JP2018126015A - Charger and power demand/supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charger and power demand/supply system, capable of further handling a user's request.SOLUTION: A charger 1 comprises a control unit 11 for determining a maximum charge current value for charging a storage battery 110a of an electric vehicle 110 using power from a power distribution circuit 4 that is supplied with power from a distributed power supply 2 to perform input/output of power from/to a power system 2a. The control unit 11 includes at least one of first processing and second processing. The first processing includes processing of increasing the maximum charge current value when first power output from the power distribution circuit 4 to the power system is larger than a first threshold. The second processing includes processing of decreasing the maximum charge current value when second power input from the power system 2a to the distribution circuit 4 is larger than a second threshold.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a charging device and a power supply / demand system, and more particularly, to a charging device that charges a storage battery of an electric vehicle and a power supply / demand system including the charging device.

  2. Description of the Related Art Conventionally, there is known an electric vehicle charging power management system (hereinafter referred to as a charging system) that charges a storage battery of an electric vehicle using electric power supplied to a house (for example, Patent Document 1). In the charging system of Patent Literature 1, grid power from a power company is connected to a distribution board on the house side via a power meter. The electric power supplied to the house is branched by the switchboard and supplied to various electric devices in the house and an electric vehicle charger (charging device) provided in the house.

JP 2008-136291 A

  By the way, the user has requested a charging system that can appropriately select the setting of the remaining capacity of the electric vehicle, the adjustment of the amount of electric power for purchasing and selling power, the setting of the charging time of the electric vehicle, or a combination thereof. However, the charging system as in Patent Document 1 cannot always meet the user's request.

  This invention is made | formed in view of the said reason, and it aims at providing the charging device and electric power supply-and-demand system which can respond more to a user's request.

  A charging device according to one aspect of the present invention is a control that determines a maximum charging current value for charging a storage battery of an electric vehicle with electric power from a power distribution circuit that is fed from a distributed power source and inputs / outputs electric power to / from an electric power system. A part. The control unit has at least one of a first process and a second process. The first process includes a process of increasing the maximum charging current value when the first power output from the power distribution circuit to the power system is greater than a first threshold value. The second process includes a process of reducing the maximum charging current value when the second power input from the power system to the power distribution circuit is larger than a second threshold value.

  A power supply and demand system according to an aspect of the present invention includes the above-described charging device, the distributed power source, and a power conditioner that supplies power from the distributed power source to the power distribution circuit.

  The charging device and the power supply and demand system according to the aspect of the present invention have an effect that the user's request can be more dealt with.

FIG. 1 is a system configuration diagram of a charging device and a power supply / demand system according to an embodiment of the present invention. FIG. 2 is a flowchart of the first process and the second process of the power supply and demand system. FIG. 3 is a flowchart of the first charging mode of the power supply and demand system. FIG. 4 is a flowchart of the second charging mode of the power supply and demand system. FIG. 5 is a flowchart of the third charging mode of the power supply and demand system. FIG. 6 is a partial flowchart of the fourth charging mode of the power supply and demand system. FIG. 7 is a remaining flowchart of the fourth charging mode of the power supply and demand system.

1. Embodiment 1.1 Overview A charging device 1 and a power supply and demand system 10 according to the present embodiment will be described with reference to the drawings. FIG. 1 is a system configuration diagram of an electric power supply and demand system 10 including the charging device 1 of the present embodiment. The power supply and demand system 10 of this embodiment is installed in a house or the like. As shown in FIG. 1, the power supply / demand system 10 uses the power generated by the distributed power supply 2 and the power from the power system 2 a to charge the storage battery 110 a of the electric vehicle (for example, an electric vehicle) 110. Furthermore, the power supply and demand system 10 can supply the power generated by the distributed power source 2 and the power from the power system 2 a to one or more load devices 100. The load device 100 is, for example, a refrigerator and a lighting device. The power system 2a is a distribution network to which power from a commercial AC power supply is supplied.

  In the power supply and demand system 10, the power of the distributed power supply 2 may exceed the sum of the power required for the load device 100 (load power) and the power required for charging the electric vehicle 110 (charging power). In this case, in the power supply and demand system 10, surplus power is generated in the power generated by the distributed power supply 2. In the power supply and demand system 10, the power can be output to the power system 2 a via the linkage cable 120 (reverse power flow). As a result, the power supply and demand system 10 can sell power. The power supply and demand system 10 receives power from the power system 2a when the load power and the charging power cannot be covered only by the power from the distributed power supply 2.

1.2 Configuration As shown in FIG. 1, the power supply and demand system 10 includes a distributed power source 2, a power conditioner 3, a power distribution circuit 4, a detection unit 5, a charging device 1, a charging cable 61, and a charging plug. 62.

  The distributed power supply 2 is, for example, a power generation device such as a solar power generation device. The distributed power source 2 is electrically connected to the power conditioner 3 and outputs DC power to the power conditioner 3. The distributed power source 2 is not limited to a solar power generation device, and may be a power generation device using renewable energy such as a wind power generation device using wind power.

  The power conditioner 3 has an inverter circuit and the like. The inverter circuit includes, for example, electronic components such as a plurality of MOSFETs (Metal-Oxide-Semiconductor Field-Effect Transistors) and electrolytic capacitors. The inverter circuit receives DC power generated by the distributed power supply 2 and converts it into AC generated power. Here, the generated power has a voltage amplitude larger than the AC power of the power system 2a, but the voltage frequency is equal to the AC power of the power system 2a. The power conditioner 3 is electrically connected to the power distribution circuit 4 and outputs AC output power to the power distribution circuit 4.

