JP2015170111A - Power conversion equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To maintain maximum power stably by maximum power follow-up control.SOLUTION: A maximum power control part 40 changes a command value which is set by a command value creation part 20, so that power outputted by a DC power supply is increased gradually. The maximum power control part 40 searches for a maximum power point where power becomes maximum. When it is detected that the power exceeds the maximum power point, the maximum power control part 40 returns the command value to a value which is a value before the power exceeds the maximum power point. The maximum power control part 40 returns the command value to the value which is a value before the power exceeds the maximum power point, when it is predicted that the power exceeds the maximum power point. Power conversion equipment 1 may have slow responsiveness, caused by its circuit configuration, or caused by feedback control of an inverter circuit 7 and converter circuit 8 thereof. Even the power conversion equipment 1 has slow responsiveness, excess reduction of the power is avoided.

Description

  The invention disclosed herein relates to a power conversion device that is controlled to extract maximum power from a power supply device.

  There is known a power conversion device that adjusts electric power supplied from a small-scale power supply device such as a solar cell and / or a fuel cell and outputs electric power to an AC device or a system. Such a power converter is sometimes called a power conditioner or a grid interconnection inverter. In this type of power conversion device, a function of automatically adjusting the output from the power generation device may be provided so as to extract the maximum power from the power supply device.

  For example, Patent Literature 1 and Patent Literature 2 disclose maximum power control for adjusting an output current from a power supply device so as to extract the maximum power from the power supply device.

  Patent Document 2 discloses a power conversion device that provides DC-AC conversion by using an inverter circuit and a converter circuit in a complementary manner.

  Also,

JP 09-56180 A JP 2001-169564 A JP2012-165499A

  In the maximum power tracking control (MPPT: Maximum Power Point Tracking) disclosed in Patent Document 1, the current value is adjusted so as to search for a current value at which the maximum power can be obtained. However, it may be difficult to stably maintain the maximum power point due to various factors such as responsiveness and noise of the power conversion device. For example, when the current value is decreased, the current value at which the maximum power is obtained is passed.

  Even when the maximum power follow-up control is used in the power conversion apparatus as in Patent Document 3, it may be difficult to stably maintain the maximum power point.

  In the device disclosed in Patent Literature 2, a ripple that is an integral multiple of the frequency of the output voltage is superimposed on the input current of the power conversion device due to the control method. For this reason, the response to the command value is slow. In a power conversion device having a slow response to a command value as an example of the device disclosed in Patent Document 2, when the maximum power tracking control is performed, the maximum power point may be passed, and the maximum power can be stably obtained. It can be difficult.

  In view of the above or other aspects not mentioned, there is a need for further improvements in power conversion devices.

  One of the objects of the invention is to provide an improved power conversion device capable of stably maintaining the maximum power by the maximum power tracking control.

  Another object of the invention is to provide a power converter that can stably maintain operation in the vicinity of the maximum power even when a power conversion method having a slow response to a current command value is adopted.

  Another object of the invention is to stably provide maximum power from a power generator in a power converter that feedback-controls the current of an AC output to a command value by alternately switching an inverter circuit and a converter circuit at high speed. It is providing the power converter device which can be taken out.

  The invention disclosed herein employs the following technical means to achieve the above object. Note that the reference numerals in parentheses described in the claims and in this section indicate a corresponding relationship with specific means described in the embodiments described later as one aspect, and limit the technical scope of the invention. Not what you want.

  According to one of the disclosed inventions, a power conversion device that converts DC power supplied from the DC power supply (4) to the DC terminal (6) into AC power and supplies the AC power from the AC terminal (5) to the AC power supply (3) ( 1) is provided. The invention includes an inverter circuit (7) provided between a DC terminal and an AC terminal, and a converter circuit (B) provided between the inverter circuit and the DC terminal, and capable of boosting at least DC power and supplying it to the inverter circuit. 8), a current sensor (14, 15) for detecting a current related to the current at the AC terminal, a command value creating unit (20) for setting a command value of the current at the AC terminal, and a voltage supplied from the DC power supply Is converted into an AC voltage, and a feedback control unit (21-31) feedback-controls the inverter circuit and the converter circuit so that the current detected by the current sensor follows the command value, and the power output from the DC power supply The command value set by the command value creation unit is changed so as to gradually increase, and the maximum power point at which the power is maximized is searched and the maximum power is A maximum power control unit (40) for returning the command value to a value before exceeding the maximum power point when it is detected that the maximum power point is exceeded and / or when the maximum power point is predicted to be exceeded. Features.

  According to this invention, the maximum power control unit changes the command value so that the power output from the DC power supply gradually increases. As a result, the maximum power point at which the power output from the DC power supply is maximized is searched. The power conversion device may have a slow response due to its circuit configuration or due to feedback control of its inverter circuit and converter circuit. According to the present invention, when the maximum power point is exceeded and / or when the maximum power point is predicted to be exceeded, the command value is returned to the value before the maximum power point is exceeded. For this reason, even if a power converter device has slow responsiveness, the fall of an excessive electric power is avoided. As a result, the maximum power can be stably maintained by the maximum power tracking control.

It is a block diagram of the power converter device concerning a 1st embodiment of the invention. It is a block diagram which shows the part relevant to the maximum power control of 1st Embodiment. It is a flowchart which shows the process relevant to the maximum electric power control of 1st Embodiment. It is a wave form diagram which shows the waveform at the time of the action | operation of 1st Embodiment. It is a graph which shows the behavior of maximum power control of a 1st embodiment. It is a wave form diagram which shows the action | operation of 1st Embodiment. It is a wave form diagram which shows the action | operation of 1st Embodiment. It is a block diagram of the power converter device which concerns on 2nd Embodiment of invention. It is a block diagram of the power converter device which concerns on 3rd Embodiment of invention. It is a block diagram of the power converter device which concerns on 4th Embodiment of invention.

  A plurality of modes for carrying out the invention disclosed herein will be described with reference to the drawings. In each embodiment, portions corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals and redundant description may be omitted. Further, in the following embodiments, the correspondence corresponding to the matters corresponding to the matters described in the preceding embodiments is indicated by adding reference numerals that differ only by one hundred or more, and redundant description may be omitted. . In each embodiment, when only a part of the structure is described, the other parts of the structure can be applied with reference to the description of the other forms.

(First embodiment)
In FIG. 1, a power conversion device 1 according to a first embodiment for carrying out the invention and a power system 2 including the power conversion device 1 are illustrated. The power system 2 is installed in a consumer connected to the grid 3. The power system 2 is configured, for example, in an individual house or business office. The grid 3 is an AC power supply provided by a power network provided by a supplier such as a power supply company or a small-scale power generation facility. The small-scale power generation facility that supplies the grid 3 can be installed in an individual house or business establishment. The system 3 is a single-phase three-wire power source and includes a neutral line (N) and voltage lines (U, V).

  The power system 2 includes a small-scale DC power supply 4. The direct current power source 4 is provided by a power generation device that outputs direct current such as a solar cell and / or a fuel cell installed in a house or the like.

