WO2016063355A1 - 充放電管理装置 - Google Patents
充放電管理装置 Download PDFInfo
- Publication number
- WO2016063355A1 WO2016063355A1 PCT/JP2014/077977 JP2014077977W WO2016063355A1 WO 2016063355 A1 WO2016063355 A1 WO 2016063355A1 JP 2014077977 W JP2014077977 W JP 2014077977W WO 2016063355 A1 WO2016063355 A1 WO 2016063355A1
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- WO
- WIPO (PCT)
- Prior art keywords
- power
- charge
- discharge
- storage battery
- target value
- Prior art date
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- 238000010248 power generation Methods 0.000 claims abstract description 109
- 238000012806 monitoring device Methods 0.000 claims abstract description 15
- 238000013459 approach Methods 0.000 claims abstract description 7
- 230000008859 change Effects 0.000 claims description 102
- 230000005855 radiation Effects 0.000 claims description 46
- 230000006866 deterioration Effects 0.000 claims description 28
- 238000007599 discharging Methods 0.000 claims description 26
- 238000012544 monitoring process Methods 0.000 claims description 5
- 230000007423 decrease Effects 0.000 claims description 4
- 238000006243 chemical reaction Methods 0.000 abstract description 4
- 230000006870 function Effects 0.000 description 49
- 238000000034 method Methods 0.000 description 28
- 230000008569 process Effects 0.000 description 27
- 238000012545 processing Methods 0.000 description 22
- 230000003247 decreasing effect Effects 0.000 description 19
- 238000010586 diagram Methods 0.000 description 16
- 230000005540 biological transmission Effects 0.000 description 12
- HBBGRARXTFLTSG-UHFFFAOYSA-N Lithium ion Chemical compound [Li+] HBBGRARXTFLTSG-UHFFFAOYSA-N 0.000 description 5
- 229910001416 lithium ion Inorganic materials 0.000 description 5
- 230000004048 modification Effects 0.000 description 4
- 238000012986 modification Methods 0.000 description 4
- BNOODXBBXFZASF-UHFFFAOYSA-N [Na].[S] Chemical compound [Na].[S] BNOODXBBXFZASF-UHFFFAOYSA-N 0.000 description 2
- 238000001514 detection method Methods 0.000 description 2
- 238000005259 measurement Methods 0.000 description 2
- 230000000087 stabilizing effect Effects 0.000 description 2
- 238000004364 calculation method Methods 0.000 description 1
- 230000007613 environmental effect Effects 0.000 description 1
- 229910052987 metal hydride Inorganic materials 0.000 description 1
- 229910052759 nickel Inorganic materials 0.000 description 1
- PXHVJJICTQNCMI-UHFFFAOYSA-N nickel Substances [Ni] PXHVJJICTQNCMI-UHFFFAOYSA-N 0.000 description 1
- -1 nickel metal hydride Chemical class 0.000 description 1
- 230000009467 reduction Effects 0.000 description 1
- 230000004044 response Effects 0.000 description 1
- 230000001629 suppression Effects 0.000 description 1
Images
Classifications
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/34—Parallel operation in networks using both storage and other dc sources, e.g. providing buffering
- H02J7/35—Parallel operation in networks using both storage and other dc sources, e.g. providing buffering with light sensitive cells
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/28—Arrangements for balancing of the load in a network by storage of energy
- H02J3/32—Arrangements for balancing of the load in a network by storage of energy using batteries with converting means
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/38—Arrangements for parallely feeding a single network by two or more generators, converters or transformers
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/38—Arrangements for parallely feeding a single network by two or more generators, converters or transformers
- H02J3/381—Dispersed generators
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for ac mains or ac distribution networks
- H02J3/38—Arrangements for parallely feeding a single network by two or more generators, converters or transformers
- H02J3/46—Controlling of the sharing of output between the generators, converters, or transformers
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/007—Regulation of charging or discharging current or voltage
- H02J7/00712—Regulation of charging or discharging current or voltage the cycle being controlled or terminated in response to electric parameters
- H02J7/007182—Regulation of charging or discharging current or voltage the cycle being controlled or terminated in response to electric parameters in response to battery voltage
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02S—GENERATION OF ELECTRIC POWER BY CONVERSION OF INFRARED RADIATION, VISIBLE LIGHT OR ULTRAVIOLET LIGHT, e.g. USING PHOTOVOLTAIC [PV] MODULES
- H02S40/00—Components or accessories in combination with PV modules, not provided for in groups H02S10/00 - H02S30/00
- H02S40/30—Electrical components
- H02S40/32—Electrical components comprising DC/AC inverter means associated with the PV module itself, e.g. AC modules
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02S—GENERATION OF ELECTRIC POWER BY CONVERSION OF INFRARED RADIATION, VISIBLE LIGHT OR ULTRAVIOLET LIGHT, e.g. USING PHOTOVOLTAIC [PV] MODULES
- H02S40/00—Components or accessories in combination with PV modules, not provided for in groups H02S10/00 - H02S30/00
- H02S40/30—Electrical components
- H02S40/38—Energy storage means, e.g. batteries, structurally associated with PV modules
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J2300/00—Systems for supplying or distributing electric power characterised by decentralized, dispersed, or local generation
- H02J2300/20—The dispersed energy generation being of renewable origin
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J2300/00—Systems for supplying or distributing electric power characterised by decentralized, dispersed, or local generation
- H02J2300/20—The dispersed energy generation being of renewable origin
- H02J2300/22—The renewable source being solar energy
- H02J2300/24—The renewable source being solar energy of photovoltaic origin
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/007—Regulation of charging or discharging current or voltage
- H02J7/0071—Regulation of charging or discharging current or voltage with a programmable schedule
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/007—Regulation of charging or discharging current or voltage
- H02J7/00712—Regulation of charging or discharging current or voltage the cycle being controlled or terminated in response to electric parameters
- H02J7/00714—Regulation of charging or discharging current or voltage the cycle being controlled or terminated in response to electric parameters in response to battery charging or discharging current
- H02J7/00716—Regulation of charging or discharging current or voltage the cycle being controlled or terminated in response to electric parameters in response to battery charging or discharging current in response to integrated charge or discharge current
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/50—Photovoltaic [PV] energy
- Y02E10/56—Power conversion systems, e.g. maximum power point trackers
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E70/00—Other energy conversion or management systems reducing GHG emissions
- Y02E70/30—Systems combining energy storage with energy generation of non-fossil origin
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P90/00—Enabling technologies with a potential contribution to greenhouse gas [GHG] emissions mitigation
- Y02P90/50—Energy storage in industry with an added climate change mitigation effect
Definitions
- the present invention relates to a charge / discharge management device provided in a power generation facility including a power generation system and a storage battery system.
- the power system is constructed by connecting power generation equipment and load equipment with power transmission and distribution equipment.
- power systems There are various types of power systems ranging from large-scale systems that connect multiple large-scale power plants to many factories, commercial facilities, and homes, to small-scale systems built within specific facilities. To do.
- One type of power generation equipment includes a power generation system that uses natural energy such as sunlight and wind power. Power generation systems using natural energy are being widely introduced in response to the recent increase in awareness of energy problems and environmental problems. However, a power generation system using natural energy has a disadvantage in that stable power supply cannot be performed because generated power is easily influenced by natural factors such as season and weather. In order to compensate for this shortcoming, power generation facilities combined with a power generation system and a storage battery system have been considered.
- the storage battery system is used as one means for stabilizing the power supplied from the power generation facility to the power system.
- it was considered difficult to store large amounts of power but the storage of large amounts of power has become possible due to the practical use of large-capacity storage batteries such as lithium-ion batteries and sodium-sulfur batteries. .
- large-capacity storage batteries such as lithium-ion batteries and sodium-sulfur batteries.
- By connecting a storage battery system including such a storage battery to the power generation system when the supply is excessive with respect to the power demand, the storage battery is charged with excess power and when the supply is insufficient with respect to the power demand. Therefore, it is possible to make up for the shortage of power by discharging from the storage battery.
- Combining a storage battery system with a power generation system that uses natural energy makes it possible to level the generated power that fluctuates depending on the season and weather, etc., by charging and discharging the storage battery, and to supply power stably to the power system.
- Patent Document 1 discloses a configuration in which a photovoltaic power generation system and a storage battery system are connected, and fluctuations in power generated by photovoltaic power generation are suppressed by charge / discharge control of the storage battery.
- the life of a storage battery varies depending on the SoC (State of Charge) to be held.
- SoC State of Charge
- the present invention has been made to solve the above-described problems, and is provided in a power generation facility including a power generation system and a storage battery system in which generated power fluctuates depending on the weather, and is supplied to a power system connected to the power generation facility.
- An object of the present invention is to provide a charge / discharge management device capable of stabilizing power to be generated and suppressing deterioration of a storage battery.
- the power generation facility provided with the charge / discharge management device according to the present invention is configured as follows.
- the charge / discharge management apparatus is provided in a power generation facility connected to an electric power system.
- the power generation facility includes a power generation system in which generated power varies depending on the weather and a storage battery system.
- the charge / discharge management apparatus according to the present invention may be incorporated in a power generation system or a storage battery system. There is no limitation on the scale and configuration of the power generation equipment and power system.
- the power generation system whose generated power fluctuates depending on the weather is, for example, a solar power generation system or a wind power generation system.
- the power generation system includes a power meter that detects generated power.
- the storage battery system includes a storage battery, a storage battery monitoring device, and an AC / DC conversion device.
