JP2013138540A - Power conversion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress frequent switching between power input/output that may be caused during constant power charging or the like.SOLUTION: A power conversion circuit 20 transmits and receives power among a power storage device 3, a power generation device 4 and a power system 5. In constant charge control, a control section 23 charges the power storage device 3 with constant electric power, using a power generated by the power generation device 4. If the generated power is insufficient, an insufficient amount of power is input from the power system 5 to the power conversion circuit 20, and if the generated power is surplus, a surplus amount of power is output from the power conversion circuit 20 to the power system 5. When the generated power of the power generation device 4 is almost equal to the constant electric power, power input/output is repeatedly switched between the power conversion circuit 20 and the power system 5. If such switching is detected or predicted, a power point of the power generation device 4 is changed from the maximum power point of an MPPT control to suppress the switching.

Description

  The present invention relates to a power conversion device.

  There is a power conversion device that performs power transmission and reception between a power storage device, a power generation device, and a power system through power conversion. In a conventional method, input / output control of a bidirectional converter connected to an electric power system is performed in order to charge a power storage device with a constant current value (charge command amount) while maximizing the output of a photovoltaic power generation device. And the charging power value is controlled (see, for example, Patent Document 1 below).

JP-A-6-78473

  However, in the above-described conventional method, when the amount of power generated by the photovoltaic power generation apparatus is near the charge command amount, a phenomenon occurs in which power input / output frequently switches between the power conversion circuit including the bidirectional converter and the power system. Yes. Such a phenomenon is undesirable for the stability of the power system. A similar phenomenon can occur when the power storage device is discharged under certain conditions. In addition, when power is output to the power system under certain conditions or when power is input from the power system, frequent switching of input / output between the power conversion circuit and the power storage device may occur as a phenomenon similar to the above phenomenon. . Such a phenomenon is not preferable for the power storage device.

  Then, an object of this invention is to provide the power converter device which contributes to suppression of the above phenomena.

  A first power conversion device according to the present invention includes a power storage side circuit connected to a power storage device capable of charging and discharging, a power generation side circuit connected to a power generation device that generates power and outputs generated power, and a power system. A power conversion circuit having a grid side circuit to be connected, performing power transmission and reception between the power storage device, the power generation device and the power system via power conversion; and controlling the power conversion circuit to transmit the power and A control unit for controlling power reception, wherein the control unit absorbs a deficiency or surplus of the generated power in an input / output of power between the power conversion circuit and the power system, and The power storage device is charged using the generated power under a certain first reference condition, or the load and the secondary connected to the power conversion circuit using the generated power of the power generation device and the discharge power of the power storage device Less battery And performing quantitative control for discharging the power storage device under a constant second reference condition to supply power to the other, and switching the input / output of power between the power conversion circuit and the power system in the quantitative control. The occurrence of the switching when a predetermined number of times is detected within a predetermined time, or based on the amount of generated power of the power generation device or a value corresponding to the generated power amount and the first reference condition or the second reference condition Is predicted, the control unit executes suppression control that suppresses the switching by changing the amount of generated power of the power generation device via a change in the power point of the power generation device.

  A second power conversion device according to the present invention includes a power storage side circuit connected to a power storage device that can be charged and discharged, a power generation side circuit connected to a power generation device that generates power and outputs generated power, and a power system. A power conversion circuit having a grid side circuit to be connected, performing power transmission and reception between the power storage device, the power generation device and the power system via power conversion; and controlling the power conversion circuit to transmit the power and A control unit that controls power reception, wherein the control unit absorbs a shortage or surplus of the generated power by charging or discharging the power storage device, and uses the generated power of the power generation device to absorb the power. Output power from the conversion circuit to the power system under a constant first reference condition, or connected to the power conversion circuit using the generated power and input power from the power system to the power conversion circuit Load and Performing quantitative control for inputting power from the power system to the power conversion circuit under a constant second reference condition so as to supply power to at least one of the secondary batteries, and in the quantitative control, the power conversion circuit and the power storage device When switching between input and output of power between the power generation devices is detected a predetermined number of times or more within a predetermined time, the generated power amount of the power generation device or a value corresponding to the generated power amount and the first reference condition or the second reference condition When the occurrence of the switching is predicted based on the control unit, the control unit executes the suppression control that suppresses the switching by changing the generated power amount of the power generation device through the change of the power point of the power generation device It is characterized by doing.

  ADVANTAGE OF THE INVENTION According to this invention, it is possible to provide the power converter device which contributes to suppression of the above phenomena.

1 is a schematic overall configuration diagram of a power supply system according to a first embodiment of the present invention. It is a figure which shows the electric power input / output state in charge fixed control. It is a figure showing the time transition of electric power generation amount, and is a figure for demonstrating the system side hunting phenomenon. It is a figure showing the time transition of electric power generation amount, and is a figure for demonstrating hunting suppression control. It is a figure for demonstrating the hunting suppression control corresponding to 1st Embodiment of this invention corresponding to charge fixed quantity control. It is a figure for demonstrating the cancellation | release conditions of hunting suppression control in connection with 1st Embodiment of this invention. It is a figure which shows the electric power input / output state in discharge quantitative control. It is a figure for demonstrating the hunting suppression control corresponding to 1st Embodiment of this invention corresponding to discharge quantitative control. It is a figure which shows the electric power input / output state in system | strain output fixed control. It is a figure for demonstrating hunting suppression control corresponding to 1st Embodiment of this invention corresponding to system | strain output fixed control. It is a figure which shows the electric power input / output state in system | strain input fixed control. It is a figure for demonstrating hunting suppression control corresponding to 1st Embodiment of this invention corresponding to system | strain input fixed control. It is an operation | movement flowchart of the power converter device which concerns on 1st Embodiment of this invention. It is a figure which concerns on 2nd Embodiment of this invention and shows the relationship between the output current of a generator, and generated electric power. It is a figure which concerns on 2nd Embodiment of this invention and shows the mode of transmission of an electric current command value. It is a figure for demonstrating the cancellation | release conditions of hunting suppression control concerning 2nd Embodiment of this invention. It is an operation | movement flowchart of the power converter device which concerns on 2nd Embodiment of this invention. It is a schematic whole block diagram of the electric power supply system which concerns on 3rd Embodiment of this invention. It is a figure which concerns on 3rd Embodiment of this invention and shows the electric power input / output state in charge fixed quantity control. It is a figure which concerns on 3rd Embodiment of this invention and shows the electric power input / output state in discharge quantitative control. It is a figure which concerns on 3rd Embodiment of this invention and shows the electric power input / output state in system | strain output fixed control. It is a figure which concerns on 3rd Embodiment of this invention and shows the electric power input / output state in system | strain input fixed control. It is an operation | movement flowchart of the power converter device which concerns on 3rd Embodiment of this invention. It is a partial deformation | transformation block diagram of an electric power supply system.

  Hereinafter, an example of an embodiment of the present invention will be specifically described with reference to the drawings. In each of the drawings to be referred to, the same part is denoted by the same reference numeral, and redundant description regarding the same part is omitted in principle. In this specification, for simplification of description, a symbol or reference that refers to information, signal, physical quantity, state quantity, member, or the like is written to indicate information, signal, physical quantity, state quantity or Names of members and the like may be omitted or abbreviated.

<< First Embodiment >>
A first embodiment of the present invention will be described. FIG. 1 is a schematic overall configuration diagram of a power supply system 1 according to the first embodiment, which can also be referred to as a storage battery system. The power supply system 1 includes all or part of the blocks shown in FIG. For example, the power supply system 1 includes at least a power conversion device 2, a power storage device 3, a power generation device 4, a display unit 9, and an operation unit 10. The display unit 9 and the operation unit 10 may be components of the power conversion device 2. The power storage device 3 is provided with a battery unit (not shown) including one or more secondary batteries. The secondary battery forming the battery unit of the power storage device 3 is any type of secondary battery, such as a lithium ion battery or a nickel metal hydride battery. In the present embodiment, discharging and charging means discharging and charging of the power storage device 3 (more specifically, discharging and charging of each secondary battery in the battery unit of the power storage device 3) unless otherwise specified.

The power conversion device 2 includes a power conversion circuit 20 and a control unit 23. The power conversion circuit 20 includes power terminals T _B1 and T _B2 , includes a power conversion unit 21 </ b> B for a power storage device connected to the power storage device 3, and power terminals T _G1 and T _G2 , and is connected to the power generation device 4. a power conversion unit 21G for power generators has a power terminal _{T S1} and _{T S2,} the common connection and the power conversion unit 21S for lines connected to the power system 5, the power conversion unit 21B, a 21G and 21S Intermediate wiring 22 to be provided.

Power storage device 3 is connected to the power conversion unit 21B by the power terminal T _B1, it is possible to output its discharge power to the power conversion unit 21B, charging when the power conversion unit 21B supplied with the charging power Is done. The power generation device 4 is a power generation device that generates power based on arbitrary energy and outputs generated power, and examples of the energy include natural energy (sunlight, wind power, hydropower, geothermal heat, and the like). Here, it is assumed that the power generation device 4 is a solar power generation device that generates power based on sunlight and outputs generated power. Power generating apparatus 4 is connected to the power conversion unit 21G by the power terminal T _G1, the power generated by the power generator 4 is output to the power conversion unit 21G. The power system 5 is connected to a commercial power source 6 that generates and outputs commercial AC power, and transmits the commercial AC power. Power system 5 is connected to the power conversion unit 21S at the power terminals T _S1, the transmission and receiving between the power conversion unit 21S and power system 5 is performed via the power terminal T _S1. The power terminals T _B2 , T _G2 and T _S2 are commonly connected in the power conversion circuit 20 by the intermediate wiring 22.

The system load 7 and the DC load 8 are, for example, industrial equipment or electrical appliances in factories, stores, buildings, or general houses where the power supply system 1 is introduced. The system load 7 is connected to the power terminal TS ₁ and the power system 5, and the DC load 8 is connected to the intermediate wiring 22. Although all or part of the power output from the power conversion circuit 20 to the power system 5 may be consumed by the system load 7, here, the power from the power conversion circuit 20 to the system load 7 is converted into power conversion. It is considered that it is a part of the output power from the circuit 20 to the power system 5 (that is, the power consumption of the system load 7 is not related to the essence of the present invention, so the following description ignores the presence of the system load 7). ). A power conversion unit may be provided between the DC load 8 and the intermediate wiring 22.

  The power conversion circuit 20 performs power transmission and power reception among the power storage device 3, the power generation device 4, and the power system 5 under the control of the control unit 23, and performs necessary power conversion at the time of power transmission and power reception.

Specifically, power conversion unit 21B converts the DC discharge power received from power storage device 3 via power terminal T _B1 into other DC power, and outputs the other DC power from power terminal _TB2 . charging power output and discharge power conversion, storage device 3 to the another DC power converts the DC power received via the power terminal T _B2 to other DC power as charging power via the power terminal T _B1 Conversion can be performed. The power output from the power terminal _TB2 by the power conversion for discharge is sent to the DC load 8 through the intermediate wiring 22 or sent to the power system 5 through the intermediate wiring 22 and the power conversion unit 21S. In charge power conversion, the DC power by the power conversion unit 21B receives via a power terminal T _B2, the power based on the power generated by the power conversion unit 21G and the intermediate wiring 22 power generator is supplied via the 4, or the power The power is based on the commercial AC power supplied from the power system 5 supplied via the converter 21S and the intermediate wiring 22, or a combination thereof.

Power conversion unit 21G includes a power generator 4 generating a power converter for outputting said other DC power generated power is converted into another DC power of the DC from the power terminal T _G2 received from via the power terminal T _G1 It is feasible. The power output from the power terminal _TG2 by the power conversion for power generation is sent to the DC load 8 via the intermediate wiring 22, sent to the power system 5 via the intermediate wiring 22 and the power conversion unit 21S, or intermediate It is sent to the power storage device 3 via the wiring 22 and the power conversion unit 21B.

The power conversion unit 21S converts the commercial AC power received from the power system 5 through the power terminal T _S1 into DC power, and outputs the DC power from the power terminal T _S2. and the system output power converter to output to the power system 5 the alternating current power via the power terminal T _S1 converts the DC power received via the _S2 to the AC power, is capable of executing. The power output from the power terminal _TS2 by the power conversion for system input is sent to the DC load 8 through the intermediate wiring 22, or is sent to the power storage device 3 through the intermediate wiring 22 and the power conversion unit 21B. In the system output power converter, a DC power by the power conversion unit 21S receives via a power terminal T _S2 is based on the discharge power of the power conversion part 21B and the intermediate wiring 22 supplied the power storage device through a 3 from the power storage device 3 DC power, or DC power based on the generated power of the power generation device 4 supplied from the power generation device 4 via the power conversion unit 21G and the intermediate wiring 22, or a combination thereof.

The control unit 23 acquires input / output power information representing a voltage value, a current value, and a power amount in each unit of the power conversion circuit 20 using various sensors. Specifically, the control unit 23 uses current sensors to measure the current values I _B , I _G , I _S flowing through the power terminals T _B1 , T _G1 , T _S1 , T _B2 , T _G2 , T _S2. , I _BINT , I _GINT , and I _SINT are acquired individually, and voltage values V _B , V _G , and V _S applied to the power terminals T _B1 , T _G1 , and T _S1 are acquired individually using the voltage sensor. . In addition, the control unit 23 acquires a common voltage value V _INT applied to the power terminals T _B2 , T _G2, and T _S2 using a voltage sensor. The input / output power information includes current values I _B , I _G , I _S , I _BINT , I _GINT and I _SINT and voltage values V _B , V _G , V _S and V _INT , and the following formulas (1a) to (1f ) _May also include power quantities P _B , P _G , P _S , P _BINT , P _GINT and P _SINT .
P _B = V _B × I _B (1a)
P _G = V _G × I _G (1b)
P _S = V _S × I _S (1c)
P _BINT = V _INT × I _BINT (1d)
P _GINT = V _INT × I _GINT (1e)
P _SINT = V _INT × I _SINT (1f)

I _B , V _B, and P _B are output to the power storage device 3 from the current value, voltage value, and power amount of the discharge power of the power storage device 3 input from the power storage device 3 to the power conversion unit 21B, or from the power conversion unit 21B, respectively. Current value, voltage value, and electric energy in the charging power of the power storage device 3 to be performed. I _G , V _G, and P _G are a current value, a voltage value, and an electric energy in the generated power of the power generation device 4 input from the power generation device 4 to the power conversion unit 21G, respectively. I _S , V _S, and P _S are current values, voltage values, and amounts of electric power in commercial AC power input from the power system 5 to the power conversion unit 21S, or AC output from the power conversion unit 21S to the power system 5, respectively. It is the current value, voltage value, and electric energy in electric power. I _{BINT and} V _INT are current values and voltage values corresponding to I _B and V _B before or after power conversion in the power conversion unit 21B. I _{GINT and} V _INT are a current value and a voltage value after power conversion in the power conversion unit 21G, corresponding to I _G and V _G. I _{SINT and} V _INT are current values and voltage values before or after power conversion in the power conversion unit 21S, corresponding to I _S and V _S.

  The control unit 23 controls the operation of the power conversion circuit 20 including the operation of each power conversion of the power conversion units 21B, 21G, and 21S based on the input / output power information, and through the control of the operation of the power conversion circuit 20, It controls power transmission and power reception among the power storage device 3, the power generation device 4, and the power system 5. Moreover, the control part 23 can display a desired image | video on the display part 9 by controlling the display part 9 which consists of a liquid crystal display etc. FIG. The operation unit 10 receives various instructions and information from an operator of the power supply system 1 and transmits the instructions and information to the control unit 23. The operator is, for example, an owner, a user, or a maintenance manager (so-called service man) of the power supply system 1. The operation unit 10 can include a touch panel on the display unit 9.

  Note that one or more other power storage devices similar to the power storage device 3 may be further provided in the power supply system 1, and in this case, a power conversion unit for the other one or more power storage devices is added to the power conversion circuit 20. This is preferable (the same applies to other embodiments described later). One or more other power generation devices similar to the power generation device 4 may be further provided in the power supply system 1, and in this case, a power conversion unit for the other one or more power generation devices is added to the power conversion circuit 20. This is preferable (the same applies to other embodiments described later). The control unit 23 may be formed by a plurality of control units (the same applies to other embodiments described later).

  The control unit 23 can execute charge quantitative control, discharge quantitative control, system output quantitative control, and system input quantitative control based on the input / output power information. Hereinafter, these controls will be described individually.

