WO2016093080A1 - Charger, current control method, and charging system - Google Patents

Abstract

A first current value found by means of a limit power value obtained by dividing a desired power by the number of electricity storage devices 4 to be charged is compared with a current command value sent to a charger 1 from the electricity storage device 4 to be charged. If the first current value is lower than the current command value, a current output to the electricity storage device 4 to be charged is controlled in accordance with the first current value, and if the first current value is equal to or greater than the current command value, the current output to the electricity storage device 4 to be charged is controlled in accordance with the current command value.

Description

Charger, current control method, and charging system

The present invention relates to control of current output from a charger to a power storage device.

For example, when the battery included in the power storage device is changed from a lead battery to a lithium ion battery, the charging rate (the current that flows through the battery when the battery is fully charged in one hour) increases, so the charger to the power storage device The output power increases.

In addition, when power supplied from one commercial power source is distributed to a plurality of chargers, and each charger charges a battery provided in the power storage device, the total output power of each charger is contract power of the commercial power source. In addition, it is desired to suppress the output power of each charger so as not to exceed the desired power set below the contract power. For example, see Patent Document 1 or Patent Document 2.

International Publication No. 2011-11817 JP 2012-235545 A

It is an object of the present invention to provide a charger, a current control method, and a charging system that can prevent the total output power of each charger from exceeding a desired power.

The charger of the embodiment compares the first current value obtained by dividing the desired power by the number of power storage devices to be charged with the current command value from the power storage device to be charged, and compares the first current value. When the value is smaller than the current command value, the current output to the power storage device to be charged is controlled according to the first current value.

According to the present invention, the total output power of each charger can be prevented from exceeding a desired power.

It is a figure which shows an example of the charging system containing the charger of embodiment. It is a flowchart which shows an example of operation | movement of the control part of an electrical storage apparatus. It is a flowchart which shows an example of operation | movement of the control part of each charger in 1st Example. It is a flowchart which shows an example of operation | movement of the control part of the master charger in 1st Example. It is a flowchart which shows an example of operation | movement of the control part of each charger in 2nd Example. It is a flowchart which shows an example of operation | movement of the control part of each charger in 3rd Example. It is a figure which shows an example of a total change of the output electric power of each charger in 3rd Example. It is a flowchart which shows an example of operation | movement of the control part of the master charger in 4th Example. It is a figure which shows an example of a total change of the output electric power of each charger in 4th Example. It is a flowchart which shows an example of operation | movement of the control part of each charger in 5th Example. It is a flowchart which shows an example of operation | movement of the control part of the master charger in 5th Example. It is a figure which shows an example of the change of the total power consumption in 5th Example. It is a flowchart which shows an example of operation | movement of the control part of each charger in 6th Example. It is a figure which shows an example of the change of the total power consumption in 6th Example.

FIG. 1 is a diagram illustrating an example of a charging system including the charger according to the embodiment.
The charging system shown in FIG. 1 includes a plurality of chargers 1. Among the plurality of chargers 1, the charger 1 for obtaining the limit power value is a master charger 1, and the other charger 1 is a slave charger 1.

Each charger 1 supplies electric power to a power storage device 4 mounted on a vehicle 3 such as an electric forklift or a plug-in hybrid vehicle using electric power supplied from a commercial power source 2. Each charger 1 includes a power supply unit 11 and a control unit 12.

The power supply unit 11 is configured by, for example, an AC / DC converter, and converts AC power supplied from the commercial power supply 2 into DC power. Further, the power supply unit 11 converts the output voltage of the commercial power supply 2 into a predetermined voltage.

The control unit 12 controls the operation of the power supply unit 11 such that a current corresponding to a current command value transmitted from the power storage device 4 that is the power supply destination of the control unit 12 is output from the power supply unit 11. Each control unit 12 is connected in a ring shape via a communication line 13. Each control unit 12 may be connected to a bus-type network. The control unit 12 of the master charger 1 transmits the limit power value to the control unit 12 of the slave charger 1. Moreover, each control part 12 calculates | requires a 1st electric current value (upper limit electric current value of the power supply part 11) based on a limit electric power value. Moreover, each control part 12 updates the output possible current value of the power supply part 11 based on a 1st current value, and transmits the output possible current value after the update to the electrical storage apparatus 4 of an own electric power supply destination. . In addition, each control unit 12 compares the first current value with the current command value, and when the first current value is smaller than the current command value, the power storage device 4 that is charged according to the first current value. It controls the current output to (the power storage device 4 of its own power supply destination). In addition, each control unit 12 controls the current output to the power storage device 4 to be charged according to the first current value, and the total power consumption that is the sum of the output power of each charger 1 is desired. When the power is equal to or lower than the electric power, the “controlling the current output to the power storage device 4 to be charged according to the first current value” is ended. The control unit 12 includes, for example, a CPU (Central Processing Unit), a multi-core CPU, or a programmable device (FPGA (Field Programmable Gate Array) or PLD (Programmable Logic Device)).

The power storage device 4 includes a battery 41 and a control unit 42.
The battery 41 is composed of, for example, a secondary battery such as a lithium ion battery or a nickel metal hydride battery, or a capacitor, and supplies power to a traveling motor or an electrical device mounted on the vehicle 3. Note that the rated voltage of the battery 41 may be 24 [V], 48 [V], or 80 [V], for example.

The control unit 42 obtains a current command value based on the voltage of the battery 41, the SOC (State Of Charge: the ratio of the current battery 41 capacity to the capacity of the battery 41 when fully charged), and the like. It transmits to the control part 12 of the charger 1. For example, the control unit 42 determines the current command value so that the charging current flowing through the battery 41 becomes a predetermined constant value during a CC (Constant-Current) charging period from the start of charging until the voltage of the battery 41 reaches a predetermined voltage. To control. In addition, the control unit 42 keeps the voltage of the battery 41 almost constant while maintaining the voltage of the battery 41 almost constant during the CV (Constant Voltage) charging period after the voltage of the battery 41 reaches a predetermined voltage. Controls the current command value. Further, the control unit 42 supplies its own power with the smaller one of the obtained current command value and the outputable current value transmitted from the control unit 12 of the charger 1 of its own power supply source as a new current command value. It transmits to the control part 12 of the original charger 1. The control unit 42 is configured by, for example, a CPU, a multi-core CPU, or a programmable device.

FIG. 2 is a flowchart showing an example of the operation of the control unit 42 of the power storage device 4. Note that the operation illustrated in FIG. 2 is repeatedly performed, for example, every charging control timing or every elapse of a certain time T (for example, 20 minutes).

First, when the control unit 42 determines that the SOC of the battery 41 is smaller than the desired SOC (S21: No), the control unit 42 receives the output possible current value transmitted from the control unit 12 of the charger 1 of its own power supply source. Then, a current command value is obtained based on the voltage of the battery 41, the SOC, etc. (S23). When the control unit 42 determines that the charging of the battery 41 has not ended, the control unit 42 receives the output possible current value transmitted from the control unit 12 of the charger 1 of its own power supply source, You may comprise so that an electric current command value may be calculated | required based on SOC etc. In the case of such a configuration, for example, the control unit 42 determines that charging of the battery 41 has not ended when the charging current flowing through the battery 41 is not the end current in the CV charging period.

Next, if the control part 42 judges that the calculated | required electric current command value is smaller than the received output possible electric current value (S24: Yes), it will use the calculated | required electric current command value of the charger 1 of its own electric power supply source. It transmits to the control part 12 (S25).

In addition, when the control unit 42 determines that the obtained current command value is equal to or greater than the received output possible current value (S24: No), the control unit 42 uses the received output possible current value as the current command value to charge its own power supply source. It transmits to the control part 12 of the device 1 (S26).