- a storage battery may be comprised by the single storage battery cell, and may be comprised as the aggregate
- a large-capacity storage battery such as a lithium ion battery, a sodium sulfur battery, or a nickel metal hydride battery is preferable.
- the storage battery monitoring device is a device that monitors the state of the storage battery. Examples of monitoring items by the storage battery monitoring device include state quantities such as current, voltage, and temperature.
- the storage battery monitoring device measures a state quantity, which is a monitoring item, at all times or at a predetermined cycle by a sensor, and outputs part or all of the obtained data to the outside as storage battery information.
- the AC / DC converter is a device that connects a storage battery to the power generation system, converts the AC power output by the power generation system into DC power and charges the storage battery, and converts the DC power of the storage battery into AC power to convert the power system It has a function of discharging.
- the AC / DC converter is also called a power conditioner, and the amount of charge power to the storage battery and the amount of discharge power from the storage battery are adjusted by the AC / DC converter.
- the charge / discharge management device is connected to a power meter, a storage battery monitoring device, and an AC / DC conversion device.
- the charge / discharge management device includes a charge / discharge command unit.
- the charge / discharge command unit is based on the generated power detected by the power meter and the storage battery information supplied from the storage battery monitoring device, and the rate of change per unit time of power supplied to the power system relative to the rating (hereinafter simply referred to as “system”).
- the charging / discharging command for the AC / DC converter is determined so that the “supplied power change rate” is within a fluctuation range of ⁇ n% and the SoC of the storage battery approaches the SoC target value.
- the rating is, for example, the rating of the power generation facility or the power generation system, and the previous measurement value by a power meter may be used.
- SoC means the charging rate with respect to the full charge of the storage battery.
- the SoC is included in the storage battery information supplied from the storage battery monitoring device. Note that SoC can be calculated from the integrated value of the current flowing through the storage battery. Since the voltage and the SoC have a correlation, the SoC may be calculated from the voltage using a predetermined relation map or relational expression.
- the SoC target value is preferably set to an ideal value suitable for suppressing deterioration of the storage battery. Further, since there is a correlation between the voltage and the SoC, the SoC may be replaced with the voltage, and the SoC target value may be replaced with the voltage target value.
- the charge / discharge command unit is configured such that the SoC is lower than the SoC target value and the rate of change per unit time of the generated power detected by the power meter with respect to the rating (hereinafter simply referred to as “ When the power generation change rate is + n% or more, the charge power is increased or decreased from the previous charge / discharge command so that the power supply change rate is -n% or more and less than 0%. Determine the charge / discharge command.
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is -n%.
- the charge / discharge command unit determines that when the SoC is lower than the SoC target value and the generated power change rate is ⁇ n% or less, the grid supply power change rate is ⁇ n% or more and less than 0%.
- a charge / discharge command for raising the discharge power or lowering the charge power over the charge / discharge command is determined.
- the charge / discharge command for increasing the discharge power or decreasing the charge power over the previous charge / discharge command is determined so that the rate of change in the system supply power becomes ⁇ n%.
- the charge / discharge command unit has a power supply change rate of ⁇ n% or more and less than 0% when the SoC is lower than the SoC target value and the generated power change rate is higher than ⁇ n% and lower than + n%.
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined.
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is -n%.
- the charge / discharge command unit sets the previous charge so that when the SoC is higher than the SoC target value and the generated power change rate is + n% or more, the grid supply power change rate is greater than 0% and less than + n%.
- a charge / discharge command that increases the charge power or lowers the discharge power over the discharge command is determined.
- the charging / discharging command for increasing the charging power or decreasing the discharging power from the previous charging / discharging command is determined so that the rate of change in the system power supply is + n%.
- the charge / discharge command unit determines that when the SoC is higher than the SoC target value and the generated power change rate is ⁇ n% or less, the grid supply power change rate is greater than 0% and less than + n%.
- a charge / discharge command for raising the discharge power or lowering the charge power over the charge / discharge command is determined.
- a charge / discharge command for increasing the discharge power or decreasing the charge power over the previous charge / discharge command is determined so that the rate of change in the system power supply is + n%.
- the charge / discharge command unit has a grid supply power change rate of greater than 0% and less than + n% when the SoC is higher than the SoC target value and the generated power change rate is greater than -n% and less than + n%.
- the charge / discharge command for increasing the discharge power or decreasing the charge power over the previous charge / discharge command is determined.
- a charge / discharge command for increasing the discharge power or decreasing the charge power over the previous charge / discharge command is determined so that the rate of change in the system power supply is + n%.
- Embodiment 1 is a block diagram of a system according to Embodiment 1 of the present invention. It is a figure for demonstrating the fluctuation
- 5 is a flowchart of a control routine executed by a charge / discharge management device 60 in the system according to Embodiment 1 of the present invention. It is a flowchart of the charging / discharging instruction
- FIG. 7 is a flowchart of a control routine executed by a charge / discharge management device 60 in a system according to Embodiment 2 of the present invention. It is a figure for demonstrating the scheduling of the SoC target value in the system which concerns on Embodiment 3 of this invention. It is a block diagram of the system which concerns on Embodiment 3 of this invention. It is a flowchart of the control routine which the charge / discharge management apparatus 60 performs in the system which concerns on Embodiment 3 of this invention. It is a block diagram of the system which concerns on Embodiment 5 of this invention. It is a flowchart of the control routine which the charge / discharge management apparatus 60 performs in the system which concerns on Embodiment 5 of this invention.
- FIG. 1 is a conceptual configuration diagram for explaining a system configuration according to Embodiment 1 of the present invention.
- a power generation facility 10 shown in FIG. 1 is connected to a power transmission facility 20 of a power system.
- the power system includes other power generation facilities (not shown) connected to the power transmission facility 20 and load facilities (not shown) connected to the power transmission facility 20.
- the power generation facility 10 includes a power generation system 30 and a storage battery system 40 whose generated power varies depending on the weather.
- the power generation system 30 and the storage battery system 40 are connected via the in-facility electric wire 21.
- the power generation facility 10 includes a main site controller (MSC) 50.
- MSC main site controller
- the power generation system 30, the storage battery system 40, and the main site controller 50 are connected via the computer network 22.
- a wattmeter 25 is provided at a connection point between the power generation facility 10 and the power system.
- the wattmeter 25 is connected to the main site controller 50 by a signal line.
- the power generation system 30 shown in FIG. 1 is a photovoltaic power generation (PV) system.
- the power generation system 30 may be a wind power generation system or the like.
- the power generation system 30 includes a solar power generation module 31, an AC / DC converter (hereinafter referred to as PV-PCS) 32 for solar power generation, and a wattmeter 33.
- PV-PCS AC / DC converter
- a plurality of photovoltaic power generation modules 31 are connected to one PV-PCS 32.
- FIG. 1 there are three photovoltaic power generation modules 31, but this is merely an example.
- the PV-PCS 32 is connected to the in-facility electric wire 21 via the wattmeter 33.
- the wattmeter 33 is connected to the main site controller 50 by a signal line.
- the wattmeter 33 constantly detects the generated power supplied from the power generation system 30 to the in-facility electric wire 21.
- the constant detection in the present embodiment is a concept including not only an operation of capturing a continuous signal from a sensor but also an operation of capturing a sensor signal at a predetermined short cycle.
- the generated power value detected by the wattmeter 33 is input to the main site controller 50.
- the storage battery system 40 includes a storage battery AC / DC converter (hereinafter referred to as a storage battery PCS) 41, a front battery control station panel (hereinafter referred to as an FBCS panel) 42, and a storage battery panel 43.
- a storage battery PCS storage battery AC / DC converter
- FBCS panel front battery control station panel
- a storage battery panel 43 storage battery panel 43.
- one FBCS panel 42 is connected to one storage battery PCS 41
- a plurality of storage battery panels 43 are connected in parallel to one FBCS panel 42.
- the storage battery panels 43 are arranged in three rows, but this is merely an example.
- the parallel number of the storage battery panels 43 is determined based on the specification of the storage battery PCS 41. Therefore, the parallel number of the storage battery panels 43 may be one row.
- the storage battery panel 43 includes a fuse 431, a contactor 432, a storage battery module 433, and a storage battery monitoring device (hereinafter referred to as BMU: Battery Management Unit) 434.
- the storage battery module 433 is a module in which a plurality of cells are connected in series. Each cell is a lithium ion battery (LiB).
- the storage battery module 433 is connected to the FBCS board 42 by a power transmission line via the contactor 432 and the fuse 431.
- the storage battery module 433 is connected to the BMU 434 through a signal line.
- the BMU 434 is connected to the control device 421 on the FBCS board 42 via the computer network 23 and is connected to the contactor 432 via a signal line.
- the BMU 434 monitors the state of the storage battery module 433.
- the BMU 434 includes a current sensor, a voltage sensor, and a temperature sensor as means for measuring the state quantity of the storage battery module 433.
- the current flowing through the storage battery module 433 is measured by the current sensor.
- the voltage of each cell is measured by the voltage sensor.
- the temperature of the storage battery module 433 is measured by the temperature sensor.
- Monitoring of the storage battery module 433 by the BMU 434 is always performed.
- the constant monitoring in the present embodiment is a concept including not only an operation of capturing a continuous signal from a sensor but also an operation of capturing a sensor signal at a predetermined short cycle.
- the BMU 434 transmits storage battery information including information obtained by measurement by each sensor to the control device 421.
- the contactor 432 is disposed between the fuse 431 and the storage battery module 433.
- the contactor 432 receives a closing signal
- the contact is turned on and turned on.
- the contactor 432 receives the opening signal
- the contact is turned OFF and opened.
