell circuits 100a that do not require a booster circuit and the number of series connections (n2) of solar cell circuits 100b that require a booster circuit as a target booster. The ratio α ^* (α ^* = n1 / n2) is set, and the step-up ratio constant control is performed. The control circuit 114 of the boost input unit 112 compares the actual boost ratio α (α = Vo2 / Vs2), which is the ratio of the actual output voltage Vo2 and the input voltage Vs2, with the target boost ratio α ^*, and the error is small. Thus, control is performed so as to optimize the on / off time of the signal Sg2 transmitted to the switching element.

FIG. 5 is a diagram showing voltage-power characteristics (hereinafter simply referred to as “VP characteristics”) of solar cell circuits having different numbers of series connections. In FIG. 8A, the VP characteristic of the solar cell circuit 100a connected to the standard input unit 110 is indicated by a solid line (L1), and the VP characteristic of the solar cell circuit 100b connected to the boost input unit 112 is shown. This is indicated by a broken line (L2). In FIG. 5A, the target boost ratio α ^* expressed by the ratio of the number of solar cell circuits connected in series is equal to the ratio (Vo1 / Vo2) of the open circuit voltage of each input unit. Further, the voltage ratio (Vp1 / Vp2) at which each solar cell circuit has the maximum output is also substantially equal to the target boost ratio α ^* . Therefore, the VP characteristic of the solar cell circuit 100b connected to the boost input unit 112 by the constant boost ratio control is as shown by the broken line (L4) in FIG. 5B, and the maximum power point P2max of the boost input unit 112 is shown. Moves to P2max ′ after boosting. At this time, the power conditioner 102 operates at the point Pmax of the combined output characteristic of the standard input unit 110 and the boost input unit 112 indicated by the thick line (L5), and can extract the maximum input power. As a result, the solar cell circuit 100a of the standard input unit 110 and the solar cell circuit 100b of the step-up input unit 112 can be operated at the point where the respective output power becomes maximum.

Thus, when the power conditioner 102 connected to the output of the boosting unit 101 is in an operating state, the boosting input unit 112 performs target boost ratio constant control so that the target boost ratio α ^* is constant. On the other hand, when the power conditioner 102 connected to the output of the boosting unit is not in an operating state, the boosting unit 101 is placed in a no-load state, and when the boosting circuit of the boosting input unit 112 performs a boosting operation, the output The voltage rises, and the input voltage of the power conditioner 102 exceeds the allowable input voltage range. The boost input unit 112 detects such a state and performs constant voltage control so that the output voltage of the boost unit 101 falls within the allowable input voltage range of the power conditioner 102.

  On the other hand, even if constant voltage control is performed, if the output voltage of the booster unit 101 exceeds the allowable input voltage range of the power conditioner 102, the trip signal generator 116 of the booster input unit 112 increases the overvoltage of the output voltage Vo2. By detecting and tripping the breaker 121 at the input stage to open the line with the solar cell circuit, the boosting unit 101 and the power conditioner 102 are prevented from being damaged.

  In addition, when the switching element 122 of the boost input unit 112 causes a short-circuit failure or the like and the short-circuit current of the solar cell circuit 100b continues to flow, an abnormality is caused by the temperature sensor 124 installed around the switching element 122. When the trip signal generator 116 detects a large temperature rise value, it trips the breaker 121 at the input stage to open the line with the solar cell circuit 100b and prevent the short circuit current of the solar cell circuit 100b from continuously flowing. ing.

JP 2002-51571 A

  By the way, when the booster unit's booster circuit is operating stably, when the power conditioner protection function is activated and the power conditioner is stopped, an abrupt no-load condition has occurred for the booster unit. The output voltage of the unit may exceed the upper limit within the input voltage range of the inverter. In such a situation, the trip signal generator detects an overvoltage and controls the input circuit of the booster circuit to trip to open the line of the solar cell circuit. If there is a failure, the overvoltage cannot be detected, the output of the booster circuit becomes an abnormal overvoltage, and the booster unit and the power conditioner may be damaged.

