JP2020077132A - Power conversion device, power generation system, and power control method - Google Patents

Abstract

To operate a power generation module at the maximum power point even when the efficiency in power generation is reduced.SOLUTION: A power conversion device comprises: a chopper-type step-up/down circuit that is applied with an input voltage generated from a power generation module generating a DC power, outputs an output voltage obtained through power conversion of the input voltage, and can also output the input voltage without the power conversion as the output voltage; a switching control unit that executes maximum power point follow-up processing of controlling the power conversion of the step-up/down circuit to maximize the DC power generated by the power generation module; and an efficiency change event detection unit that detects whether an efficiency change event occurs in which the efficiency in power generation of the power generation module is changed by a predetermined value or more. When the efficiency change event occurs, the switching control unit executes the maximum power point follow-up processing by a scanning method, and after the execution of the maximum power point follow-up processing by the scanning method, starts the maximum power point follow-up processing by a hill-climbing method while taking over the amount of controlling the power conversion for maximizing the DC power.SELECTED DRAWING: Figure 22

Description

  The present invention relates to a power converter, a power generation system, and a power generation control method.

  A solar power generation system that generates power using a solar cell panel is known. The solar cell panel has a peak point in a characteristic curve representing generated power with respect to generated voltage. Therefore, in the solar power generation system, power conversion is controlled so that the solar cell panel operates at the maximum power point. Such control is called maximum power point tracking (MPPT) control.

  A method called a hill climbing method is known as a method for realizing MPPT control. A power conversion device that executes the hill climbing method observes a change in power generated by a solar cell panel by continuously increasing or decreasing the voltage conversion ratio (ratio of input voltage to output voltage) by a small amount while continuing power conversion. To do. Then, the power conversion device changes the voltage conversion ratio in the direction in which the power generated by the solar cell panel increases. As a result, the power conversion device can increase or decrease the voltage conversion ratio so as to make a round trip before and after the peak point. As a result, the power conversion device can operate the solar cell panel at the maximum power point.

JP, 2018-88073, A JP, 2018-78667, A Japanese Patent No. 6215224

  By the way, when the solar cell panel operates in a state where the power generation efficiency is maximum, the characteristic representing the generated power with respect to the generated voltage is a curve having one peak point. However, in the solar cell panel, for example, when the power generation efficiency is reduced due to a part of the solar cell panel, the characteristic representing the generated power with respect to the generated voltage may be a curve having a plurality of peak points. In this case, when the hill-climbing method is executed, the power conversion device may increase or decrease the voltage conversion ratio so as to reciprocate before and after the peak point that is not the maximum power point. As a result, the power conversion device cannot operate the solar cell panel at the maximum power point.

  The present invention has been made in view of the above, and provides a power conversion device, a power generation system, and a power generation control method capable of operating a power generation module at a maximum power point even when power generation efficiency is reduced. The purpose is to

  In order to solve the above-mentioned problems and achieve the object, a power conversion device according to the present invention is applied with an input voltage generated from a power generation module that generates DC power, and outputs an output voltage obtained by power conversion of the input voltage. A chopper type step-up / down circuit capable of outputting the input voltage as the output voltage without converting the power, and the step-up / down circuit for maximizing the DC power generated by the power generation module. And a switching control unit that executes a maximum power point tracking process for controlling the power conversion of the power conversion module, and an efficiency change event detection that detects whether or not an efficiency change event occurs in which the power generation efficiency of the power generation module changes by a predetermined value or more. The switching control unit executes the maximum power point tracking process by the scanning method when the efficiency change event occurs, and executes the maximum power point tracking process by the scanning method. The control amount of the power conversion that maximizes the power is taken over, and the maximum power point tracking process by the hill climbing method is started.

  According to the present invention, the power generation module can be operated at the maximum power point even when the power generation efficiency is reduced.

FIG. 1 is a diagram showing a configuration of a power generation system. FIG. 2 is a diagram showing the power generation efficiency with and without the power converter installed. FIG. 3 is a diagram showing the configuration of the power conversion device. FIG. 4 is a diagram showing a functional configuration of the controller according to the first embodiment. FIG. 5 is a diagram showing states of switches included in the step-up / down circuit in the stop mode. FIG. 6 is a diagram showing states of switches included in the step-up / down circuit in the pass-through mode. FIG. 7 is a diagram showing states of the switches included in the step-up / down circuit when the follow-up mode is stepped down. FIG. 8 is a diagram showing the waveform of the first switching signal when the follow-up mode is stepped down. FIG. 9 is a diagram showing the states of the switches included in the step-up / down circuit when boosting in the follow-up mode. FIG. 10 is a diagram showing the waveform of the third switching signal during boosting in the follow-up mode. FIG. 11: is a figure for demonstrating the change of the input voltage in a mountain climbing method. FIG. 12 is a flowchart showing the processing contents of the mountain climbing method. FIG. 13: is a figure which shows the operation mode of the power converter device which concerns on 1st Embodiment. FIG. 14 is a state transition diagram showing transition of operation modes in the first embodiment. FIG. 15 is a diagram showing a functional configuration of the controller according to the second embodiment. FIG. 16 is a state transition diagram showing transition of operation modes in the second embodiment. FIG. 17 is a state transition diagram showing transition of operation modes in the modification of the second embodiment. FIG. 18 is a diagram for explaining changes in the input voltage during scanning in the third embodiment. FIG. 19 is a diagram showing states of switches included in the step-up / down circuit when the voltage value of the input voltage output from the solar cell panel is changed within a predetermined range. FIG. 20 is a flowchart showing the flow of processing of the switching control unit according to the third embodiment. FIG. 21 is a diagram showing changes in the input voltage and the input current when the processing is performed according to the procedure of FIG. FIG. 22 is a diagram showing a functional configuration of the controller according to the fourth embodiment. FIG. 23 is a state transition diagram showing state transitions of the switching control unit according to the fourth embodiment. FIG. 24 is a diagram showing a change example of the characteristic curve representing the generated power with respect to the generated voltage when the efficiency change event occurs.

  Hereinafter, a plurality of embodiments will be described. In addition, the same code | symbol is attached | subjected about the component common in several embodiment. Further, the configuration common to a plurality of embodiments will be described in detail in the first-mentioned embodiment, and detailed description will be omitted in the following embodiments except for differences.

(First embodiment)
FIG. 1 is a diagram showing a power generation system 10 according to the first embodiment. The power generation system 10 includes a plurality of solar cell panels 20, a connection device 22, a power conditioner 24, and one or a plurality of power conversion devices 30.

  The solar cell panel 20 receives sunlight and converts the received sunlight into electric energy. Then, the solar cell panel 20 generates DC power.

  The solar cell panel 20 includes a plurality of clusters. The solar cell panel 20 includes, for example, two or three clusters. The cluster includes a plurality of solar cells (power generation cells) connected in series. The plurality of clusters included in the solar cell panel 20 are connected in series. The solar cell panel 20 generates power at 100% efficiency when all the included clusters normally receive sunlight to generate power (normal efficiency state). However, in the solar cell panel 20, when some clusters are shaded or some clusters fail, bypass diodes connected in parallel to the partially shaded or failed clusters are turned on. , The current is bypassed to the bypass diode. As a result, when some clusters are shaded or some clusters fail, the solar cell panel 20 generates power with an efficiency lower than 100% (low efficiency state).

  The power generation system 10 includes one or more strings. One string includes a plurality of solar cell panels 20. A plurality of solar cell panels 20 included in one string are connected in series.

  The connection device 22 connects the DC power output from the plurality of strings in parallel and supplies the DC power to the power conditioner 24. The connection device 22 prevents the reverse flow of current from one string to another. In addition, in order to prevent backflow, each string is connected to a diode forwardly connected to the end that generates a positive voltage.