Further, when the control unit 42 determines that the SOC of the battery 41 is equal to or higher than the desired SOC (S21: Yes), the control unit 42 transmits a charge end instruction to the control unit 12 of the charger 1 of its own power supply source, and The charging process is terminated (S27). When the control unit 42 determines that the charging of the battery 41 has been completed, the control unit 42 is configured to transmit a charging end instruction to the control unit 12 of the charger 1 of its own power supply source and end the charging process of the battery 41. May be. In the case of such a configuration, for example, the control unit 42 determines that the charging of the battery 41 has ended when the charging current flowing through the battery 41 reaches the end current in the CV charging period.

<First embodiment>
FIG. 3 is a flowchart showing an example of the operation of the control unit 12 of each charger 1 in the first embodiment. The operation illustrated in FIG. 3 is repeatedly performed, for example, every charging control timing or every elapse of a certain time T (for example, 20 minutes).

First, the control unit 12 acquires a power limit value (S31). For example, the control unit 12 of the slave charger 1 receives the limited power value transmitted from the control unit 12 of the master charger 1 by transmitting a transmission request for the limited power value to the control unit 12 of the master charger 1. Thus, the power limit value is acquired.

Next, the control unit 12 obtains the first current value by dividing the limit power value by the voltage output to the power storage device 4 (output voltage of the charger 1) (S32). For example, when the voltage output to the power storage device 4 is 48 [V] and the limit power value is 10 [kW], the control unit 12 calculates 10 [kW] / 48 [V] ≈208 [A]. Thus, 208 [A] is obtained as the first current value. At this time, the outputable current value of the charger 1 is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4.

Next, when the control unit 12 determines that the obtained first current value is smaller than the received current command value (S33: Yes), a current corresponding to the first current value is output from the charger 1. Thus, the operation of the power supply unit 11 is controlled (S34).

Further, when the controller 12 determines that the obtained first current value is equal to or greater than the received current command value (S33: No), a current corresponding to the received current command value is output from the charger 1. Thus, the operation of the power supply unit 11 is controlled (S35).

FIG. 4 is a flowchart showing an example of the operation of the control unit 12 of the master charger 1 in the first embodiment. Note that the operation illustrated in FIG. 4 is repeatedly performed, for example, every charging control timing or every elapse of a certain time T (for example, 20 minutes).

First, the control unit 12 of the master charger 1 determines the number of power storage devices 4 to be charged (the power storage device 4 to which power is to be supplied from the charger 1 or the power storage device 4 to which power is supplied from the charger 1). Obtain (S41). For example, the control unit 12 of the master charger 1 is transmitted from the control unit 42 of the power storage device 4 of its own power supply destination and the number of transmission requests for the limit power value transmitted from the control unit 12 of the slave charger 1. The result of adding the number of charging start instructions is the number of power storage devices 4 to be charged.

Next, the control unit 12 of the master charger 1 divides the desired power set by the user arbitrarily by the number of power storage devices 4 to be charged, which is equal to or less than the contract power of the commercial power supply 2 and is set by the user. A value is obtained (S42).

For example, in a charging system including a master charger 1A, a slave charger 1B, a slave charger 1C, a slave charger 1D, and a slave charger 1E, the contract power of the commercial power supply is set to 60 [kW], and the desired power is set to 50 Consider the case of [kW].

The master charger 1A supplies power to the power storage device 4A, the slave charger 1B supplies power to the power storage device 4B, the slave charger 1C supplies power to the power storage device 4C, and the slave charger 1D stores power. It is assumed that power is supplied to the device 4D and the slave charger 1E supplies power to the power storage device 4E.

The voltages output from the chargers 1A to 1E to the power storage devices 4A to 4E are 48 [V], respectively.
Further, at a certain charge control timing, the current command value transmitted from the control unit 42 of the power storage device 4A to the control unit 12 of the master charger 1A is 200 [A], and the control unit 42 of the power storage device 4B transmits the slave charger 1B. The current command value transmitted to the control unit 12 is 200 [A], the current command value transmitted from the control unit 42 of the power storage device 4C to the control unit 12 of the slave charger 1C is 150 [A], and the slave power storage device 4D The current command value transmitted from the control unit 42 to the control unit 12 of the charger 1D is 100 [A], and the current command value transmitted from the control unit 42 of the power storage device 4E to the control unit 12 of the slave charger 1E is 50 [A]. A].

At this time, first, the control unit 12 of the master charger 1A calculates a power limit value (10 [kW]) by calculating 50 [kW] / 5 [units] = 10 [kW], and the slave charger Send to 1B-1E.

Next, the control unit 12 of the master charger 1A calculates a first current value (208 [A]) by calculating 10 [kW] / 48 [V] ≈208 [A]. At this time, the outputable current value of the charger 1A is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4A. When it is determined that the first current value (208 [A]) is equal to or greater than the current command value (200 [A]) transmitted from the control unit 42 of the power storage device 4A, the current command value (200 [A]) is determined. ] To control the operation of the power supply unit 11 so that a current according to] is output from the master charger 1A. When the voltage output to the power storage device 4 changes from 48 [V] to 80 [V], the control unit 12 of the master charger 1A calculates 10 [kW] / 80 [V] = 125 [A]. Thus, the first current value (125 [A]) is obtained. At this time, the output possible current value of the charger 1A is updated to 125 [A] which is the first current value, and is transmitted to the control unit 42 of the power storage device 4A. If it is determined that the first current value (125 [A]) is smaller than the current command value (200 [A]) transmitted from the control unit 42 of the power storage device 4A, the first current value (125 The operation of the power supply unit 11 is controlled so that a current corresponding to [A]) is output from the master charger 1A, and the first current value (125 [A]) is set as an outputable current value of the power storage device 4A. It transmits to the control part 42. As described above, when the voltage output to the power storage device 4 increases, the first current value decreases so that the limit power value does not change. Therefore, the voltage output to the power storage device 4 exceeds the predetermined voltage. Even if it becomes, the total of the output power of each charger 1 (total power consumption of each charger 1) can be prevented from exceeding the desired power, and the total output power of each charger 1 is It is possible not to exceed the contract power.

Further, the control unit 12 of the slave charger 1B calculates the first current value (208 [A]) by calculating 10 [kW] / 48 [V] ≈208 [A], and the first current value (208 [A]) is obtained. When it is determined that the current value (208 [A]) is equal to or greater than the current command value (200 [A]) transmitted from the control unit 42 of the power storage device 4B, the current corresponding to the current command value (200 [A]) Is controlled from the slave charger 1B. When the first current value is obtained, the outputtable current value of charger 1B is updated based on the first current value and transmitted to control unit 42 of power storage device 4B.

The control unit 12 of the slave charger 1C calculates the first current value (208 [A]) by calculating 10 [kW] / 48 [V] ≈208 [A], and the first current value (208 [A]) is obtained. When it is determined that the current value (208 [A]) is equal to or greater than the current command value (150 [A]) transmitted from the control unit 42 of the power storage device 4C, the current according to the current command value (150 [A]) Is controlled from the slave charger 1 </ b> C to control the operation of the power supply unit 11.

Further, the control unit 12 of the slave charger 1D calculates the first current value (208 [A]) by calculating 10 [kW] / 48 [V] ≈208 [A], and the first current value (208 [A]) is obtained. When it is determined that the current value (208 [A]) is equal to or greater than the current command value (100 [A]) transmitted from the control unit 42 of the power storage device 4D, the current corresponding to the current command value (100 [A]) Is controlled from the slave charger 1D.

Further, the control unit 12 of the slave charger 1E obtains a first current value (208 [A]) by calculating 10 [kW] / 48 [V] ≈208 [A], and the first current value (208 [A]) is obtained. When it is determined that the current value (208 [A]) is equal to or greater than the current command value (50 [A]) transmitted from the control unit 42 of the power storage device 4E, the current corresponding to the current command value (50 [A]) Is controlled from the slave charger 1E.

Next, consider a case where the current command value transmitted from the control unit 42 of the power storage device 4A increases from 200 [A] to 210 [A]. It is assumed that the current command value transmitted from power storage devices 4B to 4E does not change. Further, the total of current command values (210 [A] +200 [A] +150 [A] +100 [A] +50 [A] = 710 [A]) and each voltage (48 [V]) output to the power storage devices 4A to 4E ) Is multiplied by 710 [A] × 48 [V] ≈34 [kW].