  Further, as described above, when the trip signal generator detects an overvoltage of the output voltage or an abnormal temperature rise value, the conventional boosting unit trips the input breaker of the boosting circuit and opens the line of the solar cell circuit. It was like that. However, in general, a switch (such as a magnetic contactor) that trips DC power such as a solar cell circuit is very expensive and the component size is relatively large, which increases the cost of the product and increases the size of the product. However, there was a problem of increasing the size.

Further, in the conventional boosting unit, the ratio of the number of series connections (n1) of solar cell circuits 100a that do not require a boosting circuit and the number of series connections (n2) of solar cell circuits 100b that require a boosting circuit is set as a target boosting ratio α. ^* (Α ^* = n1 / n2) is set and constant boost ratio control is performed, but when the target boost ratio is small, such as when the number of solar cell circuits 100b is smaller than that of the solar cell circuit 100a. In addition, when the actual step-up ratio is almost equal to 1 due to variations in the solar cell circuit, the degree of sunlight irradiation, etc., there is a possibility that annoying noise may be generated by the intermittent operation of the step-up circuit.

  The present invention has been made in view of the above-described problems, and reliably prevents damage to the boosting unit and the power conditioner even when a sudden no-load state occurs in the boosting unit. It is a first object of the present invention to provide a photovoltaic power generation system and a boosting unit thereof.

  It is a second object of the present invention to provide a photovoltaic power generation system capable of realizing the same function at a low cost without using an expensive switch for tripping DC power, and a boosting unit thereof. And

  The third object of the present invention is to provide a photovoltaic power generation system and its boosting unit that can effectively prevent annoying noise that may be generated by intermittent operation of the boosting circuit.

  In order to solve the above-described problems and achieve the object, a photovoltaic power generation system according to the present invention includes a plurality of photovoltaic power generation systems that convert a direct current output of a solar cell circuit into an alternating current and are connected to a commercial power system. A booster unit comprising a solar cell circuit, a booster circuit connected to each of the plurality of solar cell circuits and boosting a DC voltage output from the connected solar cell circuit; and output from the booster unit A power conditioner that converts DC power to AC power, and the booster circuit outputs a control signal that varies the boost ratio based on the output voltage before boosting and the output voltage after boosting of the solar cell circuit output And a switching element that varies a boost ratio based on a control signal output from the control circuit, and the control circuit outputs an output of the boost circuit. When necessary to locked occurs, characterized in that it stops the control signal output to the switching element.

  According to the present invention, the boosting unit includes the booster circuit connected to each of the plurality of solar cell circuits, and the booster circuit includes the output voltage before boosting and the output voltage after boosting of the solar cell circuit output. And a control circuit that outputs a control signal that varies the boost ratio based on the control signal, and the control circuit outputs a control signal to the switching element for varying the boost ratio when the output of the boost circuit needs to be stopped. Stop output.

  According to the photovoltaic power generation system according to the present invention, when the output of the booster circuit needs to be stopped, the control signal output to the switching element is stopped. There is no need to trip a switch mounted on a product, and it is possible to reduce the device cost and reduce the device scale.

  Embodiments of a photovoltaic power generation system and a boosting unit thereof according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment.

  FIG. 1 is a diagram showing a configuration of a photovoltaic power generation system including a boosting unit according to the present invention. In the boosting unit shown in the figure, three solar cell circuits 10a, 10b, and 10c are shown for simplification of the drawing, but it goes without saying that the number of solar cell circuit inputs and the number of boosting circuits can be expanded.