- the closing signal is a current greater than or equal to a predetermined value [A]
- the release signal is a current less than a predetermined value [A].
- the FBCS panel 42 is connected to the storage battery panel 43 and the storage battery PCS 41. Specifically, each storage battery panel 43 is connected to the FBCS panel 42 by an individual power transmission line. The individual power transmission lines merge inside the FBCS board 42 and are connected to a thicker power transmission line. The merged power transmission line is connected to the storage battery PCS 41.
- the FBCS board 42 includes a control device 421.
- the control device 421 includes, for example, a memory including a ROM and a RAM, an input / output interface that inputs and outputs various types of information, and a processor that can execute various types of arithmetic processing based on the various types of information.
- the control device 421 is connected to the MCS 50 via the computer network 22, to the BMU 434 via the computer network 23, and to the storage battery PCS 41 via the computer network 24.
- the control device 421 is connected to the contactor 432 through a signal line.
- the control device 421 issues a charge / discharge command to the storage battery PCS 41.
- the charge / discharge command includes a request regarding active power and reactive power to be charged / discharged by the storage battery PCS 41.
- the charge / discharge command is determined by a charge / discharge command unit 61 described later.
- the control device 421 has a function of outputting a trip command to the storage battery PCS 41, a function of opening and closing the contactor 432, and the like.
- the storage battery PCS 41 is connected to the in-facility electric wire 21 by a power transmission line via a transformer.
- the storage battery PCS 41 converts the AC power output from the power generation system 30 into DC power and charges the storage battery module 433, and the discharge function converts the DC power of the storage battery module 433 into AC power and discharges it to the power system. With.
- the amount of charge power to the storage battery module 433 and the amount of discharge power from the storage battery module 433 are adjusted by the storage battery PCS 41. Adjustment of the charge / discharge power amount by the storage battery PCS 41 is performed in accordance with a charge / discharge command supplied from the control device 421.
- the storage battery PCS 41 includes a current sensor and a voltage sensor, and the storage battery PCS 41 refers to the output values of these sensors to adjust the charge / discharge power amount.
- the main site controller 50 includes, for example, a memory including a ROM and a RAM, an input / output interface for inputting / outputting various information, and a processor capable of executing various arithmetic processes based on the various information.
- the main site controller 50 is connected to the PV-PCS 32 and the control device 421 through the computer network 22.
- the main site controller 50 is connected to the wattmeter 33 by a signal line.
- the main site controller 50 controls power supply and demand between the power system and the power generation facility 10.
- the main site controller 50 has a charge / discharge command function described later and a PV-PCS output suppression function that suppresses the output of the power generation system 30 when the storage battery module 433 is in a fully charged state.
- the wattmeter 25 constantly detects the combined power supplied from the power generation facility 10 to the power system.
- the combined power is a power obtained by adding the generated power of the power generation system 30 and the charge / discharge power of the storage battery system 40.
- the constant detection in the present embodiment is a concept including not only an operation of capturing a continuous signal from a sensor but also an operation of capturing a sensor signal at a predetermined short cycle.
- the combined power value detected by the wattmeter 25 is input to the main site controller 50.
- FIG. 2 is a block diagram of a system according to Embodiment 1 of the present invention.
- the charge / discharge management device 60 according to the present invention is a concept that can include a main site controller 50 and a control device 421.
- main site controller 50 In the block showing the main site controller 50, some of various functions of the main site controller 50 are represented by blocks. Computing resources are allocated to each of these blocks. A program corresponding to each block is prepared in the main site controller 50, and the functions of each block are realized in the main site controller 50 by executing them by a processor.
- control device 421 some of various functions provided in the control device 421 are represented by blocks. Computing resources are allocated to each of these blocks. A program corresponding to each block is prepared in the control device 421, and the functions of each block are realized in the control device 421 by being executed by the processor.
- the charge / discharge management device 60 has a charge / discharge command function, and the charge / discharge command unit 61 takes charge of the function.
- the charge / discharge management device 60 receives the combined power value from the wattmeter 25, receives the generated power value from the wattmeter 33, and receives storage battery information from the BMU 434.
- the charge / discharge command unit 61 determines a charge / discharge command based on the generated power value and the storage battery information, and transmits the charge / discharge command to the storage battery PCS 41.
- FIG. 3 is a diagram for explaining the fluctuation of the generated power for each time by the solar power generation system.
- This solar power generation system is used as the power generation system 30 of FIG.
- the output of the solar power generation system varies depending on the amount of solar radiation. A typical case is when a cloud is flowing in fine weather, and the output fluctuates rapidly in a short time as the shadow of the cloud passes over the solar panel. It is necessary to level the steep fluctuations by charging / discharging the storage battery system 40 so as to cancel the output fluctuations of the photovoltaic power generation.
- output fluctuation is reduced as indicated by a solid line 302 by charging and discharging the storage battery system 40 so as to cancel out the output of the photovoltaic power generation system indicated by the broken line 301.
- the charge / discharge command unit 61 determines the charge / discharge command so that the steep output fluctuation of the photovoltaic power generation is leveled by the charge / discharge control of the storage battery.
- SoC means a charging rate with respect to the full charge of the storage battery.
- the SoC is included in the storage battery information supplied from the storage battery monitoring device 434. Note that SoC can be calculated from the integrated value of the current flowing through the storage battery. Further, the lithium ion battery has a characteristic that the voltage is higher as the battery is fully charged, and the voltage is lower as the battery is closer to the sky. By utilizing this voltage-SoC characteristic, it is also possible to calculate the SoC from the measured voltage value.
- the voltage referred to in this embodiment means a voltage applied to both ends of the storage battery module 433.
- the life of the storage battery module 433 changes depending on the held voltage, that is, the held SoC.
- the holding voltage is a voltage at which deterioration of the storage battery can be most suppressed, and is different for each type of storage battery.
- the holding voltage range is a range suitable for suppressing deterioration of the storage battery module 433 with the holding voltage as the center, and is set in advance.
- the charge / discharge command unit 61 equalizes the generated power to stabilize the power supplied to the power system, and provides a charge / discharge command that can suppress deterioration of the storage battery module 433. It was decided to decide.
- the charge / discharge command unit 61 changes the rate of power supplied to the power system relative to the rating (hereinafter simply referred to as “system supply”).
- system supply the rating
- the charge / discharge command for the AC / DC converter 41 is determined so that the power change rate is within a fluctuation range of ⁇ n% / min and the SoC of the storage battery module 433 approaches the SoC target value.
- the charge / discharge command is determined at predetermined control intervals.
- the SoC target value is the SoC corresponding to the holding voltage described above.
- the charge / discharge command unit 61 has a SoC lower than the SoC target value and a change rate of the generated power detected by the power meter with respect to the rating (hereinafter simply referred to as “generated power change rate”) + n.
- Charge / discharge command to increase charge power or to lower discharge power than the previous charge / discharge command is determined so that the rate of change in system power supply is -n% / min or more and less than 0% / min.
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is ⁇ n% / min.
- the charge / discharge command unit 61 is configured such that when the SoC is lower than the SoC target value and the generated power change rate is ⁇ n% / min or less, the grid power supply change rate is ⁇ n% / min or more and 0% / min.
- a charging / discharging command that increases the discharging power or lowers the charging power over the previous charging / discharging command is determined so as to be less than the value.
- a charge / discharge command for increasing the discharge power or reducing the charge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is -n% / min.
- the charge / discharge command unit 61 has a system supply power change rate of ⁇ n% / min when the SoC is lower than the SoC target value and the generated power change rate is greater than ⁇ n% / min and smaller than + n% / min.
- a charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so as to be equal to or more than 0% and less than 0% / minute.
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is ⁇ n% / min.
- the charge / discharge command unit 61 has a power supply change rate of greater than 0% and less than + n% / min when the SoC is higher than the SoC target value and the change rate of the generated power is + n% / min or more.
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined.
- the charging / discharging command for increasing the charging power or decreasing the discharging power from the previous charging / discharging command is determined so that the rate of change in the system power supply is + n% / min.
- the charge / discharge command unit 61 is configured such that when the SoC is higher than the SoC target value and the generated power change rate is ⁇ n% / min or less, the grid supply power change rate is greater than 0% / min and + n% / min.
- the charge / discharge command is determined so that the discharge power is increased or the charge power is decreased compared to the previous charge / discharge command.
- a charge / discharge command for increasing the discharge power or reducing the charge power over the previous charge / discharge command is determined so that the rate of change in the system power supply is + n% / min.
- the charge / discharge command unit 61 has a grid supply power change rate of 0% / min when the SoC is higher than the SoC target value and the generated power change rate is greater than -n% / min and less than + n% / min.
- a charge / discharge command for increasing the discharge power or decreasing the charge power over the previous charge / discharge command is determined so as to be greater than + n% / min.
- a charge / discharge command for increasing the discharge power or reducing the charge power over the previous charge / discharge command is determined so that the rate of change in the system power supply is + n% / min.
- the charge / discharge command unit 61 is arranged in the main site controller 50, but the arrangement of the charge / discharge command unit 61 is not limited to this.
- the charge / discharge command unit 61 may be disposed in the control device 421. In this case, the generated power amount detected by the wattmeter 33 is transmitted to the control device 421 via the main site controller 50 or directly.
- FIG. 4 is a flowchart of a control routine executed by the charge / discharge management device 60 in the system according to Embodiment 1 of the present invention.
- the process of the main site controller 50 shown in this flowchart is a process realized by the function of the charge / discharge command unit 61.
- a program for executing the processing of the flowchart shown in FIG. 4 is stored in the memory of the main site controller 50, and the processing shown in FIG. 4 is realized by the processor of the main site controller 50 reading and executing the program.