  The power conditioner 24 converts the DC power supplied from the connection device 22 into AC power having a predetermined frequency. The power conditioner 24 outputs the generated AC power to the outside via a power transmission line or the like. Further, the power conditioner 24 protects the interconnected system.

  Further, the power conditioner 24 executes maximum power point tracking (MPPT) control for all of the plurality of solar cell panels 20. The solar cell panel 20 has a peak point (maximum point) in the characteristic curve representing the generated power with respect to the generated voltage. The power conditioner 24 can operate the plurality of solar cell panels 20 at the maximum operating point by executing the maximum power point tracking control.

  Further, the power conversion device 30 is attached to all or part of the plurality of solar cell panels 20. The power conversion device 30 converts the DC power output from the solar cell panel 20 into DC power (DC-DC conversion). In the solar cell panel 20 to which the power conversion device 30 is attached, the output end of the power conversion device 30 is connected in series with another solar cell panel 20.

  Note that FIG. 1 illustrates an example in which the power conversion device 30 is attached to all of the plurality of solar cell panels 20. However, the power generation system 10 may include the solar cell panel 20 to which the power conversion device 30 is not attached.

  Further, the power generation system 10 according to the present embodiment may use, instead of the plurality of solar cell panels 20, another power generation module having a peak point in the characteristic curve representing the generated power with respect to the generated voltage. For example, the power generation module may be a wind power generator, a fuel cell, or the like.

  FIG. 2 is a diagram showing power generation efficiency when the power conversion device 30 is not attached and when it is attached. The power conversion device 30 executes the maximum power point tracking control so that the attached solar cell panel 20 (the solar cell panel 20 that is the target of power conversion) is operated at the maximum power point.

  For example, when the power conversion device 30 is not attached to any of the solar cell panels 20, the power generation efficiency of the other solar cell panels 20 included in the string decreases according to the decrease in the power generation efficiency of one solar cell panel 20. Will fall.

  However, even if the power generation efficiency of the solar cell panel 20 to which the power conversion device 30 is attached decreases, the power conversion device 30 increases or decreases the voltage generated by the target solar cell panel 20 and supplies the voltage to the string. , The target solar cell panel 20 is operated at the maximum power point. Therefore, the other solar cell panels 20 included in the string can operate at the maximum power point. Thus, even if the power generation efficiency of the target solar cell panel 20 is reduced, the power conversion device 30 can minimize the reduction of the power generation efficiency of the other solar cell panels 20 included in the string.

  FIG. 3 is a diagram showing the configuration of the power conversion device 30. The power conversion device 30 includes a positive side input terminal 42, a negative side input terminal 44, a positive side output terminal 46, a negative side output terminal 48, a step-up / down circuit 50, an ammeter 52, and an input side voltmeter 54. The output side voltmeter 56, the controller 60, and the power supply 62.

  The input voltage generated from the target solar cell panel 20 is applied to the positive input terminal 42 and the negative input terminal 44. The positive side input terminal 42 is connected to the positive side terminal of the target solar cell panel 20. The negative side input terminal 44 is connected to the negative side terminal of the target solar cell panel 20.

  The positive side output terminal 46 is a negative side terminal of another solar cell panel 20 adjacent to the positive side included in the same string, or a negative side of the power conversion device 30 attached to another adjacent solar cell panel 20. It is connected to the output terminal 48. In addition, when the target solar cell panel 20 is arranged at the plus side end portion in the string, the positive side output terminal 46 is connected to the connection device 22.

  The negative output terminal 48 is a positive terminal of another solar cell panel 20 adjacent to the negative side included in the same string, or a power conversion device 30 attached to another solar cell panel 20 adjacent to the negative side. Is connected to the positive output terminal 46 of. When the target solar cell panel 20 is arranged at the negative end of the string, the negative output terminal 48 is connected to the connection device 22.

The ammeter 52 measures the current value of the current (input current I _IN ) output from the target solar cell panel 20. In the present embodiment, the ammeter 52 measures the current flowing from the positive side input terminal 42 to the positive side output terminal 46. For example, the ammeter 52 is a current measuring resistor having a small resistance value inserted in the path between the positive side input terminal 42 and the positive side output terminal 46, and an amplifier for amplifying the voltage generated in the current measuring resistor. Including and The ammeter 52 as described above outputs to the controller 60 a voltage having a voltage value proportional to the current (input current I _IN ) output from the target solar cell panel 20.

The input-side voltmeter 54 measures the voltage value of the voltage (input voltage V _IN ) generated from the target solar cell panel 20. In the present embodiment, the input side voltmeter 54 measures the voltage between the positive side input terminal 42 and the negative side input terminal 44. For example, the input-side voltmeter 54 amplifies the input voltage detection resistor having a large resistance value provided between the positive side input terminal 42 and the negative side input terminal 44 and the voltage generated in the input voltage detection resistor. And an amplifier. Such an input-side voltmeter 54 outputs to the controller 60 a voltage having a voltage value proportional to the voltage (input voltage V _IN ) generated from the target solar cell panel 20.

The output-side voltmeter 56 measures the voltage value of the voltage (output voltage V _OUT ) output from the buck-boost circuit 50. In the present embodiment, the output side voltmeter 56 measures the voltage between the positive side output terminal 46 and the negative side output terminal 48. For example, the output side voltmeter 56 amplifies the output voltage detection resistor having a large resistance value provided between the positive output terminal 46 and the negative output terminal 48 and the voltage generated in the output voltage detection resistor. And an amplifier. The output-side voltmeter 56 outputs to the controller 60 a voltage having a voltage value proportional to the voltage output from the step-up / down circuit 50 (output voltage V _OUT ).

The step-up / down circuit 50 is applied with the input voltage V _IN of the DC power generated from the target solar cell panel 20. The step-up / down circuit 50 outputs an output voltage V _OUT of DC power obtained by converting the input voltage V _IN into power. The step-up / down circuit 50 is an H-bridge chopper type. The step-up / step-down circuit 50 can output the output voltage V _OUT by lowering the input voltage V _IN (V _IN > V _OUT ), or output the output voltage V _OUT by raising the input voltage V _IN (V _IN < V _OUT ) is possible. Further, the step-up / down circuit 50 can output the input voltage V _IN as it is as the output voltage V _OUT without converting the power (V _IN = V _OUT ).

  In this embodiment, the buck-boost circuit 50 includes an inductor 70, a first switch 72, a second switch 74, a third switch 76, a fourth switch 78, and a capacitor 80.

  The first switch 72 switches (turns on and off) between the positive side input terminal 42 and the first terminal 70-1 of the inductor 70 under the control of the controller 60. The second switch 74 switches (turns on and off) between the negative side input terminal 44 and the first terminal 70-1 of the inductor 70 under the control of the controller 60. The third switch 76 switches (turns on and off) between the second terminal 70-2 of the inductor 70 and the positive output terminal 46 under the control of the controller 60. The fourth switch 78 switches (turns on and off) between the second terminal 70-2 of the inductor 70 and the negative output terminal 48 under the control of the controller 60. The capacitor 80 is connected between the positive output terminal 46 and the negative output terminal 48.

The first switch 72 is, for example, an n-channel MOSFET (Metal Oxide Semiconductor Field Effect Transistor). In this case, the first switch 72 has a drain connected to the positive side input terminal 42, a source connected to the first terminal 70-1 of the inductor 70, and a gate supplied with the first switching signal S ₁ from the controller 60. ..

The second switch 74 is, for example, an n-channel MOSFET. In this case, the second switch 74 has a drain connected to the first terminal 70-1 of the inductor 70, a source connected to the negative side input terminal 44, and a gate supplied with the second switching signal S ₂ from the controller 60. ..