In this case, the controller 12 of the master charger 1A determines that the first current value (208 [A]) is smaller than the current command value (210 [A]) transmitted from the controller 42 of the power storage device 4A. The operation of the power supply unit 11 is controlled so that a current corresponding to the first current value (208 [A]) is output from the master charger 1A, and the first current value (208 [A]) is determined. Is output to the control unit 42 of the power storage device 4A as an outputable current value.

The operation of the control unit 12 of the slave chargers 1B to 1E is the same as the operation of the control unit 12 of the slave chargers 1B to 1E.
As described above, the master charger 1A according to the first embodiment has the total power value (710 [A] × 48 [V] ≈34 [kW]) obtained by the sum of the current command values transmitted from the power storage devices 4A to 4E. ) Is smaller than the desired power (50 [kW]), but if the first current value (208 [A]) is smaller than the current command value (210 [A]), the first The current output to power storage device 4A is controlled according to the current value (208 [A]).

In other words, in the master charger 1A of the first embodiment, the total of current command values (710 [A]) transmitted from the power storage devices 4A to 4E is the voltage (48 [V]) output to the power storage devices 4A to 4E. ) Is smaller than the second current value (50 [kW] / 48 [V] ≈1041 [A]) divided by the desired power (50 [kW]), the first current value ( 208 [A]) is smaller than the current command value (210 [A]), the current output to the power storage device 4A is controlled according to the first current value (208 [A]).

Thereby, the control part 12 of each charger 1 of 1st Example is the restriction | limiting which divided the desired electric power by the number of the electrical storage apparatuses 4 which charge the output current of the charger 1, even if an electric current command value becomes large. Since the power value can be made equal to or lower than the first current value obtained by dividing the power value by the voltage output to the power storage device 4, the total output power of each charger 4 when the output voltage of each charger 1 is the same as each other Can be prevented from exceeding the desired power, and the total output power of each charger 1 can be prevented from exceeding the contract power.

<Second embodiment>
The control unit 12 of each charger 1 in the second embodiment compares the first current value and the current command value when the total power consumption, which is the sum of the output power of each charger 1, is larger than the desired power. When the first current value is smaller than the current command value, the current output to the power storage device 4 to be charged (the power storage device 4 of its own power supply destination) is controlled according to the first current value.

FIG. 5 is a flowchart showing an example of the operation of the control unit 12 of each charger 1 in the second embodiment. The operation illustrated in FIG. 5 is repeatedly performed, for example, every charging control timing or every elapse of a certain time T (for example, 20 minutes).

First, the control unit 12 determines whether or not the total power consumption is larger than the desired power (S51). For example, the control unit 12 of the master charger 1 sets the total output power of the slave charger 1 indicated in the data transmitted from the control unit 12 of each slave charger 1 as the total power consumption. In addition, the control unit 12 of each slave charger 1 receives data indicating the total power consumption from the control unit 12 of the master charger 1.

Next, when the control unit 12 determines that the total power consumption is larger than the desired power (S51: Yes), the control unit 12 obtains the limit power value (S52), and sets the limit power value with the voltage output to the power storage device 4. The first current value is obtained by dividing (S53), and it is determined whether or not the first current value is smaller than the current command value (S54). In addition, operation | movement of the control part 12 of the master charger 1 in S52 is the same as the operation | movement shown in FIG. 4, for example. In S <b> 53, the outputable current value of the charger 1 is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4.

Next, when the control unit 12 determines that the first current value is smaller than the current command value (S54: Yes), the power source is configured so that a current corresponding to the first current value is output from the charger 1. The operation of the unit 11 is controlled (S55).

In addition, the control unit 12 determines that the total power consumption is equal to or less than the desired power (S51: No), or determines that the first current value is equal to or greater than the current command value (S54: No). Then, the operation of the power supply unit 11 is controlled so that a current corresponding to the current command value is output from the charger 1 (S56).

For example, in a charging system including a master charger 1A and a slave charger 1B, consider a case where the output power of the master charger 1A is 12 [kW] and the output power of the slave charger 1B is 12 [kW]. Note that the contract power of the commercial power supply is 25 [kW], and the desired power is 20 [kW]. In addition, it is assumed that master charger 1A supplies power to power storage device 4A, and slave charger 1B supplies power to power storage device 4B. Further, each voltage output from the master charger 1A and the slave charger 1B to the power storage device 4A and the power storage device 4B is set to 50 [V]. Further, at a certain charging control timing, the current command value transmitted from the control unit 42 of the power storage device 4A to the control unit 12 of the master charger 1A is set to 240 [A], and the control unit 42 of the power storage device 4B sets the slave charger 1B. The current command value transmitted to the control unit 12 is 240 [A].

First, the control unit 12 of the master charger 1A has its own output power (12 [kW]) and the output power (12 [kW]) of the slave charger 1B indicated in the data transmitted from the slave charger 1B. Is obtained as the total power consumption, and data indicating the total power consumption is transmitted to the control unit 12 of the slave charger 1B.

Next, when the control unit 12 of the master charger 1 determines that the total power consumption (24 [kW]) is larger than the desired power (20 [kW]), 20 [kW] / 2 [units] = 10 By calculating [kW], a limit power value (10 [kW]) is obtained, and data indicating the limit power value is transmitted to the slave charger 1B.

Next, the controller 12 of the master charger 1A calculates the first current value (200 [A]) by calculating 10 [kW] / 50 [V] = 200 [A]. At this time, the outputable current value of the charger 1A is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4A. When it is determined that the first current value (200 [A]) is smaller than the current command value (240 [A]) transmitted from the control unit 42 of the power storage device 4A, the first current value (200 The operation of the power supply unit 11 is controlled so that a current corresponding to [A]) is output from the master charger 1A.

When the control unit 12 of the slave charger 1B determines that the total power consumption (24 [kW]) is larger than the desired power (20 [kW]), 10 [kW] / 50 [V] = 200 [ A] is calculated to obtain the first current value (200 [A]). At this time, the output possible current value of the charger 1B is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4B. When it is determined that the first current value (200 [A]) is smaller than the current command value (240 [A]) transmitted from the control unit 42 of the power storage device 4B, the first current value (200 The operation of the power supply unit 11 is controlled so that a current corresponding to [A]) is output from the slave charger 1B.

As a result, the output power of each of the master charger 1A and the slave charger 1B is 10 [kW] (= 200 [A] × 50 [V]), and the total power consumption is 20 [kW] (= 10 [kW]. ] +10 [kW]), the total power consumption (20 [kW]) can be prevented from exceeding the desired power (20 [kW]), and the total power consumption (20 [kW]) is contracted. The power (25 [kW]) may not be exceeded.

Further, for example, in a charging system including a master charger 1A and a slave charger 1B, consider a case where the output power of the master charger 1A is 12 [kW] and the output power of the slave charger 1B is 10 [kW]. . Note that the contract power of the commercial power supply is 25 [kW], and the desired power is 20 [kW]. In addition, it is assumed that master charger 1A supplies power to power storage device 4A, and slave charger 1B supplies power to power storage device 4B. Further, each voltage output from the master charger 1A and the slave charger 1B to the power storage device 4A and the power storage device 4B is set to 50 [V]. Further, at a certain charging control timing, the current command value transmitted from the control unit 42 of the power storage device 4A to the control unit 12 of the master charger 1A is set to 240 [A], and the control unit 42 of the power storage device 4B sets the slave charger 1B. The current command value transmitted to the control unit 12 is 200 [A].

First, the control unit 12 of the master charger 1A has its own output power (12 [kW]) and the output power of the slave charger 1B (10 [10 [kW]) indicated by the data transmitted from the control unit 12 of the slave charger 1B. kW]) and the total power consumption (22 [kW]) are obtained as total power consumption, and data indicating the total power consumption is transmitted to the control unit 12 of the slave charger 1B.