- the wattmeter 33 constantly detects the generated power supplied from the power generation system 30 to the in-facility electric wire 21.
- the main site controller 50 acquires the generated power value from the wattmeter 33 at a predetermined short cycle (for example, every several tens of milliseconds) (step S101).
- the BMU 434 acquires the storage battery information at a predetermined short cycle (for example, every several tens of milliseconds) using the various sensors described above (step S401).
- the storage battery information includes the current flowing through the storage battery module 433, the voltage of each cell, and the temperature of the storage battery module 433. Thereafter, the BMU 434 transmits the acquired storage battery information to the control device 421 (step S402).
- the control device 421 receives the storage battery information transmitted from the BMU 434 (step S201).
- the control device 421 transmits the received storage battery information to the main site controller 50 (step S202).
- the main site controller 50 receives the storage battery information transmitted from the control device 421 (step S102).
- the charge / discharge command unit 61 changes the system supply power change rate by ⁇ n% / min based on the generated power acquired in step S101 and the storage battery information received in step S102.
- a charge / discharge command for the AC / DC converter is determined so as to be within the range and so that the SoC of the storage battery approaches the SoC target value (step S103). Note that the amount of power change per unit time varies depending on the control interval. When the control interval is 20 msec, it is necessary to control the power change amount for each control within a range of 1/3000 of ⁇ n%.
- step S103 Specific processing in step S103 will be described with reference to FIGS. 5 and 6 are flowcharts of a charge / discharge command determination routine executed by the charge / discharge command unit 61 in step S103.
- the charge / discharge command unit 61 determines whether the SoC of the storage battery module 433 is lower than the SoC target value based on the storage battery information (step S601). *
- the charge / discharge command unit 61 determines whether the generated power change rate is + n% / min or more (step S602). When the determination condition of step S602 is satisfied, the charge / discharge command unit 61 increases the charge power from the previous charge / discharge command so that the rate of change in the system power supply is ⁇ n% / min or more and less than 0% / min or A charge / discharge command for reducing the discharge power is determined (step S603).
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is ⁇ n% / min.
- step S604 determines whether the generated power change rate is ⁇ n% / min or less.
- the charge / discharge command unit 61 increases the discharge power from the previous charge / discharge command so that the rate of change in the system power supply is ⁇ n% / min or more and less than 0% / min or A charge / discharge command for reducing the charging power is determined (step S605).
- a charge / discharge command for increasing the discharge power or reducing the charge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is -n% / min.
- step S606 determines whether the generated power change rate is greater than ⁇ n% / min and smaller than + n% / min (step S606).
- the charge / discharge command unit 61 increases the charge power from the previous charge / discharge command so that the rate of change in the system power supply is ⁇ n% / min or more and less than 0% / min.
- a charge / discharge command for reducing the discharge power is determined (step S607).
- the charge / discharge command for increasing the charge power or decreasing the discharge power over the previous charge / discharge command is determined so that the rate of change in the system supply power is ⁇ n% / min.
- step S601 determines whether the SoC of the storage battery module 433 is higher than the SoC target value (FIG. 6, step S608).
- the charge / discharge command unit 61 determines whether the generated power change rate is + n% / min or more (step S609). When the determination condition in step S609 is satisfied, the charge / discharge command unit 61 increases the charge power from the previous charge / discharge command so that the rate of change in the system supply power is greater than 0% / min and less than or equal to + n% / min or A charge / discharge command for reducing the discharge power is determined (step S610).
- the charging / discharging command for increasing the charging power or decreasing the discharging power from the previous charging / discharging command is determined so that the rate of change in the system power supply is + n% / min.
- step S609 determines whether the generated power change rate is ⁇ n% / min or less (step S611).
- the charge / discharge command unit 61 increases the discharge power from the previous charge / discharge command so that the rate of change in the system supply power is greater than 0% / min and less than or equal to + n% / min or A charge / discharge command for reducing the charge power is determined (step S612).
- a charge / discharge command for increasing the discharge power or reducing the charge power over the previous charge / discharge command is determined so that the rate of change in the system power supply is + n% / min.
- step S613 determines whether the rate of change in generated power is greater than -n% / min and less than + n% / min (step S613).
- the charge / discharge command unit 61 increases the discharge power from the previous charge / discharge command so that the rate of change in the system supply power is greater than 0% / min and less than or equal to + n% / min or A charge / discharge command for reducing the charging power is determined (step S614).
- a charge / discharge command for increasing the discharge power or reducing the charge power over the previous charge / discharge command is determined so that the rate of change in the system power supply is + n% / min.
- step S601 and step S608 when the determination conditions of step S601 and step S608 are not satisfied, that is, when the SoC is equal to the SoC target value, the charge / discharge command unit 61 has a system supply power change rate within a range of ⁇ n% and the storage battery module 433. The charge / discharge command is determined so that the charge / discharge amount approaches 0 (step S615).
- step S104 the main site controller 50 transmits a charge / discharge command to the control device 421 (step S104).
- the control device 421 receives the charge / discharge command transmitted from the main site controller 50 (step S203).
- the control device 421 transmits the received charge / discharge command to the storage battery PCS 41 (step S204).
- the storage battery PCS 41 receives the charge / discharge command transmitted from the control device 421 (step S301).
- the storage battery PCS 41 performs a charge / discharge operation in accordance with a charge / discharge command (step S302).
- the charge / discharge management device 60 of the present embodiment equalizes fluctuations in generated power and controls the rate of change of power supplied to the power system within a range of ⁇ n% / min.
- the charge / discharge command is determined so that the SoC of the storage battery module 433 is as close as possible to the SoC target value. For this reason, according to the charge / discharge management device 60 of the present embodiment, the power supplied to the power system can be stabilized and the SoC of the storage battery module 433 can be brought close to the SoC target value. And the deterioration of the storage battery module 433 can be suppressed.
- Embodiment 2 FIG. [Overall Configuration of Embodiment 2] Next, a second embodiment of the present invention will be described with reference to FIGS.
- the system of the present embodiment can be realized by causing the charge / discharge management device 60 to execute the routine of FIG. 11 described later in the configuration shown in FIGS.
- the SoC target value is set to an ideal value suitable for suppressing deterioration of the storage battery.
- the required capacity of the storage battery increases. For example, in a storage battery with an SoC of 30%, which is ideal for suppressing deterioration, when controlling so that the SoC always becomes 30%, if 3 MWh is required for suppressing fluctuations in PV power generation, the required capacity of the storage battery is 10 MWh. It becomes.
- FIG. 7 is a diagram for explaining the relationship between the change in the combined power of the day and the required storage battery capacity.
- the combined power shown in FIG. 7 is power obtained by combining the generated power (PV generated power) of the solar power generation system and the charge / discharge power of the storage battery system.
- FIG. 7 shows an example in which the combined power of the day changes as shown by the solid line 71, but the combined power at each time changes due to changes in the weather etc. of the day. It is not limited to the changes shown. Assuming that the generated power of the solar power generation system suddenly becomes zero, the electric power supplied to the electric power system is reduced to 0 while discharging the storage battery so that the rate of change in the supplied power of the system does not fall below -n% / min.
- the amount of power required to change the power to [kW] (hereinafter simply referred to as “required power amount”) is represented by the area of the region 72 at the solar radiation peak time.
- the required amount of power changes according to the daily change in the combined power. As shown in FIG. 7, if the SoC target value is fixed to SoC ideal for suppressing deterioration of the storage battery, the above-described required power amount may not be ensured. Therefore, in the system according to the second embodiment, the SoC target value is changed according to the daily change in the required power amount.
- FIG. 8 is a diagram for explaining scheduling of the SoC target value for each time in the system according to Embodiment 2 of the present invention.
- a solid line 81 indicates the SoC target value that can secure the required power amount.
- the SoC target value is set to be higher than the SoC ideal for suppressing deterioration of the storage battery so as to satisfy the required power amount. Set high.
- the SoC target value is set to SoC ideal for suppressing deterioration of the storage battery.
- FIG. 9 is a diagram for explaining a method of calculating the SoC target value in the period from time A to time B.
- SoC target value [%] S ⁇ 100 / BT (4)
- FIG. 10 is a block diagram of a system according to Embodiment 2 of the present invention.
- the configuration shown in FIG. 10 is the same as that shown in FIG. 2 except that a SoC target value changing unit 62 is added to the charge / discharge management device 60. Therefore, description of each part other than the SoC target value changing part 62 is simplified or omitted.
- the charge / discharge management device 60 has a SoC target value changing function, and the SoC target value changing unit 62 takes charge of the function.
- the SoC target value changing unit 62 changes the SoC target value in accordance with the change in the required power amount based on the change in the combined power.
- the combined power is detected by the wattmeter 25.
- the combined power may be calculated by adding the generated power of the power generation system 30 detected by the power meter 33 by the main site controller 50 and the charge / discharge power of the storage battery system 40.
- the SoC target value changing unit 62 assumes that the SoC target value calculated from the combined power W [kW] is assumed to be 0 when the power generated by the power generation system 30 becomes 0 at each time.
- the target value is set to ensure the necessary amount of electric power that can be discharged until the electric power supplied to the electric power system becomes zero without the change rate falling below -n%.
- the SoC target value is set to an ideal value suitable for suppressing deterioration of the storage battery module 433.
- the charge / discharge command unit 61 performs the processing described in the description of the charge / discharge command function of the first embodiment using the SoC target value calculated by the SoC target value changing unit 62 based on the combined power at each time.