The third switch 76 is, for example, an n-channel MOSFET. In this case, in the third switch 76, the source is connected to the second terminal 70-2 of the inductor 70, the drain is connected to the positive output terminal 46, and the gate is supplied with the third switching signal S ₃ from the controller 60. ..

The fourth switch 78 is, for example, an n-channel MOSFET. In this case, the fourth switch 78 has a drain connected to the second terminal 70-2 of the inductor 70, a source connected to the negative output terminal 48, and a gate supplied with the fourth switching signal S ₄ from the controller 60. ..

  The controller 60 is a microcomputer or the like and controls the operation of the step-up / down circuit 50. The power supply 62 receives DC power from the target solar cell panel 20 via the positive side input terminal 42 and the negative side input terminal 44, stabilizes the voltage, and outputs it. The power supply 62 gives the stabilized DC voltage to the controller 60. Thereby, the controller 60 is driven by the DC power generated by the target solar cell panel 20.

  In the present embodiment, the controller 60 includes a CPU 82 (Central Processing Unit), a ROM 84 (Read Only Memory), a RAM 86 (Random Access Memory), an ADC 88 (Analog to Digital Converter), and an I / F circuit 90. Each unit is connected by a bus.

  The CPU 82 executes various kinds of processing in cooperation with various programs stored in the ROM 84 in advance using a predetermined area of the RAM 86 as a work area, and centrally controls the operation of each unit constituting the controller 60. Further, the CPU 82 operates the ADC 88, the I / F circuit 90, and the like in cooperation with a program stored in advance in the ROM 84.

  The ROM 84 stores a program used for controlling the controller 60, various setting information, and the like in a non-rewritable manner. The RAM 86 is a volatile storage medium such as a DRAM (Dynamic Random Access Memory). The RAM 86 functions as a work area for the CPU 82.

The ADC 88 converts the voltage output from the ammeter 52, the input voltmeter 54, and the output voltmeter 56 into a digital value. As a result, the CPU 82 can acquire the current value of the input current I _IN , the voltage value of the input voltage V _IN , and the voltage value of the output voltage V _OUT .

The I / F circuit 90 outputs the first switching signal S ₁ , the second switching signal S ₂ , the third switching signal S _3, and the fourth switching signal S ₄ under the control of the CPU 82. Accordingly, the step-up / down circuit 50 can operate under the control of the controller 60.

  FIG. 4 is a diagram showing a functional configuration of the controller 60 according to the first embodiment. The controller 60 functions by the configuration shown in FIG. 4 when the CPU 82 executes the program stored in the ROM 84.

  That is, the controller 60 includes a current value acquisition unit 102, a voltage value acquisition unit 104, a power calculation unit 106, a switch drive unit 108, a switching control unit 110, and a mode control unit 112.

The current value acquisition unit 102 acquires the current value of the input current I _IN output from the target solar cell panel 20 measured by the ammeter 52. The voltage value acquisition unit 104 acquires the voltage value of the input voltage V _IN generated from the target solar cell panel 20 measured by the input side voltmeter 54. Further, the voltage value acquisition unit 104 acquires the voltage value of the output voltage V _OUT output from the step-up / down circuit 50 measured by the output side voltmeter 56. The current value acquisition unit 102 and the voltage value acquisition unit 104 are realized by the ADC 88 and the CPU 82.

The power calculation unit 106 calculates the DC power generated by the target solar cell panel 20 based on the voltage value of the input voltage V _{IN and} the current value of the input current I _IN . The power calculation unit 106 is realized by the CPU 82.

The switch driver 108 outputs the first switching signal S ₁ , the second switching signal S ₂ , the third switching signal S _3, and the fourth switching signal S ₄ to output the first switch 72, the second switch 74, and the third switch 74. The switch 76 and the fourth switch 78 are driven. The switch driver 108 is realized by the I / F circuit 90 and the CPU 82.

  Further, the switch driving unit 108 turns on or off the first switch 72, the second switch 74, the third switch 76, and the fourth switch 78 according to the instruction from the mode control unit 112 designating the operation mode.

When the switch drive unit 108 receives an instruction to set the operation mode to the follow-up mode, the switch drive unit 108 operates the first switch 72, the second switch 74, the third switch 76, and the fourth switch 78 according to the control from the switching control unit 110. Switch. As a result, when the switch driving unit 108 receives an instruction to set the operation mode to the follow-up mode, it can cause the step-up / down circuit 50 to output the output voltage V _OUT that is the step-down or step-up of the input voltage V _IN .

When the switch driving unit 108 receives the instruction to set the operation mode to the stop mode, the switch driving unit 108 turns off the first switch 72, the second switch 74, the third switch 76, and the fourth switch 78. As a result, when the switch driving unit 108 receives the instruction to enter the stop mode, the switch driving unit 108 opens the positive side output terminal 46 and the negative side output terminal 48, and outputs the output voltage V _OUT from the step-up / down circuit 50. The output can be stopped.

When the switch drive unit 108 receives an instruction to set the operation mode to the pass-through mode, it turns on the first switch 72 and the third switch 76, and turns off the second switch 74 and the fourth switch 78. As a result, when the switch drive unit 108 receives the instruction to set the pass-through mode, the switch drive unit 108 connects the positive side input terminal 42 and the positive side output terminal 46 in a direct current manner, and the negative side input terminal 44 and the negative side. It is possible to connect the output terminal 48 in a direct current manner and output the input voltage V _IN as it is as the output voltage V _OUT to the step-up / down circuit 50 without converting the power into the step-up / down circuit 50.

  The switching control unit 110 executes maximum power point tracking processing for controlling the power conversion of the step-up / down circuit 50 so as to maximize the DC power generated by the target solar cell panel 20. The switching control unit 110 is realized by the CPU 82.

In the maximum power point tracking process, the switching control unit 110 acquires a target conversion ratio representing a target of the ratio of the voltage value of the output voltage V _{OUT to} the voltage value of the input voltage V _IN . Then, the switching control unit 110 sets the first switch 72, the second switch 74, the third switch 76, and the third switch 76 so that the ratio of the voltage value of the input voltage V _{IN and} the voltage value of the output voltage V _OUT becomes the target conversion ratio. The fourth switch 78 is switching-controlled.

  In the maximum power point tracking process, the switching control unit 110 switches between step-down operation and step-up operation of the step-up / down circuit 50 according to the target conversion ratio. For example, assume that the target conversion ratio is expressed as a percentage. In this case, the switching control unit 110 causes the step-up / down circuit 50 to perform the step-down operation if the target conversion ratio is smaller than 100%, and causes the step-up / step-down circuit 50 to perform the step-up operation if the target conversion ratio is larger than 100%.

  For example, the switching control unit 110 executes the hill climbing method as the maximum power point tracking process. Further, for example, the switching control unit 110 may use a scanning method as the maximum power point tracking process.

The mode control unit 112 controls the operation mode of the power conversion device 30 based on the input voltage V _IN and the input current I _IN . The mode control unit 112 is realized by the CPU 82.

More specifically, the mode control unit 112 sets the tracking mode when the input current I _IN output from the target solar cell panel 20 is larger than the preset current threshold I _T. In the tracking mode, the mode control unit 112 causes the switching control unit 110 to execute the maximum power point tracking process.

Further, the mode control unit 112 sets the pass-through mode when the input current I _IN is less than or equal to the current threshold I _T. In the pass-through mode, the mode control unit 112 stops the maximum power point tracking process by the switching control unit 110. Then, in the pass-through mode, the mode control unit 112 gives an instruction to the switch driving unit 108 to cause the step-up / step-down circuit 50 not to perform power conversion, and the input voltage V _IN to the step-up / step-down circuit 50 as the output voltage V _OUT as it is. Output.