  The power distribution circuit 4 receives output power from the power conditioner 3. In other words, the power distribution circuit 4 is supplied with power from the distributed power supply 2. In addition, the power distribution circuit 4 is electrically connected to the power system 2a via the linkage cable 120. Here, if there is surplus power in the power distribution circuit 4, power can be output from the power distribution circuit 4 to the power system 2a. Here, the power output from the power distribution circuit 4 to the power system 2a is referred to as first power. On the other hand, if the power is insufficient in the power distribution circuit 4, power can be input to the power distribution circuit 4 from the power system 2a. Here, the power input from the power system 2a to the power distribution circuit 4 is referred to as second power. The power distribution circuit 4 is electrically connected to the load device 100 and the charging device 1. More specifically, the power distribution circuit 4 is a distribution board and includes a main breaker and a plurality of branch breakers. The primary side of the main breaker is electrically connected to the power conditioner 3, and the plurality of branch breakers are electrically connected to the secondary side of the main breaker. The load device 100 is electrically connected to the branch breaker of the power distribution circuit 4. That is, the load device 100 is supplied with power based on at least one of the output power from the power conditioner 3 and the second power from the power system 2 a via the power distribution circuit 4. The charging device 1 is electrically connected to the branch breaker of the power distribution circuit 4. That is, the charging device 1 has power for charging the storage battery 110a of the electric vehicle 110 based on at least one of the output power from the power conditioner 3 and the second power from the power system 2a via the power distribution circuit 4. Entered.

  The detection unit 5 is used to measure the current flowing through the link cable 120. The detection unit 5 is, for example, a current transformer. The detection unit 5 outputs the measured current value (measured value) to the charging device 1.

  As illustrated in FIG. 1, the charging device 1 includes a control unit 11, a user setting unit 12, an opening / closing unit 13, and a receiving unit 14. The charging device 1 is installed in a place near the parking space of the electric vehicle 110, for example.

  The charging device 1 is connected to a charging plug 62 via a charging cable 61. Charging cable 61 includes a power supply line 611 for supplying electric power to electric vehicle 110 and a communication line 612 for communicating with electric vehicle 110. The charging plug 62 is provided at the tip of the charging cable 61 as shown in FIG. The charging plug 62 is detachably connected to an insertion port (inlet) provided in the vehicle body of the electric vehicle 110. When charging device 1 is connected to electric vehicle 110 via charging cable 61 and charging plug 62, charging device 1 can supply power to electric vehicle 110 and communicate with electric vehicle 110.

  The control unit 11 includes a measurement unit 111, a setting unit 112, and a determination unit 113. The control part 11 is comprised by the microcontroller which has CPU (Central Processing Unit) and memory, for example. The control unit 11 functions by executing a program stored in the memory by the CPU. The program executed by the CPU may be provided by being stored in a recording medium such as a memory card. In the control unit 11, the CPU and the memory may be separate electronic components, and may be configured to be electrically connected to each other.

  Based on the measurement value of the detection unit 5 and the voltage value of the power supplied from the power distribution circuit 4 to the charging device 1, the measurement unit 111 outputs power (first power) output from the power distribution circuit 4 to the power system 2a and The power (second power) input from the power system 2a to the power distribution circuit 4 is calculated. For example, the measurement unit 111 receives a measurement value from the detection unit 5. Further, the measuring unit 111 measures the voltage of the power distribution circuit 4. The measuring unit 111 obtains the tidal power from the measured value from the detecting unit 5 and the voltage of the power distribution circuit 4. Here, the tidal power is, for example, effective power when the power system 2a is the power transmission side and the power distribution circuit 4 is the power reception side. Accordingly, when the power flow is positive, power is input from the power system 2a to the power distribution circuit 4. That is, the second power is equal to the positive power flow. On the other hand, when the tidal power is negative, power is output from the power distribution circuit 4 to the power system 2a. That is, the first power is equal to the absolute value of the negative tidal power. Furthermore, negative tidal power is equal to positive reverse tidal power.

  The setting unit 112 stores information necessary for processing in the determination unit 113. The setting unit 112 updates information necessary for processing in the determination unit 113 based on the information received from the user setting unit 12 and the reception unit 14. Information necessary for processing in the determination unit 113 is, for example, a first threshold value, a second threshold value, a charging permission time zone, and a charging mode, which will be described later.

  The determination unit 113 acquires the value of the tidal power from the measurement unit 111. Further, the determination unit 113 acquires information necessary for processing in the determination unit 113 from the setting unit 112. Further, the determination unit 113 is connected to the communication line 612 of the charging cable 61.

  The determination unit 113 has four charging modes. The four charging modes are a forced charging mode, a permission time charging mode, a reverse tide charging mode, and a reverse tide / permission time charging mode. The determination unit 113 executes at least one of the first process and the second process in each of the four charging modes. The four charging modes, the first process, and the second process will be described later.

  The user setting unit 12 includes a charge permission time zone input unit 121, a charge mode input unit 122, and a threshold value input unit 123. The charge permission time zone input unit 121, the charge mode input unit 122, and the threshold value input unit 123 are configured by a user interface (for example, a touch panel and a switch button).

  The charging permission time zone input unit 121 receives an input of the charging permission time zone from the user. The setting unit 112 of the control unit 11 changes the charging permission time zone according to the input received by the charging permission time zone input unit 121. Therefore, the user can set the charging permission time zone to a desired time zone. The charging permission time zone is a time zone in which the user desires (permits) charging of the storage battery 110a of the electric vehicle 110. For example, when a user inputs a start time of a time zone in which charging is permitted and an end time of a time zone in which charging is permitted to the charging permission time zone input unit 121, the time zone between the start time and the end time is The charging permission time zone is input.

  The charging mode input unit 122 receives an input of the charging mode from the user. The setting unit 112 of the control unit 11 selects the charging mode according to the input received by the charging mode input unit 122. Therefore, the user can select a desired charging mode. The charging mode is selected from four charging modes: a forced charging mode, a permission time charging mode, a reverse power charging mode, and a reverse power / permitted time charging mode. That is, the user can select one from the forced charging mode, the permitted time charging mode, the reverse power charging mode, and the reverse power / permitted time charging mode by the charging mode input unit 122.