  In FIG. 1, for example, solar cell circuits 10 a, 10 b, and 10 c installed on a small space roof surface such as a dormitory roof are connected to a booster unit 11. The booster unit 11 is equipped with booster circuits 20a and 20b connected to the solar cell circuits 10a and 10b, respectively, and a standard input unit 18 connected to the solar cell circuit 10c. The outputs of 20a and 20b and the standard input unit 18 are connected in the boosting unit 11 and gathered into one line and output to the power conditioner 12. The power conditioner 12 includes a booster circuit for generating a commercial system voltage, an inverter circuit for converting DC power of the solar battery circuit into AC power, a protection device for system interconnection, etc. (all not shown) In addition to controlling the output of the solar cell circuit so as to operate at the maximum output operating point of the solar cell circuit (maximum power point tracking control), various processes for linking to the commercial power system 14 are performed.

  Next, the configuration of the booster circuit according to the booster unit of the present invention using the booster circuit 20a will be described. In FIG. 1, the booster circuit 20a includes a main circuit including a reactor 23, a switching element 24, a diode 25, capacitors 26 and 27, a temperature sensor 28, a current sensor 29, and the like, and a control circuit 21a. The control circuit 21a includes the input voltage Vs1 of the solar cell circuit 10a, the output voltage Vo1 of the booster circuit 20a, the current IL1 of the reactor 23 when the switching element is ON detected by the current sensor 29, and the temperature sensor 28 inside the booster unit. Each signal of the ambient temperature T1 is input. The control circuit 21a includes a sensor circuit to which these signals are input, a microcomputer (hereinafter referred to as “microcomputer”) (which is not shown in FIG. 1), which is the center of control, and the like. The microcomputer outputs a command value of the gate signal Sg1 for turning on / off the switching element of the main circuit, and generates a boosted output boosted to a target voltage value. In addition, the control circuits of each booster circuit are electrically connected to the output overvoltage protection signal Voerr and the input voltage value Vspmax when output to the outside is permitted by the microcomputer of the control circuit.

  Next, the operation of the boosting unit 11 will be briefly described. The microcomputer in each booster circuit of the booster unit 11 constantly monitors the current operating point on the VP characteristic of each connected solar cell circuit, and the solar cell circuit so that this operating point becomes the maximum power point. To control. In this control, for example, the minute change amount (dPs / dVs) of the input power (Ps) with respect to the minute change amount of the input voltage (Vs) is calculated, and the minute change amount (dPs / dVs) is almost zero. It is possible to use a technique for searching for a region to be a value. When the operation at the maximum power point of each solar cell circuit has been determined, the output voltage value of the solar cell circuit at this maximum power point (hereinafter referred to as “maximum output operating voltage value”) is output, The highest voltage value (hereinafter referred to as “the maximum value of the maximum output operating voltage value”) among the maximum output operating voltage values of the connected solar cell circuits is set. Each booster circuit sets a boost ratio with the maximum value of the maximum output operating voltage value as a target value, and performs a boosting operation. However, if the maximum value of the maximum output operating voltage value is lower than the minimum voltage value at which the rated output of the inverter can be rated, each booster circuit uses the minimum input voltage value at which the rated output of the inverter can be output as the target voltage. A boost ratio is set and a boost operation is performed.

  In this way, normally, the output voltage of the boosting unit 11 boosted to the input voltage range in which the rated output is possible in the power conditioner 12 is input to the power conditioner 12, so that the power conditioner 12 is connected to each solar cell circuit. The maximum power can be extracted efficiently.

  Next, consider a case where the power conditioner 12 connected to the booster unit 11 suddenly stops due to a protection operation or the like. At this time, the step-up unit 11 is placed in a no-load state, the output voltage of the step-up circuit performing the step-up operation rapidly increases, and the input voltage of the power conditioner 102 exceeds the allowable input voltage range. It will be. In such a state, in the above-described conventional technology, the trip signal generator of the booster circuit detects overvoltage, and controls to break the booster circuit breaker and open the solar cell circuit line. . However, when its own trip signal generator is out of order, the overvoltage cannot be detected, the output of the booster circuit becomes an abnormal overvoltage, and the booster unit and the power conditioner may be damaged.