When the input voltage V _IN is equal to or lower than the preset voltage threshold V _T , the mode control unit 112 sets the stop mode regardless of the input current I _IN . In the stop mode, the mode control unit 112 stops the maximum power point tracking process by the switching control unit 110. Then, in the stop mode, the mode control unit 112 gives an instruction to the switch driving unit 108 to stop the output of the output voltage V _OUT from the step-up / down circuit 50.

  FIG. 5 is a diagram showing states of switches included in the step-up / down circuit 50 in the stop mode. When the switch drive unit 108 receives an instruction to set the stop mode from the mode control unit 112, the first switch 72 is turned off, the second switch 74 is turned off, the third switch 76 is turned off, and the fourth switch 78 is turned on. Turn off.

As a result, the switch driving unit 108 can open the space between the positive output terminal 46 and the negative output terminal 48 in the stop mode. In addition, the switch driving unit 108 can open the space between the target solar cell panel 20 and the inductor 70 in the stop mode. Accordingly, the switch driver 108 can stop the power conversion by the step-up / step-down circuit 50 and prevent the step-up / step-down circuit 50 from outputting the output voltage V _OUT .

  FIG. 6 is a diagram showing states of switches included in the step-up / down circuit 50 in the pass-through mode. When the switch drive unit 108 receives an instruction to set the pass-through mode from the mode control unit 112, the first switch 72 is turned on, the second switch 74 is turned off, the third switch 76 is turned on, and the fourth switch 78 is turned on. Turn off.

The inductor 70 has a resistance equal to 0 in terms of direct current. Therefore, in the pass-through mode, the switch driver 108 can connect between the positive side input terminal 42 and the positive side output terminal 46 and can connect between the negative side input terminal 44 and the negative side output terminal 48. .. Accordingly, in the pass-through mode, the switch driver 108 can cause the step-up / down circuit 50 to output the input voltage V _IN as it is as the output voltage V _OUT without causing the step-up / down circuit 50 to convert the power.

  FIG. 7 is a diagram showing the states of the switches included in the step-up / down circuit 50 during step-down in the follow-up mode.

  In the follow-up mode, the switching control unit 110 operates at the time of step-down (when the target conversion ratio expressed as a percentage is smaller than 100%) and at the time of step-up (when the target conversion ratio expressed as a percentage is larger than 100%). , The switching method of the step-up / down circuit 50 is changed.

  When the tracking mode is stepped down, the switching control unit 110 performs switching as shown in FIG. 7. That is, the switching controller 110 fixes the third switch 76 on and the fourth switch 78 off. Furthermore, the switching control unit 110 complementarily switches the first switch 72 and the second switch 74 in a predetermined switching cycle. Complementary switching of the first switch 72 and the second switch 74 means that when the first switch 72 is on, the second switch 74 is off, and when the first switch 72 is off, the second switch 74 is on. It is to switch so that.

FIG. 8 is a diagram showing the first switching signal S ₁ when the follow-up mode is stepped down. When the follow-up mode is stepped down (when the target conversion ratio is smaller than 100%), the switching control unit 110 lengthens the ON period of the first switch 72 as the target conversion ratio increases.

For example, when the target conversion ratio is smaller than 100%, the switching control unit 110 sets the first switch 72 and the second switch 74 so that the ON period of the first switch 72 with respect to the switching cycle becomes a ratio according to the target conversion ratio. Are complementarily switched. More specifically, it is assumed that the predetermined switching cycle is T and the target conversion ratio expressed as a percentage is R. In this case, the switching control unit 110 sets the ON period (T _1ON ) of the first switch 72 and the OFF period (T _1OFF ) of the first switch 72 to the following values.
T _1ON = T × R / 100
T _1OFF = T-T _1ON

As a result, the switching control unit 110 can cause the step-up / down circuit 50 to output the output voltage V _OUT having a voltage value obtained by multiplying the voltage value of the input voltage V _IN by the target conversion ratio during the step-down.

  FIG. 9 is a diagram showing a state of switches included in the step-up / down circuit 50 at the time of boosting. At the time of boosting in the follow-up mode, the switching control unit 110 performs switching as shown in FIG.

  That is, the switching control unit 110 fixes the first switch 72 by turning it on and the second switch 74 by turning it off. Further, the switching control unit 110 complementarily switches the third switch 76 and the fourth switch 78 in a predetermined switching cycle. Complementary switching of the third switch 76 and the fourth switch 78 means that when the third switch 76 is on, the fourth switch 78 is off, and when the third switch 76 is off, the fourth switch 78 is on. It is to switch so that.

FIG. 10 is a diagram showing the third switching signal S ₃ during boosting. During boosting in the follow-up mode (when the target conversion ratio is greater than 100%), the switching control unit 110 lengthens the ON period of the third switch 76 as the target conversion ratio increases.

For example, when the target conversion ratio is greater than 100%, the switching control unit 110 may respond to a value obtained by dividing the ON period of the third switch 76 with respect to the switching cycle by a value obtained by subtracting 100% from the target conversion ratio by the target conversion ratio. The third switch 76 and the fourth switch 78 are complementarily switched so that the ratio becomes different. More specifically, for example, it is assumed that the predetermined switching period is T and the target conversion ratio expressed as a percentage is R. In this case, the switching control unit 110 sets the ON period (T _3ON ) of the third switch 76 and the OFF period (T _3OFF ) of the third switch 76 to the following values.
T _3ON = T × (R-100) / R
T _3OFF = T-T _3ON

As a result, the switching control unit 110 can cause the step-up / down circuit 50 to output the output voltage V _OUT having a voltage value obtained by multiplying the voltage value of the input voltage V _IN by the target conversion ratio during boosting.

FIG. 11 is a diagram for explaining changes in the input voltage V _IN in the hill climbing method. The hill climbing method is one of the methods of executing the maximum power point tracking control in a state where power conversion by the step-up / down circuit 50 is continued (without stopping power conversion).

When executing the hill climbing method, the switching control unit 110 increases or decreases the target conversion ratio by a minute amount while continuing the power conversion by the step-up / down circuit 50. Then, the switching control unit 110 observes the change in the electric power generated by the solar cell panel 20, and changes the target conversion ratio in the direction in which the electric power generated by the solar cell panel 20 increases. As a result, the switching control unit 110 can increase or decrease the target conversion ratio so that the voltage value of the input voltage V _IN reciprocates across the peak point of the power. As a result, the switching control unit 110 can operate the target solar cell panel 20 at the maximum power point.

  FIG. 12 is a flowchart showing the processing contents of the mountain climbing method. For example, when the hill climbing method is executed, the switching control unit 110 executes the processing shown in FIG.

  The switching control unit 110 repeats the processing from S212 to S219 at predetermined time intervals (loop processing between S211 and S220). In S212, the switching control unit 110 acquires the power value of the DC power generated by the target solar cell panel 20.

  Subsequently, in S213, the switching control unit 110 determines whether or not the target conversion ratio has been increased in the immediately preceding loop processing. If the number has been increased (Yes in S213), the switching control unit 110 advances the processing to S214. When not increasing, that is, when reducing the target conversion ratio (No of S213), the switching control part 110 advances a process to S215.

  In S214, the switching control unit 110 compares the power value of the DC power calculated in the immediately preceding loop process with the power value of the DC power calculated in the current loop process. If the power has increased (Yes in S214), the switching control unit 110 advances the process to S216, and if the power has not increased (No in S214), the process advances to S217.

  In S216, the switching control unit 110 increases the target conversion ratio by a predetermined amount. In S217, the switching control unit 110 reduces the target conversion ratio by a predetermined amount.

  In S215, the switching control unit 110 compares the power value of the DC power calculated in the immediately preceding loop processing with the power value of the DC power calculated in the current loop processing. When the power has increased (Yes in S215), the switching control unit 110 advances the process to S218, and when the power has not increased (No in S215), advances the process to S219.