  The power conversion device 1 includes an AC terminal 5 connected to the system 3 and a DC terminal 6 connected to a DC power source 4. The power converter 1 converts DC power supplied from the DC terminal 6 into AC power, and supplies AC power from the AC terminal 5 to the system 3. The power conversion device 1 includes an inverter circuit 7 and a step-down converter circuit 8.

  The inverter circuit 7 is provided between the system 3 and the DC power supply 4. The inverter circuit 7 is provided between the converter circuit 8 and the AC terminal 5. The inverter circuit 7 can convert at least DC power into AC power. The inverter circuit 7 has at least a modulation function for modulating DC power supplied from the DC terminal 6 and an orthogonal transformation function for converting DC power to AC power. The inverter circuit 7 can be provided by a bidirectional conversion circuit capable of performing orthogonal conversion for converting DC power to AC power and AC / DC conversion for converting AC power to DC power. When the inverter circuit 7 reversely flows power from the DC power supply 4 to the grid 3, the phase of the AC voltage Vac of the grid 3 and the phase of the output current output from the power converter 1 to the grid 3 may be matched. it can. The inverter circuit 7 provides an orthogonal conversion function that converts DC power supplied from the DC terminal 6 into AC power, and a voltage conversion function that adjusts the DC voltage Vdc to match the AC voltage Vac of the system 3.

  The inverter circuit 7 includes a full bridge circuit, a normal coil Ln, and a capacitor Cf. The full bridge circuit is a circuit in which a plurality of switch elements Q1-Q4 are connected to an H bridge. The full bridge circuit includes at least four switch elements Q1, Q2, Q3, and Q4. Switch elements Q1, Q2, Q3, and Q4 are IGBT (insulated gate bipolar transistor) elements. Since the switch elements Q1 and Q4 output a voltage having the same polarity as the DC voltage Vdc, they are referred to as a normal pair switch element. Since switch elements Q2 and Q3 output a voltage having a polarity opposite to that of DC voltage Vdc, they are called inverted pair switch elements.

  The normal coil Ln is provided between the inverter circuit 7 and the AC terminal 5. The normal coil Ln is connected to the AC terminal 5 of the full bridge circuit. The normal coil Ln is connected in series between one AC terminal 5 of the bridge circuit and the system 3. The capacitor Cf is connected in parallel between the normal coil Ln and the AC terminal 5. The normal coil Ln is also called a normal mode coil.

  Converter circuit 8 is provided between system 3 and DC power supply 4. The converter circuit 8 is a step-up converter circuit 8. The converter circuit 8 can boost at least a DC voltage supplied from the DC power supply 4 and supply the boosted voltage to the inverter circuit 7.

  The converter circuit 8 includes a reactor Lr, a switch element Qa, a diode D1, and a smoothing capacitor Cs. The switch element Qa is an IGBT element. A DC voltage Vdc is supplied to one end of the reactor Lr. The other end of the reactor Lr is connected to a connection point between the switch element Qa and the diode D1. The switch element Qa and the diode D1 are connected in series between both ends of the smoothing capacitor Cs. The diode D1 provides the upper arm of the bridge circuit, and the switch element Qa provides the lower arm of the bridge circuit. The smoothing capacitor Cs is located between the inverter circuit 7 and the converter circuit 8.

  According to this configuration, power conversion from the DC power supply 4 to the system 3 can be provided by the inverter circuit 7 and the converter circuit 8. The power conversion includes conversion between the voltage of the DC power supply 4 and the voltage of the grid 3, and conversion from DC to AC.

  The power conversion device 1 includes a filter circuit 9 for removing noise between the inverter circuit 7 and the AC terminal 5. The power conversion device 1 includes a circuit breaker 10 between the AC terminal 5 and the filter circuit 9. The circuit breaker 10 interrupts the connection between the grid 3 and the power conversion device 1. The power conversion device 1 includes a filter circuit 11 for removing noise between the DC terminal 6 and the converter circuit 8. The filter circuit 11 can include a capacitor connected between the positive electrode line and the negative electrode line.

  The power conversion device 1 includes a plurality of sensors for detecting the voltage and current of each unit. The power conversion device 1 includes a voltage sensor 12 that detects a DC voltage Vdc and a voltage sensor 13 that detects an AC voltage Vac. The power conversion device 1 includes a current sensor 14 that detects a current (also referred to as an input current) supplied from the DC power supply 4. The power conversion device 1 includes a current sensor 15 that detects a current flowing through the normal coil Ln. The power conversion device 1 includes a voltage sensor 16 that detects a voltage between terminals of the smoothing capacitor Cs.

  The power conversion device 1 includes a control device 17 that controls the inverter circuit 7 and the converter circuit 8. The control device 17 is an electronic control device. The control device has at least one arithmetic processing unit (CPU) and at least one memory device (MMR) as a storage medium for storing programs and data. The control device is provided by a microcomputer including a computer-readable storage medium. The storage medium stores a computer-readable program non-temporarily. The storage medium can be provided by a semiconductor memory or a magnetic disk. The controller can be provided by a computer or a set of computer resources linked by a data communication device. The program is executed by the control device to cause the control device to function as the device described in this specification and to cause the control device to perform the method described in this specification. The control device provides various elements. At least some of those elements can be referred to as a means for performing functions, and in another aspect, at least some of those elements can be referred to as constituent blocks or modules.

  In this embodiment, the power conversion device 1 provides power supply from the DC power supply 4 to the system 3, that is, reverse power flow. The DC power source 4 is the input side, and the system 3, that is, the AC power source is the output side. The power converter 1 employs a switching drive method as a basic operation method. In this switching drive system, there are provided a mode in which the inverter circuit 7 is driven at high speed switching and the converter circuit 8 is fixedly driven, and a mode in which the inverter circuit 7 is fixedly driven and the converter circuit 8 is driven at high speed switching. The It is not excluded that both the inverter circuit 7 and the converter circuit 8 are driven at high-speed switching between these modes.

  In the switching drive method, the inverter circuit 7 is subjected to switching control to convert DC power into AC power during a period in which the absolute value | Vac | of the AC voltage Vac is lower than the DC voltage Vdc. At this time, the switch element Qa of the converter circuit 8 is continuously maintained in the OFF state. In the switching drive system, the converter circuit 8 is subjected to switching control to convert DC power into AC power in a period in which the absolute value | Vac | of the AC voltage Vac is higher than the DC voltage Vdc, that is, the input voltage. At this time, the switch elements Q1-Q4 of the inverter circuit 7 are complementarily ON / OFF controlled in accordance with the polarity of the AC voltage Vac so that the forward rotation pair and the reverse pair are alternately turned on. That is, when the converter circuit 8 is driven at high speed switching, the inverter circuit 7 is switched at a relatively low speed such as 60 Hz or 50 Hz.

  In the embodiment, the converter circuit 8 is proportional-integral (PI) controlled using the current IL flowing through the normal coil Ln. The feedback control of the converter circuit 8 is proportional-integral control that causes the output current to follow the command value Iref. The inverter circuit 7 is hysteresis controlled using a current IL flowing through the normal coil Ln. The feedback control of the inverter circuit 7 is a hysteresis control that causes the output current to follow the command value Iref. The feedback control of the inverter circuit 7 and the feedback control of the converter circuit 8 are executed so that the phase of the output current matches the phase of the AC voltage Vac of the system (AC power supply) 3 based on the current IL flowing through the normal coil Ln. . According to this configuration, since feedback control is executed based on the current IL flowing through the normal coil Ln, the phase of the output current output to the AC terminal 5 can be accurately controlled.