- FIG. 11 is a flowchart of a control routine executed by the charge / discharge management device 60 in the system according to Embodiment 2 of the present invention.
- the process of the main site controller 50 shown in this flowchart is a process realized by the functions of the charge / discharge command unit 61 and the SoC target value changing unit 62.
- a program for executing the processing of the flowchart shown in FIG. 11 is stored in the memory of the main site controller 50, and the processing shown in FIG. 11 is realized by the processor of the main site controller 50 reading and executing the program.
- the routine shown in FIG. 11 is the same as the routine shown in FIG. 4 except that the process of step S105 is added as a pre-process of step S103.
- the same steps as those shown in FIG. 4 are denoted by the same reference numerals, and the description thereof is omitted.
- step S105 first, the main site controller 50 acquires the combined power value from the power meter 25 at a predetermined short cycle (for example, every several tens of milliseconds).
- the SoC target value changing unit 62 calculates the SoC target value based on the acquired combined power value, and sets this as a new SoC target value.
- the processing executed in step S105 is as described in the description of the SoC target value changing function.
- the SoC target value set in step S105 for each time is used in the process of step S103.
- the charge / discharge management device 60 sets the SoC target value higher than the ideal value suitable for suppressing deterioration of the storage battery module 433 during the day when the required power amount is high, and is necessary. In the morning and evening when the amount of power is low, the SoC target value is set to an ideal value suitable for suppressing deterioration of the storage battery module 433. Therefore, according to the charge / discharge management device 60 of the present embodiment, the SoC target value can be changed according to the change in the required power amount based on the change in the combined power, and the storage battery can be operated efficiently.
- Embodiment 3 FIG. [Overall Configuration of Embodiment 3] Next, a third embodiment of the present invention will be described with reference to FIGS.
- the system of the present embodiment can be realized by causing the charge / discharge management device 60 to execute the routine of FIG. 14 described later in the configuration shown in FIGS.
- the SoC target value is changed at each time, paying attention to the fact that the required power amount increases during the day compared to morning and evening.
- the output of the photovoltaic power generation system tends to increase during the period from sunrise time to solar radiation peak time. Therefore, when the SoC of the storage battery is lower than the SoC target value, it is easy to positively charge and achieve the SoC target value.
- the SoC is higher than the SoC target value, the discharge amount is limited, so the SoC is limited. It is difficult to achieve the target value.
- the output of the photovoltaic power generation system tends to decrease after the solar radiation peak time.
- the SoC when the SoC is higher than the SoC target value, it is easy to actively discharge and achieve the SoC target value.
- the SoC when the SoC is lower than the SoC target value, the output tends to decrease, so the SoC target. Difficult to achieve value. Therefore, it is desirable to schedule the SoC target value in consideration of the output tendency of the photovoltaic power generation system.
- FIG. 12 is a diagram for explaining scheduling of the SoC target value in the system according to Embodiment 3 of the present invention.
- a solid line 121 is a SoC target value for each time in consideration of the offset.
- the SoC target value indicated by the solid line 121 includes a negative offset up to the solar radiation peak and a positive offset after the solar radiation peak.
- FIG. 13 is a block diagram of a system according to the third embodiment of the present invention.
- the configuration shown in FIG. 13 is the same as that of FIG. 10 except that the solar radiation information acquisition unit 63 is added to the charge / discharge management device 60 and the processing of the SoC target value changing unit 62 is partially added. . Therefore, description of each part other than the SoC target value change part 62 and the solar radiation information acquisition part 63 is simplified or abbreviate
- the charge / discharge management device 60 has a solar radiation information acquisition function, and the solar radiation information acquisition unit 63 takes charge of this function.
- the solar radiation information acquisition unit 63 acquires solar radiation information from another computer connected to the computer network 22 or an external storage device connected to the charge / discharge management device 60.
- the solar radiation information includes the sunrise time, solar radiation peak time, sunset time, and sunrise time of the next day.
- the charge / discharge management device 60 has a SoC target value changing function, and the SoC target value changing unit 62 takes charge of the function.
- the SoC target value changing unit 62 first sets the SoC target value at each time according to the description of the SoC target value changing function described in the second embodiment.
- the offset value is added to the set SoC target value at each time, and the SoC target value at each time is reset.
- the offset value at each time is set based on solar radiation information. Between the sunrise time and the solar radiation peak time, a negative offset value is added to the SoC target value to obtain the SoC target value after resetting. Between the solar radiation peak time and the sunset time, a positive offset value is added to the SoC target value to obtain the SoC target value after resetting.
- the charge / discharge command unit 61 performs the process described in the description of the charge / discharge command function of the first embodiment using the SoC target value at each time reset by the SoC target value changing unit 62.
- FIG. 14 is a flowchart of a control routine executed by the charge / discharge management device 60 in the system according to Embodiment 3 of the present invention.
- the process of the main site controller 50 shown in this flowchart is a process realized by the functions of the charge / discharge command unit 61, the SoC target value change unit 62, and the solar radiation information acquisition unit 63.
- a program for executing the processing of the flowchart shown in FIG. 14 is stored in the memory of the main site controller 50, and the processing shown in FIG. 14 is realized by the processor of the main site controller 50 reading and executing the program.
- the routine shown in FIG. 14 is the same as the routine shown in FIG. 11 except that the process of step S106 is added as a pre-process of step S105.
- the same steps as those shown in FIGS. 4 and 11 are denoted by the same reference numerals, and the description thereof is omitted.
- step S106 the solar radiation information acquisition unit 63 acquires solar radiation information from another computer connected to the computer network 22, an external storage device connected to the charge / discharge management device 60, or the like.
- step S105 the SoC target value changing unit 62 sets the SoC target value for each time.
- the processing executed in step S105 is as described in the description of the SoC target value changing function.
- the SoC target value reset in step S105 is used in the process of step S103.
- the charge / discharge management device 60 schedules the SoC target value in consideration of the output tendency of the photovoltaic power generation system. Therefore, according to the charge / discharge management device 60 of the present embodiment, the SoC of the storage battery module 433 can be easily controlled to the SoC target value throughout the day.
- Embodiment 4 FIG. [Overall Configuration of Embodiment 4]
- the system of the present embodiment can be realized by causing the charge / discharge management device 60 to execute the routine of FIG. 14 described later in the configuration shown in FIGS.
- the SoC target value is changed at each time, paying attention to the fact that the required power amount increases during the day compared to morning and evening.
- the SoC of the storage battery at the sunset time may be different from an ideal value suitable for suppressing deterioration. Therefore, in the system of the fourth embodiment, when the power generated by the solar power generation system is 0 and the sunset time has passed, the SoC target value is set to an ideal value suitable for suppressing deterioration.
- FIG. 13 is a block diagram of a system according to Embodiment 4 of the present invention.
- the configuration shown in FIG. 13 is the same as that of FIG. 10 except that the solar radiation information acquisition unit 63 is added to the charge / discharge management device 60 and the processing of the SoC target value changing unit 62 is partially added. . Therefore, description of each part other than the SoC target value change part 62 and the solar radiation information acquisition part 63 is simplified or abbreviate
- the charge / discharge management device 60 has a solar radiation information acquisition function, and the solar radiation information acquisition unit 63 takes charge of this function.
- the solar radiation information acquisition unit 63 acquires annual solar radiation information from another computer connected to the computer network 22 or an external storage device connected to the charge / discharge management device 60.
- the solar radiation information includes the sunrise time, solar radiation peak time, sunset time, and sunrise time of the next day.
- the charge / discharge management device 60 has a SoC target value changing function, and the SoC target value changing unit 62 takes charge of the function.
- the SoC target value changing unit 62 sets the SoC target value to an ideal value suitable for suppressing deterioration of the storage battery module 433 when the power generated by the solar power generation system is zero and the sunset time has passed. It should be noted that the SoC target value from the sunrise time to the sunset time may be set to a constant value, or the SoC target value at each time is set according to the description of the SoC target value changing function described in the second embodiment. It is good as well.
- the charge / discharge command unit 61 performs the process described in the description of the charge / discharge command function of the first embodiment using the SoC target value set by the SoC target value change unit 62. Since the power generated by the photovoltaic power generation system is 0 after the sunset, when the SoC of the storage battery module 433 is lower than the SoC target value, the storage battery module receives power from other power generation equipment connected to the electrical system. 433 may be charged. On the other hand, when the SoC of the storage battery module 433 is higher than the SoC target value, excess power is discharged from the storage battery module 433.
- FIG. 14 is a flowchart of a control routine executed by the charge / discharge management device 60 in the system according to Embodiment 4 of the present invention.
- the process of the main site controller 50 shown in this flowchart is a process realized by the functions of the charge / discharge command unit 61, the SoC target value change unit 62, and the solar radiation information acquisition unit 63.
- a program for executing the processing of the flowchart shown in FIG. 14 is stored in the memory of the main site controller 50, and the processing shown in FIG. 14 is realized by the processor of the main site controller 50 reading and executing the program.
- the routine shown in FIG. 14 is the same as the routine shown in FIG. 11 except that the process of step S106 is added as a pre-process of step S105.
- the same steps as those shown in FIGS. 4 and 11 are denoted by the same reference numerals, and the description thereof is omitted.
- step S106 the solar radiation information acquisition unit 63 acquires solar radiation information from another computer connected to the computer network 22, an external storage device connected to the charge / discharge management device 60, or the like.
- step S105 the SoC target value changing unit 62 uses the SoC target value to suppress deterioration of the storage battery module 433 when the power generated by the photovoltaic power generation system is zero and the sunset time has passed. Set to a suitable ideal value.