  Then, in S218, the switching control unit 110 reduces the target conversion ratio by a predetermined amount. In S219, the switching control unit 110 increases the target conversion ratio by a predetermined amount.

  After finishing the processing of S216, S217, S218 or S219, the switching control unit 110 repeats the processing from S212 after a predetermined time (loop processing between S211 and S220).

  As described above, when the DC power increases due to the increase of the target conversion ratio, the switching control unit 110 further increases the target conversion ratio and decreases the DC power by increasing the target conversion ratio. If so, the target conversion ratio is reduced. Further, the switching control unit 110 further reduces the target conversion ratio when the direct-current power increases due to the decrease of the target conversion ratio, and when the direct-current power decreases due to the decrease of the target conversion ratio. Increases the target conversion ratio.

  Then, the switching control unit 110 repeats such processing every predetermined time. Accordingly, the switching control unit 110 can operate the solar cell panel 20 at the maximum power point.

  FIG. 13: is a figure which shows the operation mode of the power converter device 30 which concerns on 1st Embodiment. The power conversion device 30 according to the first embodiment operates in three operation modes: a stop mode, a follow-up mode, and a pass-through mode.

A current threshold I _T and a voltage threshold V _T are preset in the mode control unit 112. The mode control unit 112 compares the input current I _IN and the input voltage V _IN output from the solar cell panel 20 with the current threshold I _T and the voltage threshold V _T to switch the operation mode.

  FIG. 14 is a state transition diagram showing transition of operation modes in the first embodiment. The mode control unit 112 sets the state to the stop mode when power generation is started by the target solar cell panel 20.

In the stop mode, the mode control unit 112 compares the input voltage V _IN with the voltage threshold V _T. In the stop mode, when the input voltage V _IN is the voltage threshold V _T or less, the mode control unit 112 maintains the state in the stop mode.

In the stop mode, when the input voltage V _IN is higher than the voltage threshold V _T and the input current I _IN is equal to or lower than the current threshold I _T , the mode control unit 112 shifts the state to the pass-through mode. In addition, in the stop mode, when the input voltage V _IN is larger than the voltage threshold V _T and the input current I _IN is larger than the current threshold I _T , the mode control unit 112 shifts the state to the follow-up mode.

In the pass-through mode, when the input voltage V _IN becomes equal to or lower than the voltage threshold V _T , the mode control unit 112 shifts the state to the stop mode. In the pass-through mode, when the input voltage V _IN is larger than the voltage threshold V _T and the input current I _IN is larger than the current threshold I _T , the mode control unit 112 shifts the state to the follow-up mode.

In the tracking mode, when the input voltage V _IN becomes equal to or lower than the voltage threshold V _T , the mode control unit 112 shifts the state to the stop mode. Further, in the follow-up mode, when the input voltage V _IN is higher than the voltage threshold V _T and the input current I _IN is equal to or lower than the current threshold I _T , the mode control unit 112 shifts the state to the pass-through mode.

The amount of electric power that can be generated by the solar cell panel 20 greatly varies depending on the time of day, weather, and the like. Therefore, for example, when the amount of power that can be generated by the solar cell panel 20 is small in the morning, in the evening, in cloudy weather, or the like, the switch driving unit 108 consumes more power than the power increased by the maximum power point tracking process. Increased power. When the input current I _IN is equal to or less than the preset current threshold I _T , the power conversion device 30 according to the present embodiment sets the step-up / down circuit 50 in the pass-through mode to stop the switching of the step-up / down circuit 50. Thus, according to the power conversion device 30 of the present embodiment, when the input current I _IN is equal to or less than the preset current threshold I _T , the power consumed by the switching drive by the switch drive unit 108 is eliminated, and The electric power generated by the battery panel 20 can be efficiently output.

(Second embodiment)
FIG. 15 is a diagram showing a functional configuration of the controller 60 according to the second embodiment. The controller 60 according to the second embodiment further includes an efficiency determination unit 120.

  The efficiency determination unit 120 determines whether the solar cell panel 20 is in a normal efficiency state in which a predetermined power generation efficiency is exhibited or the solar cell panel 20 is in a low efficiency state in which the power generation efficiency is lower than the normal efficiency state. To do.

  The solar cell panel 20 includes a plurality of clusters. The solar cell panel 20 generates power at 100% efficiency when all of the plurality of clusters receive sunlight and generate power normally. However, when a part of the plurality of clusters has a shadow or the like, the solar cell panel 20 does not contribute to power generation by the cluster having the shadow or the like and generates power with an efficiency lower than 100%. For example, when the solar cell panel 20 generates power with 100% efficiency, the efficiency determination unit 120 determines that it is in the normal efficiency state. Moreover, for example, when the solar cell panel 20 generates power with an efficiency of less than 100%, the efficiency determination unit 120 determines that the efficiency is low.

For example, the efficiency determination unit 120 acquires the voltage value of the input voltage V _IN output from the target solar cell panel 20. Then, the efficiency determination unit 120 determines whether the normal efficiency state or the low efficiency state is based on the voltage value of the input voltage V _IN .

When the voltage value of the input voltage V _IN is higher than a predetermined voltage value, the efficiency determination unit 120 determines that the normal efficiency state is set, and when the voltage value of the input voltage V _IN is equal to or lower than the predetermined voltage value. Alternatively, it may be determined that the state is low efficiency.

  The mode control unit 112 according to the second embodiment acquires from the efficiency determination unit 120 a determination result indicating whether the efficiency state is the normal efficiency state or the low efficiency state.

In the following mode (when the input voltage V _IN is larger than the voltage threshold V _T and the input current I _IN is equal to or more than the current threshold I _T ), the mode control unit 112 follows the state when it is determined to be the normal efficiency state. When set to pass-through mode. In the following pass-through mode, the mode control unit 112 stops the maximum power point tracking process by the switching control unit 110. Then, in the following pass-through mode, the mode control unit 112 gives an instruction to the switch driving unit 108 to cause the buck-boost circuit 50 to convert the input voltage V _IN without changing the power, and to output the output voltage V _{IN as it} is. Output as _OUT .

  In addition, in the following pass-through mode, when it is determined that the efficiency is low, the mode control unit 112 sets the following mode. In the tracking mode, the mode control unit 112 causes the switching control unit 110 to execute the maximum power point tracking process.

  FIG. 16 is a state transition diagram showing transition of operation modes in the second embodiment. The power conversion device 30 according to the second embodiment operates in four operation modes: a stop mode, a follow-up mode, a pass-through mode, and a follow-through pass-through mode.

  When it is determined that the normal efficiency state is set in the follow-up mode, the mode control unit 112 shifts the state to the follow-through pass-through mode. Further, in the following pass-through mode, when the low efficiency state is determined, the mode control unit 112 changes the state to the following mode.

That is, when the input voltage V _IN is larger than the voltage threshold V _T and the input current I _IN is larger than the current threshold I _T , the target solar cell panel 20 is in the normal efficiency state (for example, all of the plurality of clusters are solar cells). In the case where the light is received and the power is normally generated), the mode control unit 112 sets the following pass-through mode. Further, when the input voltage V _IN is larger than the voltage threshold V _T and the input current I _IN is larger than the current threshold I _T , the target solar cell panel 20 is in a low efficiency state (for example, shadows on some clusters, etc.). In this case, the mode control unit 112 sets the tracking mode.

In the following pass-through mode, the mode control unit 112 executes the same control as in the pass-through mode. That is, the mode control unit 112 gives the switch drive unit 108 an instruction to set the pass-through mode. When the switch drive unit 108 receives an instruction to set the pass-through mode from the mode control unit 112, the first switch 72 is turned on, the second switch 74 is turned off, the third switch 76 is turned on, and the fourth switch 78 is turned on. Turn off. Accordingly, the step-up / down circuit 50 can output the input voltage V _IN as it is as the output voltage V _OUT without power conversion.