  The control device 17 controls the inverter circuit 7 by hysteresis control. In the hysteresis control, the switch elements Q1-Q4 are switched so that the detected current IL matches the command value Iref. In the hysteresis control, the switching elements Q1-Q4 are switched so as to maintain the current IL between the upper limit value IL + and the lower limit value IL- set based on the command value Iref.

  The control device 17 controls the converter circuit 8 by proportional-integral control (PI control). In the proportional-integral control, the switch element Qa is switched so that the current IL matches the command value Iref. In the proportional-integral control, the switching duty ratio of the switch element Qa is adjusted according to a proportional component proportional to the deviation between the current IL and the command value Iref and an integral component obtained by integrating the deviation.

  According to this configuration, since both the inverter circuit 7 and the converter circuit 8 are controlled by the current IL flowing through the normal coil Ln, which is an input current for which harmonics are desired to be reduced, it is easy to control and can be controlled to a current close to a sine wave.

  The control device 17 adjusts the voltage by driving the inverter circuit 7 at high-speed switching, and provides an inverter switching period for providing power conversion. The control device 17 adjusts the voltage by driving the converter circuit 8 at high-speed switching, and provides a converter switching period for providing power conversion. The control device 17 provides reverse power flow from the DC power supply 4 to the system 3 by alternately executing the inverter switching period and the converter switching period. Control device 17 switches between the inverter switching period and the converter switching period so as to provide a period in which only inverter circuit 7 is duty-driven and a period in which only converter circuit 8 is duty-driven. By switching between power conversion using only the inverter circuit 7 and power conversion using only the converter circuit 8, loss due to switching is suppressed. Further, the control device 17 may provide a combined period in which power conversion by the inverter circuit 7 and power conversion by the converter circuit 8 are used in combination.

  The control device 17 provides means for setting the start timing and stop timing of the inverter switching period and the converter switching period. The basic timing of the start timing and stop timing can be set based on the intersection of the DC voltage Vdc and the AC voltage Vac (AC voltage absolute value | Vac |). That is, Vdc> | Vac | can be associated with the inverter switching period, and Vdc <| Vac | can be associated with the converter switching period. When Vdc = | Vac |, it can be associated with either period.

  The control device 17 includes a current command value creation unit 20 that creates a current command value Iref according to the current IL flowing through the normal coil Ln. The current command value creating unit 20 divides the output voltage from the power to be output, and calculates the current command value Iref. The current IL detected by the current sensor 15 is an alternating current output to the system 3 and is also an output current. The control device 17 includes a phase synchronization unit 21 that synchronizes the phase of the command value Iref. The phase synchronization unit 21 outputs a command value Iref whose phase is adjusted. Since the output current and the output voltage need to have a power factor close to 1, the phase synchronization unit 21 obtains the zero-cross timing and period of the AC voltage Vac and sets the command value Iref of the current in phase with the AC voltage Vac.

  The control device 17 includes a first correction unit 22 that corrects the command value Iref so as to be suitable for control of the inverter circuit 7. The control device 17 includes a second correction unit 23 that corrects the command value Iref so as to be suitable for control of the converter circuit 8. In the correction units 22 and 23, the command value Iref is corrected so as to compensate and cover the current delay caused by the smoothing capacitor Cs and the like.

  The control device 17 includes an inverter control unit 24 for generating a drive signal for controlling the switch elements Q1-Q4 of the inverter circuit 7. The inverter control unit 24 performs orthogonal transform control of the inverter circuit 7 so as to function as a drive signal for feedback control of the inverter circuit 7 so as to output a voltage corresponding to the AC voltage of the system 3 and an orthogonal transform circuit. The drive signal is output. The orthogonal transformation control is also called polarity control because it controls the inverter circuit 7 in accordance with the polarity of the AC voltage. In this embodiment, hysteresis control is used as feedback control.

  The inverter control unit 24 creates an upper limit value IL + and a lower limit value IL− as hysteresis control command values from the command value Iref for hysteresis control. Hysteresis control is executed such that the current IL flows between the upper limit value IL + and the lower limit value IL−. When the absolute value | Vac | of the AC voltage Vac is smaller than the DC voltage Vdc, when the current IL of the normal coil Ln exceeds the upper limit value IL +, the switch elements Q1 and Q4 are turned on, and the switch elements Q2 and Q3 are turned on. It is turned off. When the current IL falls below the lower limit value IL−, the switch elements Q1 and Q4 are turned off, and the switch elements Q2 and Q3 are turned on.

  The inverter control unit 24 outputs a drive signal for polarity control. When the absolute value | Vac | of the AC voltage Vac is larger than the DC voltage Vdc, when the AC voltage Vac is positive, the switch elements Q1 and Q4 are turned on and the switch elements Q2 and Q3 are turned off. When the AC voltage Vac is negative, the switch elements Q1 and Q4 are turned off and the switch elements Q2 and Q3 are turned on.

  The control device 17 includes a converter control unit 25 for generating a drive signal for controlling the switch element Qa of the converter circuit 8. The converter control unit 25 causes the converter circuit 8 to output the drive signal for feedback control of the converter circuit 8 so as to output a voltage corresponding to the AC voltage of the system 3 and the input voltage from the DC power supply 4 as it is. A drive signal for direct connection control is output. In this embodiment, proportional-integral control (PI control) is used as feedback control. Converter control unit 25 takes the difference between command value Iref and input current IL flowing through normal coil Ln, performs PI control calculation, and calculates duty ratio Duty of the drive signal for switch element Qa.

  The control device 17 includes a first switching control unit 26 that switches the control method of the inverter circuit 7. The first switching control unit 26 switches between feedback control and polarity control. The first switching control unit 26 determines either feedback control or polarity control as the control method of the inverter circuit 7 based on the DC voltage Vdc and the absolute value | Vac | of the AC voltage Vac. Here, two controls are switched with Vdc = | Vac | as a boundary. The first switching control unit 26 sets a drive signal corresponding to the control method. Hysteresis may be provided for switching the control characteristics.

  When hysteresis control is selected (| Vac | <Vdc), feedback control is executed based on the current IL and the command value Iref so that the current IL follows the command value Iref. Here, hysteresis control provided by the inverter control unit 24 is used. In the hysteresis control, the current IL detected between the current upper limit value IL + set based on the command value Iref and the current lower limit value IL- set based on the command value Iref is maintained. Here, when IL + <IL, the inverting pair of switch elements Q2 and Q3 are driven to the ON state, and when IL <IL−, the forward pair of switch elements Q1 and Q4 are driven to the ON state.

  When polarity control is selected (| Vac |> Vdc), the switch elements Q1 and Q4 of the normal pair and the switch elements Q2 and Q3 of the reverse pair are complementarily turned on corresponding to the polarity of the AC voltage Vac. Driven to state. When the AC voltage Vac is positive, the forward rotation switch elements Q1 and Q4 are driven to the ON state. When the AC voltage Vac is negative, the inverting pair of switch elements Q2 and Q3 are driven to the ON state.