[Charge quantitative control]
First, charge quantitative control will be described. In the charge quantitative control, the control unit 23 controls the power conversion circuit 20 using the generated power of the power generation device 4 so that the power storage device 3 is charged under a constant charge reference condition. In this charge quantitative control, when the amount of power generated by the power generation device 4 is less than the amount of power required for charging the power storage device 3, insufficient power corresponding to the difference between them is input from the power system 5 to the power conversion circuit 20. In addition, when the amount of power generated by the power generation device 4 is larger than the amount of power required for charging the power storage device 3, the surplus power corresponding to the difference between them is output from the power conversion circuit 20 to the power system 5. In addition, the control unit 23 controls the power conversion circuit 20 based on the input / output power information. When considering charge quantitative control, the presence of the DC load 8 is ignored (regardless of the presence or absence of the DC load 8).

The charging reference condition is a condition for designating a charging power amount of the power storage device 3 or a current value and a voltage value depending on the charging power amount, and the control unit 23 can freely determine the charging reference condition. The charging reference condition may be a condition for designating only one of a current value and a voltage value depending on the amount of charging power of the power storage device 3. Here, it is assumed that the charge reference condition specifies that the power storage device 3 is charged with a constant reference power amount for storage (charge / discharge reference power amount) P _BREF .

The control unit 23 can generate a charge command amount P _B ^* that specifies the amount of charge power supplied from the power conversion unit 21B to the power storage device 3 and give the charge command amount P _B ^* to the power conversion unit 21B. The power conversion unit 21B performs power conversion for charging including control of the voltage value V _B and the current value I _B so as to supply the power storage device 3 with the charging power amount specified by the charging command amount P _B ^* . Charging command value P _B ^* may be formed from the voltage command value and the current instruction value specifying a voltage value V _B and the current value I _B. In the charging quantitative control, the control unit 23 can charge the power storage device 3 with a constant reference power amount P _BREF for storage by substituting the value of the reference power amount P _BREF for storage into the charge command amount P _B ^*. .

Now, for the sake of concrete explanation, it is considered that P _BREF = 10, and the unit of numerical values related to an arbitrary electric energy including the charge command amount is unified to be kW · s (kilowatt · second). Think. Further, for simplification of description, it is assumed that the power loss in the power conversion circuit 20 is zero unless otherwise specified (that is, the power conversion efficiency in each power conversion in the power conversion circuit 20 is assumed to be 100%). To do).

In the charge quantitative control, when P _BREF = 10, the control unit 23 can substitute 10 for the charge command amount P _B ^* .
In this case, for example, as shown in FIG. 2A, if the power generation amount of the power generation device 4 is 6 kW · s, the power generation amount of the power generation device 4 is 10 kW · Since it is less than s (= P _B ^* ), the control unit 23 controls the power conversion unit 21S so that the power shortage 4 kW · s corresponding to the difference between them is input from the power system 5 to the power conversion circuit 20. To do.
On the other hand, for example, as shown in FIG. 2B, if the power generation amount of the power generation device 4 is 13 kW · s, the power generation amount of the power generation device 4 is 10 kW · s ( = P _B ^* ), the control unit 23 controls the power conversion unit 21S so that the surplus power amount 3 kW · s corresponding to the difference is output from the power conversion circuit 20 to the power system 5.
In FIG. 3, a solid curve 311 represents a time transition of the amount of power generated by the power generation device 4, the timing t _A1 corresponds to the state of FIG. 2A, and the timing t _A2 corresponds to the state of FIG. .
As described above, in the charging quantitative control, the generated power of the power generation device 4 is used while absorbing the shortage or surplus of the generated power of the power generation device 4 by the power input / output between the power conversion circuit 20 and the power system 5. Then, the power storage device 3 is charged under a certain charging reference condition.

――― System side hunting phenomenon ―――
However, in the charging quantitative control, as shown in FIG. 2 (c), when the generated power amount of the power generation device 4 has a value in the vicinity of the storage reference power amount P _BREF, between the shortage state and the surplus state of the generated power. The switching of power input / output between the power conversion circuit 20 and the power system 5 is repeatedly generated in a relatively short period (see also FIG. 3). Such switching at the time of execution of charge quantitative control is called a system-side hunting phenomenon. When the system-side hunting phenomenon occurs, the power system 5 may become unstable. In particular, when a large number of devices into which the power conversion device 2, the power storage device 3, and the power generation device 4 are connected to the power system 5, when the system-side hunting phenomenon occurs in each device, the stability of the power system 5 May be impaired.

――― System side hunting detection processing HD _1A ―――
During the charge quantitative control execution period, the control unit 23 can detect the occurrence of the system-side hunting phenomenon by performing the system-side hunting detection process HD _1A based on the input / output power information. In mains hunting detection processing HD _1A, the control unit 23, input and output on the basis of the current value I _S or I _SINT included in the power information, the switching of the power input and output between the power conversion unit 21S and power system 5 predetermined time When a predetermined number of times is detected, the system side hunting detection determination is made. The predetermined number of times may be any number of 1 or more, but 2 or more is desirable. The system-side hunting detection determination means that it is determined that the system-side hunting phenomenon is currently occurring.

――― System side hunting prediction processing HP _1A ―――
In addition, during the charge quantitative control execution period, the control unit 23 may predict the occurrence of the system-side hunting phenomenon by performing the system-side hunting prediction process HP _1A based on the input / output power information (that is, the future It is also possible to predict whether a system-side hunting phenomenon is likely to occur).
For example, the mains hunting prediction process _{HP 1A,} the control unit 23, based on the current value _I on the basis of the _G and the voltage value _{V G} (i.e., based on the generated power quantity _{P G)} or a current value _{I GINT} and voltage _{V INT} generator _'seeking, charged electrical energy P _B' charging power amount P _B corresponding to the amount of power P _G is compared with the energy storage for the reference power P _BREF that is defined by the charge reference conditions. Then, when the absolute value | P _B '−P _BREF | of the difference is equal to or less than a predetermined positive threshold value TH _1A , or the absolute value | P _B ' −P _BREF | _When a state of _1A or less is continuously observed for a predetermined time or more, a system-side hunting prediction determination is made. The system-side hunting prediction determination means that it is determined that a system-side hunting phenomenon is likely to occur in the near future. The corresponding charge power amount P _{B 'in} generated power quantity P _G, refers to the charging electric energy for power storage device 3 based on the generated power quantity P _G of the generator 4, the power conversion unit 21G and 21B power conversion efficiency and product The charging power amount P _B ′ can be obtained using “I _G × V _G ” or using the power conversion efficiency of the power conversion unit 21 _< / _b> B and the product “I _GINT × V _INT ”. Assuming zero power loss of the power converter 21G and _21B, a _P B '= P _G.

――― Hunting suppression control CNT _1A ―――
When the system-side hunting detection determination or the system-side hunting prediction determination is made during the charge quantitative control execution period, the control unit 23 sets the charge power amount of the power storage device 3 to the power storage reference power amount P according to the charge reference condition. Hunting suppression control CNT _1A changed from _BREF is executed. In the hunting suppression control CNT _1A , the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 is increased by changing the charging power amount, thereby suppressing the system-side hunting phenomenon. The input / output power amount between the power conversion circuit 20 and the power system 5 indicates the input power amount from the power system 5 to the power conversion circuit 20 or the output power amount from the power conversion circuit 20 to the power system 5. The timing at which the system-side hunting detection determination or the system-side hunting prediction determination is performed is also referred to as a system-side hunting recognition timing. The control unit 23 can start the suppression control CNT _1A from the system-side hunting recognition timing (the same applies to the hunting suppression control CNT _1B described later). The suppression control CNT _1A is a control performed in the charge quantitative control, and the content of the charge quantitative control is corrected during the execution period of the suppression control CNT _1A .

A first implementation example of the suppression control CNT _1A will be described. Prior to the system-side hunting recognition timing, as described above, the control unit 23 substitutes the power storage reference power amount P _BREF for the charge command amount P _B ^* , whereby the charge power amount of the power storage device 3 is determined. This corresponds to the electric energy P _BREF (= 10) (see FIGS. 2A, 2B, and 2C). However, when the system-side hunting detection determination or the system-side hunting prediction determination is made, in the first implementation example of the suppression control CNT _1A , the control unit 23 stores the charge command amount P _B ^* by a predetermined amount ΔP _B ^* . Increase or decrease from the reference power amount P _BREF (that is, change the charge command amount P _B ^* with reference to before the system-side hunting recognition timing). Here, “ΔP _B ^* > 0”. The predetermined amount ΔP _B ^* may be an amount (for example, the product of P _BREF and the coefficient k) that depends on the reference power amount P _BREF for power storage.

FIG. 4 shows an example when the charge command amount P _B ^* is decreased. A broken broken line 312 represents a time transition of the charge command amount P _B ^* , and a timing t _A3 is a system-side hunting recognition timing. FIG. 5A corresponds to immediately after the timing t _A3 , and when the charge command amount P _B ^* is reduced to 8 by the suppression control CNT _1A when the power generation amount of the power generation device 4 is 10 kW · s. Indicates the power input / output state. In this state, the control unit 23 controls the power conversion unit 21 </ b> S so that the surplus power amount 2 kW · s corresponding to the difference is output from the power conversion circuit 20 to the power system 5. That is, the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 based on the pre-decrease (based on the state of FIG. 2C) due to the decrease in the charged power amount by the suppression control CNT _1A . Will increase. As a result, the system side hunting phenomenon is appropriately suppressed. The same is true when the charge command amount P _B ^* is increased from the power storage reference power amount P _BREF .

A second implementation example of the suppression control CNT _1A will be described. Although not particularly conscious in the above description, the control unit 23 generates a system input / output command amount P _S ^* that specifies an input / output power amount between the power conversion circuit 20 and the power system 5 to generate a power conversion unit 21S. Thus, the input / output power amount can be controlled. The power conversion unit 21S has a voltage value V _S and a current value I so that power input / output having a power amount matching the system input / output command amount P _S ^* is performed between the power conversion circuit 20 and the power system 5. performing system input power converter or channel output power converter including a control of the _S. Command value P _S ^* may be formed from the voltage command value and the current instruction value specifying a voltage value V _S and the current value I _S. When mains hunting detection determination or mains hunting prediction judgment is made, the control unit 23 to perform the second implementation of suppression control CNT _1A, based on the pre-system side hunting cognitive timing, system output command amount P _S ^The suppression control CNT ₁ </ b ^{> A} is realized by changing ^* by a predetermined amount ΔP _S ^* and assigning the change to the change in the charge power amount of the power storage device 3. Here, “ΔP _S ^* > 0”. The predetermined amount ΔP _S ^* may be an amount (for example, the product of P _BREF and the coefficient k) that depends on the reference power amount P _BREF for power storage.

For example, in the state of FIG. 2C, that is, the state where the amount of power generated by the power generation device 4 and the amount of charge power of the power storage device 3 are both 10 kW · s, the command amount P _S ^* is set as shown in FIG. This corresponds to the state where zero is substituted. In this state, when the system-side hunting detection determination or the system-side hunting prediction determination is made, the control unit 23 executes, for example, suppression control CNT _1A that changes the system input / output command amount P _S ^* from zero to 2. (Here, a state where P _S ^* > 0 corresponds to a power output state from the power conversion unit 21S to the power system 5). In the second implementation example of the suppression control CNT _1A , the control unit 23 gives priority to the system input / output command amount P _S ^* over the charge command amount P _B ^* , or gives the charge command amount P _B ^* to the power conversion unit 21B. Don't give. In any case, in the suppression control CNT _1A , the control unit 23 charges the power storage device 3 with the surplus power determined by the power generation amount of the power generation device 4 and the input / output power amount between the power conversion circuit 20 and the power system 5. The power converter 21B is controlled as described above. As a result, as illustrated in FIG. 5C, the charging power is directed to the power storage device 3 for only 8 kW · s. This state is equivalent to the state shown in FIG. FIG. 5C is an example when the command amount P _S ^* is changed so that power output from the power conversion circuit 20 to the power system 5 is performed. The command amount P _S ^* may be changed so that electric power is input. In this case, the charge power amount of the power storage device 3 increases from 10 kW · s.

In the first implementation example of the suppression control CNT _1A , the charge power amount is directly controlled by controlling the charge command amount P _B ^* , whereas in the second implementation example of the suppression control CNT _1A , the system input / output command amount P _The charge power amount is indirectly controlled by the control of _S ^* (by control of the input / output power amount between the power conversion circuit 20 and the power system 5).

--- cancellation determination processing _J 1A corresponding to suppression control _{CNT 1A} ---
Control unit 23, during the execution period of the suppression control CNT _1A, via the judging success or failure of the predetermined release condition, performing the determining cancellation determination processing J _1A whether to cancel the execution of the suppression control CNT _1A Can do. For example, the release determination processing _{J 1A,} the control unit 23, based on the current value _I on the basis of the _G and the voltage value _{V G} (i.e., based on the generated power quantity _{P G)} or a current value _{I GINT} and the voltage value _{V INT,} above Charge electric energy P _B ′ is obtained, and the charged electric energy P _B ′ is compared with the reference electric energy P _BREF for storage specified in the charging reference condition (as described above, the power loss amount of power conversion Is considered as zero, P _B ′ = P _G ). In the determination process J _1A , the control unit 23 determines that the absolute value | P _B '−P _BREF | of the difference is equal to or greater than a predetermined positive threshold value TH _2A (see FIG. _6A ), or , When the state in which the absolute value | P _B '−P _BREF | is _{equal to} or greater than the threshold value TH _2A is continuously observed for a predetermined time or more, or the state in which the absolute value | P _B ' −P _BREF | is positive. When the observation is continued for a predetermined time or longer (see FIG. 6B; _TL corresponds to the predetermined time in FIG. 6B), it is determined that the release condition in the determination process J _1A is satisfied (suppression control). Even if the execution of the CNT _1A is canceled, it is determined that the system-side hunting phenomenon does not occur or hardly occurs), and the execution of the suppression control CNT _1A is canceled. By canceling the execution of the suppression control CNT _1A , the charge power amount of the power storage device 3 returns to the power storage reference power amount P _BREF (= 10).

Or, for example, when the charge command amount P _B ^* is decreased from the storage reference power amount P _BREF by the predetermined amount ΔP _B ^* by the suppression control CNT _1A , the control unit 23 determines the difference (P _B ′ −P _B ^* ) _May be set as a determination target, and when the charge control amount P _B ^* is increased from the storage reference power amount P _BREF by the predetermined amount ΔP _B ^* by the suppression control CNT _1A , the control unit 23 determines the difference. (P _B ^* −P _B ′) may be set as a determination target. In the determination target, P _B ^* may be replaced with the actually measured charging power amount P _B (that is, I _B × V _B ). Then, when the determination target is equal to or greater than a predetermined positive threshold TH _2A ′, or when a state where the determination target is equal to or greater than the threshold TH _2A ′ is continuously observed for a predetermined time or longer, the control unit 23 The execution of the suppression control CNT _1A may be canceled by determining that the cancellation condition in the determination process J _1A is satisfied (TH _2A '> ΔP _B ^* ).

[Discharge quantitative control]
Next, discharge quantitative control will be described. The control unit 23 can supply power to the DC load 8 using the generated power of the power generation device 4 and the discharge power of the power storage device 3, but in the discharge quantitative control, at this time, the power storage device 3 has a constant discharge reference. The power conversion circuit 20 is controlled so as to be discharged under conditions. In this discharge quantitative control, when the total power amount of the power generation amount of the power generation device 4 and the discharge power amount of the power storage device 3 is smaller than the power consumption amount of the DC load 8, the shortage power corresponding to the difference between them is the power system 5 To the power conversion circuit 20 and when the total power amount is larger than the power consumption amount of the DC load 8, surplus power corresponding to the difference between them is output from the power conversion circuit 20 to the power system 5. As described above, the control unit 23 controls the power conversion circuit 20 based on the input / output power information.

The discharge reference condition is a condition for designating a discharge power amount of the power storage device 3 or a current value and a voltage value depending on the discharge power amount, and the control unit 23 can freely determine the discharge reference condition. The discharge reference condition may be a condition for designating only one of a current value and a voltage value depending on the amount of discharge power of the power storage device 3. Here, it is assumed that the discharge reference condition specifies that the power storage device 3 is discharged with a constant reference power amount P _BREF for power storage.