  In the present embodiment, the power conditioner 24 executes maximum power point tracking control for the entire plurality of solar cell panels 20. On the other hand, the power conversion device 30 executes the maximum power point tracking control for one target solar cell panel 20. When the solar cell panel 20 is operating in a normal efficiency state without a shadow or the like, the maximum power point tracking control by the power conditioner 24 allows the solar cell panel 20 to operate at the maximum even if the control by the power conversion device 30 is not executed. It can operate at the power point. However, the solar cell panel 20 cannot operate at the maximum power point unless it is controlled by the power conversion device 30 when a shadow or the like is present. Moreover, the other solar cell panels 20 included in the string cannot operate at the maximum power point.

When the target solar cell panel 20 is operating in the normal efficiency state, the power conversion device 30 according to the present embodiment outputs the input voltage V _{IN as it} is as the output voltage V _OUT without power conversion. Therefore, when the target solar cell panel 20 is operating in the normal efficiency state, the power conversion device 30 operates the target solar cell panel 20 at the maximum power point without consuming unnecessary power. It can be in a state of being.

  Further, the power conversion device 30 can execute the maximum power point tracking control when the target solar cell panel 20 is operating in the low efficiency state. Therefore, the power conversion device 30 can operate the target solar cell panel 20 at the maximum power point even when the target solar cell panel 20 is operating in the low efficiency state. As described above, the power conversion device 30 according to the present embodiment can efficiently operate the solar cell panel 20 with low power consumption.

FIG. 17 is a state transition diagram showing transition of operation modes in the modification of the second embodiment. As shown in FIG. 17, the power conversion device 30 according to the present embodiment may have a configuration in which the input current I _IN is not more than the current threshold I _T and does not transition to the pass-through mode.

Even with such a configuration, when the target solar cell panel 20 is operating in the normal efficiency state, the power conversion device 30 does not convert the power and directly changes the input voltage V _IN to the output voltage V _OUT. Can be output as Further, even with such a configuration, the power conversion device 30 can execute the maximum power point tracking control when the target solar cell panel 20 is operating in the low efficiency state. Therefore, even with such a configuration, the power conversion device 30 can efficiently operate the solar cell panel 20 with low power consumption.

(Third Embodiment)
FIG. 18 is a diagram for explaining changes in the input voltage V _IN during scanning in the third embodiment. The power conversion device 30 according to the third embodiment executes the scan method as the maximum power point tracking process.

When executing the scan method, the switching control unit 110 temporarily stops the power conversion by the step-up / step-down circuit 50 and opens the output end of the step-up / step-down circuit 50. Subsequently, the switching control unit 110, the voltage value of the input voltage V _IN to be outputted from the solar cell panel 20 is changed in a predetermined range, to identify the voltage value of the most power to power increases the input voltage V _IN.

Here, in the present embodiment, the switching control unit 110 changes the input voltage V _IN within a range equal to or higher than a predetermined lower limit voltage value. The lower limit voltage value is a voltage at which the power supply 62 can operate the controller 60 including the switch driving unit 108.

Subsequently, the switching control unit 110 calculates a control amount for power conversion such that the input voltage V _IN output from the solar cell panel 20 has the specified voltage value. In the present embodiment, the switching control unit 110 calculates the target conversion ratio such that the input voltage V _IN output from the solar cell panel 20 has the specified voltage value. The control amount is not limited to the target conversion ratio and may be another amount. For example, the control amount may be a switching duty ratio between the first switch 72 and the second switch 74 or a switching duty ratio between the third switch 76 and the fourth switch 78.

Then, the switching control unit 110 restarts the power conversion with the specified control amount. In the present embodiment, the switching control unit 110 switches the step-up / down circuit 50 at a target conversion ratio such that the input voltage V _IN generated by the solar cell panel 20 has a specified voltage value. By executing such processing, the switching control unit 110 can operate the solar cell panel 20 at the maximum power point thereafter, if there is no change in the situation.

FIG. 19 is a diagram showing a state of switches included in the step-up / down circuit 50 when the voltage value of the input voltage V _IN output from the solar cell panel 20 is changed within a predetermined range.

When changing the voltage value of the input voltage V _IN output from the solar cell panel 20, the switching control unit 110 performs switching as shown in FIG. 19. That is, the switching control unit 110 brings the output voltage V _OUT from the step-up / down circuit 50 into a stopped state. More specifically, the switching control section 110 turns off the third switch 76 and turns off the fourth switch 78 to open the positive side output terminal 46 and the negative side output terminal 48.

Then, the switching control unit 110 changes the voltage value of the input voltage V _IN by repeating ON and OFF while changing the duty factor between the positive side input terminal 42 and the negative side input terminal 44 of the step-up / down circuit 50. Let

For example, when setting the target voltage value of the input voltage V _IN output from the solar cell panel 20, the switching control unit 110 fixes the second switch 74 to ON and sets the first switch 72 to the target voltage value. Switching is performed with a duty factor according to the voltage value (ON / OFF is repeated at a predetermined cycle). When reducing the voltage value of the input voltage V _IN , the switching control unit 110 increases the duty factor, that is, lengthens the ON period of the first switch 72. Further, the switching control unit 110 reduces the duty factor when the voltage value of the input voltage V _IN is large, that is, shortens the ON period of the first switch 72.

The switching control unit 110 changes the input voltage V _IN output from the solar cell panel 20 within the range of the lower limit voltage value or more. Therefore, the switching control unit 110 changes the dee-di factor in a range of a predetermined value or more.

  Further, in the present embodiment, the switching control unit 110 switches the first switch 72 in a state where the second switch 74 is fixed to be on. Instead of this, the switching control unit 110 may switch the second switch 74 with the first switch 72 fixed to ON.

  FIG. 20 is a flowchart showing the flow of processing of the switching control unit 110 according to the third embodiment.

  The switching control unit 110 periodically executes the process of the flow illustrated in FIG. 20 in the follow-up mode. For example, the switching control unit 110 executes the processing of the flow shown in FIG. 20 every predetermined time or at the timing when a predetermined event occurs.

First, in S241, the switching control unit 110 acquires the voltage value of the output voltage V _OUT output from the step-up / down circuit 50.

Subsequently, in S242, the switching control unit 110 stops the power conversion of the step-up / step-down circuit 50 and opens the output end of the step-up / step-down circuit 50. Specifically, the switching control unit 110 turns off the first switch 72, turns on the second switch 74, turns off the third switch 76, and turns off the fourth switch 78. Accordingly, the switching control unit 110 can set the voltage value of the input voltage V _IN to the maximum value and open the space between the positive side output terminal 46 and the negative side output terminal 48.

  Subsequently, in S243, the switching control unit 110 sets the duty factor to 0%. Subsequently, in S244, the switching control unit 110 starts switching of the first switch 72 with the second switch 74 fixed in the ON state. The switching control unit 110 switches the first switch 72 with the set dee-di factor. Immediately after the start of this flow, the duty factor is set to 0%, so the first switch 72 is in the off state.

Subsequently, in S245, the switching control unit 110 acquires the voltage value of the input voltage V _IN . Subsequently, in S246, the switching control unit 110 acquires a power value. Subsequently, in S247, the switching control unit 110 stores the voltage value of the input voltage V _IN and the power value in association with each other.

Subsequently, in S248, the switching control unit 110 determines whether or not the input voltage V _IN has become equal to or lower than a preset lower limit voltage value. When the input voltage V _IN is not equal to or lower than the lower limit voltage value (No in S248), the switching control unit 110 advances the processing to S249. In S249, the switching control unit 110 increases the duty factor by a predetermined amount, returns the processing to S245, and repeats the processing from S245.