Next, when the control unit 12 of the master charger 1 determines that the total power consumption (22 [kW]) is larger than the desired power (20 [kW]), 20 [kW] / 2 [unit] = 10 By calculating [kW], a limit power value (10 [kW]) is obtained, and data indicating the limit power value is transmitted to the slave charger 1B.

Next, the controller 12 of the master charger 1A calculates the first current value (200 [A]) by calculating 10 [kW] / 50 [V] = 200 [A]. At this time, the outputable current value of the charger 1A is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4A. When it is determined that the first current value (200 [A]) is smaller than the current command value (240 [A]) transmitted from the control unit 42 of the power storage device 4A, the first current value (200 The operation of the power supply unit 11 is controlled so that a current corresponding to [A]) is output from the master charger 1A.

When the control unit 12 of the slave charger 1B determines that the total power consumption (22 [kW]) is larger than the desired power (20 [kW]), 10 [kW] / 50 [V] = 200 [ A] is calculated to obtain the first current value (200 [A]). At this time, the output possible current value of the charger 1B is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4B. When it is determined that the first current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from the control unit 42 of the power storage device 4B (the first current value is the current value). If it is determined that the current value is the same as the command value), the operation of the power supply unit 11 is controlled such that a current corresponding to the current command value (200 [A]) is output from the slave charger 1B.

As a result, the output power of each of the master charger 1A and the slave charger 1B is 10 [kW] (= 200 [A] × 50 [V]), and the total power consumption is 20 [kW] (= 10 [kW]. ] +10 [kW]), the total power consumption (20 [kW]) can be prevented from exceeding the desired power (20 [kW]), and the total power consumption (20 [kW]) is contracted. The power (25 [kW]) may not be exceeded.

Further, for example, in a charging system including a master charger 1A and a slave charger 1B, consider a case where the output power of the master charger 1A is 14 [kW] and the output power of the slave charger 1B is 8 [kW]. . Note that the contract power of the commercial power supply is 25 [kW], and the desired power is 20 [kW]. In addition, it is assumed that master charger 1A supplies power to power storage device 4A, and slave charger 1B supplies power to power storage device 4B. Further, each voltage output from the charger 1A and the charger 1B to the power storage device 4A and the power storage device 4B is set to 50 [V]. Further, at a certain charging control timing, the current command value transmitted from the control unit 42 of the power storage device 4A to the control unit 12 of the master charger 1A is set to 280 [A], and the control unit 42 of the power storage device 4B sets the slave charger 1B. The current command value transmitted to the control unit 12 is 160 [A].

First, the controller 12 of the master charger 1A has its own output power (14 [kW]) and the output power of the slave charger 1B (8 [8 [kW]) indicated by the data transmitted from the controller 12 of the slave charger 1B. kW]) and the total power consumption (22 [kW]) are obtained as total power consumption, and data indicating the total power consumption is transmitted to the control unit 12 of the slave charger 1B.

Next, when the control unit 12 of the master charger 1A determines that the total power consumption (22 [kW]) is larger than the desired power (20 [kW]), 20 [kW] / 2 [units] = 10 By calculating [kW], a limit power value (10 [kW]) is obtained, and data indicating the limit power value is transmitted to the slave charger 1B.

Next, the controller 12 of the master charger 1A calculates the first current value (200 [A]) by calculating 10 [kW] / 50 [V] = 200 [A]. At this time, the outputable current value of the charger 1A is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4A. When it is determined that the first current value (200 [A]) is smaller than the current command value (280 [A]) transmitted from the control unit 42 of the power storage device 4A, the first current value (200 The operation of the power supply unit 11 is controlled so that a current corresponding to [A]) is output from the master charger 1A.

When the control unit 12 of the slave charger 1B determines that the total power consumption (22 [kW]) is larger than the desired power (20 [kW]), 10 [kW] / 50 [V] = 200 [ A] is calculated to obtain the first current value (200 [A]). At this time, the output possible current value of the charger 1B is updated based on the first current value and transmitted to the control unit 42 of the power storage device 4B. When it is determined that the first current value (200 [A]) is equal to or greater than the current command value (160 [A]) transmitted from control unit 42 of power storage device 4B (current command value is the first value). If it is determined that the current is smaller than the current value), the operation of the power supply unit 11 is controlled so that a current corresponding to the current command value (160 [A]) is output from the slave charger 1B.

Thereby, the output power of the master charger 1 becomes 10 [kW] (= 200 [A] × 50 [V]), and the output power of the slave charger 1 becomes 8 [kW] (= 160 [A] × 50). [V]), and the total power consumption becomes 18 [kW] (= 10 [kW] +8 [kW]). Therefore, the total power consumption (18 [kW]) becomes the desired power (20 [kW]). The total power consumption (18 [kW]) can be prevented from exceeding the contract power (25 [kW]).

Thus, the total power consumption (18 [kW]) after controlling the current output from the charger 1 to the power storage device 4 according to the first current value is smaller than the desired power (20 [kW]). Even in this case, the current output from the charger 1 to the power storage device 4 is controlled according to the first current value.

<Third embodiment>
The control unit 12 of each charger 1 in the third embodiment determines whether or not to compare the first current value and the current command value according to the time zone.

FIG. 6 is a flowchart showing an example of the operation of the control unit 12 of each charger 1 in the third embodiment. Note that the operation illustrated in FIG. 6 is repeatedly performed, for example, every charging control timing or every elapse of a certain time T (for example, 20 minutes).

First, the control unit 12 determines whether or not the current time is a time zone when the electricity rate is high (for example, a time zone of midnight or early morning) (S61).
Next, when the control unit 12 determines that the current time is a time zone in which the electricity rate is high (S61: Yes), the control unit 12 acquires a limit power value (S62) and limits the voltage with the voltage output to the power storage device 4. The first current value is obtained by dividing the power value (S63), and it is determined whether or not the first current value is smaller than the current command value (S64). In addition, operation | movement of the control part 12 of the master charger 1 in S62 is the same as the operation | movement shown in FIG. 4, for example.

Next, when the control unit 12 determines that the first current value is smaller than the current command value (S64: Yes), the power source is configured so that a current corresponding to the first current value is output from the charger 1. The operation of the unit 11 is controlled (S65).

In addition, the control unit 12 determines that the current time is not a time zone when the electricity rate is high (S61: No), or determines that the first current value is equal to or greater than the current command value (S64). : No), the operation of the power supply unit 11 is controlled so that a current corresponding to the current command value is output from the charger 1 (S66).

Thereby, in the time zone when an electricity bill is high, the sum total of the output power of each charger 1 can be suppressed.
FIG. 7 is a diagram illustrating an example of a change in the total output power of each charger 1 in the third embodiment. In addition, the time zone when the electricity rate is high is set to 8:00 to 16:00, and the time zone where the electricity rate is not high is set to 0:00 to 8:00 and 16:00 to 24:00.

For example, when the current time is from 12:00 to 13:00 and the first current value is smaller than the current command value at 12:00 to 13:00, the control unit 12 determines that the current time is a time when the electricity rate is high. The power supply unit 11 is controlled so that a current corresponding to the first current value is output from the charger 1 while the first current value is determined to be smaller than the current command value. To do. As a result, even if the total power value obtained by the sum of the current command values transmitted from the power storage device 4 to be charged exceeds the desired power from 12:00 to 13:00, the total output power of each charger 1 is The desired power can be prevented from exceeding. In the example shown in FIG. 7, the power (hatched portion) that could not be supplied to the power storage device 4 from 12:00 to 13:00 is supplied to the power storage device 4 from 13:00 to 14:00.

Thus, the control unit 12 of each charger 1 in the third embodiment determines whether or not to compare the first current value and the current command value according to the time zone, so that the electricity charge is reduced. Since the total output power of each charger 1 can be suppressed in a high time zone, the electricity bill can be suppressed.

<Fourth embodiment>
When determining the power limit value, the control unit 12 of the master charger 1 in the fourth embodiment changes the desired power according to the time zone.