- the processing executed in step S105 is as described in the description of the SoC target value changing function.
- the SoC target value set in step S105 is used in the process of step S103.
- the charge / discharge management device 60 controls the SoC of the storage battery module 433 to an ideal value suitable for suppressing deterioration during a period when the storage battery module 433 is not used for suppressing fluctuations in generated power. can do. For this reason, according to the charging / discharging management apparatus 60 of this Embodiment, deterioration of the storage battery module 433 can be suppressed and performance and a lifetime can be maintained.
- the SoC target value changing unit 62 may set the SoC target value higher than an ideal value suitable for suppressing deterioration of the storage battery module 433 before the sunset time. By setting in this way, it becomes possible to make the SoC of the storage battery module 433 coincide with the SoC target value only by discharging after the sunset time.
- the SoC target value is set to an ideal value suitable for suppressing deterioration of the storage battery module 433 from the sunset time to the sunrise time of the next day.
- the generated power of the photovoltaic power generation system tends to increase, and if the storage battery module 433 is in a fully charged state, the output fluctuation of the photovoltaic power generation cannot be leveled by charging. In this case, it becomes necessary to suppress the power generated by the solar power generation system. Therefore, it is desirable that the SoC of the storage battery module 433 at the sunrise time is close to zero.
- the SoC target value changing unit 62 may gradually decrease the SoC target value to near 0 from the sunset time to the sunrise time of the next day. By setting in this way, night discharge is performed, and the SoC of the storage battery module 433 at the sunrise time can be brought close to zero.
- Embodiment 5 FIG. [Overall Configuration of Embodiment 5] Next, a fifth embodiment of the present invention will be described with reference to FIGS.
- the system of this embodiment can be realized by causing the charge / discharge management device 60 to execute the routine of FIG. 16 described later in the configuration shown in FIGS.
- FIG. 15 is a block diagram of a system according to the fifth embodiment of the present invention.
- the configuration shown in FIG. 15 is the same as FIG. 13 except that the weather forecast information acquisition unit 64 is added to the charge / discharge management device 60 and the processing of the SoC target value changing unit 62 is partly added. is there. Therefore, description of each part other than the SoC target value change part 62 and the weather forecast information acquisition part 64 is simplified or abbreviate
- the charge / discharge management device 60 has a weather forecast information acquisition function, and the function is handled by the weather forecast information acquisition unit 64.
- the solar radiation information acquisition unit 63 acquires weather forecast information from another computer connected to the computer network 22 or an external storage device connected to the charge / discharge management device 60.
- the weather forecast information includes a weather forecast for each time.
- the charge / discharge management device 60 has a SoC target value changing function, and the SoC target value changing unit 62 takes charge of the function.
- the SoC target value changing unit 62 sets the SoC target value to an ideal value suitable for suppressing deterioration of the storage battery module 433 when the power generated by the solar power generation system is zero and the sunset time has passed. Further, when the next day's weather forecast based on the weather forecast information is suitable for power generation, the SoC target value changing unit 62 gradually sets the SoC target value from the sunset time to the next day's sunrise time. Lower to near zero.
- the SoC target value changing unit 62 does not lower the SoC target value between the sunset time and the sunrise time of the next day when the next day's weather forecast based on the weather forecast information is unsuitable for power generation. It should be noted that the SoC target value from the sunrise time to the sunset time may be set to a constant value, or the SoC target value at each time is set according to the description of the SoC target value changing function described in the second embodiment. It is good as well.
- the charge / discharge command unit 61 performs the process described in the description of the charge / discharge command function of the first embodiment using the SoC target value set by the SoC target value change unit 62.
- FIG. 16 is a flowchart of a control routine executed by charge / discharge management device 60 in the system according to Embodiment 5 of the present invention.
- the process of the main site controller 50 shown in this flowchart is a process realized by the functions of the charge / discharge command unit 61, the SoC target value change unit 62, the solar radiation information acquisition unit 63, and the weather forecast information acquisition unit 64.
- a program for executing the processing of the flowchart shown in FIG. 16 is stored in the memory of the main site controller 50, and the processing shown in FIG. 16 is realized by the processor of the main site controller 50 reading and executing the program.
- the routine shown in FIG. 16 is the same as the routine shown in FIG. 14 except that the process of step S107 is added as a pre-process of step S105.
- the same steps as those shown in FIGS. 4, 11, and 14 are denoted by the same reference numerals and description thereof is omitted.