  Therefore, in the present invention, the control circuit of each booster circuit is configured as shown in FIG. 2 to solve the above-mentioned problems. Here, FIG. 2 is a diagram showing a configuration of each control circuit according to the present invention and a connection configuration between the control circuits. In the control circuit shown in the figure, an overvoltage detection signal generated based on the output voltage of each booster circuit grouped in a series is transmitted not only to its own booster circuit but also to other booster circuits. Yes.

  Next, the configuration of the control circuit provided in the booster circuit of the booster unit of the present invention will be described. In FIG. 2, the control circuit 21a detects an output voltage (Vo1) of the output voltage of each booster circuit (that is, the booster unit 11) collected in a series, and outputs to the output of the overvoltage detection circuit 31a. A gate drive circuit 32a and a microcomputer 33a to be connected are provided. The control signal from the microcomputer 33a is connected to the gate drive circuit 32a. Further, the control circuit 21b, which is another booster circuit, is configured in the same manner as the control circuit 21a, and the overvoltage detection signals of the overvoltage detection circuits 31a and 31b of each control circuit are output not only to itself but also to other control circuits. It is comprised so that.

  Next, the operation of the control circuit will be described. Since the outputs of the booster circuits 20a and 20b are grouped in one line at the output stage of the booster unit 11, they should output the same output value except for the transient state. It is shown as Vo1 and Vo2. In FIG. 2, when the overvoltage detection circuit 31a in the control circuit 21a that detects the output voltage Vo1 detects an overvoltage, a Vo1 overvoltage detection signal is output to the microcomputer 33a and also to the gate drive circuit 32a. At this time, a signal for stopping the switching operation of the switching element 24 is output from the gate drive circuit 32a. This Vo1 overvoltage detection signal is also output to the control circuit 21b of another booster circuit connected in hardware. According to the boost unit configured in this way, even if the overvoltage detection circuit 31a of the control circuit 21a fails, the control circuit of another normal boost circuit (in this embodiment, the control circuit The overvoltage detection circuit 31b) of 21b detects the overvoltage, and the operation of the switching element 24 of the booster circuit in which the overvoltage detection circuit has failed is detected by a signal from the overvoltage detection circuit 31b of the normal control circuit 21b as indicated by a broken line. It becomes possible to stop.

FIG. 3A is a diagram illustrating an example in which the control pulse width (G1) for turning on the switching element is not extremely small as compared to the control pulse width (G2) for turning off the switching element. FIG. 5 is a diagram illustrating an example of a case where a control pulse width (G3) for turning on a switching element is extremely smaller than a control pulse width (G4) for performing off control. In FIGS. 3A and 3B, the vertical axis represents the collector terminal of the switching element connected to the positive line of the solar cell circuit output and the emitter terminal of the switching element connected to the negative line. A terminal voltage (V _CE ) is used.

  As shown in FIG. 3A, the switching element of the booster circuit is a switching operation in which the ON / OFF ratio changes at a fixed frequency of about several tens of kHz at normal time, that is, when an appropriate boost ratio is set. It is carried out. On the other hand, as the step-up ratio becomes smaller, the on-time of the switching element becomes shorter. When there is almost no difference between the output voltage and the input voltage, the on-time within the basic switching period is almost eliminated, as shown in FIG. The control pulse width for on-control of such a switching element is extremely smaller than the control pulse width for off-control. In this state, the switching operation of the switching element becomes an intermittent operation, and there is a possibility that annoying noise having a frequency component of about several kHz based on the intermittent operation is generated.

  On the other hand, in such a situation, there is almost no difference between the maximum output operating voltage of the solar cell circuit input to the booster circuit and the maximum output point voltage of the target solar cell circuit. do not have to. Therefore, a predetermined threshold value is set for the boost ratio at which the boost operation is performed, and when the boost ratio is less than the predetermined threshold value, the booster circuit is stopped and the intermittent switching operation is not performed. . By performing such control, noise generated from the boosting unit can be prevented.