  The control device 17 includes a second switching control unit 27 that switches the control method of the converter circuit 8. The second switching control unit 27 switches between feedback control and direct connection control. When the DC voltage Vdc is smaller than the absolute value | Vac | of the AC voltage Vac, the switching control unit 27 performs PWM (pulse width modulation) so that the switching element Qa can be switched with the duty ratio Duty set by the PI control calculation. ) Perform switching control by calculation. On the other hand, when the DC voltage Vdc is larger than the absolute value | Vac | of the AC voltage Vac of the system 3, the switch element Qa is continuously controlled to be in the OFF state.

  In the second switching control unit 27, one of the feedback control and the direct connection control is determined as the control method of the converter circuit 8 based on the DC voltage Vdc and the absolute value | Vac | of the AC voltage Vac. Here, when | Vac | exceeds Vdc, feedback control of converter circuit 8 is started. Thereafter, when | Vac | falls below Vdc, the feedback control of converter circuit 8 is terminated. In the second switching control unit 27, a drive signal corresponding to the control method is set.

  When direct connection control is selected, that is, in the process of decreasing | Vac |, after | Vac | falls below Vdc, the switch element Qa is continuously controlled to be in the OFF state. Thereby, the converter circuit 8 is directly connected via the diode D1.

  When feedback control is selected, that is, in the process of increasing | Vac |, after | Vac | exceeds Vdc, the switching element Qa is subjected to switching control with the duty ratio set by the duty setting unit 27b. Thereby, converter circuit 8 is controlled to convert DC voltage Vdc into AC voltage Vac and to make the output current coincide with command value Iref.

  The control device 17 includes a dead time generating unit 28 that gives a dead time to the drive signals of the switch elements Q1-Q4 of the inverter circuit 7. The control device 17 includes a dead time generation unit 29 that gives a dead time to the drive signal of the switch element Qa of the converter circuit 8.

  The control device 17 includes a gate drive unit 30 for driving the switch elements Q1-Q4 of the inverter circuit 7. The control device 17 includes a gate drive unit 31 for driving the switch element Qa of the converter circuit 8. Elements 21-31 of the control device 17 provide a feedback control.

  The control device 17 includes a maximum power control unit 40 for providing maximum power control (also referred to as maximum power tracking control). Maximum power control unit 40 changes command value Iref in the increasing direction and / or decreasing direction. The maximum power control unit 40 monitors the input power before and after the change of the command value Iref. The maximum power control unit 40 searches for the command value Iref that maximizes the input power extracted from the DC power source 4, that is, the operating state of the power converter 1. Furthermore, the maximum power control unit 40 adjusts the command value Iref so as to maintain an operation state in which the maximum input power can be obtained. The maximum power control unit 40 has a plurality of elements therein. The maximum power control unit 40 includes a creation unit 32, a comparison unit 33, a determination unit 34, and a calculation unit 35. The maximum power control unit 40 inputs various input signals described below.

  The creation unit 32 calculates the correction amount of the command value Iref for maximum power control. The correction amount is calculated as the amplitude Iref_amp of the output current command value. The comparison unit 33 compares the input power extracted from the DC power supply 4 with a target power target, searches for an operating state in which the input power is maximum according to the comparison result, and maintains the vicinity of the maximum power. The increase / decrease of the command value Iref is determined so as to do so. The determination unit 34 determines the maximum power control based on the comparison between the input power and the target power, that is, whether or not search is possible. The calculation unit 35 processes a signal necessary for maximum power control. The calculator 35 calculates the effective value of the input power. In this embodiment, the command value Iref is adjusted so that the effective value of the input power is maximized.

  The maximum power control unit 40 provides a comparison unit that compares two input powers at different command values Iref to determine which command value Iref is taken out in order to perform maximum power tracking control. . For example, input powers at a plurality of time points that are two or more times apart by a predetermined time, a predetermined period, and a predetermined number of control cycles are compared. The maximum power control unit 40 provides, for example, a comparison unit that compares current input power with past input power. The current input power can be the input power in the current control cycle. The past input power can be the previous input power by one control cycle. The past input power may be input power that is two or more control cycles before.

  Whether the maximum power control unit 40 has exceeded the maximum power point or an event that is predicted to exceed the maximum power point has been detected under the relationship with the search for changing the command value Iref in one direction. A determination unit for determining whether or not is provided. Exceeding the maximum power point can be determined by detecting that the change tendency of the input power is reversed. Also, an event that is predicted to exceed the maximum power point can be detected when the change in the command value Iref exceeds a predetermined upper limit value. The maximum power control unit 40 provides a holding control unit that sets and maintains the command value Iref to a value at which the maximum power can be obtained when the maximum power point is exceeded or when the maximum power point is predicted to be exceeded. . The setting of the command value Iref by the holding control unit is a large current width change in a short time as compared with the change of the command value Iref for the search. Therefore, the change in the command value Iref given by the holding control unit can also be called a skip-like change. The change in the command value Iref given by the holding control unit is a change that is returned to the direction of the maximum power point or before the maximum power point is exceeded with respect to exceeding the maximum power point. Therefore, the change in the command value Iref given by the holding control unit can also be called skip-back.

  In this embodiment, after the maximum power point is exceeded, the holding control unit changes the command value Iref in a short time by a predetermined value in a direction opposite to the change direction being searched. Furthermore, the holding control unit maintains the value after the change over a predetermined period. When the command value Iref is increased during the search, the command value Iref is decreased by a predetermined width in a short time after exceeding the maximum power point. Thereby, the slow response of the power converter 1 is compensated, and the command value Iref near the maximum power point is set. Specifically, the change width for the skip-like change is set using the command value Iref (i−1) before the current time. Furthermore, a predetermined coefficient is used to return to the command value before the maximum power point in the search direction by skip change. The change width is set so that the command value Iref is instantaneously lowered to a value before the command value at which the maximum power can be obtained. That is, on the premise that the maximum power point is passed by the change of the command value Iref for the search, a function of returning to the command value before the passage, preferably just before the passage is provided.

  In this embodiment, when it is predicted that the maximum power point will be exceeded, the holding control unit changes the command value Iref in a short time by a predetermined value in a direction opposite to the changing direction during the search. Furthermore, the holding control unit maintains the value after the change over a predetermined period. When the command value Iref is increased during the search, the command value Iref is decreased by a predetermined width in a short time after it is predicted that the maximum power point will be exceeded. Thereby, the slow response of the power converter 1 is compensated, and the command value Iref near the maximum power point is set. Specifically, the change width for the skip-like change is set using the command value Iref (i−1) before the current time. Furthermore, a predetermined coefficient is used to return to the command value before the maximum power point in the search direction by skip change. The change width is set so that the command value Iref is instantaneously lowered to a value before the command value at which the maximum power can be obtained. That is, on the premise that the maximum power point is passed by the change of the command value Iref for the search, a function of returning to the command value before the passage, preferably just before the passage is provided.

  The maximum power control unit 40 provides a search stop unit that stops the process of searching for the maximum power until the input power starts increasing again after the command value Iref is changed in a skipping manner. When the input power starts to rise again after the command value Iref changes in a skipping manner, the search stop unit resumes the change in the command value Iref and resumes the process of searching for the maximum power.