When considering discharge quantitative control, the above-mentioned symbol P _B ^* is referred to as a symbol of the discharge command amount. The control unit 23 can generate a discharge command amount P _B ^* that specifies the amount of discharge power supplied from the power storage device 3 to the power conversion unit 21B and give the generated discharge command amount P _B ^* to the power conversion unit 21B. Power conversion unit 21B, as the discharge amount of power specified by the discharge command amount P _B ^* is output from the power storage device 3, the discharging power conversion, including the control of the voltage value V _B and the current value I _B Do. Discharge command amount P _B ^* may be formed from the voltage command value and the current instruction value specifying a voltage value V _B and the current value I _B. In the discharge quantitative control, the control unit 23 can _cause the power storage device 3 to discharge with a constant reference power amount P _BREF for storage by substituting the value of the reference power amount P _BREF for storage into the discharge command amount P _B ^*. .

Again, for the sake of concrete explanation, consider that P _BREF = 10. Further, although the power consumption of the DC load 8 can fluctuate, it is assumed here that the power consumption of the DC load 8 is always 20 kW · s. When P _BREF = 10 in the discharge quantitative control, the control unit 23 can substitute 10 for the discharge command amount P _B ^* , and the discharge power amount becomes 10 kW · s.
In this case, for example, as shown in FIG. 7A, if the power generation amount of the power generation device 4 is 6 kW · s, the total power amount is less than the power consumption amount 20 kW · s of the DC load 8, The control unit 23 controls the power conversion unit 21 </ b> S so that the insufficient power amount 4 kW · s corresponding to the difference is input from the power system 5 to the power conversion circuit 20.
On the other hand, for example, as shown in FIG. 7 (b), if the power generation amount of the power generation device 4 is 13 kW · s, the total power amount is larger than the power consumption amount 20 kW · s of the DC load 8; The control unit 23 controls the power conversion unit 21 </ b> S so that the surplus power amount 3 kW · s corresponding to the difference is output from the power conversion circuit 20 to the power system 5.
As described above, in the discharge quantitative control, the generated power and power storage of the power generator 4 are absorbed while the shortage or surplus of the generated power of the power generator 4 is absorbed by the power input / output between the power conversion circuit 20 and the power system 5. In order to supply power to the DC load 8 using the discharge power of the device 3, the power storage device 3 is discharged under a certain discharge reference condition.

  However, in the discharge quantitative control, as shown in FIG. 7C, when the total electric power has a value in the vicinity of the electric power consumption of the DC load 8, the change between the insufficient state and the surplus state of the generated power is performed. As a result, the switching of power input / output between the power conversion circuit 20 and the power system 5 repeatedly occurs in a relatively short period of time. Such switching at the time of execution of discharge quantitative control is also a system-side hunting phenomenon.

――― System side hunting detection processing HD _1B ―――
During the execution period of the discharge quantitative control, the control unit 23 can execute the system-side hunting detection process HD _1B . The system side hunting detection process HD _1B is the same as the system side hunting detection process HD _1A .

――― System side hunting prediction processing HP _1B ―――
Further, during the discharge quantitative control execution period, the control unit 23 may predict the occurrence of the system side hunting phenomenon by performing the system side hunting prediction process HP _1B based on the input / output power information.
For example, the mains hunting prediction process _{HP 1B,} the control unit 23, based on the current value _I on the basis of the _G and the voltage value _{V G} (i.e., based on the generated power quantity _{P G)} or a current value _{I GINT} and voltage _{V INT} generator 'seeking, electric energy _{P G'} power amount _{P G} corresponding to the amount of power _{P G} total power amount of the power storage for the reference power _{P BREF} that is defined by the discharge reference condition _{(P G '+ P BREF)} Is compared with the power consumption of the DC load 8. The amount of power P _G ′ is the amount of power output from the power converter 21G, and can be considered to be equal to the product (I _GINT × V _INT ). In addition, here, it is considered that the discharge power of the power storage reference power amount P _BREF (= 10) is supplied to the DC load 8 from the power conversion unit 21B by the discharge quantitative control. Therefore, the total power amount (P _G ′ + P _BREF ) is the total power amount output from the power conversion units 21G and 21B based on the generated power of the power generation device 4 and the discharge power of the power storage device 3 (power conversion circuit 20 If we ignore the power loss of P _G ′ + P _BREF = P _G + P _B ). Then, the control unit 23 determines _{whether or not} the absolute value of the difference between the total electric energy (P _G ′ + P _BREF ) and the electric power consumption of the DC load 8 is equal to or less than a predetermined positive threshold TH _3A. There when the state is less than the threshold value TH _3A was observed continuously for a predetermined time or more, forming a prediction judgment mains hunting.

――― Hunting suppression control CNT _1B ―――
When the system-side hunting detection determination or the system-side hunting prediction determination is made during the execution of the discharge quantitative control, the control unit 23 sets the discharge power amount of the power storage device 3 according to the discharge reference condition P Hunting suppression control CNT _1B changed from _BREF is executed. In the hunting suppression control CNT _1B , the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 is increased by changing the discharge power amount, thereby suppressing the system-side hunting phenomenon. The suppression control CNT _1B is control performed in the discharge quantitative control, and correction is made to the content of the discharge quantitative control during the execution period of the suppression control CNT _1B .

A first implementation example of the suppression control CNT _1B will be described. Before the system-side hunting recognition timing, as described above, the control unit 23 substitutes the power storage reference power amount P _BREF for the discharge command amount P _B ^* , whereby the discharge power amount of the power storage device 3 is determined as the power storage reference power. It corresponds to the electric energy P _BREF (= 10) (see FIGS. 7A, 7B, and 7C). However, when the system-side hunting detection determination or the system-side hunting prediction determination is made, in the first implementation example of the suppression control CNT _1B , the control unit 23 stores the discharge command amount P _B ^* by a predetermined amount ΔP _B ^* . Increase or decrease from the reference power amount P _BREF (that is, change the discharge command amount P _B ^* with reference to before the system-side hunting recognition timing).

FIG. 8A shows a power input / output state when the discharge command amount P _B ^* is increased by 2 from the power storage reference power amount P _BREF (= 10). In this state, since the surplus power amount 2 kW · s is included in the generated power amount of the power generation device 4 and the discharge power amount of the power storage device 3, the control unit 23 determines that the surplus power amount 2 kW · s is the power conversion circuit 20. The power conversion unit 21S is controlled so as to be output to the power system 5. That is, the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 with the increase in the discharge power amount by the suppression control CNT _1B as a reference (based on the state of FIG. 7C). Will increase. As a result, the system side hunting phenomenon is appropriately suppressed. The same _applies to the case where the discharge command amount P _B ^* is decreased from the reference power amount P _BREF for power storage.

A second implementation example of the suppression control CNT _1B will be described. When mains hunting detection determination or mains hunting prediction judgment is made, the control unit 23 to perform the second implementation of suppression control CNT _1B, based on the pre-system side hunting cognitive timing, system output command amount P _S ^The suppression control CNT _1B is realized by changing ^* by a predetermined amount ΔP _S ^* and assigning the change to the change in the amount of discharge power of the power storage device 3.

For example, the state of FIG. 7C, that is, the state in which the total amount of power generated by the power generation device 4 and the amount of discharge power of the power storage device 3 matches the power consumption of the DC load 8 is shown in FIG. As shown, this corresponds to a state in which zero is substituted for the command amount P _S ^* . In this state, when the system-side hunting detection determination or the system-side hunting prediction determination is made, the control unit 23 executes, for example, the suppression control CNT _1B that changes the system input / output command amount P _S ^* from zero to 2. (Here, a state where P _S ^* > 0 corresponds to a power output state from the power conversion unit 21S to the power system 5). In the second implementation example of the suppression control CNT _1B , the control unit 23 prioritizes the system input / output command amount P _S ^* over the discharge command amount P _B ^* , or gives the discharge command amount P _B ^* to the power conversion unit 21B. Don't give. In any case, in the suppression control CNT _1B , the control unit 23 is determined by the amount of power generated by the power generation device 4, the amount of input / output power between the power conversion circuit 20 and the power system 5, and the power consumption of the DC load 8. Then, the power conversion unit 21B is controlled so that the insufficient power (the insufficient power to be supplied to the DC load 8) is discharged from the power storage device 3. As a result, as shown in FIG. 8C, discharging power of 12 W · s is output from the power storage device 3. This state is equivalent to the state shown in FIG. FIG. 8C is an example when the command amount P _S ^* is changed so that power output from the power conversion circuit 20 to the power system 5 is performed. The command amount P _S ^* may be changed so that electric power is input. In that case, the discharge power amount of the power storage device 3 decreases from 10 kW · s.

In the first implementation example of the suppression control CNT _1B , the discharge power amount is directly controlled by controlling the discharge command amount P _B ^* , whereas in the second implementation example of the suppression control CNT _1B , the system input / output command amount P _The discharge power amount is indirectly controlled by the control of _S ^* (by controlling the input / output power amount between the power conversion circuit 20 and the power system 5).

--- cancellation determination processing _J 1B corresponding to suppression control _{CNT 1B} ---
Control unit 23, during the execution period of the suppression control CNT _1B, through the success determination of a predetermined cancellation condition, performing the cancellation determination processing J _1B determines whether to cancel the execution of the suppression control CNT _1B Can do. For example, the release determination processing _{J 1B,} the control unit 23 'obtains the _{(+ P BREF,} the total amount of power _{(P G} total electric power amount by the method described above _{P G)'} power consumption _{+ P BREF)} and the DC load 8 (The power loss of the power conversion circuit 20 is ignored, P _G '+ P _BREF = P _G + P _B ). In the determination process J _1B , the control unit 23 continues the state where the absolute value is equal to or greater than the predetermined positive threshold TH _4A or the absolute value is equal to or greater than the threshold TH _4A for a predetermined time. When observed, or when a state in which the absolute value is positive is continuously observed for a predetermined time or more, it is determined that the release condition in the determination process J _1B is satisfied (execution of the suppression control CNT _1B is performed). It is determined that the system-side hunting phenomenon does not occur or is unlikely to occur even if it is canceled), and the execution of the suppression control CNT _1B is canceled. By canceling the execution of the suppression control CNT _1B , the discharge power amount of the power storage device 3 returns to the power storage reference power amount P _BREF (= 10).

Alternatively, for example, when the suppression control _{CNT 1B} has reduced the discharge command amount _P ^{B *} from the predetermined amount [Delta] P _B ^* only energy storage for the reference power _{P BREF,} the control unit 23 the difference _(P C8 - _{(P G} ' + P _B ^* )) may be set as a determination target, and control is performed when the discharge command amount P _B ^* is increased from the storage reference power amount P _BREF by a predetermined amount ΔP _B ^* by the suppression control CNT _1B. The unit 23 may set the difference ((P _G '+ P _B ^* ) − P _C8 ) as a determination target. In the determination target, P _B ^* may be replaced with the actually measured discharge power amount P _B (that is, I _B × V _B ). _PC 8 represents the power consumption of the DC load 8. Then, when the determination target is equal to or greater than a predetermined positive threshold TH _4A ′, or when a state where the determination target is equal to or greater than the threshold TH _4A ′ is continuously observed for a predetermined time or longer, the control unit 23 The execution of the suppression control CNT _1B may be canceled by determining that the cancellation condition in the determination process J _1B is satisfied (TH _4A '> ΔP _B ^* ).

[System output quantitative control]
Next, system output quantitative control will be described. In the system output quantitative control, the control unit 23 controls the power conversion circuit 20 so that power is output from the power conversion circuit 20 to the power system 5 under a certain system output reference condition using the generated power of the power generation device 4. To do. In this grid output quantitative control, when the amount of power generated by the power generation device 4 is less than the amount of power required for output to the power grid 5, the insufficient power corresponding to the difference between them is discharged from the power storage device 3. In addition, when the amount of power generated by the power generation device 4 is larger than the amount of power required for output to the power system 5, the input / output power information is set so that the power storage device 3 is charged with surplus power corresponding to the difference between them. Based on the above, the control unit 23 controls the power conversion circuit 20. When system output quantitative control is considered, the presence of the DC load 8 is ignored (regardless of the presence or absence of the DC load 8).

The system output reference condition is a condition for designating an output power amount from the power conversion circuit 20 to the power system 5 or a current value and a voltage value depending on the output power amount, and the control unit 23 freely sets the system output reference condition. Can be determined. The system output reference condition may be a condition for designating only one of the current value and the voltage value depending on the output power amount from the power conversion circuit 20 to the power system 5. Here, it is assumed that the system output reference condition specifies that the power conversion circuit 20 outputs power to the power system 5 with a constant system reference power amount (system input / output reference power amount) P _SREF .

In the system output quantitative control, the flow of power between the power conversion circuit 20 and the power system 5 is limited from the power conversion circuit 20 to the power system 5, so the system input / output command amount P _S ^{* is changed} to the system output command amount P _S ^*. Also say. In the system output quantitative control, the control unit 23 gives the system output command amount P _S ^* into which the value of the system reference power amount P _SREF is substituted to the power conversion unit 21S, so that the system is transferred from the power conversion unit 21S to the power system 5. The power of the reference power amount P _SREF can be output.

Now, for the sake of concrete explanation, consider that P _SREF = 10. In the system output quantitative control, when P _SREF = 10, the control unit 23 can substitute 10 for the system output command amount P _S ^* .
In this case, for example, as shown in FIG. 9A, if the power generation amount of the power generation device 4 is 6 kW · s, the power generation amount of the power generation device 4 is 10 kW necessary for output to the power system 5. · s (= P S ^_*) for less than, deficient power amount 4 kW · s which corresponds to the difference thereof as discharged from the power storage device 3, the control unit 23 controls the power conversion unit 21B.
On the other hand, for example, as shown in FIG. 9B, if the amount of power generated by the power generator 4 is 13 kW · s, the amount of power generated by the power generator 4 is 10 kW · s required for output to the power system 5. since (= P S ^_*) greater than, as power storage device 3 is charged by excess power amount 3 kW · s corresponding to their difference, the control unit 23 controls the power conversion unit 21B.
Thus, in the system output quantitative control, the power conversion circuit 20 uses the generated power of the power generation device 4 while absorbing the shortage or surplus of the generated power of the power generation device 4 by charging or discharging the power storage device 3. Electric power is output to the electric power system 5 under a certain system output reference condition.

――― Storage hunting phenomenon ――――
However, in the grid output quantitative control, as shown in FIG. 9C, when the generated power amount of the power generator 4 has a value near the grid reference power amount P _SREF , the generated power is in shortage and surplus state. Switching between input and output of power between the power conversion circuit 20 and the power storage device 3 (switching between charging and discharging) occurs repeatedly in a relatively short period of time. Such switching at the time of executing the system output quantitative control is called a power storage side hunting phenomenon. The switching associated with the power storage side hunting phenomenon is not preferable for the power storage device 3 and can promote deterioration of the power storage device 3.

――― Storage hunting detection processing HD _1C ―――
During the execution period of the system output quantitative control, the control unit 23 can detect the occurrence of the power storage side hunting phenomenon by performing the power storage side hunting detection process HD _1C based on the input / output power information. The electric storage side hunting detection processing HD _1C, the control unit 23, input and output on the basis of the current value I _B or I _BINT included in the power information, the switching of the power input and output between the power conversion unit 21B and the power storage device 3 a predetermined time When it is detected a predetermined number of times or more, a storage side hunting detection determination is made. The predetermined number of times may be any number of 1 or more, but 2 or more is desirable. The storage-side hunting detection determination means that it is determined that the storage-side hunting phenomenon is currently occurring.

――― Storage side hunting prediction processing HP _1C ―――
In addition, during the execution period of the system output quantitative control, the control unit 23 may predict the occurrence of the power storage side hunting phenomenon by performing the power storage side hunting prediction process HP _1C based on the input / output power information (that is, It may be predicted whether the storage-side hunting phenomenon is likely to occur in the future).
For example, in the power storage-side hunting prediction process HP _1C , the control unit 23 generates power based on the current value I _G and the voltage value V _G (that is, based on the generated power amount P _G ) or based on the current value I _GINT and the voltage value V _{INT. 'seeking,} channel output power amount P _S' channel output power amount P _S corresponding to the amount of power P _G is compared with the system for the reference power P _SREF which is defined by the system output reference conditions. Then, when the absolute value | P _S '-P _SREF | of the difference is equal to or less than a predetermined positive threshold value TH _5A , or the absolute value | P _S ' -P _SREF | _When the state of _{5 A} or less is continuously observed for a predetermined time or more, the storage side hunting prediction determination is made. The storage side hunting prediction determination means that it is determined that the storage side hunting phenomenon is likely to occur in the near future. The grid output power amount P _S ′ corresponding to the generated power amount P _G indicates the output power amount for the power system 5 based on the generated power amount P _G of the power generation device 4, and the power conversion efficiency of the power conversion units 21G and 21S The system output power P _S ′ can be obtained using the product “I _G × V _G ” or using the power conversion efficiency of the power conversion unit 21 _< / _b> S and the product “I _GINT × V _INT ”. Assuming zero power loss of the power converter 21G and _21S, a _P S '= P _G.

