JP5874268B2 - Charging apparatus and charging method - Google Patents

Description

  The present invention relates to a charging device and a charging method.

  One rectifier that converts AC power from an AC power source into DC power, a plurality of chargers that use the rectifier as a DC power source to obtain DC power for charging a secondary battery, and the operation is designated among the plurality of chargers There is known a centralized charging apparatus including a control device that controls charging of the charger in a time-sharing manner (Patent Document 1).

JP-A-5-336673

  However, since the charging time is sequentially and evenly assigned to the plurality of batteries connected to the plurality of chargers, there is a problem that the charging time becomes long.

  The problem to be solved by the present invention is to provide a charging device and a charging method that shorten the charging time.

  The present invention sets the charging power of a charging target battery having a high priority to a power higher than the charging power of the charging target battery having a low priority, and supplies the set charging power to a plurality of batteries simultaneously. To solve the above problem.

  According to the present invention, a battery with a high priority is charged with a high charge power, and a battery with a low priority is also charged. Therefore, there is an effect that the charging time can be shortened.

1 is a block diagram of a charging system including a charging device according to an embodiment of the present invention. It is a graph which shows the time characteristic of the charging current set by the charging power setting part of FIG. It is a graph which shows the time characteristic of the charging current set by the charging power setting part of FIG. It is a flowchart which shows the control procedure of the charging device of FIG. It is a figure of the table which shows the corresponding | compatible relationship between a priority and a distribution ratio stored in the charging device which concerns on other embodiment of this invention. It is a graph which shows the time characteristic of the charging power of a battery in the charging device which concerns on other embodiment of this invention. It is a graph which shows the time characteristic of the charging power of a battery in the charging device which concerns on other embodiment of this invention. It is a flowchart which shows the control procedure in the charging device which concerns on other embodiment of this invention. It is a graph which shows the time characteristic of the charging power of a battery in the charging device which concerns on the modification of this invention. It is a flowchart which shows the control procedure in the charging device which concerns on other embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<< First Embodiment >>
FIG. 1 is a block diagram of a charging system including the charging device of this example. The charging device of this example is provided in a parking lot of a shopping mall, a parking lot of a facility that provides a car sharing service for an electric vehicle, a parking lot of a company that uses an electric vehicle as a company car, etc. And a control device for charging a battery provided in an electric vehicle or a hybrid vehicle to be charged.

  The charging device 100 is connected to the AC power source 200, distributes the power supplied from the AC power source 200 to the vehicles 300a to 300c connected to the charging connectors 2a to 2c, and includes a battery 301a included in the vehicles 300a to 300c. To 301c, respectively, to charge the batteries 301a to 301c. The battery 301 is configured by a secondary battery such as a lithium ion battery. Each of the vehicles 300a to 300c is provided with a battery controller (not shown) that manages the batteries 301a to 301c. The battery controller is configured to control the battery voltage, the charge / discharge current, or the state of charge of the battery (State of). Charge) is detected and the state of the battery is managed.

  Charging device 100 is connected to AC power source 200 and distributes the power supplied from AC power source 200 to batteries 301a to 301c of vehicles 300a to 300c connected to charging connectors 2a to 2c. The charging device 100 includes a charger 1, charging connectors 2 a to 2 c, a control unit 3, an ID control unit 4, and an operation panel 5. The charger 1 includes an AC / DC converter 11, a power supply wiring 12, and DC / DC converters 13a to 13c. The AC / DC converter 11 converts AC power supplied from the AC power source 200 into DC power and outputs the DC power to the power supply wiring 12. The power supply wiring 12 branches from the AC / DC converter 11 and is connected to the charging connectors 2a to 2c via the DC / DC converters 13a to 13c. The DC / DC converters 13a to 13c include switching elements such as transistors. Based on a control signal from the control unit, the DC / DC converters 13a to 13c boost the input DC power by switching the switching elements on and off. Thus, charging power suitable for charging each of the batteries 301a to 301 is output.