  The threshold value input unit 123 receives input of the first threshold value and the second threshold value from the user. The setting unit 112 of the control unit 11 changes at least one of the first threshold value and the second threshold value according to the input received by the threshold value input unit 123. Therefore, the user can set at least one of the first threshold value and the second threshold value to a desired value. The first threshold value is a value for setting an upper limit value (in other words, a lower limit value of negative tidal power) of reverse tidal power (first power). The amount of power sold can be limited by the first threshold. The second threshold is a value for setting an upper limit value of the tidal power (second power). The amount of power purchase can be limited by the second threshold. For example, the second threshold value may be set to a value of electric power based on a contract ampere (eg, 10A, 15A, 20A) with the electric power company.

  The opening / closing part 13 is inserted between the power distribution circuit 4 and the power supply line 611 of the charging cable 61. The opening / closing part 13 is, for example, an electromagnetic relay. The opening / closing unit 13 is opened / closed in response to an instruction from the determining unit 113.

  The receiving unit 14 is configured to receive information from an external device. The receiving unit 14 is electrically connected to the control unit 11 and outputs information received from an external device to the control unit 11. The external device includes, for example, a smart meter and a power distribution circuit 4. The receiving unit 14 can thus receive the charging permission time zone, the charging mode, the first threshold value, and the second threshold value from the external device. The receiving unit 14 receives information from an external device using a wired or wireless communication method. Therefore, according to the receiving part 14, the charging device 1 can receive automatically the 1st threshold value and 2nd threshold value for respond | corresponding to the request from an electric power company, for example, a demand response, for example. Accordingly, the setting unit 112 of the control unit 11 can change at least one of the first threshold value and the second threshold value according to the information received from the receiving unit 14.

  The electric vehicle 110 includes a storage battery 110a and a charger 110b. The charger 110b monitors an SOC (State of Charge) indicating the charge / discharge state of the storage battery 110a. The charger 110 b transmits the state of the storage battery 110 a to the charging device 1 via the communication line 612 of the charging cable 61. More specifically, the charger 110b transmits a charging start permission instruction, a charging end instruction, and a minimum chargeable current value to the charging device 1. The minimum chargeable current value is a value of a minimum current necessary for charging the storage battery 110a.

  The charger 110 b receives a signal including the maximum charging current value and the like from the charging device 1 via the communication line 612 of the charging cable 61. When the charger 110b determines that the storage battery 110a needs to be charged, the charger 110b transmits a charge start permission instruction to the charging device 1. The charger 110b converts AC power supplied from the charging device 1 into DC power. The charger 110b charges the storage battery 110a so that the value of the current supplied to the storage battery 110a does not exceed the maximum charging current value. When the SOC of the storage battery 110a reaches the target level, an instruction to end charging is output to the charging device 1, and the charging of the storage battery 110a is ended.

1.3 First Process and Second Process The determining unit 113 determines the maximum current value (maximum charging current value) in the first process or the second process. More specifically, the determination unit 113 increases, decreases, or maintains the maximum charging current value step by step (for example, every 1 A) in the first process or the second process. The determination unit 113 closes the opening / closing unit 13 when permitting the supply of power to the storage battery 110 a of the electric vehicle 110. On the other hand, the determination unit 113 opens the opening / closing unit 13 when the supply of power to the storage battery 110a of the electric vehicle 110 is not permitted. Moreover, the determination part 113 determines the maximum value (maximum charging current value) of the electric current used for charge of the storage battery 110a of the electric vehicle 110 in a 1st process or a 2nd process.

1.3.1 First Process The first process will be briefly described with reference to the flowchart of FIG. The first process is a process defined in steps S102 to S104 shown in FIG. Note that the processing here includes a case where the tidal power is zero.

  The determination unit 113 determines whether or not the tidal power obtained by the measurement unit 111 is 0 or less (step S101). If the tidal power is positive, the second power is input from the power system 2a to the power distribution circuit 4. On the other hand, if the tidal power is negative, the first power is output from the power distribution system 4a from the power distribution circuit 4. When it is determined that the tidal power is 0 or less (step S101: Yes), the determination unit 113 determines whether the absolute value of the negative tidal power (that is, the first power) is greater than the first threshold value. (Step S102). When it is determined that the absolute value of the negative tidal power is greater than the first threshold (step S102: Yes), the determination unit 113 increases the maximum charging current value (step S103). As a result, the electric power that can be used to charge the electric vehicle 110 increases, and thus a decrease in the first electric power can be expected.

  On the other hand, when determining that the absolute value of the negative tidal power is equal to or less than the first threshold (step S102: No), the determination unit 113 maintains or decreases the maximum charging current value (step S104). As a result, the power that can be used for charging the storage battery 110a of the electric vehicle 110 is maintained or decreased, so that the maintenance or increase of the first power can be expected.

  Thus, the first process is a process when the tidal power is negative. In the first process, the determination unit 113 compares the first power (equal to the absolute value of the negative tidal power) with the first threshold value. Then, the determination unit 113 determines the maximum charging current value according to the comparison result between the absolute value of the tidal power and the first threshold value.

1.3.2 Second Process Next, the second process will be briefly described with reference to the flowchart of FIG. The second process is a process defined in steps S105 to S107 shown in FIG.

  When determining unit 113 determines that the tidal power is greater than 0 (step S101: No), determining unit 113 determines whether the tidal power (that is, the second power) is greater than the second threshold value. (Step S105). When it is determined that the tidal power is larger than the second threshold (step S105: Yes), the determination unit 113 decreases the maximum charging current value (step S106). Thereby, since the electric power which can be used for the charge of the storage battery 110a of the electric vehicle 110 decreases, the reduction | decrease of 2nd electric power can be anticipated.

  On the other hand, when it is determined that the tidal current power is equal to or lower than the second threshold (step S105: No), the determination unit 113 maintains or increases the maximum charging current value (step S107). As a result, the power that can be used for charging the storage battery 110a of the electric vehicle 110 is maintained or increased, so that the second power can be maintained or increased.

  Thus, the second process is a process when the tidal power is positive. In the second process, the determination unit 113 compares the second power (equal to the positive power flow) and the second threshold value. And the determination part 113 determines the maximum charging current value according to the comparison result of tidal power and a 2nd threshold value.

1.4 Charge Mode Next, forced charge mode (first charge mode), permission time charge mode (second charge mode), reverse power charge mode (third charge mode), and reverse power / permit time charge mode (first 4 charging mode) will be described.