When the input voltage V _IN becomes equal to or lower than the lower limit voltage value (Yes in S248), the switching control unit 110 advances the process to S250. In S250, the switching control unit 110 acquires the voltage value of the input voltage V _IN . Subsequently, in S251, the switching control unit 110 acquires a power value. Subsequently, in S252, the switching control unit 110 stores the voltage value of the input voltage V _IN and the power value in association with each other.

  Subsequently, in S253, the switching control unit 110 determines whether the duty factor becomes 0%. When the duty factor is not 0% (No in S253), the switching control unit 110 advances the processing to S254. In S254, the switching control unit 110 reduces the duty factor by a predetermined amount, returns the processing to S250, and repeats the processing from S250.

  When the duty factor becomes 0% (Yes in S253), the switching control unit 110 advances the processing to S255. In S255, the switching control unit 110 stops the switching of the first switch 72 when the duty factor is 0%. That is, the switching control unit 110 turns off the first switch 72.

Subsequently, in S256, the switching control unit 110 identifies the maximum power value from the stored power values. Subsequently, in S257, the switching control unit 110 specifies the voltage value of the input voltage V _IN stored corresponding to the specified maximum power value as the target voltage value.

Subsequently, in S258, the switching control unit 110 calculates a target conversion ratio that maximizes the DC power generated by the target solar cell panel 20, based on the target voltage value. For example, the switching control unit 110 calculates the ratio of the voltage value of the output voltage V _OUT acquired in S241 to the specified target voltage value, and sets the calculated ratio as the target conversion ratio.

  Then, in S259, the switching control unit 110 causes the step-up / down circuit 50 to start power conversion at the calculated target conversion ratio.

FIG. 21 is a diagram showing changes in the input voltage V _IN and the input current I _IN when the process is performed according to the procedure of FIG.

When the switching control unit 110 executes the processing in the procedure shown in FIG. 20, the input voltage V _IN and the input current I _IN change as shown in FIG. That is, at the first stage when the duty factor is 0%, the input voltage V _IN becomes the maximum value and the input current I _IN becomes 0. As the duty factor gradually increases from 0%, the input voltage V _IN gradually decreases and the input current I _IN gradually increases. Then, the input voltage V _IN stops decreasing when reaching the lower limit voltage value.

After that, as the duty factor gradually decreases, the input voltage V _IN gradually increases and the input current I _IN gradually decreases. Then, when the input current I _IN becomes 0, the process ends.

It should be noted that the switching control unit 110 gradually reduces the duty factor to 0% after the input voltage V _IN reaches the lower limit voltage value, instead of immediately reducing the duty factor to 0%. Accordingly, the switching control unit 110 can protect the circuit without generating a counter electromotive force due to the inductance component of the wiring impedance.

  In the present embodiment, the power conversion device 30 is driven by the power generated by the target solar cell panel 20. As a result, the power conversion device 30 can operate without receiving power from the outside.

However, when the maximum power point tracking process by the scanning method is executed, if the voltage value of the input voltage V _IN generated from the target solar cell panel 20 is set to the minimum value (for example, 0), the power conversion device 30 However, the power cannot be received from the solar cell panel 20, and the operation stops. The power conversion device 30 according to the present embodiment does not make the input voltage V _IN output from the solar cell panel 20 smaller than the preset lower limit voltage value when executing the maximum power point tracking process by the scanning method. As a result, according to the power conversion device 30 according to the present embodiment, when the maximum power point tracking process by the scanning method is executed, the maximum power point can be reliably specified without stopping the operation.

(Fourth Embodiment)
FIG. 22 is a diagram showing a functional configuration of the controller 60 according to the fourth embodiment. The controller 60 according to the fourth embodiment further includes an efficiency change event detection unit 130.

  Note that the configuration of FIG. 22 is a configuration in which the efficiency change event detection unit 130 is added to the functional configuration of the controller 60 according to the first embodiment shown in FIG. However, the efficiency change event detection unit 130 may be added to the functional configuration of the controller 60 according to the second embodiment shown in FIG.

  The efficiency change event detection unit 130 detects whether or not an efficiency change event has occurred in which the power generation efficiency of the target solar cell panel 20 changes by a predetermined value or more.

  For example, the solar cell panel 20 including three clusters generates power with 100% efficiency when all three clusters receive sunlight and generate power normally. However, such a solar cell panel 20 generates power at an efficiency of, for example, 66% when a shadow or the like is cast on one of the three clusters. Further, such a solar cell panel 20 generates power at an efficiency of 33%, for example, when a shadow or the like is cast on two of the three clusters.

  In such a case, for example, the efficiency change event detection unit 130 determines that the target solar cell panel 20 has changed from a state of generating power with 100% efficiency to a state of generating power with 66% efficiency, with efficiency of 66%. A change in the state of generating electricity to the state of generating electricity with an efficiency of 33% is detected. Furthermore, the efficiency change event detection unit 130 determines that the target solar cell panel 20 has changed from a state of generating power at 33% efficiency to a state of generating power at 66% efficiency, and a state of generating power at 66% efficiency of 100%. It may also be possible to detect a change in a state in which power is generated at a efficiency of%.

For example, the efficiency change event detection unit 130 may determine whether the power generation efficiency has changed by a predetermined value or more based on the voltage value of the input voltage V _IN . The efficiency change event detection unit 130 may determine that the power generation efficiency has changed by a predetermined value or more when the voltage value of the input voltage V _IN changes by a predetermined voltage value or more.

  The switching control unit 110 can execute two types of control as a maximum power point tracking process, that is, control by a scan method and control by a hill climbing method. The switching control unit 110 switches between control by the scan method and control by the hill climbing method according to an efficiency change event.

  FIG. 23 is a state transition diagram showing state transitions of the switching control unit 110 according to the fourth embodiment. The switching control unit 110 switches the control by the scan method and the control by the hill climbing method at the timings shown in FIG.

  First, the switching control unit 110 executes the maximum power point tracking process by the hill climbing method in a state where the efficiency change event has not occurred. Subsequently, when an efficiency change event occurs during execution of the maximum power point tracking processing by the hill climbing method, the switching control unit 110 terminates the maximum power point tracking processing by the hill climbing method, and the maximum power point tracking by the scan method. Execute the process.

When the control by the scanning method is executed, the switching control unit 110 specifies the voltage value of the input voltage V _IN that maximizes the DC power generated by the target solar cell panel 20. Furthermore, the switching control part 110 also specifies the control amount of the power conversion for maximizing the DC power generated by the target solar cell panel 20.

  In the present embodiment, the switching control unit 110 specifies, as the control amount, the target conversion ratio that maximizes the DC power generated by the target solar cell panel 20. The control amount is not limited to the target conversion ratio and may be another amount. For example, the control amount may be a switching duty ratio between the first switch 72 and the second switch 74 or a switching duty ratio between the third switch 76 and the fourth switch 78.

  Then, after performing the maximum power point tracking process by the scanning method, the switching control unit 110 takes over the control amount of the power conversion that maximizes the DC power and starts the maximum power point tracking process by the hill climbing method. In the present embodiment, the switching control unit 110 executes the maximum power point tracking process by the scan method, then takes over the target conversion ratio, and starts the maximum power point tracking process by the hill climbing method.

  FIG. 24 is a diagram showing a change example of the characteristic curve representing the generated power with respect to the generated voltage when the efficiency change event occurs. When the solar cell panel 20 is operating in the normal efficiency state (for example, the state where the power generation efficiency is 100%), the characteristic showing the generated power with respect to the generated voltage has a single peak point curve. However, in the solar cell panel 20, for example, when the power generation efficiency is lowered due to a partial shadow or the like, the characteristic representing the generated power with respect to the generated voltage may be a curve having a plurality of peak points.

  Therefore, when the efficiency change event occurs, if the hill climbing method is continued, the power conversion device 30 increases or decreases the target conversion ratio so as to reciprocate before and after the peak point other than the maximum power point. The possibility arises.