――― Hunting suppression control CNT _1C ―――
When the storage-side hunting detection determination or the storage-side hunting prediction determination is made during the execution period of the system output quantitative control, the control unit 23 sets the output power amount from the power conversion circuit 20 to the power system 5 as the system output reference condition. The hunting suppression control CNT _1C that changes from the reference power amount P _SREF for the system is executed. In the hunting suppression control CNT _1C , the absolute value of the input / output power amount between the power conversion circuit 20 and the power storage device 3 is increased by changing the output power amount from the power conversion circuit 20 to the power system 5, thereby storing power. Suppresses side hunting phenomenon. The input / output power amount between the power conversion circuit 20 and the power storage device 3 is an input power amount from the power storage device 3 to the power conversion circuit 20 (that is, a discharge power amount of the power storage device 3) or from the power conversion circuit 20 to the power storage device 3. Output electric energy (that is, charging electric energy of the power storage device 3). The timing at which the storage-side hunting detection determination or the storage-side hunting prediction determination is made is also referred to as a storage-side hunting recognition timing. The control unit 23 can start the suppression control CNT _1C from the storage side hunting recognition timing (the same applies to the hunting suppression control CNT _1D described later). The suppression control CNT _1C is control performed in the system output quantitative control, and the contents of the system output quantitative control are corrected during the execution period of the suppression control CNT _1C .

  In the following description, the output power or output power amount from the power conversion circuit 20 to the power system 5 may be simply referred to as output power or output power amount to the power system 5. The input power or input power amount to 20 may be simply referred to as input power or input power amount from the power system 5.

A first implementation example of the suppression control CNT _1C will be described. Before power storage side hunting cognitive timing, as described above, the control unit 23 is by substituting a system for reference power P _SREF to the system output command value P _S ^*, whereby the output power of the power system 5 strains This is consistent with the reference power amount P _SREF (= 10) (see FIGS. 9A, 9B, and 9C). However, when the storage-side hunting detection determination or the storage-side hunting prediction determination is made, in the first implementation example of the suppression control CNT _1C , the control unit 23 reduces the system output command amount P _S ^* to the system by a predetermined amount ΔP _S ^*. The reference power amount P _{SREF is} increased or decreased (that is, the system output command amount P _S ^* is changed with reference to the power storage side hunting recognition timing). Here, “ΔP _S ^* > 0”. The predetermined amount ΔP _S ^* may be an amount that depends on the grid reference power amount P _SREF (for example, the product of P _SREF and the coefficient k).

FIG. 10A shows the power input / output state when the system output command amount P _S ^* is increased by 2 from the system reference power amount P _SREF (= 10). In this state, the control unit 23, the power conversion unit 21B as insufficient amount of power 2 kW · s which corresponds to the difference between the generated power and the system output instruction value P _S ^* of the generator 4 is discharged from the power storage device 3 To control. That is, the input / output between the power conversion circuit 20 and the power storage device 3 based on the increase in the amount of output power to the power system 5 by the suppression control CNT _1C (based on the state of FIG. 9C) before the increase. The absolute value of the electric energy increases. As a result, the power storage side hunting phenomenon is appropriately suppressed. The same applies when the system output command amount P _S ^* is reduced from the system reference power amount P _SREF .

A second implementation example of the suppression control CNT _1C will be described. When the storage-side hunting detection determination or the storage-side hunting prediction determination is made, the control unit 23 that performs the second implementation example of the suppression control CNT _1C uses the charging command to the power conversion unit 21B with reference to the timing before the storage-side hunting recognition timing. The suppression control CNT _1C is realized by changing the amount or the discharge command amount P _B ^* by a predetermined amount ΔP _B ^* and assigning the change amount to the change in the output power amount from the power conversion circuit 20 to the power system 5. Here, “ΔP _B ^* > 0”. The predetermined amount ΔP _B ^* may be an amount that depends on the grid reference power amount P _SREF , for example, the product of P _SREF and the coefficient k.

For example, in the state of FIG. 9C, that is, the state in which the amount of power generated by the power generator 4 and the amount of power output to the power system 5 are both 10 kW · s, the command amount (charge or This corresponds to a state where zero is substituted for the discharge command amount) P _B ^* . In this state, when the storage-side hunting detection determination or the storage-side hunting prediction determination is made, the control unit 23 executes, for example, suppression control CNT _1C that changes the discharge command amount P _B ^* from zero to 2. Can do. In the second implementation example of the suppression control CNT _1C , the control unit 23 prioritizes the discharge command amount (or charge command amount) P _B ^* over the system output command amount P _S ^* , or the system output command amount P _S ^* Is not given to the power converter 21S. In any case, in the suppression control CNT _1C , the control unit 23 controls the power conversion unit 21S so that the total power amount of the power generation amount of the power generation device 4 and the discharge power of the power storage device 3 is output to the power system 5. . As a result, as shown in FIG. 10C, 12 kW · s of power is output from the power conversion circuit 20 to the power system 5. This state is equivalent to the state shown in FIG. FIG. 10 (c) is an example of when the discharge of the power storage device 3 has changed the command amount P _B ^* as is done, changes the command value P _B ^* as charging of the electricity storage device 3 is carried out In this case, the output power amount to the power system 5 is reduced from 10 kW · s.

In a first implementation of suppression control CNT _1C, whereas controls directly the output power of the power system 5 by the control of the system output command value P _S ^*, in the second implementation of suppression control CNT _1C, The output power amount to the power system 5 is indirectly controlled by controlling the charge or discharge command amount P _B ^* (by controlling the input / output power amount between the power conversion circuit 20 and the power storage device 3).

――― Release enable / disable judgment processing corresponding to suppression control CNT _1C J _1C ―――
Control unit 23, during the execution period of the suppression control CNT _1C, through the success determination of a predetermined cancellation condition, performing the determining cancellation determination processing J _1C whether to cancel the execution of the suppression control CNT _1C Can do. For example, in the cancelability determination process _J1C , the control unit 23 performs the above-described processing based on the current value I _G and the voltage value V _G (that is, based on the generated power amount P _G ) or based on the current value I _GINT and the voltage value V _{INT 'seeking,} channel output power amount P _S' of the system output electric energy P _S is compared with the system for the reference power P _SREF which is defined by the system output reference conditions (power conversion unit 21G and 21S power neglecting _losses, a _P S '= P _G). In the determination process J _1C , the control unit 23 determines that the absolute value | P _S '−P _SREF | of the difference is equal to or greater than a predetermined positive threshold TH _6A or the absolute value | P _S'- When a state in which P _SREF | is equal to or greater than the threshold TH _6A is continuously observed for a predetermined time or longer, or a state in which the absolute value | P _S '−P _SREF | is positive is continuously observed for a predetermined time or longer. The release condition in the determination process J _1C is satisfied (determined that the storage-side hunting phenomenon does not occur or is unlikely to occur even when the execution of the suppression control CNT _1C is canceled), and the suppression control CNT _1C Cancel execution. By canceling the execution of the suppression control CNT _1C , the output power amount to the power system 5 returns to the grid reference power amount P _SREF (= 10).

Alternatively, for example, when the system output command amount P _S ^* is decreased from the system reference power amount P _SREF by the predetermined amount ΔP _S ^* by the suppression control CNT _1C , the control unit 23 determines the difference (P _S ′ −P _S ^* ) May be set as a determination target, and when the control output CNT _1C increases the system output command amount P _S ^* by a predetermined amount ΔP _S ^{* from the} system reference power amount P _SREF , the control unit 23 May set the difference (P _S ^* −P _S ′) as a determination target. In the determination target, P _S ^* may be replaced with the actually measured output power amount P _S (that is, I _S × V _S ). When the determination target is greater than or equal to a predetermined positive threshold TH _6A ′, or when a state where the determination target is greater than or equal to the threshold TH _6A ′ is continuously observed for a predetermined time or longer, the control unit 23 The execution of the suppression control CNT _1C may be canceled by determining that the cancellation condition in the determination process J _1C is satisfied (TH _6A ′> ΔP _S ^* ).

[System input quantitative control]
Next, system input quantitative control will be described. The control unit 23 can supply power to the DC load 8 using the generated power of the power generation device 4 and the input power from the power system 5 to the power conversion circuit 20, but in the system input quantitative control, The power conversion circuit 20 is controlled so that power is input from the system 5 to the power conversion circuit 20 under a constant system input reference condition. In this system input quantitative control, when the total power amount of the generated power amount of the power generation device 4 and the input power amount from the power system 5 to the power conversion circuit 20 is smaller than the power consumption amount of the DC load 8, it corresponds to the difference between them. When the total power amount is larger than the power consumption amount of the DC load 8 so that the insufficient power is discharged from the power storage device 3, the power storage device 3 is charged with surplus power corresponding to the difference between them. As described above, the control unit 23 controls the power conversion circuit 20 based on the input / output power information.

The system input reference condition is a condition for designating an input power amount from the power system 5 to the power conversion circuit 20 or a current value and a voltage value depending on the input power amount, and the control unit 23 freely sets the system input reference condition. Can be determined. The system input reference condition may be a condition for designating only one of the current value and the voltage value depending on the input power amount from the power system 5 to the power conversion circuit 20. Here, it is assumed that the system input reference condition specifies that power input from the power system 5 to the power conversion circuit 20 is performed with a constant system reference power amount (system input / output reference power amount) P _SREF. To do.

In the system input quantitative control, since the power flow between the power conversion circuit 20 and the power system 5 is limited from the power system 5 to the power conversion circuit 20, the system input / output command quantity P _S ^{* is changed} to the system input command quantity P _S ^*. Also say. In the system input quantitative control, the control unit 23 gives the system input command amount P _S ^* into which the value of the system reference power amount P _SREF is substituted to the power conversion unit 21S, so that the power system 5 sends the power conversion unit 21S to the power conversion unit 21S. Thus, the power of the system reference power amount P _SREF can be input.

Here again, it is considered that P _SREF = 10 for the sake of concrete description. Further, although the power consumption of the DC load 8 can fluctuate, it is assumed here that the power consumption of the DC load 8 is always 20 kW · s. In the system input quantitative control, when P _SREF = 10, the control unit 23 can substitute 10 for the system input command amount P _S ^* , and thereby the input power amount from the power system 5 becomes 10 kW · s.
In this case, for example, as shown in FIG. 11 (a), if the power generation amount of the power generation device 4 is 6 kW · s, the total power amount is less than the power consumption amount 20 kW · s of the DC load 8, The control unit 23 controls the power conversion unit 21 </ b> B so that the insufficient power amount 4 kW · s corresponding to the difference is discharged from the power storage device 3.
On the other hand, for example, as shown in FIG. 11 (b), if the generated power amount of the power generation device 4 is 13 kW · s, the total power amount is larger than the power consumption amount 20 kW · s of the DC load 8. The control unit 23 controls the power conversion unit 21B so that the power storage device 3 is charged with a surplus power amount 3 kW · s corresponding to the difference.
As described above, in the grid input quantitative control, the power conversion circuit is connected to the power generated by the power generator 4 and the power grid 5 while absorbing the shortage or surplus of the power generated by the power generator 4 by charging or discharging the power storage device 3. In order to supply power to the DC load 8 using the input power to 20, power is input from the power system 5 to the power conversion circuit 20 under a certain system input reference condition.

  However, in the system input quantitative control, as shown in FIG. 11 (c), when the above total power amount has a value near the power consumption amount of the DC load 8, between the shortage state and the surplus state of the generated power. Switching between input and output of power between the power conversion circuit 20 and the power storage device 3 (switching between charge and discharge) occurs repeatedly in a relatively short period. Such switching at the time of executing the system input quantitative control is also a storage-side hunting phenomenon.

――― Storage hunting detection processing HD _1D ―――
During the execution period of the system input quantitative control, the control unit 23 can execute the power storage side hunting detection process HD _1D . The power storage side hunting detection process HD _1D is the same as the power storage side hunting detection process HD _1C described above.

――― Storage hunting prediction processing HP _1D ―――
Further, during the execution period of the system input quantitative control, the control unit 23 may predict the occurrence of the power storage side hunting phenomenon by performing the power storage side hunting prediction process HP _1D based on the input / output power information.
For example, in the energy storage side hunting prediction process _{HP 1D,} the control unit 23, based on the current value _I on the basis of the _G and the voltage value _{V G} (i.e., based on the generated power quantity _{P G)} or a current value _{I GINT} and voltage _{V INT} generator 'seeking, electric energy _{P G'} power amount _{P G} corresponding to the amount of power _{P G} total electric energy of the power system reference power _{P SREF} which is defined by the system input reference condition _{(P G '+ P SREF} ) Is compared with the power consumption of the DC load 8. The amount of power P _G ′ is the amount of power output from the power converter 21G, and can be considered to be equal to the product (I _GINT × V _INT ). Here, it is considered that the power of the grid reference power amount P _SREF (= 10) is supplied to the DC load 8 from the power conversion unit 21S by the grid input quantitative control. Therefore, the total amount of power (P _G ′ + P _SREF ) is the total amount of power output from the power conversion units 21G and 21S based on the generated power of the power generation device 4 and the commercial AC power from the power system 5 (power conversion If the power loss of the circuit 20 is ignored, P _G ′ + P _SREF = P _G + P _S ). Then, the control unit 23, when the absolute value of the difference between the total amount of power (P _G '+ P _SREF) and power consumption of the DC load 8 is less than a predetermined positive threshold value TH _7A, or the absolute value When the state where the threshold value is equal to or less than the threshold TH _7A is continuously observed for a predetermined time or more, the storage side hunting prediction determination is made.

――― Hunting suppression control CNT _1D ―――
When the storage-side hunting detection determination or the storage-side hunting prediction determination is made during the execution period of the system input quantitative control, the control unit 23 uses the input power amount from the power system 5 to the power conversion circuit 20 as a system input reference condition. The hunting suppression control CNT _1D to be changed from the system reference power amount P _SREF is executed. In the hunting suppression control CNT _1D , the absolute value of the input / output power amount between the power conversion circuit 20 and the power storage device 3 is increased by changing the input power amount from the power system 5 to the power conversion circuit 20, thereby storing the power. Suppresses side hunting phenomenon. The suppression control CNT _1D is control performed in the system input quantitative control, and the contents of the system input quantitative control are corrected during the execution period of the suppression control CNT _1D .

A first implementation example of the suppression control CNT _1D will be described. Before the storage-side hunting recognition timing, as described above, the control unit 23 substitutes the system reference power amount P _SREF for the system input command amount P _S ^* , whereby the input power amount from the power system 5 is This matches the reference power amount P _SREF (= 10) (see FIGS. 11A, 11B, and 11C). However, when the storage-side hunting detection determination or the storage-side hunting prediction determination is made, in the first implementation example of the suppression control CNT _1D , the control unit 23 reduces the system input command amount P _S ^* to the system by a predetermined amount ΔP _S ^*. The reference power amount P _{SREF is} increased or decreased (that is, the system input command amount P _S ^* is changed with reference to the power storage side hunting recognition timing).

FIG. 12A shows a power input / output state when the system input command amount P _S ^* is increased by 2 from the system reference power amount P _SREF (= 10). In this state, the control unit 23 causes the power conversion unit to charge the power storage device 3 with a surplus power amount 2 kW · s corresponding to the difference between the power generation amount of the power generation device 4 and the system input command amount P _S ^*. 21B is controlled. That is, the input / output between the power conversion circuit 20 and the power storage device 3 based on the increase in the amount of input power from the power system 5 by the suppression control CNT _1D with reference to the state before the increase (based on the state of FIG. 11C). The absolute value of the electric energy increases. As a result, the power storage side hunting phenomenon is appropriately suppressed. The same applies when the system input command amount P _S ^* is reduced from the system reference power amount P _SREF .

A second implementation example of the suppression control CNT _1D will be described. When the storage-side hunting detection determination or the storage-side hunting prediction determination is made, the control unit 23 that performs the second implementation example of the suppression control CNT _1D uses the charging command to the power conversion unit 21B as a reference before the storage-side hunting recognition timing. The suppression control CNT _1D is realized by changing the amount or discharge command amount P _B ^* by a predetermined amount ΔP _B ^* and assigning the change amount to the change in the input power amount from the power system 5 to the power conversion circuit 20.