  This control concept can also be applied to the case where the booster circuit is stopped based on the temperature sensor output. In the conventional temperature control, the booster circuit detects the internal ambient temperature with a temperature sensor, and immediately stops the booster circuit when the internal ambient temperature reaches a predetermined temperature level. On the other hand, when the internal ambient temperature reaches a predetermined level, the booster circuit is not stopped immediately, but the current flowing through the main circuit of the booster circuit is reduced so that the internal ambient temperature does not rise above the predetermined temperature. Thus, the output power may be suppressed. By performing such control, the on / off ratio of the switching element can be varied so that the internal ambient temperature does not rise above the specified temperature, thereby reducing the current flowing through the main circuit of the booster circuit and suppressing the output power. You just have to do it. If the temperature rises even if the output power is suppressed, the booster circuit may be stopped by turning off the gate signal of the switching element.

  In this embodiment, the configuration of the booster circuit in which the switching control of the switching element changes the ON / OFF pulse width ratio using a fixed frequency of about several tens of kHz is described as an example. It goes without saying that the switching frequency need not be a fixed frequency, and can be applied to a booster circuit configured to perform variable frequency switching control.

  As described above, according to the photovoltaic power generation system and its boosting unit of this embodiment, the control circuit has an overvoltage detection that detects whether or not the output voltage of its own boosting circuit has exceeded a predetermined voltage value. A circuit is further provided, and the overvoltage detection circuit provided in the control circuit of one booster circuit outputs the detected overvoltage detection signal to the control circuit of another booster circuit, so that the protection against the output overvoltage is ensured. It is possible to improve the performance, and it is possible to prevent damage due to overvoltage to the booster unit due to overvoltage and the power conditioner to which the output is connected.

  Further, according to the photovoltaic power generation system and its boosting unit of this embodiment, when it is necessary to stop the output of the booster circuit, the control signal output to the switching element is stopped. For protection by detection, it is not necessary to trip an expensive DC switch mounted on the product, and the device cost can be reduced and the device scale can be reduced.

  Moreover, according to the photovoltaic power generation system and its boosting unit of this embodiment, when the boosting ratio set by itself is less than a predetermined threshold, the boosting operation of the boosting circuit is stopped. Intermittent switching of the booster circuit can be prevented, and noise resulting from the switching can be prevented.

  Further, according to the photovoltaic power generation system and its boosting unit of this embodiment, when the atmospheric temperature of the boosting circuit reaches a predetermined level, the current flowing through the boosting circuit is determined based on the control signal to the switching element. Since the power generation time is ensured as much as possible by controlling so that the temperature in the booster circuit or the booster unit does not rise, the power utilization rate of the solar cell circuit can be increased.

  As described above, the solar power generation system according to the present invention is useful as a clean power generation system using inexhaustible solar energy, and the boosting unit is useful as a component for realizing the solar power generation system. is there.

FIG. 1 is a diagram showing a configuration of a photovoltaic power generation system including a boosting unit according to the present invention. FIG. 2 is a diagram showing a configuration of each control circuit according to the present invention and a connection configuration between the control circuits. FIG. 3A is a diagram illustrating an example in which the control pulse width (G1) for turning on the switching element is not extremely smaller than the control pulse width (G2) for turning off the switching element. FIG. 3-2 is a diagram illustrating an example in which the control pulse width (G3) for turning on the switching element is extremely smaller than the control pulse width (G4) for turning off the switching element. FIG. 4 is a diagram illustrating an example of a boosting unit of a photovoltaic power generation system according to a conventional technique. FIG. 5 is a diagram illustrating VP characteristics of solar cell circuits having different numbers of series connections.