  For example, on and off of the switching elements included in the DC / DC converter 13a and the DC / DC converter 13b are respectively switched by the control signal of the control unit 3, and the switching elements included in the DC / DC converter 13c are maintained in the off state. In this case, the power output from the AC / DC converter 11 is distributed and input to the DC / DC converter 13a and the DC / DC converter 13b, but not input to the DC / DC converter 13c. The charging power output from the DC / DC converters 13a to 13c is set by controlling the on / off duty ratios of the switching elements included in the DC / DC converters 13a to 13c. Thus, the control unit 3 controls the switching elements of the DC / DC converters 13a to 13c to distribute the output power from the AC power source 200, which is one power source, and supply the output power to the batteries 301a to 301b. Charging power is set. The AC / DC converter 11 and the DC / DC converters 13a to 13c are part of a charging circuit included in the charger 1, and the charger 1 may include other circuit elements.

  The charging connectors 2 a to 2 c are terminal portions connected to the charging port of the vehicle, and are provided at the end portion of the power supply wiring 12. The DC / DC converters 13a to 13c are connected to the branched power supply wirings 12 corresponding to the charging connectors 2a to 2c. Each DC / DC converter 13a to 13c is provided with a communication circuit. When the vehicle 300 is connected to the charging connectors 2a to 2c, the communication circuit can transmit / receive information to / from a battery controller (not shown) of the vehicle 300. The communication circuit is also connected to the control unit 3, and information is transmitted and received between the control unit 3 and the vehicle 300. Note that the communication between the vehicle 300 and the control unit 3 may be performed by power line communication using the power supply wiring 12, a communication wiring may be incorporated in the power supply wiring 12, or performed by wireless communication. Also good.

  The control unit 3 includes a charger control unit 31, a charge amount detection unit 32, a charging power setting unit 33, and a priority setting unit 34.

  The charger control unit 31 distributes the output power from the AC power supply 200 and supplies the AC / DC converter 11 and the DC / DC converters 13a to 13c so that the charging power set by the charging power setting unit 33 is obtained. The charger 1 is controlled by generating a control signal to be controlled and transmitting the AC / DC converter 11 to the DC / DC converters 13a to 13c. The charge amount detection unit 32 detects the charge amounts of the batteries 301a to 301c based on the voltage, current, or SOC of the batteries 301a to 301c transmitted from the battery controllers of the vehicles 300a to 300c.

  The charging power setting unit 33 sets the charging power supplied to the battery 301 based on the charging amount of the battery 301 detected by the charging amount detection unit 32 and the priority set in the priority setting unit 34. That is, the charging power setting unit 33 sets charging power distributed from the output power of the AC power 200 to the batteries 301a to 301c. In addition, the charging power setting unit 33 charges the battery 301 by controlling the charging power according to the charging amount of the batteries 301a to 301c.

  The priority setting unit 34 sets the charging priority according to the vehicle 300. As described above, the charging device 100 of this example distributes the power supplied from one power source and charges each of the batteries 301a to 301c, so that the power is limited. Therefore, in this example, priority is set according to the vehicle 300 so that power is distributed with priority. And in the case of a vehicle with a high priority, compared with a vehicle with a low priority, high charge electric power is distributed to the battery 301 of a vehicle with a high priority.

  The ID authentication unit 4 is equipped with a system for authenticating the user of the vehicle 300. For example, when the charging apparatus 100 of this example is an apparatus that can be used only for a user who has been registered in advance, the ID authentication unit 4 can be obtained by bringing the registered user-owned IC card or the like closer to the ID authentication unit 4. Identifies the user by reading the information registered in the IC card by a magnetic action. The operation panel 5 is an input unit that receives a user operation, and includes, for example, a touch panel. The vehicle 300 can operate the charging device 100 of this example by operating the operation panel 5.

  Next, the control content of the charging apparatus 100 of this example is demonstrated using FIG. First, charge control by the charger control unit 31, the charge amount detection unit 32, and the charge power setting unit 33 will be described with reference to FIG. FIG. 2 is a graph showing the time characteristics of the charging current set by the charging power setting unit 33. The charger control unit 31 and the charging power setting unit 33 charge the batteries 301a to 301b by constant voltage charging control that controls the charging current with a constant voltage. For example, when the vehicle 300a is connected to the charging connector 2a, the vehicles 300b and 300c are not connected to the charging connectors 2b and 2c, and the charging amount charged in the battery 301a is low, the charging power setting unit 33 2, the charging current is set to the maximum current, and the maximum power of the charger 1 is set to the charging power of the battery 301b. The charge amount detection unit 32 detects the charge amount of the battery 301a based on the SOC transmitted from the battery controller of the vehicle 300a while the battery 301a is being charged.