For example, in the state of FIG. 11C, that is, the state in which the amount of power generated by the power generation device 4 and the amount of input power from the power system 5 are both 10 kW · s, as shown in FIG. This corresponds to a state where zero is substituted for the discharge command amount) P _B ^* . In this state, when the storage-side hunting detection determination or the storage-side hunting prediction determination is made, the control unit 23 executes, for example, suppression control CNT _1D that changes the charge command amount P _B ^* from zero to 2. Can do. In the second implementation example of the suppression control CNT _1D , the control unit 23 prioritizes the charge command amount (or discharge command amount) P _B ^* over the system input command amount P _S ^* or the system input command amount P _S. ^* Is not given to the power converter 21S. In any case, in the suppression control CNT _1D , the control unit 23 supplies an insufficient power amount (supplied to the DC load 8) determined by the power generation amount of the power generation device 4, the charge power amount of the power storage device 3, and the power consumption amount of the DC load 8. The power converter 21S is controlled so that the power shortage) is input from the power system 5. As a result, as shown in FIG. 12C, 12 kW · s of power is input from the power system 5 to the power conversion circuit 20. This state is equivalent to the state shown in FIG. FIG. 12 (c) is an example of when the charging of power storage device 3 has changed the command amount P _B ^* as is done, changes the command value P _B ^* as discharge of the power storage device 3 is carried out In this case, the input power amount from the power system 5 is reduced from 10 kW · s.

In a first implementation of suppression control CNT _1D, whereas controls directly the input electric energy from the electric power system 5 by the control of the system input command value P _S ^*, in the second implementation of suppression control CNT _1D, By controlling the charge or discharge command amount P _B ^* (by controlling the input / output power amount between the power conversion circuit 20 and the power storage device 3), the input power amount from the power system 5 is indirectly controlled.

--- cancellation determination processing _J 1D corresponding to suppression control _{CNT 1D} ---
Control unit 23, during the execution period of the suppression control CNT _1D, through a success determination of the predetermined release condition, release determination processing J _1D be performed determines whether to cancel the execution of the suppression control CNT _1D Can do. For example, in the cancelability determination process _J1D , the control unit 23 _{obtains the} total power amount (P _G '+ P _SREF ) by the above-described method, and _calculates the total power amount (P _G ' + P _SREF ) and the power consumption amount of the DC load 8. (If the power loss of the power conversion circuit 20 is ignored, P _G ′ + P _SREF = P _G + P _S ). In the determination process J _1D , the control unit 23 continues the state where the absolute value is equal to or greater than the predetermined positive threshold TH _8A or the absolute value is equal to or greater than the threshold TH _8A for a predetermined time or longer. When observed, or when a state in which the absolute value is positive is continuously observed for a predetermined time or more, it is determined that the release condition in the determination process J _1D is satisfied (execution of the suppression control CNT _1D is performed). It is determined that the storage-side hunting phenomenon does not occur or is unlikely to occur even when the release is canceled), and the execution of the suppression control CNT _1D is canceled. By canceling the execution of the suppression control CNT _1D , the input power amount from the power system 5 returns to the system reference power amount P _SREF (= 10).

Alternatively, for example, if you are reducing the system input command amount _P ^{S *} by suppression control _{CNT 1D} from a predetermined amount [Delta] P _S ^* only lines for the reference power _{P SREF,} the control unit 23 the difference _(P C8 - _{(P G} '+ P _S ^* )) may be set as a determination target, and when the system input command amount P _S ^* is increased from the system reference power amount P _SREF by a predetermined amount ΔP _S ^* by the suppression control CNT _1D. , the control unit 23 may be set in the determination target difference ^{_{((P G '+ P S}} *) -P C8). In the determination target, P _S ^* may be replaced with the actually measured input power amount P _S (that is, I _S × V _S ). As described above, _PC 8 represents the power consumption of the DC load 8. When the determination target is greater than or equal to a predetermined positive threshold value TH _8A ′, or when a state where the determination target is greater than or equal to the threshold value TH _8A ′ is continuously observed for a predetermined time or longer, the control unit 23 The execution of the suppression control CNT _1D may be canceled by determining that the cancellation condition in the determination process J _1D is satisfied (TH _8A '> ΔP _S ^* ).

[Operation flowchart]
Next, the operation flow of the power conversion device 2 will be described with reference to FIG. FIG. 13 is an operation flowchart of the power conversion device 2 focusing on the above-described various quantitative controls. First, in step S11, the control unit 23 starts execution of the above-described charge quantitative control, discharge quantitative control, system output quantitative control, or system input quantitative control (hereinafter, charge quantitative control, discharge quantitative control, system output quantitative control). Alternatively, system input quantitative control is also simply referred to as quantitative control). Thereafter, in step S12, the control unit 23, based on the input / output power information, performs the above-described system side or power storage side hunting detection process (HD _1A , HD _1B , HD _1C , HD _1D ) or system side or power storage side hunting prediction process. (HP _1A , HP _1B , HP _1C , HP _1D ). In subsequent step S13, the control unit 23 checks whether the system side or power storage side hunting detection determination or the system side or power storage side hunting prediction determination has been made, and if neither of these determinations has been made. Returning from step S13 to step S12, the processes in steps S12 and S13 are repeated. If any of these determinations is made, a transition to step S14 is generated, and hunting suppression control (CNT _1A , CNT _1B , CNT _1C , CNT _1D ) starts to be executed.

After starting the execution of the hunting suppression control, the control unit 23 performs a hunting suppression control cancelability determination process (J _1A , J _1B , J _1C , J _1D ) (step S15). The control unit 23 continues to execute the hunting suppression control until a predetermined release condition is satisfied (steps S15 and S16), and cancels the execution of the hunting suppression control when the release condition is satisfied (step S17). Return to step S12. As described above, the hunting suppression control is a control that is performed in the quantitative control and modifies the content of the quantitative control (for example, if the hunting suppression control is performed during the execution of the charge quantitative control, the charging power The charge quantitative control is performed after the amount is corrected upward or downward from the storage reference power amount P _BREF ), and when the execution of the hunting suppression control is canceled, the correction is also canceled and the basic quantitative control is performed. Resumed. However, the execution of the quantitative control is stopped during the execution of the hunting suppression control, and the quantitative control can be resumed when the hunting suppression control is canceled (in this case, the hunting suppression control is canceled in step S17). Then, the process returns to step S11). Further, in the case where there is a possibility that the reference power _{P BREF} or _{P SREF} during hunting suppression control is changed, when releasing the hunting suppression control, as the reference power _{P BREF} or _{P SREF} latest It is good to update to. Alternatively, if the reference power _{P BREF} or _{P SREF} is changed at any timing, the reference power _{P BREF} or _{P SREF} with updated to the latest ones may be returned to step S11.

Moreover, the control part 23 may perform the cancellation | release permission determination processing _J1A , _J1B , _J1C, or _J1D as follows. That is, during the execution period of the suppression control CNT _1A or CNT _1B , the control unit 23 executes the system-side hunting detection process HD _1A and observes the occurrence of the system-side hunting phenomenon for a predetermined number of times (any number of 1 or more). It may be determined that the release condition is satisfied when the control is performed, and the execution of the suppression control CNT _1A or CNT _1B may be released. Similarly, during the execution period of the suppression control CNT _1C or CNT _1D , the control unit 23 executes the storage-side hunting detection process HD _1C, and the occurrence of the storage-side hunting phenomenon is a predetermined number of times (any number of 1 or more). When the observation is observed, it may be determined that the release condition is satisfied, and the execution of the suppression control CNT _1C or CNT _1D may be released. On the contrary, a hunting phenomenon may occur if an increase in the amount of generated power occurs during execution of the suppression control. In such a case, the release of the suppression control contributes to avoiding the hunting phenomenon.

  As described above, according to the hunting suppression control according to the present embodiment, the system side hunting phenomenon that affects the stability of the power system 5 or the power storage side hunting phenomenon that may adversely affect the power storage device 3 is appropriately performed. It is possible to suppress. When realizing the hunting suppression control, the same hunting suppression effect can be obtained regardless of which of the first and second implementation examples described above (see, for example, FIGS. 5A and 5C). In addition, the execution of hunting suppression control should be monitored for whether release conditions are satisfied, and when it is determined that the hunting phenomenon does not occur or is difficult to occur even if the execution is canceled, a method of canceling hunting suppression control should be adopted. Thus, charging or the like can be performed with as much original power as possible while avoiding the hunting phenomenon as much as possible.

  In the case where the hunting detection process is used without using the hunting prediction process, the hunting suppression control is executed after the occurrence of the hunting phenomenon is detected. On the other hand, if the hunting prediction process is used, the occurrence of the hunting phenomenon can be completely or almost completely avoided. However, when the hunting prediction process is used, the time for performing charging or the like with the original amount of power is shorter than when the hunting detection process is used. Whether to execute the hunting detection process or the prediction process may be set in accordance with which one of priority is given to the suppression of the hunting phenomenon and the charging with the original electric energy.

<< Second Embodiment >>
A second embodiment of the present invention will be described. The second embodiment and the third embodiment which will be described later are embodiments based on the first embodiment. The matters not particularly described in the second and third embodiments are the same as those of the first embodiment as long as there is no contradiction. The description also applies to the second and third embodiments.

  The configuration of the power supply system 1 according to the second embodiment is the same as that of the first embodiment (FIG. 1). Although not particularly conscious in the first embodiment, in the second embodiment, the first embodiment described above, and the third embodiment described later, the control unit 23 controls the maximum power point tracking control (Maximum Power point control) for the power generation device 4. Point Tracking Control; hereinafter referred to as MPPT control).

A curve 400 in FIG. 14 represents the relationship between the output current of the power generation device 4 and the generated power. The value of the output current of the power generator 4 is the above-described current value _IG , and the amount of power generated by the power generator 4 is the above-described power amount P _G (= I _G × V _G ) (see FIG. 1). In the power generation device 4, the generated power changes depending on the output current. Output current _{I G} is generated power _{P G} when matching the current value _{I MPP} becomes maximum (i.e., the maximum amount of power _{P MPP} becomes), the absolute value _| I _{G -I MPP} | as increases, generated power the amount _{P G} decreases from the maximum amount of power _{P MPP.} The point on the curve 400 that defines the amount of power generated by the power generation device 4 is called a power point (or operating point). The power point 401 is a power point that makes the generated power amount of the power generation device 4 coincide with the maximum power amount P _MPP . On the other hand, power point 402 and 403 are power point to match the small amount of power P _Q than the maximum amount of power P _MPP the generated power of the generator 4. In power point 402 and 403, the current value _{I G} shall take each value _{I Q1} and _{I Q2.} Here, “0 <I _Q1 <I _MPP <I _Q2 ”. Further, it is assumed that “P _MPP −P _Q = ΔP _G ” is satisfied (ΔP _G > 0).

As shown in FIG. 15, the control unit 23 generates a current command value I _G ^* that specifies the current value I _G can be given to the power conversion unit 21G, whereby it is possible to control the current value I _G together, it is possible to control the voltage value V _G and the amount of power P _G through control of the current value I _G. Power conversion unit 21G generates power for power conversion so that the current value I _G matches the current command value I _G ^*. When performing the MPPT control, the control unit 23 sets the current command value I _G ^* so that the amount of power generated by the power generation device 4 is maximized based on the current value _IG and the voltage value V _G included in the input / output power information. Set and adjust. That is, when executing the MPPT control, the control unit 23 substitutes the value I _MPP for the current command value I _G ^* . Since the implementation method of MPPT control is well-known, description is omitted.

  On the other hand, also in the second embodiment, the control unit 23 can individually execute the charge quantitative control, the discharge quantitative control, the system output quantitative control, and the system input quantitative control described in the first embodiment. At this time, the control unit 23 can execute charge quantitative control, discharge quantitative control, system output quantitative control, or system input quantitative control while performing MPPT control (the same applies to the first and third embodiments).

Also in the second embodiment, the above-mentioned system side or power storage side hunting phenomenon may occur during execution of quantitative control. The control unit 23 can perform hunting detection processing or prediction processing similar to that described in the first embodiment during the execution period of each quantitative control. The same applies to a third embodiment described later. That is, the control unit 23 according to the second and third embodiments
During the execution period of MPPT control and charge quantitative control, the above-described hunting detection process HD _1A or prediction process HP _1A can be performed,
During the execution period of MPPT control and discharge quantitative control, the above-described hunting detection processing HD _1B or prediction processing HP _1B can be performed,
During the execution period of the MPPT control and the system output quantitative control, the hunting detection process HD _1C or the prediction process HP _1C described above can be performed.
The hunting detection process HD _1D or the prediction process HP _1D can be performed during the execution period of the MPPT control and the system input quantitative control.

――― Hunting suppression control CNT ₂ ―――
When system-side hunting detection determination or system-side hunting prediction determination is made during the period in which MPPT control and charge quantitative control or discharge quantitative control are executed, or MPPT control and system output quantitative control or system input quantitative control When the storage-side hunting detection determination or the storage-side hunting prediction determination is made during the period in which the power generation device 4 is executed, the control unit 23 changes the power generation amount of the power generation device 4 through the change of the power point of the power generation device 4. performing the hunting suppression control CNT _2. In the hunting suppression control CNT ₂ applied to the charge quantitative control or the discharge quantitative control, the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 is increased by changing the generated power amount of the power generation device 4. This suppresses the system-side hunting phenomenon. In the hunting suppression control CNT ₂ applied to the system output quantitative control or the system input quantitative control, the absolute value of the input / output power amount between the power conversion circuit 20 and the power storage device 3 by changing the power generation amount of the power generation device 4. This suppresses the storage-side hunting phenomenon. Suppression control CNT ₂ is a control performed in each quantitative control, although the execution of the suppression control CNT ₂ does not affect the contents of each quantitative control, the MPPT control during execution of the suppression control CNT ₂ Stopped.

A specific method of the suppression control CNT ₂ will be described. In the following description of the second embodiment, it is assumed that charge quantitative control, discharge quantitative control, system output quantitative control, or system input quantitative control is continuously executed unless otherwise specified.

Before the system-side hunting recognition timing or the power storage-side hunting recognition timing, the control unit 23 implements MPPT control by giving a current command value I _G ^* into which the value I _MPP is substituted to the power conversion unit 21G. In this state, power point of the generator 4 is the maximum amount of power P _MPP is outputted to the power conversion unit 21G as generated power P _G is a consistent with power point 401 (see FIG. 14), power generating apparatus 4 . However, when the system-side hunting detection determination, the system-side hunting prediction determination, the power storage-side hunting detection determination, or the power storage-side hunting prediction determination is performed, in the suppression control CNT ₂ , the control unit 23 supplies the current to the power conversion unit 21G. The command value I _G ^* is changed from the value I _MPP to the value I _Q1 or I _Q2 , thereby changing the power point of the power generation device 4 from the power point 401 to the power point 402 or 403 (see FIG. 14). Result, power generation amount of the generator 4 is decreased to the amount of power P _Q from the amount of power P _MPP.

  As can be easily understood from the description of the first embodiment, when the power generation amount of the power generation device 4 decreases when the system-side hunting phenomenon occurs, the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 is reduced. Since the value increases, the system-side hunting phenomenon is appropriately suppressed. Similarly, if the power generation amount of the power generation device 4 decreases when the power storage side hunting phenomenon occurs, the absolute value of the input / output power amount between the power conversion circuit 20 and the power storage device 3 increases, so that the power storage side hunting phenomenon is appropriate. To be suppressed.

--- cancellation determination processing _J 2 corresponding to suppression control CNT ₂ ---
Control unit 23, during the execution period of the suppression control CNT _2, via the judging success or failure of the predetermined release condition, performing the determining cancellation determination processing J ₂ whether to cancel the execution of the suppression control CNT ₂ Can do. On the assumption that the charging quantitative control is made for explaining an example of a cancellation determination processing J _2. In release determination processing J _2, the control unit 23, for example, when one of the first to fourth release following conditions are satisfied, it is possible to resume the MPPT control by releasing the execution of the suppression control CNT _2.

With reference to FIGS. 16A and 16B, the first and second release conditions will be described. 16A and 16B, solid line curves 411 and 411 ′ represent a first example and a second example of the time transition of the generated power amount of the power generation device 4. Since it is assumed that the charge quantitative control is currently performed, the control unit 23 substitutes the reference power amount P _BREF for power storage into the charge command amount P _B ^* , thereby charging power of the power storage device 3. The amount corresponds to the reference power amount P _BREF for power storage. The MPPT control is continuously executed until the timing t _B1 is reached. The timing _{t B1} is mains hunting cognitive timing, at the timing _{t B1,} the control unit 23 starts the execution of the suppression control CNT _2, thereby the timing _{t B1} boundary in the generated power quantity _{P G} and is decreased by [Delta] P _G . Timings t _B2 and t _B2 ′ are timings after timing t _B1 .