1.4.1 Forced charging mode (first charging mode)
The first charging mode is a mode for always setting the storage battery 110a of the electric vehicle 110 to a fully charged state. The first charging mode will be described in detail with reference to the flowchart of FIG. In the first charging mode, the first process is not executed and the second process is executed. The second threshold value is set based on the power value (contract power value) corresponding to the contract ampere. If the second threshold value is set smaller than the contract power value, the possibility that the value of the current flowing from the power system 2a to the power distribution circuit 4 exceeds the contract ampere can be reduced. Furthermore, the initial value of the maximum charging current value is set to the minimum chargeable current value.

  Determination unit 113 determines whether or not charging plug 62 is connected to electrically powered vehicle 110 (step S201). When it is determined that the charging plug 62 is connected to the electric vehicle 110 (step S201: Yes), the determination unit 113 determines whether or not an instruction to permit charging start is received from the electric vehicle 110 (step S202). . When it is determined that an instruction to permit charging start has been received from the electric vehicle 110 (step S202: Yes), the determination unit 113 closes the opening / closing unit 13 and enables charging of the storage battery 110a of the electric vehicle 110 (step S203). ).

  Next, the determination unit 113 determines whether or not the tidal power is equal to or less than the second threshold (Step S204). In other words, the determination unit 113 determines whether or not the second power is equal to or less than the second threshold value. When it is determined that the tidal power is equal to or lower than the second threshold (step S204: Yes), the determination unit 113 determines whether or not the maximum charging current value is equal to a preset maximum value (step S205). In other words, the determination unit 113 determines whether or not the maximum charging current value is equal to the maximum value of current that can be used to charge the storage battery 110a of the electric vehicle 110. When determining that the maximum charging current value is not equal to the preset maximum value (step S205: No), the determination unit 113 increases the maximum charging current value by one step (step S206). Then, charging device 1 transmits the changed maximum charging current value to electric vehicle 110 (step S207). On the other hand, when determining that the maximum charging current value is equal to the preset maximum value (step S205: Yes), the determination unit 113 shifts the process to S204. That is, the determination unit 113 maintains the maximum charging current value.

  Thus, the charger 110b of the electric vehicle 110 can charge the storage battery 110a within a range not exceeding the maximum charging current value received from the charging device 1.

  On the other hand, when it is determined that the tidal power is larger than the second threshold (step S204: No), the determination unit 113 determines whether or not the maximum charging current value is equal to the minimum chargeable current value (step S208). When it is determined that the maximum charging current value is not equal to the minimum chargeable current value (step S208: No), the determination unit 113 decreases the maximum charging current value by one step (step S209). Then, determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S207).

  On the other hand, when determining that the maximum charging current value is equal to the minimum chargeable current value (step S208: Yes), the determination unit 113 ends the forced charging mode (step S210). Thereby, the charging of the storage battery 110a is stopped.

  Moreover, when the charging device 1 is not connected with the electric vehicle 110 (step S201: No), the determination part 113 complete | finishes forced charging mode (step S210). Moreover, when the instruction | indication of charge start permission is not received from the charger 110b of the electric vehicle 110 (step S202: No), the determination part 113 complete | finishes forced charging mode (step S210). In addition, also when the instruction | indication of a charge end is received from the charger 110b, the determination part 113 complete | finishes forced charging mode.

  In the forced charging mode (first charging mode) described above, the charging device 1 executes the second process (steps S204, S206, and S209). In other words, in the first charging mode, the charging device 1 stores the storage battery in the charger 110b of the electric vehicle 110 regardless of whether or not the power distribution circuit 4 supplies the first power to the power system 2a via the link cable 120. Allow charging of 110a. Then, the charging device 1 increases the maximum charging current value step by step until the second power reaches the second threshold value (contract power). However, an upper limit is set for the maximum charging current value. And if 2nd electric power becomes larger than a 2nd threshold value, the charging device 1 will reduce the maximum charging current value by one step. Here, if the second power does not become the second threshold value or less even though the maximum charging current value matches the minimum chargeable current, the charging device 1 finishes charging the storage battery 110a of the electric vehicle 110. To do.

  In the first charging mode, since the charging device 1 can charge the storage battery 110a of the electric vehicle 110 using the second threshold based on the contract power as the upper limit of the tidal power, the storage battery 110a of the electric vehicle 110 can be charged in a short time. Become.

1.4.2 Allowed time charging mode (second charging mode)
In the second charging mode, the charging device 1 charges the storage battery 110a of the electric vehicle 110, for example, at a time zone (time) determined every day.

  The second charging mode will be described in detail with reference to the flowchart of FIG. In the second charging mode, the first process is not executed and the second process is executed. The second threshold value is set based on the power value (contract power value) corresponding to the contract ampere. Furthermore, the initial value of the maximum charging current value is set to the minimum chargeable current value.

  Determination unit 113 determines whether or not charging plug 62 is connected to electrically powered vehicle 110 (step S301). When it is determined that the charging plug 62 is connected to the electric vehicle 110 (step S301: Yes), the determination unit 113 determines whether or not an instruction to permit charging start is received from the electric vehicle 110 (step S302). . When the instruction to permit charging start is received from the electric vehicle 110 (step S302: Yes), the determination unit 113 determines whether or not the current time is in the charging permission time zone (step S303). When the current time is within the range of the charging permission time zone (step S303: Yes), the determination unit 113 closes the opening / closing unit 13 and enables charging of the storage battery 110a of the electric vehicle 110 (step S304).

  Next, the determination unit 113 determines whether or not the tidal power is equal to or less than the second threshold (step S305). When it is determined that the tidal power is equal to or less than the second threshold (step S305: Yes), the determination unit 113 determines whether or not the maximum charging current value is equal to a preset maximum value (step S306). In other words, the determination unit 113 determines whether or not the maximum charging current value is equal to the maximum value of current that can be used to charge the storage battery 110a of the electric vehicle 110. When determining that the maximum charging current value is not equal to the preset maximum value (step S306: No), the determination unit 113 increases the maximum charging current value by one level (step S307). Then, determination unit 113 transmits the maximum charging current value to electric vehicle 110 (step S308). After this, the determination unit 113 determines whether or not the current time is within the charging permission time zone (step S309). When the current time is within the range of the charging permission time zone (step S309: Yes), the determination unit 113 shifts the processing to step S305.