  FIG. 2 is a block diagram showing signal processing in the maximum power control unit 40. The maximum power control unit 40 uses the previous command value Iref_amp_pre by one or a plurality of control periods. This command value Iref_amp_pre is also the command value Iref (i−1). The maximum power control unit 40 uses the difference dIref_amp of the command value Iref. The difference dIref_amp is a difference between the command value Iref (i) after exceeding the maximum power point and the previous command value Iref (i−1). The command value Iref_amp_pre and the difference dIref_amp are obtained in the maximum power control unit 40. The maximum power control unit 40 uses the input voltage Vin. The input voltage Vin is input from the voltage sensor 12. The maximum power control unit 40 uses the input power Pin. The input power Pin can be obtained from the input voltage Vin and a command value Iref which is a current. The input voltage Vin is calculated as an effective value.

  The maximum power control unit 40 provides a search unit 40a that gradually changes the command value. The maximum power control unit 40 gradually increases the command value Iref during normal times, that is, when searching for the maximum power point. The command value may be gradually decreased. The search direction can be selected according to the output characteristics of the DC power supply 4. The maximum power control unit 40 gradually increases the amplitude Iref_amp, which is a correction amount for the command value of the output current, in order to increase the command value Iref. At this time, the maximum power control unit 40 provides a maximum power search unit. The amplitude Iref_amp is given by the following equation (1) where β (beta) is an increase amount for each control cycle. Formula (1) can also be expressed as Formula (2). Note that n can be a natural number of 1 or more, and indicates the number of control cycles. (I) shows a value in the current control cycle, and (i−n) shows a previous value by the number of control cycles n times.

Iref_amp = Iref_amp + β (1)
Iref_amp (i) = Iref_amp (i−n) + β (2)
The maximum power control unit 40 provides an overshoot return control unit 40b. The overshoot return control unit returns the command value Iref to a value before the maximum power point when the command value Iref has exceeded the maximum power point by the maximum power search. When the command value Iref exceeds the maximum power point and the input power Pin falls below the maximum power Pmax, the maximum power control unit 40 decreases the command value Iref in a skipping manner.

  The maximum power control unit 40 provides a function of determining that the input power Pin has decreased below the maximum power Pmax (Pin <Pmax) as a result of a normal increase search. This function is a function for determining that the maximum power point has been exceeded. The maximum power control unit 40 returns the amplitude Iref_amp to a value smaller than the previous command value Iref_amp_pre in order to decrease the command value Iref in a skipping manner. The amount of change in the command value when the command value is returned (the amount of change in one control cycle) is larger than the amount of change in the command value when searching for the maximum power point (the amount of change in one control cycle). The maximum power control unit 40 sets the amplitude Iref_amp according to the following equation (3).

  Voc is a voltage when the DC power source 4, for example, a solar cell is opened. α (alpha) is an adjustment value for compensating for fluctuations due to individual differences in components such as circuit elements and DC power supply 4. α is a value less than 1.0. α can be set to a value of about 0 to 0.1. Since the open circuit voltage Voc is always higher than the input voltage Vin, the coefficient (Vin / Voc + α) is a value less than 1.0. Therefore, a reduction to a command value smaller than the previous command value is realized. Equation (3) can also be expressed as Equation (4).

Iref_amp = (Vin / Voc + α) × Iref_amp_pre (3)
Iref_amp (i) = (Vin / Voc + α) × Iref_amp (i−n) (4)
The maximum power control unit 40 searches for the maximum power point again after a predetermined period of time has elapsed after the command value Iref has been skipped. Since the response delay of the power converter 1 is relatively large, the effective value of the actual current catches up with the command value Iref before the command value Iref reaches the maximum power point by the search after the skip change.

  The maximum power control unit 40 provides an excessive fluctuation return control unit 40c. The excessive fluctuation return control unit returns the command value Iref to a value before the maximum power point when an excessive fluctuation that greatly affects the maximum power control occurs during the maximum power search. The maximum power control unit 40 changes the command value Iref in a skip manner when the current output from the DC power supply 4 and the input current in the power conversion device 1 are rapidly reduced.

  The decrease in the input current can be calculated as the change amount of the command value Iref. For example, an abrupt decrease in current is determined by comparing a difference dIref_amp between the command value in the previous control cycle and the command value in the current control cycle with a predetermined threshold value. More specifically, when the difference dIref_amp exceeds a preset upper limit value dIref_max, it is possible to determine an abrupt decrease in current. A sudden drop in current corresponds to a case where the maximum power point is expected to be exceeded.

  The sudden decrease in current is caused by a decrease in the output of the DC power supply 4. For example, this is a case where the amount of solar radiation supplied to the solar cell is drastically reduced. In this case, the power conversion apparatus 1 may have a command value Iref exceeding the maximum power point due to its slow response. Further, when the command value Iref is gradually increased for searching for the maximum power point, the input current rapidly decreases against the increase of the command value Iref, and therefore the command value Iref exceeds the maximum power point. It tends to be a value. The amount of change in the command value when the command value is returned (the amount of change in one control cycle) is larger than the amount of change in the command value when searching for the maximum power point (the amount of change in one control cycle). The maximum power control unit 40 sets the amplitude Iref_amp according to the following equation (5). The coefficient (1-Vin / Voc-α) is a value less than 1.0. Equation (5) can also be expressed as Equation (6).

Iref_amp = (1-Vin / Voc-α) × Iref_amp_pre (5)
Iref_amp (i) = (1-Vin / Voc-α) × Iref_amp (in) (6)
The maximum power control unit 40 searches for the maximum power point again after a predetermined period of time has elapsed after the command value Iref has been skipped. Since the response delay of the power converter 1 is relatively large, the effective value of the actual current catches up with the command value Iref before the command value Iref reaches the maximum power point by the search after the skip change.

  The maximum power control unit 40 stops the search for the maximum power by the search unit 40a after the command value Iref changes in a skip-like manner, and the maximum power after the predetermined condition is satisfied, that is, after a predetermined period elapses. A search stop control unit 40d for restarting the search is provided. In this embodiment, the search for the maximum power is stopped for a predetermined period after the skip change. When the command value Iref is returned in a skip-like manner by the overshoot return control unit and / or the excessive fluctuation return control unit, if the power comparison is performed for the maximum power search control immediately after that, the slow response of the power conversion device 1 is caused. Due to the delay caused by the error, it may be erroneously detected that the maximum power point has been passed. In this case, since the command value is repeatedly lowered, an excessive decrease occurs. In order to prevent such an excessive decrease, the search for the maximum power is stopped for a predetermined period.

  Specifically, the search is stopped for a period until the input power (effective value) Pin increases again after the command value is reduced in a skipping manner. When the input power Pin increases again, the planned change of the command value Iref for searching for the maximum power and the comparison of power are resumed. Here, an increase in input power is determined by comparing the input power Pin (i) in the current control cycle with the input power Pin (i-1) in the previous control cycle. Thus, even when the amount of solar radiation changes suddenly, maximum power tracking control can be realized without causing excessive power reduction.