FIG. 8 is a flowchart showing an example of the operation of the control unit 12 of the master charger 1 in the fourth embodiment. Note that the operation illustrated in FIG. 8 is repeatedly performed, for example, every charging control timing or every elapse of a certain time T (for example, 20 minutes). The operation of the control unit 12 of each charger 1 in the fourth embodiment is the same as the operation shown in FIG. 3 or the operation shown in FIG.

First, the control unit 12 of the master charger 1 obtains the number of power storage devices 4 to be charged (S81).
Next, when the controller 12 of the master charger 1 determines that the current time is not a time zone when the electricity rate is high (S82: No), the first desired number of power storage devices 4 to be charged is determined. The power limit value is obtained by dividing the power (S83).

Moreover, when the control part 12 of the master charger 1 judges that the present time is a time slot | zone when an electricity bill is high (S82: Yes), it is 1st desired electric power by the number of the electrical storage apparatuses 4 to charge. The power limit value is obtained by dividing the second desired power smaller than (S84). In addition, the 1st and 2nd desired electric power shall be smaller than the contract electric power of the commercial power supply 2, and shall be arbitrarily set by the user.

This makes it possible to reduce the power limit value required in a time zone when the electricity rate is high compared to the power limit value required in a time zone where the electricity rate is not high. Therefore, compared with the sum total of the output power of each charger 1 in the time zone which is not a time zone when the electricity rate is high, the total output power of each charger 1 in the time zone where the electricity rate is high can be suppressed.

FIG. 9 is a diagram illustrating an example of a change in the total output power of each charger 1 in the fourth embodiment. In addition, the time zone when the electricity rate is high is set to 8:00 to 16:00, and the time zone where the electricity rate is not high is set to 0:00 to 8:00 and 16:00 to 24:00. In addition, from 0 o'clock to 24 o'clock, the control unit 12 determines that the first current value is smaller than the current command value, and the power supply so that the current corresponding to the first current value is output from the charger 1. It is assumed that the operation of the unit 11 is controlled.

For example, when the current time is from 17:00 to 18:00, the control unit 12 of the master charger 1 determines that the current time is not a time zone when the electricity rate is high, and the number of power storage devices 4 to be charged is Then, the power limit value is obtained by dividing the first desired power. Thus, even if the total power value obtained by the sum of the current command values transmitted from the power storage device 4 to be charged exceeds the first desired power at 17:00 to 18:00 shown in FIG. The sum of the output powers of one may not exceed the first desired power. In the example shown in FIG. 9, the power (shaded portion) that could not be supplied to the power storage device 4 from 17:00 to 18:00 is supplied to the power storage device 4 from 18:00 to 19:00.

Further, for example, when the current time is from 12:00 to 13:00, the control unit 12 of the master charger 1 determines that the current time is a time zone when the electricity rate is high, and the charging of the power storage device 4 to be charged is performed. The power limit value is determined by dividing the second desired power by the number. Accordingly, even if the total power value obtained by the sum of the current command values transmitted from the power storage device 4 to be charged exceeds the second desired power at 12:00 to 13:00 shown in FIG. The sum of the output powers of 1 may not exceed the second desired power. In the example shown in FIG. 9, the power (shaded portion) that could not be supplied to the power storage device 4 from 12:00 to 13:00 is supplied to the power storage device 4 from 13:00 to 14:00.

As described above, the control unit 12 of the master charger 1 in the fourth embodiment changes the desired power according to the time zone, so that it can be compared with the desired power in the time zone where the electricity rate is not high. In addition, it is possible to reduce the desired power in the time zone when the electricity charge is high, and to suppress the electricity charge.

Further, as in the first embodiment, the control unit 12 of each charger 1 in the fourth embodiment is configured such that the total output power of each charger 4 is a desired power (first and second) in all time zones. Desired power), and the total output power of each charger 1 does not exceed the contract power.

<Fifth embodiment>
FIG. 10 is a flowchart illustrating an example of the operation of the control unit 12 of each charger 1 in the fifth embodiment. Note that the operation shown in FIG. 10 is repeatedly performed at every charging control timing or every elapse of a fixed time T (for example, 20 minutes).

First, the control unit 12 determines whether or not the total power consumption is larger than desired power (S101). For example, the control unit 12 of the master charger 1 adds the result of adding its own output power and the output power of the slave charger 1 indicated in the data transmitted from the control unit 12 of the slave charger 1 to the total power consumption. And Further, the control unit 12 of the slave charger 1 receives data indicating the total power consumption transmitted from the control unit 12 of the master charger 1.

Next, when it is determined that the total power consumption is larger than the desired power (S101: Yes), the control unit 12 acquires a power limit value (S102). In addition, the control part 12 of the master charger 1 acquires a control electric power value by calculation so that it may mention later. Further, the control unit 12 of the slave charger 1 acquires the limit power value by receiving data indicating the limit power value transmitted from the control unit 12 of the master charger 1.

Next, the control unit 12 obtains the upper limit current value (first current value) by dividing the limit power value by the voltage (output voltage of the charger 1) output to the power storage device 4 to which the power is supplied. Then, the output possible current value is updated based on the obtained upper limit current value, and the updated output possible current value is transmitted to the control unit 42 of the power storage device 4 of its own power supply destination (S103).

Next, the control unit 12 determines whether or not the upper limit current value obtained in S103 is smaller than the current command value transmitted from the control unit 42 of the power storage device 4 that is the power supply destination of the control unit 12 (S104).
Next, when the control unit 12 determines that the upper limit current value is smaller than the current command value (S104: Yes), the power supply unit 11 is configured so that a current corresponding to the upper limit current value is output from its own charger 1. Is controlled (S105).

In addition, when the control unit 12 determines that the upper limit current value is equal to or greater than the current command value (S104: No), the control unit 12 causes the power supply unit 11 to output a current corresponding to the current command value from its own charger 1. The operation is controlled (S106).

In addition, when determining that the total power consumption is equal to or less than the desired power (S101: No), the control unit 12 returns the outputtable current value to the initial value and the outputable current value that has been returned to the initial value. So as to output a current corresponding to the current command value transmitted from the control unit 42 of the power storage device 4 from its own charger 1. The operation of the power supply unit 11 is controlled (S106). For example, when the current command value obtained by the control unit 42 of the power storage device 4 is 300 [A], the outputable current value is changed from 200 [A] to 300 [A] by returning the outputable current value to the initial value. When the current value changes to 200 [A], the current command value transmitted from the control unit 42 of the power storage device 4 to the control unit 12 of the charger 1 also changes from 200 [A]. The initial value of the output possible current value is the maximum current value that each charger 1 can output. The initial value of the output possible current value is determined in advance by the output performance of the power supply unit 11 of each charger 1 and the performance of other components, and is stored in the control unit 12.

FIG. 11 is a flowchart showing an example of the operation of the control unit 12 of the master charger 1 in the fifth embodiment. Note that the operation shown in FIG. 11 is repeatedly performed at every charge control timing or every elapse of a certain time T (for example, 20 minutes).

First, the control unit 12 of the master charger 1 determines the number of power storage devices 4 to be charged (the power storage device 4 to which power is to be supplied from the charger 1 or the power storage device 4 to which power is supplied from the charger 1). Obtain (S111). For example, the control unit 12 of the master charger 1 is transmitted from the control unit 42 of the power storage device 4 of its own power supply destination and the number of transmission requests for the limit power value transmitted from the control unit 12 of the slave charger 1. The result of adding the number of charging start instructions is the number of power storage devices 4 to be charged.

Next, the control unit 12 of the master charger 1 obtains a limit power value by dividing desired power arbitrarily set by the user by the number of power storage devices 4 to be charged (S112). Note that the desired power is set to be equal to or lower than the contract power of the commercial power source 2.