  On the other hand, when determining that the maximum charging current value is equal to the preset maximum value (step S306: Yes), the determination unit 113 proceeds to step S305. That is, the determination unit 113 maintains the maximum charging current value.

  On the other hand, when it is determined that the tidal power is not equal to or less than the second threshold (step S305: No), the determination unit 113 determines whether or not the maximum charging current value is equal to the minimum chargeable current value (step S310). When determining that the maximum charging current value is not equal to the minimum chargeable current value (step S310: No), the determination unit 113 decreases the maximum charging current value by one step (step S311). Determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S308). Thereafter, the determination unit 113 shifts the processing to S309.

  Thereby, the charger 110b of the electric vehicle 110 can charge the storage battery 110a within a range not exceeding the maximum charging current value received from the charging device 1 during the charging permission time zone.

  On the other hand, when determining that the maximum charging current value is equal to the minimum chargeable current value (step S310: Yes), the determination unit 113 ends the permitted time charging mode (step S312). Thereby, the charging of the storage battery 110a is terminated.

  Moreover, when the charging device 1 is not connected with the electric vehicle 110 (step S301: No), the determination part 113 complete | finishes permission time charge mode (step S312). In addition, when an instruction to permit charging start is not received from the charger 110b of the electric vehicle 110 (step S302: No), the determination unit 113 ends the permitted time charging mode (step S312). Further, when the current time is not the charging permission time zone (step S303: No), the determination unit 113 ends the permission time charging mode (step S312). Further, after the start of charging (step S304), when the current time is not the charging permission start time zone (step S309: No), the determination unit 113 ends the permission time charging mode (step S312). In addition, also when the instruction | indication of completion | finish of charge is received from the charger 110b, the determination part 113 complete | finishes permission time charge mode. Thereby, the charging of the storage battery 110a is terminated.

  In the permission time charging mode (second charging mode) described above, the charging device 1 executes the second process in the charging permission time zone (steps S305, S307, and S311). In other words, in the second charging mode, regardless of whether the power distribution circuit 4 supplies the first power to the power system 2a via the link cable 120 during the charging permission time period, the charging device 1 The charger 110b of the electric vehicle 110 is allowed to charge the storage battery 110a during the time zone. Then, the charging device 1 increases the maximum charging current value step by step until the second power reaches the second threshold value (contract power). However, an upper limit is set for the maximum charging current value. And if 2nd electric power becomes larger than a 2nd threshold value in the charge permission time slot | zone, the charging device 1 will reduce the maximum charging current value by one step. Here, if the second power does not become the second threshold value or less even though the maximum charging current value matches the minimum chargeable current, the charging device 1 finishes charging the storage battery 110a of the electric vehicle 110. To do.

  In the second charging mode, power can be supplied to the storage battery 110a of the electric vehicle 110 in the time zone desired by the user (charging permission time zone), with the second threshold value based on the contract power as the upper limit of the tidal power. Therefore, in the second charging mode, it is possible to charge the storage battery 110a of the electric vehicle 110 during a time zone where the electricity bill is cheap.

1.4.3 Reverse tide charging mode (third charging mode)
In the third charging mode, the charging device 1 charges the storage battery 110a of the electric vehicle 110 only when a reverse power flow by the distributed power source 2 occurs. The third charging mode will be described in detail with reference to the flowchart of FIG. In the third charging mode, the second process is not executed and the first process is executed. In the third charging mode, in order to suppress hunting in the vicinity of the first threshold value, a value aW and a value bW for giving a desired hysteresis to the first threshold value are set. Furthermore, the initial value of the maximum charging current value is set to the minimum chargeable current value.

  Determination unit 113 determines whether or not charging plug 62 is connected to electrically powered vehicle 110 (step S401). When it is determined that the charging plug 62 is connected to the electric vehicle 110 (step S401: Yes), the determination unit 113 determines whether or not an instruction to permit charging start is received from the electric vehicle 110 (step S402). ). When the charging start permission instruction is received from the electric vehicle 110 (step S402: Yes), the charging device 1 determines whether or not the tidal power is a value equal to or less than 0 (step S403). When it is determined that the tidal power is 0 or less (step S403: Yes), the determination unit 113 closes the opening / closing unit 13 to allow the storage battery 110a of the electric vehicle 110 to be charged (step S404).

  Next, the determination unit 113 determines whether or not the absolute value of the tidal power is larger than a value obtained by adding the value aW to the first threshold (step S405). When it is determined that the absolute value of the tidal current is larger than the value obtained by adding the value aW to the first threshold (step S405: Yes), the determination unit 113 determines whether or not the maximum charging current value is equal to the preset maximum value. Is determined (step S406). In other words, the determination unit 113 determines whether or not the maximum charging current value is equal to the maximum value of current that can be used to charge the storage battery 110a of the electric vehicle 110. When it is determined that the maximum charging current value is equal to the preset maximum value (step S406: Yes), the determination unit 113 proceeds to step S405. Therefore, the determination unit 113 maintains the maximum charging current value.

  On the other hand, when determining that the maximum charging current value is not equal to the preset maximum value (step S406: No), the determination unit 113 increases the maximum charging current value by one level (step S407). Then, determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S408). Next, the determination unit 113 determines whether or not the value of the tidal power is 0 or less (step S409). When the value of tidal power is 0 or less (step S409: Yes), the power supply / demand system 10 shifts the processing to step S405.