  FIG. 3 is a flowchart showing a control process 150 for realizing a function related to the maximum power control. In step 151, it is determined whether a search for maximum power, that is, power comparison is permitted. The search for the maximum power is prohibited immediately after the above-described skip change, and thereafter permitted by the processing of steps 158 and 159 described later. If the maximum power search is permitted, the process proceeds to step 152.

  In step 152, it is determined whether or not the command value Iref has exceeded the maximum power point by searching for the maximum power. Here, by comparing input power Pin (i) and input power Pin (i-1), it is determined that the maximum power point has been exceeded if Pin (i)> Pin (i-1) is not satisfied. . Step 152 provides a determination means for determining that the maximum power point has been exceeded when the input power from the DC power supply 4 starts to increase and decreases. If the maximum power point is not exceeded, the process proceeds to step 153 to continue searching for the maximum power. In step 153, the command value Iref is increased by the above equation (1).

  In step 154, it is determined whether or not an excessive fluctuation has occurred. Here, it is determined whether or not the change amount of the amplitude Iref_amp, that is, the difference dIref_amp exceeds a preset upper limit value dIref_max. Step 154 provides a predicting means for predicting that the maximum power point will be exceeded if the difference in the command value during the predetermined control period exceeds a predetermined threshold value. If excessive fluctuation has not occurred, the process proceeds to step 155.

  In step 155, the amplitude Iref_amp set in step 153 is determined as a correction amount for maximum power control. As a result, the power converter 1 is controlled by the command value Iref corrected by the amplitude Iref_amp.

  When the input power Pin (i) has not increased from the previous input power Pin (i−1) in step 152, the process proceeds to step 156. In this case, it can be determined that the maximum power point has been exceeded.

  In step 156, the command value Iref is reduced in a skipping manner by the above equation (3). In the case of going through step 156, in step 155, the amplitude Iref_amp for rapidly reducing the command value Iref is determined. Step 156 provides overshoot return setting means for setting a value before exceeding the maximum power point based on the command value Iref_amp_pre, the input voltage Vin, and the open voltage Voc of the DC power supply 4 in the past control cycle.

  If the difference dIref_amp exceeds the upper limit dIref_max in step 154, the process proceeds to step 157. In this case, it is predicted that the command value Iref exceeds the maximum power point.

  In step 157, the command value Iref is skipped by the above equation (5). Step 157 provides an excessive fluctuation return setting means for setting a value before exceeding the maximum power point based on the command value Iref_amp_pre, the input voltage Vin, and the open voltage Voc of the DC power supply 4 in the past control cycle. . In the case of going through step 157, in step 155, the amplitude Iref_amp for rapidly reducing the command value Iref is determined.

  FIG. 4 shows an example of the operation of the power conversion device 1. In the following description, the DC power supply 4 is the input side and the system 3 is the output side.

  In the period of | Vac |> Vdc (between time t11 and time t12), converter circuit 8 is PI (proportional integral) controlled using the current of normal coil Ln. The converter circuit 8 functions as a booster circuit. In PI control, PI control calculation is performed by taking the difference between the command value Iref and the current flowing through the normal coil Ln, and the duty ratio Duty for switching is calculated. Therefore, during this period, the switching element Qa of the converter circuit 8 is switching-driven at a high frequency with the duty ratio Duty. During this period, the inverter circuit 7 is fixedly controlled in a switching state for rectification. In the inverter circuit 7, when the AC voltage is positive, the switch elements Q1 and Q4 are turned on, and Q2 and Q3 are turned off. When the AC voltage is negative, the switch elements Q1 and Q4 are turned off and Q2 and Q3 are turned on.

  In the period of | Vac | <Vdc (between time t12 and time t13), the inverter circuit 7 is hysteresis controlled using the current of the normal coil Ln. The inverter circuit 7 steps down the voltage supplied from the DC power supply 4 and supplies it to the system 3. In the hysteresis control of the inverter circuit 7, the switching elements Q1-Q4 are switched and driven so that a current between the upper limit value and the lower limit value flows. When the normal coil current exceeds the upper limit value, the switch elements Q1 and Q4 are turned on and Q2 and Q3 are turned off. When the normal coil current falls below the lower limit value, the switch elements Q1 and Q4 are turned off and Q2 and Q3 are turned on. At this time, the converter circuit 8 is fixedly controlled so that electric power flows directly.

  According to this configuration, since both the inverter circuit 7 and the converter circuit 8 are controlled by the current of the normal coil Ln, which is an input current for which harmonics are desired to be reduced, it is easy to control and can be controlled to a current close to a sine wave.

  When the DC power supply 4 is a solar battery, the output of the DC power supply 4 frequently fluctuates due to changes in the amount of solar radiation. The maximum power generated by the solar cell changes according to the amount of solar radiation. Therefore, conventionally, maximum power tracking control (MPPT: Maximum Power Point Tracking) for controlling so that the power that can be generated by the solar cell at that time can be output to the load to the maximum is known. In order to realize this MPPT, a hill-climbing method disclosed in Patent Document 1 is conventionally known. This hill-climbing method searches for the maximum power point.

  In this hill-climbing method, the current power is compared with the power of the previous cycle in a certain control cycle, and the current command value is increased or decreased by a certain amount. For example, the output power is increased or decreased by controlling the switching duty ratio of the converter circuit for solar cell output control. For example, when the power increases when the duty ratio is increased, the operating point where the maximum output power is obtained is on the positive side where the duty ratio is increased from the current operating point. On the other hand, when the power decreases, it can be said that it is on the negative side. Therefore, when it is determined that the maximum power point is on the positive side, the duty ratio is increased by a certain value from the current duty ratio in the next control cycle. By repeating such a search operation, the actual output power is controlled to approach the maximum output power.

  FIG. 5 shows changes in the operating point in the maximum power tracking control. The solar cell as the DC power source 4 has operating characteristics having different slopes on both sides of the operating point where the maximum power is obtained as shown in the figure. In the illustrated example, the slope on the left side in the figure where the current is smaller than the operating points PC and PF where the maximum power can be obtained is smaller than the slope on the right side in the figure where the current is larger than the operating points PC and PF. The search for the maximum power is advanced by changing the current value from the side where the slope is small.

  When the search for the maximum power is started from the operating point PA, the operating point shifts to PA-PB-PC. When passing through the operating point PC where the maximum power is obtained and reaching the operating point PD, a decrease in power is observed. In this case, the control device attempts to reduce the current and approach the operating point PC where the maximum power can be obtained. However, in the power conversion device 1 with low responsiveness, it may pass through the operating point PD and further reach the operating point PE. When such an excessive decrease occurs, it is difficult to obtain the maximum power. In such a case, in this embodiment, a process of skipping from the operating point PE to the operating point PA or its vicinity is executed. Thereby, the search can be started again while suppressing an excessive decrease in power. The skip change is provided by a change from the high voltage side to the low voltage side from the operating point PC where the maximum power is obtained. Further, the destination of the skip change is not limited to the operating point PA. The range can be set on the operating point PA side from the operating point PC.