For example, in a charging system including a master charger 1A, a slave charger 1B, and a slave charger 1C, as shown in FIG. 12, the contract power of the commercial power source is 45 [kW], and the desired power is 30 [kW]. Consider the case. The output voltage of each charger 1 is 50 [V]. Further, the initial value of the output possible current value of the master charger 1A, the initial value of the output possible current value of the slave charger 1B, and the initial value of the output possible current value of the slave charger 1C are each 300 [A]. . Further, the current command value obtained by the control unit 42 of the power storage device 4A that is the power supply destination of the master charger 1A is set to 200 [A], and the control unit 42 of the power storage device 4B that is the power supply destination of the slave charger 1B. The obtained current command value is 300 [A], and the current command value obtained by the control unit 42 of the power storage device 4C, which is the power supply destination of the slave charger 1C, is 200 [A]. In addition, during time T1 to time T2, power is supplied to the power storage device 4C in addition to the power storage device 4A and the power storage device 4B.

First, at time T1, the control unit 12 of the master charger 1A has its own output power (10 [kW]), the output power of the slave charger 1B (15 [kW]), and the output power of the slave charger 1C. When it is determined that the total power consumption (25 [kW]), which is the sum of (0 [kW]), is less than or equal to the desired power (30 [kW]), a current command transmitted from the control unit 42 of the power storage device 4A The operation of the power supply unit 11 is controlled so that a current corresponding to the value (200 [A]) is output from the own charger 1. Similarly, when the control unit 12 of the slave charger 1B determines that the total power consumption (25 [kW]) is equal to or less than the desired power (30 [kW]), the control unit 42 of the power storage device 4B transmits it. The operation of the power supply unit 11 is controlled so that a current corresponding to the current command value (300 [A]) is output from the charger 1 of its own.

Next, at time T2, the control unit 12 of the master charger 1A has its own output power (10 [kW]), the output power of the slave charger 1B (15 [kW]), and the output of the slave charger 1C. When it is determined that the total power consumption (35 [kW]), which is the sum of the power (10 [kW]), is larger than the desired power (30 [kW]), 30 [kW] / 3 [unit] = 10 [ The power limit value (10 [kW]) is obtained by calculating [kW], and the upper limit current value (200 [A]) is calculated by calculating 10 [kW] / 50 [V] = 200 [A]. Ask. Further, the control unit 12 of the master charger 1A updates the output possible current value from 200 [A] to 200 [A] based on the upper limit current value (200 [A]), and can output after the update. The current value (200 [A]) is transmitted to the control unit 42 of the power storage device 4A. When determining that the current command value (200 [A]) obtained by itself is equal to or greater than the received output possible current value (200 [A]), control unit 42 of power storage device 4A determines the output possible current value (200 [A]). A]) is transmitted as a current command value to the control unit 12 of the master charger 1A. When control unit 12 of master charger 1A determines that the upper limit current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from control unit 42 of power storage device 4A, current command The operation of the power supply unit 11 is controlled so that a current corresponding to the value (200 [A]) is output from the own charger 1. Similarly, when the control unit 12 of the slave charger 1B determines that the total power consumption (35 [kW]) is larger than the desired power (30 [kW]), 10 [kW] / 50 [V] = 200 The upper limit current value (200 [A]) is obtained by calculating [A]. Further, the control unit 12 of the slave charger 1B updates the output possible current value from 300 [A] to 200 [A] based on the upper limit current value (200 [A]), and can output after the update. The current value (200 [A]) is transmitted to the control unit 42 of the power storage device 4B. When the control unit 42 of the power storage device 4B determines that the current command value (300 [A]) obtained by itself is equal to or greater than the received outputable current value (200 [A]), the outputable current value (200 [A]) is determined. A]) is transmitted to the control unit 12 of the slave charger 1B as a current command value. When control unit 12 of slave charger 1B determines that the upper limit current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from control unit 42 of power storage device 4B, current command The operation of the power supply unit 11 is controlled so that a current corresponding to the value (200 [A]) is output from the own charger 1. Similarly, when the control unit 12 of the slave charger 1C determines that the total power consumption (35 [kW]) is larger than the desired power (30 [kW]), 10 [kW] / 50 [V] = 200 The upper limit current value (200 [A]) is obtained by calculating [A]. Moreover, the control part 12 of 1 C of slave chargers can update the output possible electric current value from 200 [A] to 200 [A] based on an upper limit electric current value (200 [A]), and the output after the update is possible The current value (200 [A]) is transmitted to the control unit 42 of the power storage device 4C. When the control unit 42 of the power storage device 4C determines that the current command value (200 [A]) obtained by itself is equal to or greater than the received output possible current value (200 [A]), the output possible current value (200 [A]) is determined. A]) is transmitted as a current command value to the control unit 12 of the slave charger 1C. When control unit 12 of slave charger 1C determines that the upper limit current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from control unit 42 of power storage device 4C, current command The operation of the power supply unit 11 is controlled so that a current corresponding to the value (200 [A]) is output from the own charger 1. As a result, the total power consumption is set to a desired power (30 [kW]) (master charger 1A: 10 [kW] = 200 [A] × 50 [V], slave charging immediately before time T2 to time T3. Device 1B: 10 [kW] = 200 [A] × 50 [V], slave charger 1C: 10 [kW] = 200 [A] × 50 [V]).

Next, at time T3, the control unit 12 of the master charger 1A, its own output power (10 [kW]), the output power of the slave charger 1B (10 kW), and the output power of the slave charger 1C ( 10 [kW]), when it is determined that the total power consumption (30 [kW]) is equal to or less than the desired power (30 [kW]), the output possible current value (300 [A]) returned to the initial value ) Is transmitted to the control unit 42 of the power storage device 4A. When the control unit 42 of the power storage device 4A determines that the current command value (200 [A]) obtained by itself is smaller than the received output possible current value (300 [A]), the current command value (200 [A] ]) To the controller 12 of the master charger 1A. The control unit 12 of the master charger 1A is configured so that the current corresponding to the current command value (200 [A]) transmitted from the control unit 42 of the power storage device 4A is output from its own charger 1. Control the behavior. Similarly, when the control unit 12 of the slave charger 1B determines that the total power consumption (30 [kW]) is equal to or less than the desired power (30 [kW]) at time T3, the output can be returned to the initial value. The current value (300 [A]) is transmitted to the control unit 42 of the power storage device 4B. When the control unit 42 of the power storage device 4B determines that the current command value (300 [A]) obtained by itself is equal to or greater than the received output possible current value (300 [A]), the output possible current value (300 [A] A]) is transmitted to the control unit 12 of the slave charger 1B as a current command value. Control unit 12 of slave charger 1B controls the operation of power supply unit 11 so that a current corresponding to the current command value (300 [A]) transmitted from control unit 42 of power storage device 4B is output from itself. . Similarly, when the control unit 12 of the slave charger 1C determines that the total power consumption (30 [kW]) is equal to or less than the desired power (30 [kW]) at time T3, the output can be returned to the initial value. The current value (300 [A]) is transmitted to the control unit 42 of the power storage device 4C. When the control unit 42 of the power storage device 4C determines that the current command value (200 [A]) obtained by itself is smaller than the received output possible current value (300 [A]), the current command value (200 [A] ]) Is transmitted to the control unit 12 of the slave charger 1C. Control unit 12 of slave charger 1C controls the operation of power supply unit 11 such that a current corresponding to the current command value (200 [A]) transmitted from control unit 42 of power storage device 4C is output from itself. . Thereby, between time T3 and immediately before time T4, the total power consumption before suppressing the total power consumption (35 [kW]) (master charger 1A: 10 [kW] = 200 [A] × 50 [V Slave charger 1B: 15 [kW] = 300 [A] × 50 [V], slave charger 1C: 10 [kW] = 200 [A] × 50 [V]).

Further, at times T4 and T5 and at times T6 and T7, the same charging control as at times T2 and T3 is repeated, and the total power consumption fluctuates in the same manner as at times T2 and T3.
In the example of FIG. 12, it is assumed that charging of the power storage device 4A is completed between time T7 and time T8, and thereafter, the total power consumption does not become larger than desired power.