  However, the power conversion device 30 according to the present embodiment detects the maximum power point by using the maximum power point tracking process by the scanning method when the efficiency change event occurs. Accordingly, the power conversion device 30 can detect the maximum power point even if the characteristic indicating the generated power with respect to the generated voltage is a curve having a plurality of peak points. Then, after that, the power conversion device 30 takes over the control amount (for example, the target conversion ratio) of the maximum power point tracking processing by the scanning method, and executes the maximum power point tracking processing by the hill climbing method. Therefore, the power conversion device 30 can eliminate increasing or decreasing the control amount (for example, the target conversion ratio) so that the power conversion device 30 reciprocates before and after the peak point that is not the maximum power point. As a result, the power conversion device 30 can operate the solar cell panel 20 at the maximum power point even when the power generation efficiency is reduced.

  Although the embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. The embodiment can make various modifications.

10 power generation system 20 solar cell panel 22 connection device 24 power conditioner 30 power converter 42 positive side input terminal 44 negative side input terminal 46 positive side output terminal 48 negative side output terminal 50 buck-boost circuit 52 ammeter 54 input side voltmeter 56 Output-side voltmeter 60 Controller 62 Power supply 70 Inductor 72 First switch 74 Second switch 76 Third switch 78 Fourth switch 80 Capacitor 82 CPU
84 ROM
86 RAM
88 ADC
90 I / F circuit 102 Current value acquisition unit 104 Voltage value acquisition unit 106 Electric power calculation unit 108 Switch drive unit 110 Switching control unit 112 Mode control unit 120 Efficiency determination unit 130 Efficiency change event detection unit

Claims (12)

A chopper to which an input voltage generated from a power generation module that generates DC power is applied, which outputs an output voltage obtained by converting the input voltage into power, and which can also output the input voltage as the output voltage without performing power conversion Mold buck-boost circuit,
A switching control unit that executes a maximum power point tracking process that controls power conversion of the step-up / down circuit so as to maximize the DC power generated by the power generation module;
An efficiency change event detection unit that detects whether or not an efficiency change event in which the power generation efficiency of the power generation module changes by a predetermined value or more has occurred,
Equipped with
The switching control unit,
When the efficiency change event occurs, the maximum power point tracking process by the scanning method is executed,
After executing the maximum power point tracking process by the scan method, the maximum power point tracking process by the hill climbing method is started by taking over the control amount of the power conversion that maximizes the DC power. The switching control unit controls power conversion of the buck-boost circuit according to a target conversion ratio representing a target of a ratio of a voltage value of the output voltage to a voltage value of the input voltage,
The switching control unit, as the maximum power point tracking process by the hill climbing method,
When the DC power is increased by increasing the target conversion ratio, further increase the target conversion ratio,
When the DC power is decreased by increasing the target conversion ratio, decrease the target conversion ratio,
When the DC power is increased by decreasing the target conversion ratio, further decrease the target conversion ratio,
The power conversion device according to claim 1, wherein when the DC power decreases due to the reduction of the target conversion ratio, a process of increasing the target conversion ratio is executed. Further comprising a positive side input terminal and a negative side input terminal to which the input voltage generated from the power generation module is applied,
The switching control unit, as the maximum power point tracking process by the scanning method,
In a state where the output of the output voltage from the step-up / down circuit is stopped, the voltage value of the input voltage is changed by switching between the positive side input terminal and the negative side input terminal while changing the duty factor. Change within a predetermined range,
Among the voltage values in the predetermined range, the voltage value of the input voltage at which the DC power generated by the power generation module is maximum is specified,
The power conversion device according to claim 2, further comprising: a process of causing the step-up / down circuit to perform power conversion at the target conversion ratio that causes the input voltage to be the specified voltage value. The power conversion device according to claim 3, wherein the switching control unit takes over the target conversion ratio after executing the maximum power point tracking process by the scan method and starts the maximum power point tracking process by the hill climbing method. . Further comprising a positive output terminal and a negative output terminal for outputting the output voltage,
The step-up / down circuit is
An inductor,
A first switch for turning on and off between the positive side input terminal and the first terminal of the inductor;
A second switch for turning on and off between the negative side input terminal and the first terminal of the inductor;
A third switch that turns on and off between a second terminal of the inductor and the positive output terminal;
A fourth switch for turning on and off between the second terminal of the inductor and the negative output terminal;
A capacitor connected between the positive output terminal and the negative output terminal,
The power conversion device according to claim 4, further comprising: A switch driving unit that drives the first switch, the second switch, the third switch, and the fourth switch,
The power conversion device according to claim 5, wherein the switch drive unit is driven by the DC power generated by the power generation module. The switching control unit,
When the target conversion ratio is less than 100%, the third switch is turned on and the fourth switch is turned off, and the first switch and the second switch are complementarily switched,
The power conversion device according to claim 6, wherein when the target conversion ratio is greater than 100%, the first switch is turned on and the second switch is turned off, and the third switch and the fourth switch are complementarily switched. . The switching control unit,
When the target conversion ratio is smaller than 100%, the first switch and the second switch are complementarily switched so that the ON period of the first switch with respect to the switching cycle becomes a ratio according to the target conversion ratio. ,
When the target conversion ratio is greater than 100%, the ON period of the third switch with respect to the switching cycle is set to a ratio according to a value obtained by dividing the target conversion ratio by 100% by the target conversion ratio. The power conversion device according to claim 7, wherein the third switch and the fourth switch are complementarily switched. The power conversion device according to any one of claims 1 to 8, wherein the power generation module is a solar cell panel. Driven by the DC power generated by the power generation module, further comprising a switch drive unit for switching the buck-boost circuit,
The switching control unit, in the maximum power point tracking process by the scanning method,
The power conversion device according to claim 1, wherein the input voltage is changed within a predetermined range equal to or higher than a lower limit voltage value with which the switch driving unit can be operated. A plurality of power generation modules connected in series, each of which generates DC power,
At least one power converter provided corresponding to at least one target power generation module of the plurality of power generation modules;
Equipped with
The power conversion device,
An input voltage generated from the target power generation module is applied, an output voltage obtained by power conversion of the input voltage is output, and the input voltage can be output as the output voltage without power conversion. Buck-boost circuit,
A switching control unit that executes a maximum power point tracking process that controls the power conversion of the step-up / down circuit so as to maximize the DC power generated by the target power generation module,
An efficiency change event detection unit that detects whether or not an efficiency change event in which the power generation efficiency of the target power generation module changes by a predetermined value or more has occurred,
Equipped with
The switching control unit,
When the efficiency change event occurs, the maximum power point tracking process by the scanning method is executed,
A power generation system that executes the maximum power point tracking process by the hill climbing method by taking over the control amount of power conversion that maximizes the DC power after executing the maximum power point tracking process by the scan method. A power generation control method for controlling a power generation system comprising a plurality of power generation modules connected in series,
Each of the plurality of power generation modules generates DC power,
At least one target power generation module of the plurality of power generation modules is subjected to power conversion by a power conversion device,
The power conversion device,
An input voltage generated from the target power generation module is applied, an output voltage obtained by power conversion of the input voltage is output, and the input voltage can be output as the output voltage without power conversion. Buck-boost circuit,
A switching control unit that executes a maximum power point tracking process that controls the power conversion of the step-up / down circuit so as to maximize the DC power generated by the target power generation module,
Prepare,
The switching control unit,
When an efficiency change event occurs in which the power generation efficiency of the target power generation module changes by a predetermined value or more, the maximum power point tracking process by the scanning method is executed,
A power generation control method, which, after executing the maximum power point tracking processing by the scan method, takes over the control amount of power conversion that maximizes the DC power and starts the maximum power point tracking processing by the hill climbing method.

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