  In the figure, a solid line PSH indicates the output of the DC power supply 4 in a high solar radiation state with a large amount of solar radiation. A broken line PSL indicates the output of the DC power supply 4 in a low solar radiation state with a small amount of solar radiation. When a change from the high solar radiation state PSH to the low solar radiation state PSL occurs, the operating point easily moves to a position beyond the maximum power point. For example, even when the operating point PC is obtained in the high solar radiation state PSH, when the power conversion device 1 has a slow response, when the operating point PC changes to the low solar radiation state PSL, the operating point may change as indicated by the broken line arrow. is there. This is because the control is delayed with respect to the change in power caused by the decrease in the amount of solar radiation. In this case, the current value changes greatly. In such a case, in this embodiment, a skip change process from the operating point PH to the operating point PG or its vicinity is executed. Thereby, since the command value of electric current changes rapidly, the excessive fall of electric power is suppressed. The skip change is provided by a change from the high voltage side to the low voltage side from the operating point PF where the maximum power is obtained. Further, the skip change destination is not limited to the operating point PG. The range can be set on the operating point PG side from the operating point PF.

  When the maximum output follow-up control is applied to the power converter 1 as in this embodiment, that is, the solar cell power conditioner to which the alternating drive control for alternately driving the inverter circuit 7 and the converter circuit 8 at high frequency is applied. There are issues to be solved. In this case, since the alternate drive control is performed so that the output current is formed into a sine wave, a ripple that is a multiple of the frequency of the system 3, for example, a ripple of 100 Hz or 120 Hz is superimposed on the input current. Therefore, the change in the current command value given by the maximum power tracking control is not immediately reflected in the change in the input current, and when the current is lowered after reaching the maximum power, the responsiveness cannot catch up and the output power further decreases. May end up. Even if the command value multiplied by the coefficient of the input voltage / normalized voltage as in Patent Document 2 is used as the output current command value, the response to the command value is poor and power may be reduced.

  In this embodiment, in order to suppress an excessive decrease in power due to the slow response of the power conversion device 1, the command value of the current is returned in a reverse manner to the direction opposite to the change direction at the time of search. First, in order to search for the maximum power during normal times, the current command value is increased by a certain amount. Eventually, when the input power exceeds the maximum power, the command value is switched to the command value given by the above equation (3), thereby reducing the command value to the command value before the maximum power. According to this control, the actual current effective value catches up with the command value while searching for the maximum power point again. For this reason, the operating point of the power converter device 1 is maintained near the operating point at which the maximum power is obtained.

  Even when the current suddenly drops, the command value of the current is returned in a skipping direction in the direction opposite to the direction of change during the search. When the change in the command value of the current exceeds a predetermined threshold value, the operation is switched to the command value given by the above equation (5), so that the operation is located in the opposite direction with respect to the change direction during the search from the operating point at which the maximum power is obtained. Return to point. According to this control, the actual current effective value catches up with the command value while searching for the maximum power point again. For this reason, the operating point of the power converter device 1 is maintained near the operating point at which the maximum power is obtained.

  Further, in this embodiment, after the command value is reduced in a skipping manner, the power comparison for searching for the maximum power is stopped for a predetermined period, and the search for the maximum power is resumed after the predetermined period. For this reason, it is possible to avoid a malfunction caused by a transient state immediately after the skip change.

  FIG. 6 is a graph with time on the horizontal axis, showing the amount of solar radiation SOL, the power POW extracted from the DC power supply 4, and the efficiency EFF of the power converter 1. At time t21, the solar radiation amount SOL is rapidly decreasing. A broken line OPT indicates an ideal change in the power POW. The solid line EMB shows the change in power POW according to this embodiment. According to this embodiment, a behavior close to the broken line OPT is obtained. In addition, a decrease in efficiency EFF is also suppressed.

  In the drawing, an alternate long and short dash line MF1 indicates a first modification in the case where the skip change by the overshoot return control unit is not employed. In the first modification, every time the power POW exceeds the maximum power, the power POW is excessively reduced. In the drawing, a fine broken line MF2 indicates a second modification when the skip change by the excessive fluctuation return control unit is not adopted. As illustrated, after time t21, the power POW is greatly reduced. After this, it takes a long time to return to the vicinity of the maximum power.

  FIG. 7 is a graph when the solar radiation amount SOL suddenly increases at time t31. According to this embodiment, as shown by the solid line EMB, an output POW close to the broken line OPT is obtained. In addition, a decrease in efficiency EFF is also suppressed.

(Second Embodiment)
This embodiment is a modification based on the preceding embodiment. In the above embodiment, both the inverter circuit 7 and the converter circuit 8 are controlled according to the current IL of the normal coil Ln. Instead, in this embodiment, the inverter circuit 7 is controlled according to the current IL of the normal coil Ln, and the converter circuit 8 is controlled according to the input current Is from the DC power supply 4.

  As illustrated in FIG. 8, the converter control unit 225 inputs the current Is from the current sensor 14. The converter control unit 225 takes the difference between the command value obtained from the maximum power follow-up control and the command value Iref in consideration of the current flowing through the intermediate capacitor and the current Is, and executes the PI control calculation to drive the switch element Qa. The duty ratio Duty is calculated. According to this embodiment, the harmonics of the current supplied to the grid 3 are suppressed by controlling the inverter circuit 7 with the current IL of the normal coil Ln. On the other hand, in the period of | Vac |> Vdc, the responsiveness to the current change from the DC power supply 4 can be improved by controlling the converter circuit 8 with the current Is from the DC power supply 4.

(Third embodiment)
This embodiment is a modification based on the preceding embodiment. In the above embodiment, a skip change is given to the command value based on the above equations (3) and (5). Instead, in this embodiment, a skip change is given to the command value based on a numerical value preset in the map.

  As illustrated in FIG. 9, the maximum power control unit 40 includes a coefficient storage unit 336. The coefficient storage unit 336 stores a numerical value corresponding to the coefficient part in the equations (3) and (5) on a map using the variable in the coefficient part as a parameter for search.

  For example, numerical values corresponding to a coefficient (Vin / Voc + α) and a coefficient (1−Vin / Voc−α) are measured or calculated according to the operating state of the DC power supply 4 and set in advance. The coefficient storage unit 336 stores numerical values corresponding to the coefficient (Vin / Voc + α) and the coefficient (1−Vin / Voc−α) in association with the parameter indicating the operating state of the DC power supply 4. The coefficient storage unit 336 provides a coefficient corresponding to the operating state of the DC power supply 4 so that a command value for giving a skip-like change based on the command value in the previous control cycle and the provided coefficient is obtained. Calculated. For example, the coefficient or the command value for the skip change is stored on the map using the input current Is, the input voltage Vin, the open circuit voltage Voc, and the command value Iref_amp_pre of the previous control cycle as parameters for the search. be able to. In this case, a command value for a coefficient or skip change is set based on the parameter.

(Fourth embodiment)
This embodiment is a modification based on the preceding embodiment. In the above embodiment, after the command value is lowered stepwise, the search for the maximum power is stopped until the power starts to increase again. Instead, in this embodiment, the search for the maximum power is stopped for a predetermined time.