As described above, the control unit 12 of each charger 1 according to the fifth embodiment uses the power limit value obtained by dividing the desired power by the number of power storage devices 4 to be charged because the total power consumption is larger than the desired power. When the upper limit current value obtained by dividing by the voltage output to 4 is smaller than the current command value, the output current of the charger 1 can be made equal to or lower than the upper limit current value. If they are the same, the total power consumption can be prevented from exceeding the desired power, and the total power consumption can be prevented from exceeding the contract power.

In addition, the control unit 12 of each charger 1 of the fifth embodiment, when controlling the output current according to the upper limit current value, if the total power consumption becomes less than the desired power, the output possible current value By returning to the initial value and controlling the output current according to the current command value (ending the control of the output current according to the upper limit current value), the total power consumption is increased to the total power consumption before suppression. Therefore, compared with the case where the output power of each charger 1 is continuously suppressed, the charging rate can be increased and the charging time can be suppressed from being extended.

<Sixth embodiment>
FIG. 13 is a flowchart showing an example of the operation of the control unit 12 of each charger 1 in the sixth embodiment. Note that the operation shown in FIG. 13 is repeatedly performed at every charging control timing or every elapse of a fixed time T (for example, 20 minutes).

First, the control unit 12 determines that the total power consumption is larger than the desired power (S131: Yes) or determines that the total power consumption is equal to or less than the desired power (S131: No). When it is determined that there is at least one charger 1 having the peak cut flag of the state (S132: Yes), the power limit value is acquired (S133). In S133, the control unit 12 of the master charger 1 obtains the limit power value by executing the operation shown in FIG. 11, for example.

Next, the control unit 12 obtains the upper limit current value by dividing the limit power value by the voltage (output voltage of the charger 1) output to the power storage device 4 that is the power supply destination of the control unit 12, and the obtained upper limit current value. The output possible current value is updated based on the information, and the updated output possible current value is transmitted to the control unit 42 of the power storage device 4 of its own power supply destination (S134).

Next, the control unit 12 determines whether or not the upper limit current value obtained in S134 is smaller than the current command value transmitted from the control unit 42 of the power storage device 4 of its own power supply destination (S135).
Next, when the control unit 12 determines that the upper limit current value is smaller than the current command value (S135: Yes), the operation of the power supply unit 11 so that a current corresponding to the upper limit current value is output from the charger 1. (S136), the peak cut flag corresponding to itself is changed from the OFF state to the ON state and transmitted to the other charger 1 (S137).

In addition, when the control unit 12 determines that the upper limit current value is equal to or greater than the current command value (S135: No), the control unit 12 operates the power supply unit 11 so that a current corresponding to the current command value is output from the charger 1. Control is performed (S138).

Further, the control unit 12 determines that the total power consumption is equal to or less than the desired power (S131: No), and determines that there is no charger 1 having an on-state peak cut flag (S132: No). The outputtable current value is returned to the initial value, and the outputtable current value returned to the initial value is transmitted to the control unit 42 of the power storage device 4 that is the power supply destination (S139), and the control unit of the power storage device 4 is transmitted. The operation of the power supply unit 11 is controlled such that a current corresponding to the current command value transmitted from 42 is output from its own charger 1 (S138).

Note that the peak cut flag in the on state is reset to the off state when the charging process of the corresponding charger 1 is completed.
For example, in a charging system including a master charger 1A, a slave charger 1B, and a slave charger 1C, as shown in FIG. 14, the contract power of the commercial power source is 45 [kW], and the desired power is 30 [kW]. Consider the case. The output voltage of each charger 1 is 50 [V]. Further, the initial value of the output possible current value of the master charger 1A, the initial value of the output possible current value of the slave charger 1B, and the initial value of the output possible current value of the slave charger 1C are each 300 [A]. . Further, the current command value obtained by the control unit 42 of the power storage device 4A that is the power supply destination of the master charger 1A is set to 200 [A], and the control unit 42 of the power storage device 4B that is the power supply destination of the slave charger 1B. The obtained current command value is 300 [A], and the current command value obtained by the control unit 42 of the power storage device 4C, which is the power supply destination of the slave charger 1C, is 200 [A]. In addition, during time T1 to time T2, power is supplied to the power storage device 4C in addition to the power storage device 4A and the power storage device 4B. Further, the processing of the control unit 12 of each charger 1 at time T1 and time T2 in FIG. 14 (processing other than the peak cut flag on / off switching control processing) is performed by each charger 1 at time T1 and time T2 in FIG. This is the same as the current control process of the control unit 12. Further, at time T2 in FIG. 14, the peak cut flag corresponding to the master charger 1A remains in the OFF state, the peak cut flag corresponding to the slave charger 1B changes from the OFF state to the ON state, and the slave charger 1C. The peak cut flag corresponding to is left in the off state.

At time T3 in FIG. 14, the control unit 12 of the master charger 1A determines that the total power consumption (30 [kW]) is equal to or less than the desired power (30 [kW]), and sets the peak cut flag in the on state. If it is determined that the slave charger 1B is applicable as the charger, the power limit value (10 [kW]) is obtained by calculating 30 [kW] / 3 [unit] = 10 [kW], and 10 [kW] ] / 50 [V] = 200 [A] to obtain the upper limit current value (200 [A]). Further, the control unit 12 of the master charger 1A updates the output possible current value from 200 [A] to 200 [A] based on the upper limit current value (200 [A]), and can output after the update. The current value (200 [A]) is transmitted to the control unit 42 of the power storage device 4A. When determining that the current command value (200 [A]) obtained by itself is equal to or greater than the received output possible current value (200 [A]), control unit 42 of power storage device 4A determines the output possible current value (200 [A]). A]) is transmitted as a current command value to the control unit 12 of the master charger 1A. When control unit 12 of master charger 1A determines that the upper limit current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from control unit 42 of power storage device 4A, current command The operation of the power supply unit 11 is controlled so that a current corresponding to the value (200 [A]) is output from the own charger 1. Similarly, the control unit 12 of the slave charger 1B determines that the total power consumption (30 [kW]) is equal to or less than the desired power (30 [kW]), and as a charger having an on-state peak cut flag. When it is determined that it corresponds, the upper limit current value (200 [A]) is obtained by calculating 10 [kW] / 50 [V] = 200 [A]. Further, the control unit 12 of the slave charger 1B updates the output possible current value from 200 [A] to 200 [A] based on the upper limit current value (200 [A]), and can output after the update. The current value (200 [A]) is transmitted to the control unit 42 of the power storage device 4B. When the control unit 42 of the power storage device 4B determines that the current command value (300 [A]) obtained by itself is equal to or greater than the received outputable current value (200 [A]), the outputable current value (200 [A]) is determined. A]) is transmitted to the control unit 12 of the slave charger 1B as a current command value. When the control unit of slave charger 1B determines that the upper limit current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from control unit 42 of power storage device 4B, the current command value The operation of the power supply unit 11 is controlled so that a current corresponding to (200 [A]) is output from the charger 1 of itself. Similarly, the control unit 12 of the slave charger 1C determines that the total power consumption (30 [kW]) is equal to or less than the desired power (30 [kW]), and as a charger having an on-state peak cut flag. If the slave charger 1B is determined to be applicable, the upper limit current value (200 [A]) is obtained by calculating 10 [kW] / 50 [V] = 200 [A]. Moreover, the control part 12 of 1 C of slave chargers can update the output possible electric current value from 200 [A] to 200 [A] based on an upper limit electric current value (200 [A]), and the output after the update is possible The current value (200 [A]) is transmitted to the control unit 42 of the power storage device 4C. When the control unit 42 of the power storage device 4C determines that the current command value (200 [A]) obtained by itself is equal to or greater than the received output possible current value (200 [A]), the output possible current value (200 [A]) is determined. A]) is transmitted as a current command value to the control unit 12 of the slave charger 1C. When the control unit of slave charger 1C determines that the upper limit current value (200 [A]) is equal to or greater than the current command value (200 [A]) transmitted from control unit 42 of power storage device 4C, the current command value The operation of the power supply unit 11 is controlled so that a current corresponding to (200 [A]) is output from the charger 1 of itself.