During the execution period of the suppression control CNT ₂ , the control unit 23 is based on the current value I _G and the voltage value V _G (that is, based on the generated power amount P _G ) or based on the current value I _GINT and the voltage value V _INT. A charge power amount P _B ′ is obtained. As described above, the charging power amount P _{B 'is} a charge power amount based on the generated power quantity P _G, (is regarded ie power conversion efficiency is 100%) is regarded as zero power loss of the power converter, is a _{P B} '= P _G.

The first release condition is satisfied when a charging power amount P _B ′ that satisfies the following inequality (A1) is observed. In the example of FIG. 16 (a), the suppression control CNT ₂ is performed continuously between the timing _{t B1} and _{t B2} for charging power amount _{P B} 'does not satisfy the inequality (A1) at each timing between the timing _{t B1} and _{t B2} However, since the charging power amount P _B ′ at the timing t _B2 satisfies the inequality (A1), the control unit 23 cancels the execution of the suppression control CNT _{2 at} the timing t _B2 and restarts the MPPT control. Left side of the equation (A1) is consistent with Neglecting power conversion loss _{(P BREF} -P _G) or ^_(P B * -P _G). That is, establishment of formula (A1), the difference between the power storage for reference power _{P BREF} and ^(* = charge command amount _P ^B) and the generated power _{P G} defined in charging reference conditions shrinks enough, the MPPT control more does not occur again mains hunting when resumed, generated power P _G represents a possible increased. TH _B1 is a zero or a predetermined threshold, smaller than the value of [Delta] P _G (Assuming that is _{TH B1} = [Delta] P _G, when the MPPT control resumption, there is a possibility that immediately mains hunting phenomenon occurs For). To perform the setting of the value of TH _B1, the control unit 23 can hold the value of [Delta] P _G.
P _BREF −P _B ′ ≦ TH _B1 (A1)

The second release condition is satisfied when the charging power amount P _B ′ satisfying the following inequality (A2) is observed. In the example of FIG. 16 (b), the timing _{t B1} and _{t B2} timing _{t B1} and _{t B2} 'suppression control between CNT ₂ for' charging power amount _{P B} in each timing between 'does not satisfy the inequality (A2) Although it is continuously executed, since the charging power amount P _B ′ at timing t _B2 ′ satisfies the inequality (A2), the control unit 23 cancels execution of the suppression control CNT ₂ at timing t _B2 ′ and performs MPPT control. Resume. Left side of the equation (A2) is consistent with Neglecting power conversion loss _{(P BREF} -P _G) or ^_(P B * -P _G). That is, establishment of formula (A2) is spread enough difference in power storage for reference power _{P BREF} and ^(* = charge command amount _P ^B) and the generated power _{P G} defined in charging reference conditions, the MPPT control more does not occur again mains hunting when resumed, generated power P _G represents a that becomes smaller. TH _B2 is a large predetermined threshold than [Delta] P _G (Assuming that is _{TH B2} = [Delta] P _G, because when the MPPT control resumption, there is a possibility that immediately mains hunting phenomenon occurs).
P _BREF −P _B ′ ≧ TH _B2 (A2)

Next, the third release condition will be described. In order to confirm the success or failure of the third release condition, the control unit 23, based on the current value I _G and the voltage value V _G or based on the current value I _GINT and the voltage value V _INT during the execution period of the suppression control CNT ₂ , The charge power amount P _B ″ is obtained. The charged power amount P _B ″ corresponds to the virtual generated power amount that would have been obtained if MPPT control was performed, multiplied by the power conversion efficiencies of the power conversion units 21G and 21B. Virtual generated power amount, assuming generated power P _G is obtained by adding the [Delta] P _G in (the power conversion efficiency at the suppression control CNT ₂ execution to be 100%, P B _'' is a virtual It corresponds to the amount of generated power (P _G + ΔP _G ). Then, the control unit 23 determines that the third release condition is satisfied when a state where the absolute value | P _B ″ −P _BREF | is positive is continuously observed for a predetermined time or more. This is because it is expected that the system-side hunting phenomenon will not occur even if the MPPT control is resumed under the situation where the observation is made.

Next, the fourth release condition will be described. Controller 23 determines during the execution period of the suppression control CNT _2, and executes the mains hunting detection processing HD _1A, fourth release condition when the occurrence of mains hunting phenomenon is observed more than a predetermined number of times is met To do. The predetermined number of times may be an arbitrary number of 1 or more. This is because when the system-side hunting phenomenon occurs despite the suppression control CNT ₂ being executed, the system-side hunting phenomenon is avoided due to the increase in the amount of generated power accompanying the restart of the MPPT control.

In the case where the quantitative control of the non-charging quantitative control has been made, it can also perform a cancellation determination processing J ₂ above when suppression control CNT ₂ is running. However, if the quantitative control of the non-charging quantitative control has been made, the contents of the release determination process J ₂ is modified as follows. First, at the time of execution of system output or system input quantitative control, the above-described timing t _B1 corresponds to the storage side hunting recognition timing.

For the discharge quantitative control, the first to third release conditions may be changed as follows.
In the first and second release condition which corresponds to the discharge quantitative control, the above-mentioned formula (A1) and (A2) is changed to respectively the following formulas (B1) and (B2), wherein during the execution of the suppression control CNT ₂ When the electric energy P _G ′ satisfying (B1) or (B2) is observed, the control unit 23 determines that the first or second release condition is satisfied (the first implementation is performed for the definition of P _G ′). See form). Q represents the power consumption of the DC load 8.
P _G '+ P _BREF −Q ≦ TH _B1 (B1)
P _G '+ P _BREF −Q ≧ TH _B2 (B2)
In addition, regarding the discharge quantitative control, the control unit 23 determines the electric energy P _G based on the current value I _G and the voltage value V _G or based on the current value I _GINT and the voltage value V _INT during the execution period of the suppression control CNT _2. Ask for ''. The power amount P _G ″ corresponds to the virtual power generation amount multiplied by the power conversion efficiency of the power conversion unit 21G (assuming that the power conversion efficiency is 100%, P _G ″ It corresponds to the amount of electric power (P _G + ΔP _G ). Then, the control unit 23, the absolute value _{| P G '' + P BREF} -Q | if is positive status was observed continuously for a predetermined time or more, the third release condition corresponding to the discharge quantitative control is satisfied Judge.
The fourth release condition corresponding to the discharge quantitative control is the same as the fourth release condition described above for the charge quantitative control.

For the system output quantitative control, the first to third release conditions may be changed as follows.
In the first and second release conditions corresponding to the system output quantitative control, the above formulas (A1) and (A2) are changed to the following formulas (C1) and (C2), respectively, and during the execution period of the suppression control CNT ₂ When the electric energy P _S ′ satisfying the expression (C1) or (C2) is observed, the control unit 23 determines that the first or second release condition is satisfied (the first definition for P _S ′ is the first). See embodiment).
P _SREF −P _S ′ ≦ TH _B1 (C1)
P _SREF −P _S ′ ≧ TH _B2 (C2)
In addition, regarding the system output quantitative control, the control unit 23 performs the power amount P based on the current value I _G and the voltage value V _G or based on the current value I _GINT and the voltage value V _INT during the execution period of the suppression control CNT _{2. Find S} ''. The power amount P _S ″ corresponds to the virtual power generation amount multiplied by each power conversion efficiency of the power conversion units 21G and 21S (assuming that each power conversion efficiency is 100%, P _S ′ 'Is the same as the virtual power generation amount (P _G + ΔP _G )). Then, the control unit 23, the absolute value _| P S _'' -P _SREF | if is positive status was observed continuously for a predetermined time or more, the third release condition corresponding to the channel output quantitative control is satisfied Judge.

For system input quantitative control, the first to third release conditions may be changed as follows.
In the first and second release conditions corresponding to the system input quantitative control, the above formulas (A1) and (A2) are changed to the following formulas (D1) and (D2), respectively, and during the execution period of the suppression control CNT ₂ When the power amount P _G ′ satisfying the expression (D1) or (D2) is observed, the control unit 23 determines that the first or second release condition is satisfied.
P _G '+ P _SREF −Q ≦ TH _B1 (D1)
P _G '+ P _SREF −Q ≧ TH _B2 (D2)
In addition, regarding the system input quantitative control, the control unit 23 performs the above-described electric power based on the current value I _G and the voltage value V _G or based on the current value I _GINT and the voltage value V _INT during the execution period of the suppression control CNT _2. Determine the quantity P _G ″. Then, the control unit 23 satisfies the third release condition corresponding to the system input quantitative control when a state where the absolute value | P _G ″ + P _SREF −Q | is positive is continuously observed for a predetermined time or more. Judge that

When the suppression control CNT ₂ is executed when the system output quantitative control or the system input quantitative control is executed, the control unit 23 executes the storage-side hunting detection process HD _1C and observes the occurrence of the storage-side hunting phenomenon more than a predetermined number of times. It is good to determine that the fourth release condition has been satisfied. The predetermined number of times may be an arbitrary number of 1 or more.

[Operation flowchart]
Next, the operation flow of the power conversion device 2 will be described with reference to FIG. FIG. 17 is an operation flowchart of the power conversion device 2 focusing on the above-described various quantitative controls. Steps S22 and S23 are the same as steps S12 and S13 in FIG. First, in step S21, the control unit 23 starts executing any quantitative control and also starts executing MPPT control. Thereafter, in step S22, the control unit 23 performs the above-described hunting detection process or prediction process based on the input / output power information. In subsequent step S23, the control unit 23 checks whether the hunting detection determination or the prediction determination is made, and if any of the determinations is made, the control unit 23 causes the transition to step S24 to generate the hunting suppression control CNT ₂ . Execution is started (ie, MPPT control is stopped).

After executing the start of hunting suppression control CNT _2, the control unit 23 performs the cancellation determination processing _{J 2} hunting suppression control CNT ₂ (step S25). The control unit 23 continues to execute the hunting suppression control CNT ₂ until any of the first to fourth release conditions is satisfied (steps S25 and S26), and when the release condition is satisfied, the hunting suppression control CNT ₂ is confirmed. Is canceled (step S27), and the process returns to step S22. As described above, MPPT control is resumed by the release of the execution of the hunting suppression control CNT _2.

  Even in the hunting suppression control according to the second embodiment, as in the first embodiment, the system side hunting phenomenon that affects the stability of the power system 5 or the power storage side hunting phenomenon that may adversely affect the power storage device 3 is performed. It is possible to suppress appropriately. In addition, since the hunting suppression control in the second embodiment does not affect the quantitative control, the desired quantitative control can be continued during the execution period of the hunting suppression control. However, the hunting suppression control of the second embodiment is accompanied by a decrease in the amount of generated power. In this regard, a method of monitoring whether or not the release condition is satisfied at the time of execution of the hunting suppression control and adopting a method of canceling the hunting suppression control when it is determined that the hunting phenomenon does not occur or hardly occurs even when the execution is canceled. As a result, it is possible to extract as much generated power as possible from the power generator 4 while avoiding the hunting phenomenon as much as possible.

  In the case where the hunting detection process is used without using the hunting prediction process, the hunting suppression control is executed after the occurrence of the hunting phenomenon is detected. On the other hand, if the hunting prediction process is used, the occurrence of the hunting phenomenon can be completely or almost completely avoided. However, when the hunting prediction process is used, the time for performing the MPPT control is shorter than when the hunting detection process is used. What is necessary is just to set which of a hunting detection process and a prediction process is performed according to which priority is given to hunting phenomenon suppression or generated electric power amount.

Further, the control unit 23 may supply the power conversion unit 21G with a voltage command value V _G ^* that specifies the voltage value V _G instead of the current command value I _G ^* . In this case, the control unit 23 can realize the MPPT control by giving the voltage command value V _G ^* corresponding to the power point 401 to the power conversion unit 21G, and when performing the suppression control CNT ₂ , the power point 402 Alternatively, the voltage command value V _G ^* corresponding to 403 may be given to the power conversion unit 21G.

<< Third Embodiment >>
A third embodiment of the present invention will be described. The power supply system 1 according to the third embodiment is provided with two power storage devices 3, and correspondingly, the power conversion circuit 20 according to the third embodiment includes a power conversion unit 21B for the power storage device. Are provided. The characteristics, configuration and operation of the power storage device can be different between the two power storage devices 3, and the characteristics, configuration and operation of the power conversion unit can be different between the two power conversion units 21B. However, here, for simplification of explanation, each of the two power storage devices 3 has the same characteristics and configuration as the power storage device 3 described in the first embodiment and is the same as the power storage device 3 described in the first embodiment. Operation is realized, and each of the two power conversion units 21B has the same characteristics and configuration as the power conversion unit 21B described in the first embodiment and the same operation as the power conversion unit 21B described in the first embodiment Shall be realized. The control unit 23 can control the power conversion unit 21B described in the first embodiment for each of the two power conversion units 21B.

  The power supply system according to the third embodiment including two power storage devices 3 is referred to by reference numeral 1a, the power conversion circuit according to the third embodiment including two power conversion units 21B is referred to by reference numeral 20a, The power conversion device according to the third embodiment including the conversion circuit 20a is referred to by reference numeral 2a. FIG. 18 is a schematic overall configuration diagram of a power supply system 1a according to the third embodiment. Hereinafter, the two power storage devices 3 are referred to as power storage devices 3 and 3a, and the two power conversion units 21B are referred to as power conversion units 21B and 21Ba. The power conversion circuit 20a and the power conversion device 2a of FIG. 18 are formed by adding the power conversion unit 21Ba to the power conversion circuit 20 and the power conversion device 2 of FIG. The power conversion unit 21Ba is provided in the power conversion circuit 20a. In the power supply system 1 of FIG. 1, the power supply system 1a is formed by replacing the power conversion device 2 with the power conversion device 2a and adding the power storage device 3a. When the description of the first or second embodiment is applied to the third embodiment, the reference numerals “1”, “2”, and “20” in the description of the first or second embodiment are “1a”, It is read as “2a” and “20a”.

The power conversion unit 21Ba has power terminals T _B1a and T _B2a corresponding to the power terminals T _B1 and T _B2 of the power conversion unit 21B. Power storage device 3a is connected to the power conversion unit 21Ba by the power terminal T _B1a, it is possible to output its discharge power to the power conversion unit 21Ba, charging when the power conversion unit 21Ba supplied with the charging power Is done. The power terminals T _B2a , T _B2 , T _G2, and T _S2 are commonly connected in the power conversion circuit 20a by the intermediate wiring 22.

The power conversion circuit 20a performs power transmission and power reception among the power storage device 3, the power storage device 3a, the power generation device 4, and the power system 5 under the control of the control unit 23, and performs necessary power conversion at the time of power transmission and power reception. . The power conversion unit 21Ba converts the DC discharge power received from the power storage device 3a through the power terminal T _B1a into another DC power and outputs the other DC power from the power terminal T _B2a. , Converting the DC power received via the power terminal T _B2a into another DC power and outputting the other DC power to the power storage device 3a as the charging power via the power terminal _TB1a Is possible. The operations of the power conversion units 21B, 21G, and 21S are as described in the first embodiment. However, with the addition of the power storage device 3a and the power conversion unit 21Ba, the power from the power storage device 3, the power generation device 4, or the power system 5 may be sent to the power storage device 3a, and the power from the power storage device 3a is stored in the power storage device. 3. It may be sent to the electric power system 5 or the DC load 8.

In the third embodiment, the input / output power information acquired by the control unit 23 includes the current value _IBa and the voltage value based on the measurement results of the current sensor and the voltage sensor, in addition to the values described in the first embodiment. V _Ba and current value I _BINTa may be included, and power amounts P _Ba and P _BINTa represented by the following formulas (1g) and (1h) may be included. I _{Ba, V Ba} and _{P Ba,} respectively, the output current value in the discharge power of the power storage device 3a which is input from the power storage device 3a to the power conversion unit 21Ba, from the voltage value and the electric energy or power converter unit 21Ba storage device 3a Current value, voltage value, and electric energy in the charging power of the power storage device 3a. I _{BINTa and} V _INTa are current values and voltage values before or after power conversion in the power conversion unit 21Ba corresponding to I _Ba and V _Ba , respectively.
P _Ba = V _Ba × I _Ba (1 g)
P _BINTA = V _INT × I _BINTA (1h)

  The control unit 23 controls the operation of the power conversion circuit 20a including the operation of each power conversion of the power conversion units 21B, 21Ba, 21G, and 21S based on the input / output power information, and controls the operation of the power conversion circuit 20a. The power transmission device 3, the power storage device 3 a, the power generation device 4, and the power grid 5 are controlled.