  The maximum power control unit 40 illustrated in FIG. 10 includes a time measurement unit 437. The time measuring unit 437 measures the elapsed time after the command value is lowered stepwise, stops the increase of the command value for searching for the maximum power and the power comparison until the predetermined time elapses, When elapses, the increase of the command value for searching for the maximum power and the power comparison are resumed. The predetermined time can be set using various variables such as a fixed fixed time, a variable time according to disturbance factors such as the operating state of the DC power supply 4, and a predetermined number of control cycles.

(Other embodiments)
In the above embodiment, the IGBT element is exemplified as the switch element. Instead, various power control switching elements such as MOSFET elements may be used.

  In the above embodiment, the high-speed switching control of the inverter circuit 7 and the high-speed switching control of the converter circuit 8 are alternately switched. Instead, a period in which the inverter circuit 7 and the converter circuit 8 are simultaneously subjected to high-speed switching control may be provided. Even in these configurations, only the converter circuit 8 is subjected to high-speed switching control near the peak of AC power, and only the inverter circuit 7 is controlled to high-speed switching near the zero cross of the AC power, so that switching loss is suppressed.

  The invention disclosed herein is not limited to the embodiments for carrying out the invention, and can be implemented with various modifications. The disclosed invention is not limited to the combinations shown in the embodiments, and can be implemented in various combinations. Embodiments can have additional parts. The portion of the embodiment may be omitted. The parts of the embodiments can be replaced or combined with the parts of the other embodiments. The structure, operation, and effect of the embodiment are merely examples. The technical scope of the disclosed invention is not limited to the description of the embodiments. Some technical scope of the disclosed invention is indicated by the description of the claims, and should be understood to include all modifications within the meaning and scope equivalent to the description of the claims. It is.

  For example, the means and functions provided by the control device can be provided by software only, hardware only, or a combination thereof. For example, the control device may be configured by an analog circuit.

1 power converter, 2 power system, 3 systems, 4 DC power supply,
5 AC terminal, 6 DC terminal, 7 inverter circuit, 8 converter circuit,
9, 11 Filter circuit, 10 Relay,
12, 13, 16 voltage sensor, 14, 15 current sensor, 17 control device,
20 current command value creation unit, 21 phase synchronization unit, 22, 23 correction unit,
24 inverter control unit, 25 converter control unit, 26, 27 switching control unit,
28, 29 Dead time generator, 30, 31 Gate driver,
40 Maximum power controller.

Claims (15)

In the power converter (1) for converting DC power supplied from the DC power source (4) to the DC terminal (6) into AC power and supplying the AC power from the AC terminal (5) to the AC power source (3),
An inverter circuit (7) provided between the DC terminal and the AC terminal;
A converter circuit (8) provided between the inverter circuit and the DC terminal and capable of boosting at least DC power and supplying it to the inverter circuit;
A current sensor (14, 15) for detecting a current related to the current at the AC terminal;
A command value creating section (20) for creating a current command value at the AC terminal;
A feedback control unit (21) that converts the voltage supplied from the DC power source into an AC voltage and feedback-controls the inverter circuit and the converter circuit so that the current detected by the current sensor follows the command value. -31),
The command value set by the command value creation unit is changed so that the power output from the DC power supply gradually increases, and the maximum power point at which the power is maximized is searched. A maximum power control unit (40) for returning the command value to a value before exceeding the maximum power point when it is detected that the maximum power point is exceeded and / or when the maximum power point is predicted to be exceeded The power converter characterized by the above-mentioned.   The power conversion device according to claim 1, wherein a change amount of the command value when the command value is returned is larger than a change amount of the command value when the maximum power point is searched. The maximum power control unit is:
A search unit (40a) for gradually changing the command value;
The overshoot return control unit (40b) for returning the command value to a value before exceeding the maximum power point when it is detected that the maximum power point has been exceeded. 2. The power conversion device according to 2. The maximum power control unit is:
A search unit (40a) for gradually changing the command value;
The over-variation return control unit (40c) for returning the command value to a value before the maximum power point is exceeded when the maximum power point is predicted to be exceeded. 2. The power conversion device according to 2. The maximum power control unit is:
A search unit (40a) for gradually changing the command value;
When it is detected that the maximum power point has been exceeded, it is predicted that the overpower return control unit (40b) that returns the command value to the value before exceeding the maximum power point and the maximum power point will be exceeded. The power converter according to claim 1 or 2, further comprising an over-variation return control unit (40c) that returns the command value to a value before exceeding the maximum power point. The maximum power control unit is:
The power conversion device according to any one of claims 1 to 5, further comprising search stop control (40d) for stopping the search for the maximum power point for a predetermined period after the command value is returned. .   The power conversion apparatus according to claim 6, wherein the search stop control stops searching for the maximum power point until input power from the DC power supply increases.   The power conversion apparatus according to claim 6, wherein the search stop control stops searching for the maximum power point until a predetermined time elapses. The feedback control unit includes:
Feedback control for feedback control of the inverter circuit so as to convert a voltage supplied from the converter circuit into an AC voltage (Vac) of the AC power supply, and control the inverter circuit to a state corresponding to the polarity of the AC voltage. A first switching control unit (26) for switching between polarity control;
Direct connection control for controlling the converter circuit to supply a DC voltage supplied to the DC terminal to the inverter circuit, and feedback control for feedback control of the converter circuit to convert the DC voltage to the AC voltage; The power conversion device according to claim 1, further comprising: a second switching control unit (27) that switches between the two.   The feedback control unit feedback-controls only the inverter circuit in a range including a peak of the AC voltage (Vac) of the AC power supply, and only the converter circuit in a range including a zero cross of the AC voltage (Vac) of the AC power supply. Feedback control is performed, The power converter device in any one of Claims 1-9 characterized by the above-mentioned. Furthermore, a normal coil (Ln) provided between the inverter circuit and the AC terminal is provided,
The current sensor (15) detects an output current flowing through the normal coil,
The feedback control of the inverter circuit and / or the feedback control of the converter circuit is configured so that the phase of the output current matches the phase of the AC voltage of the AC power supply based on the output current (IL) flowing through the normal coil. The power conversion device according to claim 1, wherein the power conversion device is executed as follows.   The power converter according to any one of claims 1 to 11, wherein the feedback control of the inverter circuit is hysteresis control that causes a current to follow a command value.   The power converter according to any one of claims 1 to 12, wherein the feedback control of the converter circuit is proportional-integral control that causes a current to follow a command value. The maximum power control unit is:
A determination means (152) for determining that the maximum power point has been exceeded when the input power from the DC power supply has changed from increasing to decreasing;
Based on the command value (Iref_amp_pre) in the past control cycle, the input voltage (Vin), and the open voltage (Voc) of the DC power supply, the overshoot return setting means for setting the value before exceeding the maximum power point ( 156), The power converter device in any one of the Claims 1-13 characterized by the above-mentioned. The maximum power control unit is:
Predicting means (154) for predicting that the maximum power point is exceeded when the difference between the command values during a predetermined control period exceeds a predetermined threshold;
Excessive fluctuation return setting means for setting a value before exceeding the maximum power point based on a command value (Iref_amp_pre), an input voltage (Vin), and an open voltage (Voc) of the DC power supply in a past control cycle (157), The power converter device in any one of Claims 1-14 characterized by the above-mentioned.

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