From time T4 to T7, the same charging control as that at time T3 is repeated, and the total power consumption at time T4 to T7 is the same as the total power consumption at time T3 (30 [kW]). That is, in the sixth embodiment, when there is at least one charger 1 having an on-state peak cut flag, the total power consumption (30 [kW]) is set to a desired value until the charging process of the charger 1 is completed. The power can be kept below the power (30 [kW]).

As described above, in the control unit 12 of each charger 1 of the sixth embodiment, the total power consumption is larger than the desired power, and the limit power value obtained by dividing the desired power by the number of power storage devices 4 to be charged is stored. When the upper limit current value obtained by dividing by the voltage output to the device 4 is smaller than the current command value, the output current of the charger 1 can be made lower than the upper limit current value. Are the same as each other, the total power consumption can be prevented from exceeding the desired power, and the total power consumption can be prevented from exceeding the contract power.

Moreover, the control part 12 of each charger 1 of 6th Example is a case where the total power consumption becomes below desired power when controlling the output current according to the upper limit current value, and the upper limit current. When there is at least one charger 1 that does not control the output current according to the value, the output current is continuously controlled according to the upper limit current value (the control of the output current according to the upper limit current value is not terminated). Therefore, the total power consumption can be continuously suppressed, and the total power consumption can be prevented from rising to the total power consumption before the suppression.

Further, when the charger 1 compares the first current value with the current command value and the first current value is smaller than the current command value, the output current is controlled according to the first current value. At this time, when the current command value is 240 [A], for example, when viewed from the power storage device 4, the actual current is the first current value, for example, 200 [A]. There is a risk that the difference will be judged as an error. Therefore, in the charging system according to the present embodiment, the current command value is changed so that the power storage device 4 becomes equal to or less than the outputable current value based on the first current value sent from the charger 1. It is possible to suppress an increase in the difference between the value and the actual current and prevent an error from being determined.

DESCRIPTION OF SYMBOLS 1 Charger 2 Commercial power supply 3 Vehicle 4 Power storage apparatus 11 Power supply part 12 Control part 13 Communication line 41 Battery 42 Control part

Claims (19)

1. A first current value obtained by dividing a desired power by the number of power storage devices to be charged is compared with a current command value from the power storage device to be charged, and the first current value is the current command. When the value is smaller than the value, a current output to the power storage device to be charged is controlled according to the first current value.
2. The charger according to claim 1,
   When the first current value is equal to or greater than the current command value, a current output to the power storage device to be charged is controlled according to the current command value.
3. The charger according to claim 1 or 2,
   The first current value is a value obtained by dividing a power value obtained by dividing the desired power by the number of power storage devices to be charged by a voltage output to the power storage device to be charged.
4. The charger according to any one of claims 1 to 3,
   When the first current value is smaller than the current command value even if the total power value obtained by the sum of the current command values transmitted from the power storage device to be charged is smaller than the desired power The charger controls the current output to the power storage device to be charged in accordance with the first current value.
5. The charger according to any one of claims 1 to 3,
   Even when the total of current command values transmitted from the charging power storage device is smaller than the second current value obtained by dividing the desired power by the voltage output to the charging power storage device, the first When the current value is smaller than the current command value, the current output to the power storage device to be charged is controlled according to the first current value.
6. The charger according to any one of claims 1 to 3,
   When the total power consumption, which is the sum of the output powers of the plurality of chargers, is greater than the desired power, the first current value is compared with the current command value, and the first current value is the current. When smaller than a command value, a current output to the power storage device to be charged is controlled according to the first current value.
7. The charger according to claim 6, wherein
   Even if the total power consumption after controlling the current output to the power storage device to be charged according to the first current value is smaller than the desired power, according to the first current value Then, a current output to the power storage device to be charged is controlled.
8. The charger according to any one of claims 1 to 7,
   It is determined whether or not to compare the first current value and the current command value according to a time zone.
9. The charger according to claim 8, wherein
   When the current time is a time zone when the electricity rate is high, the first current value is compared with the current command value, and when the first current value is smaller than the current command value, A charger that controls a current output to the power storage device to be charged according to a current value of the battery.
10. The charger according to claim 8 or 9, wherein
    If the current time is not a time zone when the electricity rate is high, or if the first current value is greater than or equal to the current command value, the current output to the power storage device to be charged according to the current command value A battery charger characterized by controlling.
11. The charger according to any one of claims 1 to 7,
    A charger characterized by changing the desired power according to a time zone.
12. The charger according to claim 11, wherein
    The charger, wherein the desired power in a time zone with a high electricity charge is made smaller than the desired power in a time zone not in a time zone with a high electricity charge.
13. In a charger that outputs a current to a power storage device to be charged, a current control method for controlling a current output to the power storage device to be charged according to a current command value,
    A first current value obtained by dividing a desired power by the number of power storage devices to be charged is compared with a current command value from the power storage device to be charged, and the first current value is the current. When the current value is smaller than the command value, the current output to the power storage device to be charged is controlled according to the first current value.
14. The charger according to claim 1,
    A first current value obtained by a power value obtained by dividing the desired power by the number of power storage devices to be charged when a total power consumption that is a sum of output powers of the plurality of chargers is larger than the desired power. And the current command value from the power storage device to be charged, and if the first current value is smaller than the current command value, the current command value is output to the power storage device to be charged according to the first current value Control the current,
    When the total power consumption is less than or equal to the desired power when controlling the current output to the power storage device to be charged according to the first current value, the current according to the first current value Controlling the electric current output to the electrical storage apparatus to charge is complete | finished. The charger characterized by the above-mentioned.
15. The charger according to claim 14, wherein
    When the total power consumption is less than or equal to the desired power when controlling the current output to the power storage device to be charged according to the first current value, the output possible current value is set to an initial value, A charger characterized by transmitting an outputable current value to a power storage device of its own power supply destination.
16. The charger according to claim 15, wherein
    When the total power consumption is larger than the desired power, the outputable current value is updated based on the first current value, and the outputtable current value is transmitted to the power storage device of its own power supply destination. 1 transmission process,
    When the total power consumption is less than or equal to the desired power when controlling the current output to the power storage device to be charged according to the first current value, the output possible current value is set to an initial value, Performing a second transmission process of transmitting the outputtable current value to the power storage device of its own power supply destination;
    The charger characterized by repeating the first transmission process and the second transmission process.
17. The charger according to claim 14, wherein
    When the total power consumption is less than or equal to the desired power when controlling the current output to the power storage device to be charged according to the first current value, and to the first current value Accordingly, when there is at least one charger that does not control the current output to the power storage device to be charged, the control of the current output to the power storage device to be charged is not terminated according to the first current value. A charger characterized by that.
18. The current control method according to claim 13,
    The first current obtained by a power value obtained by dividing the desired power by the number of power storage devices to be charged when total power consumption, which is a sum of output powers of the plurality of chargers, is larger than the desired power. When the first current value is smaller than the current command value, the current output to the power storage device to be charged is controlled according to the first current value.
    When the total power consumption is less than or equal to the desired power when controlling the current output to the power storage device to be charged according to the first current value, the current according to the first current value Controlling the current output to the power storage device to be charged is terminated.
19. In a charging system including a charger and a power storage device,
    The charger is
    A first current value obtained by dividing a desired power by the number of power storage devices to be charged is compared with a current command value from the power storage device to be charged, and the first current value is the current. If smaller than the command value, according to the first current value, to control the current output to the power storage device to be charged,
    Update the output possible current value of the charger based on the first current value and transmit it to the power storage device,
    The power storage device
    The updated output possible current value is received,
    The current command value obtained based on the voltage of the battery or the SOC and the received output possible current value are compared, and when the obtained current command value is smaller than the output possible current value, the obtained current Send the command value to the charger,
    When the obtained current command value is equal to or greater than the outputtable current value, the outputtable current value is transmitted to the charger as a current command value.

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