10a, 10b, 10c, 100a, 100b Solar cell circuit 11, 101 Booster unit 12, 102 Power conditioner 14, 104 Commercial power system 18, 110 Standard input unit 20a, 20b Booster circuit 21a, 21b, 114 Control circuit 23 Reactor 24 , 30, 122 Switching element 25 Diode 26, 27 Capacitor 28, 124 Temperature sensor 29 Current sensor 31a, 31b Overvoltage detection circuit 32a, 32b Gate drive circuit 33a, 33b Microcomputer 112 Boost input unit 116 Trip signal generation unit 121 Breaker

Claims (6)

A plurality of solar cell circuits; a booster unit including a booster circuit capable of boosting a DC voltage output from the plurality of solar cell circuits; a power conditioner that converts DC power output from the booster unit into AC power; A solar power generation system comprising:
The booster circuit includes:
A control circuit that outputs a control signal that varies the boost ratio based on the output voltage before boosting and the output voltage after boosting of the solar cell circuit output;
A switching element that varies a boost ratio based on a control signal output from the control circuit;
With
The control circuit includes:
When it is necessary to stop the output of the booster circuit, the control signal output to the switching element is stopped , and when the boost ratio set by itself is less than a predetermined threshold, the booster included in itself A photovoltaic power generation system characterized by stopping the step-up operation of the circuit . The control circuit further includes an overvoltage detection circuit that detects whether or not the output voltage of its own booster circuit exceeds a predetermined voltage value,
2. The photovoltaic power generation system according to claim 1, wherein the overvoltage detection circuit included in the control circuit of one booster circuit outputs the detected overvoltage detection signal to the control circuit of another booster circuit. 3. A plurality of solar cell circuits; a booster unit including a booster circuit capable of boosting a DC voltage output from the plurality of solar cell circuits; a power conditioner that converts DC power output from the booster unit into AC power; A solar power generation system comprising:
The booster circuit includes:
A control circuit that outputs a control signal that varies the boost ratio based on the output voltage before boosting and the output voltage after boosting of the solar cell circuit output;
A switching element that varies a boost ratio based on a control signal output from the control circuit;
With
The control circuit reduces the current flowing through the booster circuit based on a control signal to the switching element when the ambient temperature of the booster circuit including the control circuit reaches a predetermined level. Power generation system. In the boosting unit of the photovoltaic power generation system that boosts the DC voltage output from the solar cell circuit to a predetermined level,
A booster circuit capable of boosting a DC voltage output from the solar cell circuit;
The booster circuit includes:
A control circuit that outputs a control signal that varies the boost ratio based on the output voltage before boosting and the output voltage after boosting of the solar cell circuit output;
A switching element that varies a boost ratio based on a control signal output from the control circuit;
With
The control circuit stops the control signal output to the switching element when it is necessary to stop the output of the booster circuit, and when the boost ratio set by itself is less than a predetermined threshold value, A step-up unit for a photovoltaic power generation system, characterized in that the step-up operation of a step-up circuit including itself is stopped . The control circuit further includes an overvoltage detection circuit that detects whether or not the output voltage of its own booster circuit exceeds a predetermined voltage value,
5. The boosting unit of a photovoltaic power generation system according to claim 4 , wherein the overvoltage detection circuit included in the control circuit of one booster circuit outputs the detected overvoltage detection signal to the control circuit of another booster circuit. In the boosting unit of the photovoltaic power generation system that boosts the DC voltage output from the solar cell circuit to a predetermined level,
A booster circuit capable of boosting a DC voltage output from the solar cell circuit;
The booster circuit includes:
A control circuit that outputs a control signal that varies the boost ratio based on the output voltage before boosting and the output voltage after boosting of the solar cell circuit output;
A switching element that varies a boost ratio based on a control signal output from the control circuit;
With
The control circuit reduces the current flowing through the booster circuit based on a control signal to the switching element when the ambient temperature of the booster circuit including the control circuit reaches a predetermined level. Booster unit for power generation system.

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