- step S106 the solar radiation information acquisition unit 63 acquires solar radiation information from another computer connected to the computer network 22, an external storage device connected to the charge / discharge management device 60, or the like.
- step S ⁇ b> 107 the weather forecast information acquisition unit 64 acquires weather forecast information from another computer connected to the computer network 22 or an external storage device connected to the charge / discharge management device 60.
- step S105 the SoC target value changing unit 62 sets the SoC target value for each time.
- the processing executed in step S105 is as described in the description of the SoC target value changing unit.
- the SoC target value set in step S105 is used in the process of step S103.
- the charge / discharge management device 60 when the next day's weather forecast based on the weather forecast information is unsuitable for power generation, between the sunset time and the next day's sunrise time. Do not lower the SoC target value. Therefore, it becomes possible to level the output fluctuation of the photovoltaic power generation on the next day by charge / discharge control of the storage battery without lowering the SoC of the storage battery module 433 until the next morning.
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- Engineering & Computer Science (AREA)
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- Supply And Distribution Of Alternating Current (AREA)
- Charge And Discharge Circuits For Batteries Or The Like (AREA)
Abstract
Description
[実施の形態1の全体構成]
図1は、本発明の実施の形態1に係るシステム構成を説明するための概念構成図である。図1に示す発電設備10は、電力系統の送電設備20に接続される。電力系統には、送電設備20の他、送電設備20に接続された他の発電設備(図示省略)、送電設備20に接続された負荷設備(図示省略)が含まれる。発電設備10は、天候によって発電電力が変動する発電システム30と蓄電池システム40とを備える。発電システム30と蓄電池システム40とは、設備内電線21を介して接続される。さらに、発電設備10は、メインサイトコントローラ(MSC)50を備える。発電システム30と蓄電池システム40とメインサイトコントローラ50とは、コンピュータネットワーク22を介して接続される。発電設備10と電力系統との連系点には電力計25が設けられる。電力計25は、信号線によりメインサイトコントローラ50に接続される。
図1に示す発電システム30は、太陽光発電(PV)システムである。なお、発電システム30は、風力発電システム等であってもよい。発電システム30は、太陽光発電モジュール31、太陽光発電用の交直変換装置(以下、PV-PCS)32、電力計33を備える。発電システム30では、1つのPV-PCS32に対して複数の太陽光発電モジュール31が接続される。図1では、太陽光発電モジュール31は3つであるが、これは単なる一例である。PV-PCS32は電力計33を介して設備内電線21に接続される。電力計33は、信号線によりメインサイトコントローラ50に接続される。
蓄電池システム40は、蓄電池用の交直変換装置(以下、蓄電池用PCS)41、フロントバッテリーコントロールステーション盤(以下、FBCS盤)42、及び蓄電池盤43を備える。蓄電池システム40では、1つの蓄電池用PCS41に対して1つのFBCS盤42が接続され、1つのFBCS盤42に対して複数の蓄電池盤43が並列に接続される。図1では、蓄電池盤43は3列であるが、これは単なる一例である。蓄電池盤43の並列数は蓄電池用PCS41の仕様に基づいて定められる。よって、蓄電池盤43の並列数が1列となることもあり得る。
蓄電池盤43は、ヒューズ431、コンタクタ432、蓄電池モジュール433、及び蓄電池監視装置(以下、BMU:Battery Management Unit)434を備える。蓄電池モジュール433は、複数のセルが直列に接続されたモジュールである。各セルはリチウムイオン電池(LiB)である。蓄電池モジュール433は、コンタクタ432及びヒューズ431を介して送電線によりFBCS盤42に接続される。また、蓄電池モジュール433は、信号線によりBMU434に接続される。BMU434は、コンピュータネットワーク23によりFBCS盤42上の制御装置421に接続され、信号線によりコンタクタ432に接続される。
FBCS盤42は、蓄電池盤43と蓄電池用PCS41とに接続される。具体的には、各蓄電池盤43は、個別の送電線によりFBCS盤42に接続される。個別の送電線はFBCS盤42の内部で合流し、より太い送電線に接続される。合流後の送電線は蓄電池用PCS41に接続される。また、FBCS盤42は制御装置421を備える。制御装置421は、例えばROM、RAM等を含むメモリ、各種情報を入出力する入出力インタフェース、各種情報に基づいて各種演算処理を実行可能なプロセッサを備える。制御装置421は、コンピュータネットワーク22を介してMCS50に、コンピュータネットワーク23を介してBMU434に、コンピュータネットワーク24を介して蓄電池用PCS41に接続される。また、制御装置421は、信号線によりコンタクタ432に接続される。
蓄電池用PCS41は、変圧器を介して送電線により設備内電線21に接続される。蓄電池用PCS41は、発電システム30が出力した交流電力を直流電力に変換して蓄電池モジュール433に充電する充電機能と、蓄電池モジュール433の直流電力を交流電力に変換して電力系統に放電する放電機能とを備える。蓄電池モジュール433への充電電力量、及び蓄電池モジュール433からの放電電力量は、蓄電池用PCS41によって調整される。蓄電池用PCS41による充放電電力量の調整は、制御装置421から供給される充放電指令に従って行われる。蓄電池用PCS41は電流センサと電圧センサとを備え、蓄電池用PCS41はこれらのセンサの出力値を参照して充放電電力量の調整を実施する。
メインサイトコントローラ50は、例えばROM、RAM等を含むメモリ、各種情報を入出力する入出力インタフェース、各種情報に基づいて各種演算処理を実行可能なプロセッサを備える。メインサイトコントローラ50は、コンピュータネットワーク22によりPV-PCS32、制御装置421に接続される。メインサイトコントローラ50は、信号線により電力計33に接続される。
図2は、本発明の実施の形態1に係るシステムのブロック図である。本発明に係る充放電管理装置60は、メインサイトコントローラ50と制御装置421とを含みうる概念である。
充放電管理装置60は充放電指令機能を有し、その機能は充放電指令部61が受け持つ。充放電管理装置60は、電力計25から合成電力値を受信し、電力計33から発電電力値を受信し、BMU434から蓄電池情報を受信する。充放電指令部61は、発電電力値と蓄電池情報とに基づいて充放電指令を決定し、充放電指令を蓄電池用PCS41に送信する。
図4は、本発明の実施の形態1に係るシステムにおいて、充放電管理装置60が実行する制御ルーチンのフローチャートである。このフローチャートに示すメインサイトコントローラ50の処理は、充放電指令部61の機能によって実現される処理である。メインサイトコントローラ50のメモリには、図4に示すフローチャートの処理を実行するプログラムが記憶されており、メインサイトコントローラ50のプロセッサがプログラムを読み出して、実行することにより図4に示す処理が実現される。
[実施の形態2の全体構成]
次に、図7~図11を参照して本発明の実施の形態2について説明する。本実施形態のシステムは図1、図10に示す構成において、充放電管理装置60に後述する図11のルーチンを実施させることで実現することができる。
上述した実施の形態1では、SoC目標値を蓄電池の劣化抑制に適した理想値に設定することとした。しかしながら、蓄電池の劣化抑制に適した理想的なSoCに一定制御すると、必要とされる蓄電池の容量は大きくなる。例えば、劣化抑制に理想的なSoCが30%の蓄電池において、常にSoCが30%になるように制御する場合、PV発電量の変動抑制に3MWhを要するとすれば、必要な蓄電池の容量は10MWhとなる。
tan(θ)=100/(n×60×P) ・・・(1)
となる。
S[kWh]=W×W×tan(θ)×2 ・・・(2)
となる。
S[kWh]=W×W×100/(n×60×P×2) ・・・(3)
となる。
SoC目標値[%]=S×100/BT ・・・(4)
充放電管理装置60はSoC目標値変更機能を有し、その機能はSoC目標値変更部62が受け持つ。SoC目標値変更部62は、合成電力の変化に基づく必要電力量の変化に応じてSoC目標値を変更する。なお、合成電力は、電力計25により検出される。また、合成電力は、メインサイトコントローラ50が電力計33により検出される発電システム30の発電電力と、蓄電池システム40の充放電電力とを足しあわせて算出してもよい。
図11は、本発明の実施の形態2に係るシステムにおいて、充放電管理装置60が実行する制御ルーチンのフローチャートである。このフローチャートに示すメインサイトコントローラ50の処理は、充放電指令部61とSoC目標値変更部62の各機能によって実現される処理である。メインサイトコントローラ50のメモリには、図11に示すフローチャートの処理を実行するプログラムが記憶されており、メインサイトコントローラ50のプロセッサがプログラムを読み出して、実行することにより図11に示す処理が実現される。
[実施の形態3の全体構成]
次に、図12~図14を参照して本発明の実施の形態3について説明する。本実施形態のシステムは図1、図13に示す構成において、充放電管理装置60に後述する図14のルーチンを実施させることで実現することができる。
上述した実施の形態2では、朝夕に比して日中に必要電力量が高まることに着目して、時刻毎にSoC目標値を変更することとした。ところで、太陽光発電システムの出力は、日の出時刻から日射ピーク時刻までの期間は増加傾向にある。そのため、蓄電池のSoCがSoC目標値より低い場合には、積極的に充電してSoC目標値を達成し易い反面、SoCがSoC目標値よりも高い場合には、放電量が制限されるためSoC目標値を達成し難い。また、太陽光発電システムの出力は、日射ピーク時刻を過ぎると減少傾向にある。そのため、SoCがSoC目標値よりも高い場合には、積極的に放電してSoC目標値を達成し易い反面、SoCがSoC目標値よりも低い場合には、出力が減少傾向にあるためSoC目標値を達成し難い。そのため、太陽光発電システムの出力傾向を加味して、SoC目標値をスケジューリングすることが望ましい。
充放電管理装置60は日射情報取得機能を有し、その機能は日射情報取得部63が受け持つ。日射情報取得部63は、コンピュータネットワーク22に接続された他のコンピュータ又は充放電管理装置60に接続された外部記憶装置等から日射情報を取得する。日射情報は、日の出時刻、日射ピーク時刻、日の入り時刻、翌日の日の出時刻を含む。
充放電管理装置60はSoC目標値変更機能を有し、その機能はSoC目標値変更部62が受け持つ。SoC目標値変更部62は、まず、実施の形態2で述べたSoC目標値変更機能の説明に従って、各時刻のSoC目標値を設定する。実施の形態3では、設定された各時刻のSoC目標値にオフセット値を加味して、各時刻のSoC目標値を再設定する。各時刻のオフセット値は、日射情報に基づいて設定される。日の出時刻から日射ピーク時刻までの間は、SoC目標値に負のオフセット値を加えて再設定後のSoC目標値とする。日射ピーク時刻から日の入り時刻までの間は、SoC目標値に正のオフセット値を加えて、再設定後のSoC目標値とする。