  On the other hand, when it is determined that the absolute value of the tidal power is not larger than the value obtained by adding the value aW to the first threshold (step S405: No), the determination unit 113 determines whether the maximum charging current value is equal to the minimum chargeable current value. It is determined whether or not (step S410). If it is determined that the maximum charging current value is not equal to the minimum chargeable current value (step S410: No), the determination unit 113 determines whether or not the absolute value of the tidal power is smaller than the value obtained by subtracting the value bW from the first threshold value. Is determined (step S411). When determining that the absolute value of the tidal power is smaller than the value obtained by subtracting the value bW from the first threshold (step S411: Yes), the determination unit 113 decreases the maximum charging current value by one step. Then, determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S408). Then, the determination part 113 transfers a process to step S409.

  On the other hand, when it is determined that the tidal power is not smaller than the value obtained by subtracting the value bW from the first threshold (step S411: No), the determination unit 113 does not change the maximum charging current value (step S413). Then, determining unit 113 transmits the unchanged maximum charging current value to electric vehicle 110 (step S408). Then, the determination part 113 transfers a process to step S409.

  As a result, the charger 110b of the electric vehicle 110 can charge the storage battery 110a only when the reverse flow is occurring.

  On the other hand, when the charging plug 62 is not connected to the electric vehicle 110 (step S401: No), the determination unit 113 ends the reverse power charging mode (step S414). Moreover, when the instruction | indication of charge start permission is not received from the charger 110b of the electric vehicle 110 (step S402: No), the determination part 113 complete | finishes a reverse tide charge mode (step S413). When the value of the tidal power is greater than 0 (step S403: No), the determination unit 113 ends the reverse power charging mode (step S414). When it is determined that the value of the tidal power is not 0 or less after the start of charging (step S404) (step S409: No), the determination unit 113 ends the reverse power charging mode (step S414). When the maximum charging current value is equal to the minimum chargeable current value (step S410: Yes), the determination unit 113 ends the reverse power charging mode (step S414). In addition, also when the instruction | indication of completion | finish of charge is received from the charger 110b, the determination part 113 complete | finishes a reverse power charging mode (step S414). Thereby, the charging of the storage battery 110a is stopped.

  In the reverse power charging mode (third charging mode) described above, when a reverse power flow is occurring, the charging device 1 executes the first process (steps S405, S407, S411, S412, and S413). In other words, in the third charging mode, when the power distribution circuit 4 supplies the first power to the power system 2a via the link cable, the charging device 1 charges the battery 110a to the charger 110b of the electric vehicle 110. Allow. Charging device 1 does not allow electric vehicle 110 to charge storage battery 110a unless a reverse power flow occurs.

  In the third charging mode, the storage battery 110a of the electric vehicle 110 is charged only with the power from the distributed power source 2 without using the power from the power system 2a. Therefore, it can be expected to reduce the cost for charging the storage battery 110a of the electric vehicle 110.

1.4.4 Reverse tide / permission time charge mode (4th charge mode)
In the fourth charging mode, charging device 1 permits charging of electrically powered vehicle 110 when a reverse power flow occurs. Moreover, the charging device 1 permits charging of the storage battery 110a of the electric vehicle 110 during the charging permission time period.

  The fourth charging mode will be described in detail with reference to the flowcharts of FIGS. In the fourth charging mode, both the first process and the second process are executed. In the fourth charging mode, a value aW and a value bW are set for giving a desired hysteresis to the first threshold value in order to suppress hunting in the vicinity of the first threshold value. The second threshold value is set based on the power value (contract power value) corresponding to the contract ampere. Furthermore, the initial value of the maximum charging current value is set to the minimum chargeable current value.

  Determination unit 113 determines whether or not charging plug 62 is connected to electric vehicle 110 (step S501). When it is determined that the charging plug 62 is connected to the electric vehicle 110 (step S501: Yes), the determination unit 113 determines whether or not an instruction to permit charging start is received from the electric vehicle 110 (step S502). . When it is determined that an instruction to allow charging start is received from the electric vehicle 110 (step S502: Yes), the determination unit 113 determines whether or not the current time is within the charging permission time zone (step S503). When the current time is not within the range of the charge permission time zone (step S503: No), the determination unit 113 determines whether or not the flow current is a value equal to or less than 0 (step S504). When it is determined that the tidal current is a value equal to or less than 0 (step S504: Yes), the determination unit 113 closes the opening / closing unit 13 and enables the storage battery 110a of the electric vehicle 110 to be charged (step S505).

  Next, the determination unit 113 determines whether or not the absolute value of the tidal power is larger than a value obtained by adding the value aW to the first threshold value (step S506). When it is determined that the absolute value of the tidal current is larger than the value obtained by adding the value aW to the first threshold (step S506: Yes), the determination unit 113 determines whether or not the maximum charging current value is equal to the preset maximum value. Is determined (step S507). In other words, the determination unit 113 determines whether or not the maximum charging current value is equal to the maximum value of current that can be used to charge the storage battery 110a of the electric vehicle 110. When determining that the maximum charging current value is equal to the preset maximum value (step S507: Yes), the determination unit 113 shifts the processing to step S506. Therefore, the determination unit 113 maintains the maximum charging current value.

  On the other hand, when determining that the maximum charging current value is not equal to the preset maximum value (step S507: No), the determination unit 113 increases the maximum charging current value by one step (step S508). Then, determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S509). Next, the determination unit 113 determines whether or not the value of the tidal power is 0 or less (step S510). When the value of tidal power is 0 or less (step S510: Yes), the power supply and demand system 10 shifts the processing to step S506.

  On the other hand, when determining that the absolute value of the tidal power is not larger than the value obtained by adding the value aW to the first threshold (step S506: No), the determination unit 113 has the maximum charging current value equal to the minimum chargeable current value. It is determined whether or not (step S511). When determining that the maximum charging current value is not equal to the minimum chargeable current value (step S511: No), the determination unit 113 determines whether or not the absolute value of the tidal power is smaller than a value obtained by subtracting the value bW from the first threshold value. Is determined (step S512). If it is determined that the absolute value of the tidal power is smaller than the value obtained by subtracting the value bW from the first threshold (step S512: Yes), the determination unit 113 decreases the maximum charging current value by one step (step S513). Then, determination unit 113 transmits the changed maximum charging current value to the electric vehicle (step S509). Thereafter, the determination unit 113 proceeds to step S510.