Also in the third embodiment, the control unit 23 can individually execute the charge quantitative control, the discharge quantitative control, the system output quantitative control, and the system input quantitative control described in the first embodiment. When forming the respective quantitative control, charge or discharge state of the power storage device 3a is not limited, here, on the specific description, during the period which is not made hunting suppression control CNT ₃ below, charging of the power storage device 3a And the discharge power is zero. Further, as described in the description of the second embodiment, the control unit 23 performs the hunting detection process (HD _1A , HD _1B , HD _1C) corresponding to the quantitative control being performed during the execution period of each quantitative control. , HD _1D ) or hunting prediction processing (HP _1A , HP _1B , HP _1C , HP _1D ) can be executed.

――― Hunting suppression control CNT ₃ ―――
When system-side hunting detection judgment or system-side hunting prediction judgment is made during the period when charge quantitative control or discharge quantitative control is executed, or during the period when system output quantitative control or system input quantitative control is executed when it made a power storage side hunting detection determination or power storage side hunting prediction judgment, the control unit 23 performs the hunting suppression control CNT ₃ in which power is input and output between the power conversion circuit 20a and the power storage device 3a. The power input / output between the power conversion circuit 20a and the power storage device 3a means power output from the power conversion circuit 20a to the power storage device 3a or power input from the power storage device 3a to the power conversion circuit 20a. The power output from the power conversion circuit 20a to the power storage device 3a means that charging power is supplied from the power conversion unit 21Ba to the power storage device 3a. The power input from the power storage device 3a to the power conversion circuit 20a is the power storage device 3a. Is supplied to the power converter 21Ba.

In the hunting suppression control CNT ₃ applied to the charge quantitative control or the discharge quantitative control, the absolute value of the input / output power amount between the power conversion circuit 20 and the power system 5 by the power input / output between the power conversion circuit 20a and the power storage device 3a. Thereby suppressing the system-side hunting phenomenon. In the hunting suppression control CNT ₃ applied to the system output quantitative control or the system input quantitative control, the input / output power amount between the power conversion circuit 20 and the power storage device 3 is determined by the power input / output between the power conversion circuit 20a and the power storage device 3a. The absolute value is increased, thereby suppressing the power storage side hunting phenomenon. The suppression control CNT ₃ is control performed in each quantitative control, and the execution of the suppression control CNT ₃ does not affect the content of each quantitative control.

FIGS. 19A and 19B are conceptual diagrams of the suppression control CNT ₃ that can be performed during the execution of the charge quantitative control. 20A and 20B are conceptual diagrams of the suppression control CNT ₃ that can be performed during the execution period of the discharge quantitative control. When the system-side hunting phenomenon as in the example of FIG. 2C or FIG. 7C is detected or predicted, the control unit 23 performs the suppression control CNT ₃ in FIG. 19A or FIG. As shown in FIG. 19, the power conversion unit 21Ba is controlled so that a predetermined amount of charging power is supplied from the power conversion unit 21Ba to the power storage device 3a, or as shown in FIG. 19B or FIG. The power conversion unit 21Ba is controlled so that a predetermined amount of discharge power is output from the power storage device 3a to the power conversion unit 21Ba.

In the example of FIG. 19A and FIG. 20A, it can be considered that all or part of the charging power of the power storage device 3a is supplied from the power system 5, or the power generation device 4 or the power storage device 3 It can be thought that it is supplied from.
In the example of FIG. 19B and FIG. 20B, it can be considered that all or part of the discharged power of the power storage device 3a is output to the power system 5, or the power storage device 3 or the DC load 8 You can also think that it is output to.
In any case, the charging or discharging of the power storage device 3a causes a continuous power flow in a certain direction between the power conversion circuit 20a and the power system 5, thereby suppressing the system-side hunting phenomenon.

FIGS. 21A and 21B are conceptual diagrams of the suppression control CNT ₃ that can be performed during the execution period of the system output quantitative control. 22A and 22B are conceptual diagrams of the suppression control CNT ₃ that can be performed during the execution period of the system input quantitative control. When the storage-side hunting phenomenon as in the example of FIG. 9C or FIG. 11C is detected or predicted, the control unit 23 performs the suppression control CNT ₃ in FIG. 21A or FIG. As shown in FIG. 21, the power conversion unit 21Ba is controlled such that a predetermined amount of charging power is supplied from the power conversion unit 21Ba to the power storage device 3a, or as shown in FIG. 21 (b) or FIG. 22 (b), The power conversion unit 21Ba is controlled so that a predetermined amount of discharge power is output from the power storage device 3a to the power conversion unit 21Ba.

  In the example of FIG. 21A and FIG. 22A, it can be considered that all or part of the charging power of the power storage device 3a is supplied from the power storage device 3, or the power generation device 4 or the power system 5 It can be thought that it is supplied from. In the example of FIG. 21B and FIG. 22B, it can be considered that all or part of the discharged power of the power storage device 3a is output to the power storage device 3, or the power system 5 or the DC load 8 You can also think that it is output to. In any case, the charging or discharging of the power storage device 3a causes a continuous flow of power in a certain direction between the power conversion circuit 20a and the power storage device 3, and the power storage side hunting phenomenon is suppressed.

The release possibility determination process that can be performed during the execution period of the hunting suppression control CNT ₃ is the same as that described in the first embodiment. That is, when the suppression control CNT ₃ is executed in the case where the charge quantitative control, the discharge quantitative control, the system output quantitative control, or the system input quantitative control is performed, during the execution period of the suppression control CNT ₃ , the control unit 23 , Respectively, the above-described cancelability determination processing J _1A , J _1B , J _1C or J _1D can be performed. When applying the descriptive text of the first embodiment regarding the release possibility determination process J _1A , J _1B , J _1C or J _1D to the third embodiment, the reference numerals “CNT _1A ”, “CNT _1B ”, “CNT _1C ” and “CNT _1D ” should all be read as “CNT ₃ ”.

When the release condition in the determination process J _1A is satisfied during execution of the charge quantitative control and suppression control CNT ₃ , and when the release condition in the determination process J _1B is satisfied during execution of the discharge quantitative control and suppression control CNT ₃ , When the release condition in the determination process J _1C is satisfied during the execution of the system output quantitative control and the suppression control CNT ₃ , or the release condition in the determination process J _1D is satisfied during the execution of the system input quantitative control and the suppression control CNT ₃ When this is done, the control unit 23 cancels the execution of the suppression control CNT ₃ , that is, stops the power input / output between the power conversion circuit 20a and the power storage device 3a (as a result, the charge power and the discharge power of the power storage device 3a are zero). Back to).

Also, similar to that described in the first embodiment, during the execution period of the charging quantification control or discharge quantitative control and suppression control CNT _3, the control unit 23 executes the mains hunting detection processing HD _1A, mains hunting The execution of the suppression control CNT ₃ may be canceled by determining that the cancellation condition is satisfied when the occurrence of the phenomenon is observed a predetermined number of times (an arbitrary number of 1 or more). Similarly, during the execution period of the system output quantitative control or the system input quantitative control and the suppression control CNT ₃ , the control unit 23 executes the power storage side hunting detection process HD _1C , and the power storage side hunting phenomenon occurs a predetermined number of times (1 It may be determined that the release condition has been satisfied when the number of observations above is observed, and the execution of the suppression control CNT ₃ may be released. On the contrary, a hunting phenomenon may occur if an increase in the amount of generated power occurs during execution of the suppression control. In such a case, the release of the suppression control contributes to avoiding the hunting phenomenon.

[Operation flowchart]
Next, the operation flow of the power conversion device 2a will be described with reference to FIG. FIG. 23 is an operation flowchart of the power converter 2a focusing on the above-described various quantitative controls. Steps S31 to S33, S35 and S36 are the same as steps S11 to S13, S15 and S16 of FIG. First, in step S31, the control unit 23 starts executing any quantitative control. Thereafter, in step S32, the control unit 23 performs the above-described hunting detection process or prediction process based on the input / output power information. In subsequent step S33, the control unit 23 checks whether the hunting detection determination or the prediction determination is made, and if any of the determinations is made, the control unit 23 shifts to step S34 to execute the hunting suppression control CNT ₃ . The execution is started (that is, charging / discharging for suppressing hunting is performed by the power storage device 3a).

After the execution of the hunting suppression control CNT ₃ is started, the control unit 23 performs a hunting suppression control CNT ₃ release possibility determination process (J _1A , J _1B , J _1C or J _1D ) (step S35). The control unit 23 continues the execution of the hunting suppression control CNT ₃ until one of the predetermined release conditions is satisfied (steps S35 and S36). When the satisfaction of the release condition is confirmed, the execution of the hunting suppression control CNT ₃ is performed. Cancel (step S37) and return to step S32. As described above, (charging and discharging of the power storage device 3a) charging and discharging for hunting suppressed by canceling the execution of the hunting suppression control CNT ₃ is stopped.

  Even in the hunting suppression control according to the third embodiment, the system side hunting phenomenon that affects the stability of the power system 5 or the power storage side hunting phenomenon that may adversely affect the power storage device 3 as in the first embodiment. It is possible to suppress appropriately. Moreover, since the hunting suppression control in the third embodiment does not affect the quantitative control, the desired quantitative control can be continued during the execution period of the hunting suppression control. However, in the hunting suppression control of the third embodiment, the power storage device 3a is charged / discharged which is not necessary originally. In this regard, a method of monitoring whether or not the release condition is satisfied at the time of execution of the hunting suppression control and adopting a method of canceling the hunting suppression control when it is determined that the hunting phenomenon does not occur or hardly occurs even when the execution is canceled. Thus, unnecessary charging / discharging can be suppressed as much as possible while avoiding the hunting phenomenon as much as possible.

  In the case where the hunting detection process is used without using the hunting prediction process, the hunting suppression control is executed after the occurrence of the hunting phenomenon is detected. On the other hand, if the hunting prediction process is used, the occurrence of the hunting phenomenon can be completely or almost completely avoided. However, when the hunting prediction process is used, the unnecessary charge / discharge execution time increases as compared with the case where the hunting detection process is used, and the efficiency of the entire system is reduced (power conversion associated with unnecessary charge / discharge). Loss reduces overall system efficiency). Whether to execute the hunting detection process or the prediction process may be set according to which of the hunting phenomenon suppression and the system efficiency is given priority.

Moreover, which of the two power storage devices provided in the power supply system 1a is set as the power storage device 3 and which is set as the power storage device 3a is arbitrary. The control unit 23 may perform a selection process of selecting any one of the two power storage devices as the power storage device 3 and selecting the other as the power storage device 3a. The control unit 23 may obtain the degree of deterioration (for example, SOH (State Of Health)) of each of the two power storage devices and perform the selection process according to the degree of deterioration. Further, in the hunting suppression control CNT ₃ , it may be fixed in advance whether the power storage device 3 a is to be charged or discharged, or the control unit 23 may determine according to the remaining capacity of the power storage device 3 a. It may be determined.

<< Deformation, etc. >>
The embodiment of the present invention can be appropriately modified in various ways within the scope of the technical idea shown in the claims. The above embodiment is merely an example of the embodiment of the present invention, and the meaning of the term of the present invention or each constituent element is not limited to that described in the above embodiment. The specific numerical values shown in the above description are merely examples, and as a matter of course, they can be changed to various numerical values. As annotations applicable to the above-described embodiment, notes 1 to 8 are described below. The contents described in each comment can be arbitrarily combined as long as there is no contradiction.

[Note 1]
In each of the above-described embodiments, it is assumed that the charging reference condition specifies that the charging power amount of the power storage device 3 is constant, and accordingly, the charge quantitative control keeps the charging power amount of the power storage device 3 constant. Assumed to be control. However, as long as charge quantitative control is what charges the electrical storage apparatus 3 on fixed charge reference conditions, charge quantitative control is not limited to what was illustrated in each embodiment. That is, for example, the charge quantitative control may be control (constant current charge control) for charging the power storage device 3 with a constant current value, or control for charging the power storage device 3 with a constant voltage value (constant voltage charge control). ). Similarly, as long as the discharge quantitative control is to discharge the power storage device 3 under a certain discharge reference condition, the discharge quantitative control is not limited to those exemplified in each embodiment. For example, the discharge quantitative control is not limited to the power storage device. 3 may be controlled to discharge at a constant current value (constant current discharge control).

  Similarly, as long as the system output quantitative control is to output power from the power conversion circuit (20 or 20a) to the power system 5 under a certain system output reference condition, the system output quantitative control is as exemplified in each embodiment. For example, the system output quantitative control may be control that keeps the output current value (effective value) from the power conversion circuit (20 or 20a) to the power system 5 constant. Similarly, as long as the system input quantitative control is to input power from the power system 5 to the power conversion circuit (20 or 20a) under a certain system input reference condition, the system input quantitative control is as illustrated in each embodiment. For example, the system input quantitative control may be control that keeps the input current value (effective value) from the power system 5 to the power conversion circuit (20 or 20a) constant.

[Note 2]
As can be understood from the description in Note 1, in charge quantitative control, the control unit 23 determines the charge current supplied from the power conversion unit 21B to the power storage device 3 instead of the charge command amount P _B ^* for power. may be provided to generate a charge command amount I _B ^* which specifies the current value I _B to the power conversion unit 21B, the power conversion unit 21B, the charging current having a current value specified in the charge command value I _B ^* May be converted to supply power to the power storage device 3. In the charge quantitative control, the control unit 23 can charge the power storage device 3 with a constant reference current amount I _BREF for storage by substituting the value of the reference current amount I _BREF for storage into the charge command amount I _B ^*. . In this case, the charging reference condition specifies that the power storage device 3 is charged with a constant reference current amount I _BREF for power storage. In this specification, the term “current value” and the term “current amount” are synonymous, and the term “voltage value” and the term “voltage amount” are synonymous.

Similarly, in the discharge quantitative control, the control unit 23 generates a discharge command amount I _B ^* that specifies the current value I _B of the discharge current of the power storage device 3 instead of the discharge command amount P _B ^* for power. The power conversion unit 21B may perform the discharge power conversion so that a discharge current having a current value specified by the discharge command amount I _B ^* is output from the power storage device 3. Also good. In the discharge quantitative control, the control unit 23 can _cause the power storage device 3 to discharge at a constant reference current amount I _BREF for storage by substituting the value of the reference current amount I _BREF for storage into the discharge command amount I _B ^*. . In this case, the discharge reference condition specifies that the power storage device 3 is discharged with a constant reference current amount I _BREF for power storage.

Similarly, in the channel output quantitative control, the control unit 23, instead of the channel output command value P _S ^* for power, system output for designating a current value I _S of the output current to the power system 5 from the power conversion unit 21S The command amount I _S ^* may be generated and given to the power conversion unit 21S. The power conversion unit 21S receives a current having a current value specified by the system output command amount I _S ^* from the power conversion unit 21S. System output power conversion may be performed so that the power is output to 5. In the system output quantitative control, the control unit 23 substitutes the value of the system reference current amount I _{SREF into} the system output command amount I _S ^* to transfer the current from the power conversion unit 21S to the power system 5 with a constant current amount I _SREF . Output can be performed. In this case, the grid output reference condition specifies that the power output from the power conversion circuit (20 or 20a) to the power grid 5 is performed with a constant grid reference current amount I _SREF .

Similarly, in the system input quantitative control, the control unit 23, the system inputs in place of the system input command value P _S ^* for power, specifies the current value I _S of the input current from the electric power system 5 to the power conversion unit 21S The command amount I _S ^* may be generated and given to the power conversion unit 21S, and the power conversion unit 21S receives a current having a current value specified by the system input command amount I _S ^* from the power system 5 to the power conversion unit. System input power conversion may be performed so as to be input to 21S. In the system input quantitative control, the control unit 23 substitutes the value of the system reference current amount I _{SREF into} the system input command amount I _S ^* so that the current is transferred from the power system 5 to the power conversion unit 21S with a constant current amount I _SREF . Input can be made. In this case, the grid input reference condition specifies that the current input from the power grid 5 to the power conversion circuit (20 or 20a) is performed with a constant grid reference current amount I _SREF .