図14は、本発明の実施の形態3に係るシステムにおいて、充放電管理装置60が実行する制御ルーチンのフローチャートである。このフローチャートに示すメインサイトコントローラ50の処理は、充放電指令部61、SoC目標値変更部62、日射情報取得部63の各機能によって実現される処理である。メインサイトコントローラ50のメモリには、図14に示すフローチャートの処理を実行するプログラムが記憶されており、メインサイトコントローラ50のプロセッサがプログラムを読み出して、実行することにより図14に示す処理が実現される。
ところで、上述した実施の形態3のシステムにおいては、オフセット値が0の時間が存在してもよい。更に、季節ごとに日射情報は変わるので、日付によってSoC目標値やオフセット値を変更することとしてもよい。更に、天気予報や日射情報から自動的にPV発電傾向を予測してオフセット値を自動的に算出することとしてもよい。
[実施の形態4の全体構成]
次に、図13、図14を参照して本発明の実施の形態4について説明する。本実施形態のシステムは図1、図13に示す構成において、充放電管理装置60に後述する図14のルーチンを実施させることで実現することができる。
上述した実施の形態2では、朝夕に比して日中に必要電力量が高まることに着目して、時刻毎にSoC目標値を変更することとした。ところで、日の入り時刻の蓄電池のSoCが、劣化抑制に適した理想値と異なる場合もある。そこで、実施の形態4のシステムでは、太陽光発電システムによる発電電力が0、かつ、日の入り時刻を過ぎている場合に、SoC目標値を劣化抑制に適した理想値に設定することとする。
充放電管理装置60は日射情報取得機能を有し、その機能は日射情報取得部63が受け持つ。日射情報取得部63は、コンピュータネットワーク22に接続された他のコンピュータ又は充放電管理装置60に接続された外部記憶装置等から年間の日射情報を取得する。日射情報は、日の出時刻、日射ピーク時刻、日の入り時刻、翌日の日の出時刻を含む。
充放電管理装置60はSoC目標値変更機能を有し、その機能はSoC目標値変更部62が受け持つ。SoC目標値変更部62は、太陽光発電システムによる発電電力が0、かつ、日の入り時刻を過ぎている場合に、SoC目標値を蓄電池モジュール433の劣化抑制に適した理想値に設定する。なお、日の出時刻から日の入り時刻までのSoC目標値の設定については一定値であっても良いし、実施の形態2で述べたSoC目標値変更機能の説明に従って、各時刻のSoC目標値を設定することとしてもよい。
図14は、本発明の実施の形態4に係るシステムにおいて、充放電管理装置60が実行する制御ルーチンのフローチャートである。このフローチャートに示すメインサイトコントローラ50の処理は、充放電指令部61、SoC目標値変更部62、日射情報取得部63の各機能によって実現される処理である。メインサイトコントローラ50のメモリには、図14に示すフローチャートの処理を実行するプログラムが記憶されており、メインサイトコントローラ50のプロセッサがプログラムを読み出して、実行することにより図14に示す処理が実現される。
ところで、上述した実施の形態4のシステムにおいては、日の入り時刻後に蓄電池モジュール433のSoCがSoC目標値よりも低い場合には、電力系統から電力供給を受けて充電する。しかし、電力系統からの受電は電力会社との協定などで禁止されていたり、コスト面でデメリットが生じるケースがあったりする。そこで、SoC目標値変更部62は、日の入り時刻前において、SoC目標値を蓄電池モジュール433の劣化抑制に適した理想値よりも高く設定することとしてもよい。このように設定することで、日の入り時刻後に放電のみで蓄電池モジュール433のSoCをSoC目標値に一致させることが可能となる。
また、上述した実施の形態4のシステムにおいては、日の入り時刻から翌日の日の出時刻まで、SoC目標値を蓄電池モジュール433の劣化抑制に適した理想値に設定している。しかしながら、日の出時刻後は太陽光発電システムの発電電力は増加傾向にあり、蓄電池モジュール433が満充電状態となれば、太陽光発電の出力変動を充電により平準化することができなくなる。この場合、太陽光発電システムによる発電電力を抑制する必要が生じてしまう。そのため、日の出時刻の蓄電池モジュール433のSoCは0近傍であることが望ましい。そこで、SoC目標値変更部62は、日の入り時刻から翌日の日の出時刻までの間に、段階的にSoC目標値を0近傍まで下げることとしてもよい。このように設定することで、夜間放電が行われ、日の出時刻の蓄電池モジュール433のSoCを0に近づけることが可能となる。
[実施の形態5の全体構成]
次に、図15、図16を参照して本発明の実施の形態5について説明する。本実施形態のシステムは図1、図15に示す構成において、充放電管理装置60に後述する図16のルーチンを実施させることで実現することができる。
上述した実施の形態4の変形例2の構成では、翌日の日の出時刻における蓄電池モジュール433のSoCは0近傍となる。しかしながら、翌日の天気が雨や雪などの場合には、蓄電池モジュール433への充電ができない。そのため、実施の形態5のシステムでは、天気予報情報を取得して、翌日の天気予報が発電に適さない天候である場合には、日の入り時刻から翌日の日の出時刻までの間に、SoC目標値を下げないこととする。
充放電管理装置60は天気予報情報取得機能を有し、その機能は天気予報情報取得部64が受け持つ。日射情報取得部63は、コンピュータネットワーク22に接続された他のコンピュータ又は充放電管理装置60に接続された外部記憶装置等から天気予報情報を取得する。天気予報情報には、時刻毎の天気予報を含む。
充放電管理装置60はSoC目標値変更機能を有し、その機能はSoC目標値変更部62が受け持つ。SoC目標値変更部62は、太陽光発電システムによる発電電力が0、かつ、日の入り時刻を過ぎている場合に、SoC目標値を蓄電池モジュール433の劣化抑制に適した理想値に設定する。また、SoC目標値変更部62は、天気予報情報に基づく翌日の天気予報が発電に適した天候である場合には、日の入り時刻から翌日の日の出時刻までの間に、段階的にSoC目標値を0近傍まで下げる。また、SoC目標値変更部62は、天気予報情報に基づく翌日の天気予報が発電に適さない天候である場合には、日の入り時刻から翌日の日の出時刻までの間に、SoC目標値を下げない。なお、日の出時刻から日の入り時刻までのSoC目標値の設定については一定値であっても良いし、実施の形態2で述べたSoC目標値変更機能の説明に従って、各時刻のSoC目標値を設定することとしてもよい。
図16は、本発明の実施の形態5に係るシステムにおいて、充放電管理装置60が実行する制御ルーチンのフローチャートである。このフローチャートに示すメインサイトコントローラ50の処理は、充放電指令部61、SoC目標値変更部62、日射情報取得部63、天気予報情報取得部64の各機能によって実現される処理である。メインサイトコントローラ50のメモリには、図16に示すフローチャートの処理を実行するプログラムが記憶されており、メインサイトコントローラ50のプロセッサがプログラムを読み出して、実行することにより図16に示す処理が実現される。
20 送電設備
21 設備内電線
22、23、24 コンピュータネットワーク
30 発電システム
31 太陽光発電モジュール
32 PV-PCS
33 電力計
40 蓄電池システム
41 蓄電池用PCS
42 FBCS盤
43 蓄電池盤
50 メインサイトコントローラ
60 充放電管理装置
61 充放電指令部
62 SoC目標値変更部
63 日射情報取得部
64 天気予報情報取得部
421 制御装置
431 ヒューズ
432 コンタクタ
433 蓄電池モジュール
434 蓄電池監視装置(BMU)
Claims (14)
- 天候によって発電電力が変動する発電システムと蓄電池システムとを含み電力系統に接続された発電設備に設けられた充放電管理装置であって、
前記発電システムは、発電電力を検出する電力計を備え、
前記蓄電池システムは、
蓄電池と、
前記蓄電池の状態を監視する蓄電池監視装置と、
前記発電システムが出力した交流電力を直流電力に変換して前記蓄電池に充電する機能と、前記蓄電池の直流電力を交流電力に変換して前記電力系統に放電する機能とを有する交直変換装置と、を備え、
前記充放電管理装置は、
前記電力計が検出した発電電力と前記蓄電池監視装置から供給される蓄電池情報とに基づいて、定格に対する前記電力系統に供給される電力の単位時間当たりの変化率(以下、系統供給電力変化率と記す。)が±n%の変動範囲内に収まるように、かつ、前記蓄電池のSoC(State of Charge)がSoC目標値に近づくように前記交直変換装置に対する充放電指令を決定する充放電指令部を備えること、
を特徴とする充放電管理装置。 - 前記充放電指令部は、前記SoCが前記SoC目標値より低く、かつ、前記定格に対する前記電力計が検出した発電電力の単位時間当たりの変化率が+n%以上の場合に、前記系統供給電力変化率が-n%以上0%未満となるように前回の充放電指令よりも充電電力を上げる又は放電電力を下げる充放電指令を決定すること、
を特徴する請求項1記載の充放電管理装置。 - 前記充放電指令部は、前記SoCが前記SoC目標値より低く、かつ、前記定格に対する前記電力計が検出した発電電力の単位時間当たりの変化率が-n%以下の場合に、前記系統供給電力変化率が-n%以上0%未満となるように前回の充放電指令よりも放電電力を上げる又は充電電力を下げる充放電指令を決定すること、
を特徴とする請求項1又は2記載の充放電管理装置。 - 前記充放電指令部は、前記SoCが前記SoC目標値より低く、かつ、前記定格に対する前記電力計が検出した発電電力の単位時間当たりの変化率が-n%より大きく+n%より小さい場合に、前記系統供給電力変化率が-n%以上0%未満となるように前回の充放電指令よりも充電電力を上げる又は放電電力を下げる充放電指令を決定すること、
を特徴とする請求項1乃至3のいずれか1項記載の充放電管理装置。 - 前記充放電指令部は、前記SoCが前記SoC目標値より高く、かつ、前記定格に対する前記電力計が検出した発電電力の単位時間当たりの変化率が+n%以上の場合に、前記系統供給電力変化率が0%より大きく+n%以下となるように前回の充放電指令よりも充電電力を上げる又は放電電力を下げる充放電指令を決定すること、
を特徴とする請求項1乃至4のいずれか1項記載の充放電管理装置。 - 前記充放電指令部は、前記SoCが前記SoC目標値より高く、かつ、前記定格に対する前記電力計が検出した発電電力の単位時間当たりの変化率が-n%以下の場合に、前記系統供給電力変化率が0%より大きく+n%以下となるように前回の充放電指令よりも放電電力を上げる又は充電電力を下げる充放電指令を決定すること、
を特徴とする請求項1乃至5のいずれか1項記載の充放電管理装置。 - 前記充放電指令部は、前記SoCが前記SoC目標値より高く、かつ、前記定格に対する前記電力計が検出した発電電力の単位時間当たりの変化率が-n%より大きく+n%より小さい場合に、前記系統供給電力変化率が0%より大きく+n%以下となるように前回の充放電指令よりも放電電力を上げる又は充電電力を下げる充放電指令を決定すること、
を特徴とする請求項1乃至5のいずれか1項記載の充放電管理装置。 - 前記充放電管理装置は、各時刻において、前記発電システムの発電電力と前記蓄電池システムの充放電電力とを合算した合成電力に基づいて前記SoC目標値を変更するSoC目標値変更部をさらに備えること、
を特徴とする請求項1乃至7のいずれか1項記載の充放電管理装置。 - 前記SoC目標値変更部は、各時刻における前記SoC目標値を、各時刻において前記発電システムによる発電電力が0となったと仮定した場合に、前記系統供給電力変化率が-n%を下回らずに、前記電力系統に供給される電力が0になるまで放電を継続可能な電力を確保するための目標値に設定すること、
を特徴とする請求項8記載の充放電管理装置。 - 前記充放電管理装置は、日の出時刻、日射ピーク時刻、日の入り時刻を取得する日射情報取得部をさらに備え、
前記SoC目標値変更部は、
前記日の出時刻から前記日射ピーク時刻までの間、前記SoC目標値に負のオフセット値を加え、
前記日射ピーク時刻から前記日の入り時刻までの間、前記SoC目標値に正のオフセット値を加えること、
を特徴とする請求項8又は9記載の充放電管理装置。 - 前記充放電管理装置は、日の出時刻、日射ピーク時刻、日の入り時刻を取得する日射情報取得部をさらに備え、
前記SoC目標値変更部は、前記発電システムによる発電電力が0の場合、かつ、前記日の入り時刻を過ぎている場合に、前記SoC目標値を前記蓄電池の劣化抑制に適した理想値に設定すること、
を特徴とする請求項8又は9記載の充放電管理装置。 - 前記SoC目標値変更部は、前記日の入り時刻前において、前記SoC目標値を、前記理想値よりも高く設定すること、
を特徴とする請求項11記載の充放電管理装置。 - 前記SoC目標値変更部は、前記日の入り時刻から翌日の日の出時刻までの間に、段階的に前記SoC目標値を0近傍まで下げること、
を特徴とする請求項11又は12記載の充放電管理装置。 - 前記充放電管理装置は、天気予報情報を取得する天気予報情報取得部を更に備え、
前記SoC目標値変更部は、前記天気予報情報に基づく翌日の天気予報が発電に適さない天候である場合には、前記日の入り時刻から翌日の日の出時刻までの間に、前記SoC目標値を下げないこと、
を特徴とする請求項13記載の充放電管理装置。
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