  If it is determined that the absolute value of the tidal power is not smaller than the value obtained by subtracting the value bW from the first threshold (step S512: No), the determination unit 113 does not change the maximum charging current value (step S514). Then, determination unit 113 transmits an unchanged maximum charging current value to electric vehicle 110 (step S509). Thereafter, the determination unit 113 proceeds to step S510.

  As a result, the charger 110b of the electric vehicle 110 can charge the storage battery 110a in the case of reverse power flow.

  On the other hand, when the current time is within the range of the charging permission time zone (step S503: Yes), the determination unit 113 closes the opening / closing unit 13 and enables charging of the storage battery 110a of the electric vehicle 110 (step S515). . Next, the determination unit 113 determines whether or not the maximum charging current value is equal to a preset maximum value (step S516). When it is determined that the maximum charging current value is not equal to the preset maximum value (step S516: No), the determination unit 113 determines whether or not the tidal power is equal to or less than the second threshold (step S517). When it is determined that the tidal current power is equal to or lower than the second threshold (step S517: Yes), the determination unit 113 increases the maximum charging current value by one step (step S518). Then, determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S519).

  On the other hand, when it is determined that the tidal power is larger than the second threshold (step S517: No), the determination unit 113 determines whether or not the maximum charging current value is equal to the minimum chargeable current value (step S521). When determining that the maximum charging current value is not equal to the minimum chargeable current value (step S521: No), the determination unit 113 decreases the maximum charging current value by one step (step S522). Then, determination unit 113 transmits the changed maximum charging current value to electric vehicle 110 (step S519). Thereby, the charger 110b of the electric vehicle 110 can charge the storage battery 110a within a range not exceeding the maximum charging current value received from the charging device 1 during the charging permission time zone. Thereafter, the determination unit 113 determines whether or not the current time is within the charging permission time zone (step S520). When the current time is within the range of the charging permission time zone (step S520: Yes), the determination unit 113 shifts the processing to step S516. On the other hand, when the current time is not within the range of the charging permission time zone (step S520: No), the determination unit 113 ends the reverse tide / permission time charging mode (step S523).

  On the other hand, when the charging plug 62 is not connected to the electric vehicle 110 (step S501: No), the determination unit 113 ends the reverse tide / permitted time charging mode (step S523). In addition, when an instruction to permit charging start is not received from the charger 110b of the electric vehicle 110 (step S502: No), the determination unit 113 ends the reverse tide / permitted time charging mode (step S523). If it is determined that the tidal power is not less than or equal to 0 (step S504: No, step S510: No), the determination unit 113 ends the reverse tide / permitted time charging mode (step S523). If it is determined that the maximum charging current value is equal to the minimum chargeable current value (step S511: Yes, step S521: Yes), the determination unit 113 ends the reverse tide / permitted time charging mode (step S523). Thereby, the charging of the storage battery 110a is stopped.

  In the reverse power / permitted time charging mode (fourth charging mode), when a reverse power flow occurs, the charging device 1 executes the first process (steps S506, S508, S512, S513, and S514). In other words, in the fourth charging mode, when the power distribution circuit 4 supplies the first power to the power system 2a via the linkage cable, the charging device 1 charges the battery 110a to the charger 110b of the electric vehicle 110. Allow. In the fourth charging mode, the charging device 1 executes the second process in the charging permission time zone (steps S517, S518, and S522). In other words, in the fourth charging mode, regardless of whether or not the power distribution circuit 4 supplies the first power to the power system 2a via the link cable 120 during the charging permission time period, the charging device 1 The charger 110b of the electric vehicle 110 is allowed to charge the storage battery 110a during the time zone.

  Therefore, in the fourth charging mode, it is possible to efficiently charge the storage battery 110a of the electric vehicle 110 in a time zone with a low electricity bill.

2. Modification The above embodiment is only one of various embodiments of the present invention. Moreover, the said embodiment can be variously changed according to a design etc., if it can achieve with the objective of this invention. Below, the modification of the said embodiment is enumerated.

  In the modification, the electric vehicle 110 is not limited to an electric vehicle. The charging device 1 can be used for charging various electric vehicles.

  In the modification, the power conditioner 3 may be electrically connected to the charging device 1. Since the power conditioner 3 and the charging device 1 are electrically connected, the charging device 1 can acquire information input to the power conditioner 3.

  Moreover, in the modification, the power conditioner 3 and the detection part 5 may be electrically connected. Since the power conditioner 3 and the detection unit 5 are electrically connected, the power conditioner 3 can acquire the measurement result of the detection unit 5 and control the generated power based on the acquired measurement result. it can.

  Further, the distributed power source 2 is not limited to a power generation device such as a solar power generation device. The distributed power source 2 may be a storage battery. Moreover, the distributed power supply 2 may include a plurality of power supplies (for example, a solar power generation device, a fuel cell, and a storage battery).

  Moreover, the power conditioner 3 may be electrically connected with another storage battery. In this case, the power conditioner 3 may charge the storage battery with the generated power. Further, the charging device 1 may charge the storage battery 110 a of the electric vehicle 110 using the power of the storage battery electrically connected to the power conditioner 3.

  The communication method between charging device 1 and charger 110b of electric vehicle 110 is not limited to CPLT. The communication method may be, for example, wireless communication, LAN communication, CAN communication, serial communication, or PLC communication.

3. Aspect As is apparent from the above-described embodiments and modifications, the charging device (1) of the first aspect includes a control unit (11). The control unit (11) supplies the storage battery (110a) of the electric vehicle (110) with power from the power distribution circuit (4) that is fed from the distributed power source (2) and inputs / outputs power to / from the power system (2a). It is configured to determine a maximum charging current value for charging. The control unit (11) has at least one of a first process and a second process. The first process includes a process of increasing the maximum charging current value when the first power output from the power distribution circuit (4) to the power system (2a) is larger than the first threshold. The second process includes a process of reducing the maximum charging current value when the second power input from the power system (2a) to the power distribution circuit (4) is larger than the second threshold. According to the first aspect, the control unit (11) adjusts the maximum charging current value according to the first threshold value, thereby adjusting the first power from the power distribution circuit (4) to the power system (2a). . Moreover, the 2nd electric power from the electric power grid | system (2a) to a power distribution circuit (4) is adjusted because a control part (11) adjusts a maximum charging current value according to a 2nd threshold value. Therefore, the user sets power supply and demand between the power system (2a) and the power distribution circuit (4) according to preference by setting at least one of the first threshold and the second threshold to a desired value. it can. Therefore, it is possible to respond more to the user's request.