[Note 3]
The prediction processes HP _1A and HP _1B and the release possibility determination processes J _1A and J _1B using both the voltage value and the current value depending on the amount of power generated by the power generation device 4 have been described above. However, if the ratio between the voltage value V _G and the voltage value V _B , the ratio between the voltage value V _INT and the voltage value V _B , or the voltage values V _G , V _B and V _INT are known to the control unit 23, , the control unit 23, using only the information of the current value corresponding to the amount of power generation of the generator 4, i.e. the current value _{I G} or _{I GINT} only prediction process using the _{HP 1A} and _{HP 1B} and cancellation determination processing J _1A and J _1B can also be formed. At this time, in the processes HP _1A , HP _1B , J _1A and J _1B described above, arbitrary “power amount” and “symbol representing power amount” are set to “current value” and “current value” using information on known voltages. The processing realized through this conversion is equivalent to the above-described processing HP _1A , HP _1B , J _1A and J _1B .

For example, for simplification of description, if the power conversion efficiency of the power conversion units 21G and 21B is considered to be 100%, | P _B '−P _BREF | = | I _G · V _G −I _BREF · V _B | = | I _GINT · V _INT −I _BREF · V _B | (see prediction process HP _1A ). Therefore, if the ratio “V _G / V _B ” or the ratio “V _INT / V _B ” is known, the absolute value | I _G instead of the absolute value | P _B '−P _BREF | is used in the prediction process HP _1A . · V _G / V _B -I _BREF | or | I _GINT · V _INT / V _B -I _BREF | (this corresponds to the above conversion), and the absolute value | I _G · V _G / V _B -I _BREF | Or | I _GINT · V _INT / V _B −I _BREF | may be compared with the threshold TH _1A .

Similarly, the ratio between the voltage value V _G and the voltage value (effective value) V _S , the ratio of the voltage value V _INT and the voltage value (effective value) V _S , or the voltage values V _G , V _S and V _INT are controlled. if parts 23 is known to the control unit 23 can also form a prediction process _{HP 1C} and _{HP 1D} and cancellation determination processing _{J 1C} and _{J 1D} using only current value _{I G} or _{I GINT.} At this time, in the processes HP _1C , HP _1C , J _1C and J _1D described above, arbitrary “power amount” and “symbol representing power amount” are set to “current value” and “current value” using information on known voltages. The process realized through this conversion is equivalent to the processes HP _1C , HP _1C , J _1C and J _1D described above.

Similarly, in the second embodiment, the ratio between the voltage value V _G and the voltage value V _B , the ratio between the voltage value V _INT and the voltage value V _B , the voltage value V _G and the voltage value (effective value) V _S. If the ratio, voltage value V _INT and voltage value (effective value) V _S ratio, voltage values V _G , V _B and V _INT , or voltage values V _G , V _S and V _INT are known to the control unit 23 if, the control unit 23 can also form a release determination process _{J 2} using only current value _{I G} or _{I GINT.} At this time, the release determination process J ₂ described above, converted into a "symbol representing the current value of" any "watt" and "symbol represents the amount of power""current" and by using the information of the known voltage it is sufficient, processing realized through this transform is equivalent to the release determination process J ₂ above.

[Note 4]
As described above, in charging quantitative control, the charging condition of the power storage device 3 (hereinafter referred to as charging condition) is specified by the charging reference condition, and in discharging quantitative control, the discharging condition of the power storage device 3 (hereinafter referred to as discharging condition). Is specified in the discharge reference condition, and in the grid output quantitative control, the power output condition from the power conversion circuit (20 or 20a) to the power grid 5 (hereinafter referred to as the grid output condition) is specified in the grid output reference condition. In the system input quantitative control, the power input condition (hereinafter referred to as system input condition) from the power system 5 to the power conversion circuit (20 or 20a) is designated by the system input reference condition.

In the first embodiment, the specific method of the hunting suppression control CNT _1A for changing the charging condition from the charging reference condition on the assumption that the charging reference condition defines the reference power amount P _BREF for power storage has been described. The above-described method is only one method for changing the charging condition from the charging reference condition.

That is, the suppression control CNT _1A can be realized by any method that can change the charging condition of the power storage device 3 (condition of the electric energy, current value, or voltage value in charging) from the charging reference condition. For example, in the charging quantitative control, when the control unit 23 has given current instruction values I _B ^* which specifies the current value I _B to the power conversion unit 21B, that is, the control unit 23 via the control of the current value I _B charge When realizing the hunting suppression control CNT _1A in the case where the quantitative control is realized, the control unit 23 changes the charge command by changing the current command amount I _B ^* from the current value (I _BREF ) according to the charge reference condition. You may change from conditions. Alternatively, for example, in the charging quantitative control, when the control unit 23 has given voltage command value V _B ^* that specifies the voltage value V _B to the power conversion unit 21B, that is, the control unit 23 via the control voltage value V _B When realizing the hunting suppression control CNT _1A when the charge quantitative control is realized, the control unit 23 changes the voltage command amount V _B ^* from the voltage amount V _BREF according to the charge reference condition, thereby changing the charge condition to the charge reference condition. (P _BREF = I _BREF × V _BREF ). In any case, a change in the charging condition by the suppression control CNT _1A is accompanied by a change in the amount of charging power of the power storage device 3 (for example, a change from P _BREF ).

Similarly, the suppression control CNT _1B can be realized by any method that can change the discharge condition of the power storage device 3 (the condition of the electric energy, current value, or voltage value in discharge) from the discharge reference condition. For example, in the discharge quantitative control, when the control unit 23 has given current instruction values I _B ^* which specifies the current value I _B to the power conversion unit 21B, that is, the control unit 23 via the control of the current value I _B discharge When realizing the hunting suppression control CNT _1B in the case where the quantitative control is realized, the control unit 23 changes the discharge condition by changing the current command amount I _B ^* from the current value (I _BREF ) according to the discharge reference condition. You may change from conditions. Alternatively, for example, in the discharge quantitative control, when the control unit 23 has given voltage command value V _B ^* that specifies the voltage value V _B to the power conversion unit 21B, that is, the control unit 23 via the control voltage value V _B When the hunting suppression control CNT _1B is achieved when the quantitative discharge control is realized, the control unit 23 changes the voltage command amount V _B ^* from the voltage amount V _BREF according to the discharge reference condition, thereby changing the discharge condition to the discharge reference condition. It may be changed from In any case, a change in the discharge condition by the suppression control CNT _1B is accompanied by a change in the amount of discharge power of the power storage device 3 (for example, a change from P _BREF ).

Each of P _B ^* , I _B ^*, and V _B ^* is a kind of command amount (charge / discharge command amount) that specifies the charge condition or the discharge condition. P _BREF , I _BREF, and V _BREF are all _types of reference amounts (charge / discharge reference amounts) according to the charge reference condition or the discharge reference condition.

Similarly, the suppression control CNT _1C changes the system output condition (the power amount, current value or voltage value condition in the power output from the power conversion circuit (20 or 20a) to the power system 5) from the system output reference condition. It can be realized by an arbitrary method. For example, the channel output quantitative control, the current instruction values I _S ^* by the control unit 23 specifies the current value I _S If given to the power conversion unit 21S, i.e. the control unit 23 via the control of the current value I _S When the hunting suppression control CNT _1C is realized when the system output quantitative control is realized, the control unit 23 changes the current command amount I _S ^* from the current value (I _SREF ) in accordance with the system output reference condition, thereby generating the system output. The condition may be changed from the system output reference condition. Alternatively, for example, in the channel output quantitative control, when the control unit 23 has given voltage command value V _S ^* to specify the voltage value V _S to the power conversion unit 21S, i.e. the control unit 23 via the control voltage value V _S When the system output quantitative control is realized, when the hunting suppression control CNT _1C is performed, the control unit 23 changes the voltage command amount V _S ^* from the voltage amount V _SREF according to the system output reference condition, thereby generating the system output condition. _May be changed from the system output reference condition (P _SREF = I _SREF × V _SREF ). In any case, the change in the grid output condition by the suppression control CNT _1C is accompanied by the change in the output power amount from the power conversion circuit (20 or 20a) to the power grid 5 (for example, the change from P _SREF ).

Similarly, the suppression control CNT _1D changes the grid input condition (the power amount, current value or voltage value condition in the power input from the power grid 5 to the power conversion circuit (20 or 20a)) from the grid input reference condition. It can be realized by an arbitrary method. For example, the system inputs quantitative control, the current instruction values I _S ^* by the control unit 23 specifies the current value I _S If given to the power conversion unit 21S, i.e. the control unit 23 via the control of the current value I _S When the hunting suppression control CNT _1D is realized when the system input quantitative control is realized, the control unit 23 changes the current command amount I _S ^* from the current value (I _SREF ) according to the system input reference condition, thereby inputting the system input. The condition may be changed from the system input reference condition. Alternatively, for example, in the system input quantitative control, when the control unit 23 has given voltage command value V _S ^* to specify the voltage value V _S to the power conversion unit 21S, i.e. the control unit 23 via the control voltage value V _S When the hunting suppression control CNT _1D is realized when the system input quantitative control is realized, the control unit 23 changes the voltage command amount V _S ^* from the voltage amount V _SREF according to the system input reference condition to May be changed from the system input reference condition. In any case, a change in the grid input condition by the suppression control CNT _1D is accompanied by a change in the amount of input power (for example, a change from P _SREF ) from the power grid 5 to the power conversion circuit (20 or 20a).

Each of P _S ^* , I _S ^*, and V _S ^* is a kind of command amount (system input / output command amount) that specifies a system output condition or a system input condition. P _SREF , I _SREF, and V _SREF are all types of reference quantities (system input / output reference quantities) according to the system output reference condition or the system input reference condition.

[Note 5]
The input / output power information to be acquired by the control unit 23 is not necessarily required to include all information indicating the voltage value, current value, and power amount. In the first to third embodiments, the input / output power information includes voltage information representing voltage values (that is, V _B , V _G , V _S and V _INT , or V _B , V _Ba , V _G , V _S and V _INT ), current information representing a current value (ie, I _B , I _G , I _S , I _BINT , I _GINT and I _SINT , or I _B , I _Ba , I _G , I _S , I _BINT , I _BINTa , I _GINT and I _SINT ) and power information representing the amount of power (ie, P _B , P _G , P _S , P _BINT , P _GINT and P _SINT , or P _B , P _Ba , P _G , P _S , P _BINT , P _BINTA , P _GINT, and P _SINT ) only need to be included.

[Note 6]
The power conversion units 21B, 21Ba, 21G, and 21S respectively include a first power storage side circuit, a second power storage side circuit, a power generation side circuit, and a system connected to the power storage device 3, the power storage device 3a, the power generation device 4, and the power system 5. This is an example of the side circuit, and the first power storage side circuit, the second power storage side circuit, the power generation side circuit, or the system side circuit further includes a circuit other than the circuit that forms the power conversion unit 21B, 21Ba, 21G, or 21S. May be.

[Note 7]
In each of the first to third embodiments, the DC load 8 and the secondary battery 8a may be connected to the intermediate wiring 22 as shown in FIG. The secondary battery 8a is composed of one or more secondary batteries of any type (for example, a lithium ion battery or a nickel metal hydride battery). The secondary battery 8a is a battery mounted on an electric vehicle such as an electric vehicle, for example. When the DC load 8 and the secondary battery 8a are connected to the intermediate wiring 22, in each of the above description including the description of the first to third embodiments, the power sent to the DC load 8 is changed to the DC load 8 and What is necessary is just to consider it as the electric power sent to the secondary battery 8a, that is, for example, the power consumption of the DC load 8 is regarded as the sum of the power consumption of the DC load 8 and the charging power of the secondary battery 8a and the power supplied to the DC load 8 May be regarded as the power supplied to the DC load 8 and the secondary battery 8a. When the DC load 8 and the secondary battery 8a are connected to the intermediate wiring 22, one or more power conversion units may be interposed between the intermediate wiring 22, the DC load 8, and the secondary battery 8a.

  Alternatively, in each of the first to third embodiments, as shown in FIG. 24B, a secondary battery 8 a may be connected to the intermediate wiring 22 instead of the DC load 8. In the configuration shown in FIG. 24B, the DC load 8 is not connected to the intermediate wiring 22. When the secondary battery 8a is connected to the intermediate wiring 22 without being connected to the DC load 8, the power sent to the DC load 8 in each of the above-described explanations including the explanations of the first to third embodiments. What is necessary is just to regard the power sent to the secondary battery 8a, that is, for example, the power consumption of the DC load 8 is regarded as the charging power of the secondary battery 8a and the power supplied to the DC load 8 is the power supplied to the secondary battery 8a. You should consider it. When the secondary battery 8a is connected to the intermediate wiring 22 without connecting the DC load 8, a power conversion unit may be interposed between the intermediate wiring 22 and the secondary battery 8a.

[Note 8]
The control unit 23 can be configured by hardware or a combination of hardware and software. A function realized using software may be described as a program, and the function may be realized by executing the program on a program execution device (for example, a computer). Specifically, for example, a CPU (Central Processing Unit) is provided in the control unit 23, and a necessary function can be realized by causing the CPU to execute a program stored in a flash memory (not shown).

DESCRIPTION OF SYMBOLS 1, 1a Power supply system 2, 2a Power conversion device 3, 3a Power storage device 4 Power generation device 5 Power system 8 DC load 20, 20a Power conversion circuit 21B, 21Ba, 21G, 21S Power conversion unit 22 Intermediate wiring 23 Control unit

Claims (5)

A power storage side circuit connected to a power storage device capable of charging and discharging, a power generation side circuit connected to a power generation device that generates power and outputs generated power, and a system side circuit connected to a power system, and converts power A power conversion circuit that performs power transmission and reception between the power storage device, the power generation device, and the power system via
A control unit for controlling the power transmission and reception by controlling the power conversion circuit,
The control unit absorbs a deficiency or surplus of the generated power at an input / output of power between the power conversion circuit and the power system, and uses the generated power of the power generation device to fix the power storage device to a certain level. The battery is charged under a first reference condition, or power is supplied to at least one of a load and a secondary battery connected to the power conversion circuit using generated power of the power generation device and discharge power of the power storage device. Execute quantitative control to discharge the power storage device under a constant second reference condition,
In the quantitative control, when switching of power input / output between the power conversion circuit and the power system is detected a predetermined number of times or more within a predetermined time, or depending on the amount of power generated by the power generation device or the amount of power generated When the occurrence of the switching is predicted based on the measured value and the first reference condition or the second reference condition, the control unit generates power generated by the power generator via a change in the power point of the power generator. A power conversion apparatus that performs suppression control that suppresses the switching by changing an amount. A power storage side circuit connected to a power storage device capable of charging and discharging, a power generation side circuit connected to a power generation device that generates power and outputs generated power, and a system side circuit connected to a power system, and converts power A power conversion circuit that performs power transmission and reception between the power storage device, the power generation device, and the power system via
A control unit for controlling the power transmission and reception by controlling the power conversion circuit,
The control unit absorbs a shortage or surplus of the generated power by charging or discharging the power storage device, and uses the generated power of the power generation device to make a constant first power from the power conversion circuit to the power system. Outputs power under reference conditions, or supplies power to at least one of a load and a secondary battery connected to the power conversion circuit using the generated power and input power from the power system to the power conversion circuit To perform quantitative control for inputting electric power from the electric power system to the electric power conversion circuit under a constant second reference condition,
In the quantitative control, when switching of power input / output between the power conversion circuit and the power storage device is detected a predetermined number of times or more within a predetermined time, the power generation amount of the power generation device or a value corresponding to the power generation amount And when the occurrence of the switching is predicted based on the first reference condition or the second reference condition, the control unit determines the power generation amount of the power generation device through a change in the power point of the power generation device. A power conversion device that executes suppression control that suppresses the switching by changing. The control unit controls the power generation side circuit to operate the power generation device at a first power point that maximizes the amount of power generated by the power generation device before the detection or the prediction is performed, After the prediction is made, the suppression control is realized by controlling the power generation side circuit so that the power point of the power generator is changed to a second power point different from the first power point. The power converter according to claim 1 or 2. The control unit, during an execution period of the suppression control, based on a value corresponding to the amount of generated power of the power generation device or the amount of generated power, and the previous first reference condition or the second reference condition, The power converter according to any one of claims 1 to 3, wherein execution of the suppression control is canceled when it is determined that a cancellation condition is satisfied. The said control part cancels | releases execution of the said suppression control when the said switching is detected during the execution period of the said suppression control, The power converter device in any one of Claims 1-3 characterized by the above-mentioned. .

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