  The charging device (1) of the second aspect can be realized in combination with the first aspect. In the second aspect, the first process includes a process of maintaining or reducing the maximum charging current value when the first power is equal to or lower than the first threshold value. The second process includes a process of maintaining or increasing the maximum charging current value when the second power is equal to or lower than the second threshold value. According to the second aspect, since the control unit (11) further adjusts the maximum charging current value according to the conditions, the value of the first power and the value of the second power are adjusted according to the user's request. Thus, the charging device (1) of the 2nd aspect can respond more to a user's request.

  The charging device (1) of the third aspect can be realized by a combination with the first or second aspect. In a 3rd aspect, the user setting part (12) which receives the input from a user is further provided. The control unit (11) is configured to change at least one of the first threshold value and the second threshold value according to the input received by the user setting unit (12). According to the third aspect, the user can set at least one of the first threshold and the second threshold to a desired value.

  The charging device (1) of the fourth aspect can be realized by a combination with any one of the first to third aspects. In a 4th aspect, the receiving part (14) which receives the information from an external apparatus is further provided. The controller (11) is configured to change at least one of the first threshold and the second threshold according to the information received by the receiver (14). According to the fourth aspect, for example, at least one of the first threshold value and the second threshold value can be automatically received from an external device such as a power distribution circuit (distribution panel) (4) or a smart meter.

  The charging device (1) of the fifth aspect can be realized by a combination with any one of the first to fourth aspects. In the fifth aspect, the control unit (11) is configured to execute at least one of the first process and the second process in a predetermined charging permission time zone. According to the 5th aspect, since the storage battery (110a) of an electric vehicle (110) can be charged in the cheap time zone which a user desires, an electricity bill can be restrained cheaply.

  The charging device (1) of the sixth aspect can be realized by a combination with the fifth aspect. In the sixth aspect, the control unit (11) is configured to execute at least one of the first process and the second process in a time zone other than the charging permission time zone when the first power is 0 or more. . According to the 6th aspect, when the reverse power flow has generate | occur | produced, since the storage battery (110a) of an electric vehicle (110) is charged, an electricity bill can be restrained cheaply.

  The charging device (1) of the seventh aspect can be realized by a combination with any one of the first to sixth aspects. In the seventh aspect, the control unit (11) is configured to end the charging of the storage battery when the first power is equal to or lower than the first threshold value. According to the seventh aspect, since the storage battery (110a) of the electric vehicle (110) is charged only when there is a surplus in the power of the distributed power supply 2, there is no need to sell power from the power system 2a.

  The charging device (1) of the eighth aspect can be realized by a combination with the fifth or sixth aspect. In the eighth aspect, the control unit (11) is configured to end the charging of the storage battery when the second power is larger than the second threshold. According to the eighth aspect, since charging ends when the maximum amount of power purchase desired by the user or the second threshold set automatically is reached, excessive use of power can be suppressed. .

  The charging device (1) of the ninth aspect can be realized by a combination with any one of the first to eighth aspects. In the ninth aspect, the first threshold is selected from 0 or more. According to the 9th aspect, the user can charge the storage battery (110a) of an electric vehicle (110) also in the state currently selling to the electric power grid | system 2a.

  The power supply and demand system (10) of the tenth aspect is a distribution circuit that distributes power from the charging device (1) of any one of the first to ninth aspects, the distributed power source (2), and the distributed power source (2) A power conditioner (3) to be supplied to (4). According to the 10th aspect, since a charging device (1) adjusts a maximum charging current value, it can respond to a user's request more.

DESCRIPTION OF SYMBOLS 1 Charging apparatus 10 Electric power supply and demand system 11 Control part 110 Electric vehicle 110a Storage battery 12 User setting part 14 Receiving part 2 Distributed power supply 2a Electric power system 3 Power conditioner 4 Power distribution circuit

Claims (10)

A control unit for determining a maximum charging current value for charging a storage battery of an electric vehicle with electric power from a distribution circuit that is fed from a distributed power source and inputs / outputs electric power to / from an electric power system;
The control unit has at least one of a first process and a second process,
The first process includes a process of increasing the maximum charging current value when the first power output from the power distribution circuit to the power system is greater than a first threshold,
The second process includes a process of reducing the maximum charging current value when the second power input from the power system to the power distribution circuit is greater than a second threshold.
Charging device. The first process includes a process of maintaining or reducing the maximum charging current value when the first power is equal to or lower than the first threshold value.
The second process includes a process of maintaining or increasing the maximum charging current value when the second power is equal to or lower than the second threshold.
The charging device according to claim 1. A user setting unit for receiving input from the user;
The control unit is configured to change at least one of the first threshold value and the second threshold value according to the input received by the user setting unit.
The charging device according to claim 1 or 2. A receiving unit for receiving information from an external device;
The controller is configured to change at least one of the first threshold and the second threshold according to the information received by the receiver.
The charging device according to claim 1. The control unit is configured to allow charging of the storage battery in a predetermined charging permission time zone,
The charging device according to claim 1. The control unit is configured to permit charging of the storage battery even in a time zone other than the charging permission time zone if the first power is greater than 0.
The charging device according to claim 5. The control unit is configured to permit charging of the storage battery and execute the first process when the first power is larger than the first threshold.
The charging device according to claim 1. The control unit is configured to execute the second process in the charging permission time zone.
The charging device according to claim 5 or 6. The first threshold value is selected from a value of 0 or more.
The charging device according to claim 1. A charging device according to any one of claims 1 to 9,
The distributed power source;
A power conditioner for supplying power from the distributed power source to the power distribution circuit;
Comprising
Electricity supply and demand system.

Images