  When the charge amount detection unit 32 detects that the battery 301a is approaching full charge, the charge power setting unit 33 gradually reduces the charge power by gradually reducing the charge current, and the charger control unit 31 charges. The DC / DC converter 13a is controlled so that the charging power set by the power setting unit 33 is obtained. When the charge amount detection unit 32 detects that the charge amount of the battery 301a has reached full charge, the charge power setting unit 33 sets the charge current to zero and ends the charge.

  Next, charging control in a state where the vehicle 300 is connected to the charging connectors 2a to 2c will be described. A case where vehicles 300a to 300c are simultaneously connected to charging connectors 2a to 2c will be described.

  First, before charging the battery 301, the control unit 3 detects the charge amount of the battery 301 by the charge amount detection unit 32, and the priority setting unit 34 decreases the charge amount in the battery 301. The priority of each vehicle 300 is set so that the priority is high. For example, when the charging amount of the battery 301a is the lowest among the batteries 301, the charging amount of the battery 301b is the second lowest, and the charging amount of the battery 301c is the highest, the priority of the vehicle 300a is the highest, and the vehicle 300b Is the second highest priority, and the priority of the vehicle 300c is the lowest.

  Then, the charging power setting unit 33 sets the maximum power of the charger 1 as the charging power for the battery 301a of the vehicle 300a having the highest priority. Here, the maximum power of the charger 1 is the power boosted to the highest level by charging the output power of the AC / DC converter 11 into the DC / DC converter 13a without branching and charging control by the DC / DC converter 13a. This corresponds to the power converted power without distributing the output power of the AC power supply 200. In this example, since the power source of charging power is only the AC power source 200, when the maximum power of the charger 1 is distributed to the charging power of the battery 301a, the charging power is not distributed to the other batteries 301b and 301c. . Then, the charging control unit 31 controls the switching element of the DC / DC converter 13a to supply the maximum power of the charger 1 to the battery 301a, while the switching elements of the DC / DC converters 13b and 13c are turned off. To do. Thereby, in this example, the battery 301 with a low charge amount is preferentially charged.

  When the charge amount detection unit 32 detects that the charge amount of the battery 301a is approaching full charge, the charge power setting unit 33 reduces the charge power of the battery 301a under constant voltage charge control. When the charging power of the battery 31 a becomes lower than the maximum power of the charger 1, the remaining power is generated in the power of the charger 1. Therefore, the charging power setting unit 33 sets the remaining power as the charging power of the battery 301b having the second highest priority. That is, in this example, the charging power setting unit 33 sets the battery 301b of the vehicle 300b having the second highest priority before charging the battery 301a having the highest priority. Charging power can be supplied to the battery 301a and the battery 301b simultaneously. Note that the charging power corresponding to the remaining power distributed to the battery 301b corresponds to the power obtained by subtracting the charging power set for the battery 301a from the maximum power of the charger 1. In other words, the charging power setting unit 33 sets the charging power to distribute the maximum power of the charger 1 when distributing and setting the charging power to the plurality of batteries 301, and the charging distributed to each battery 301. The charging power is set so that the total power corresponds to the maximum power of the charger 1.

  Further, when the amount of charge of the battery 301a approaches full charge, the charging power setting unit 33 further reduces the charging power of the battery 301a, and increases the charging power of the battery 301b by the amount of power reduction. When the amount of charge of the battery 301a reaches full charge, the charge power setting unit 33 sets the charge power of the battery 301a to zero and sets the charge power of the battery 301b to the maximum power of the charger 1.

  Similarly, for the charging of the battery 301b and the battery 301c, when the charging amount detection unit 32 detects that the charging amount of the battery 301b is approaching full charging, the charging power setting unit 33 performs the constant voltage charging control, The charging power of the battery 301b is decreased from the maximum power of the charger 1, and the charging power of the battery 301c is increased by the amount corresponding to the decreased power. When the amount of charge of the battery 301b reaches full charge, the charging power setting unit 33 sets the charging power of the battery 301b to zero and sets the charging power of the battery 301c to the maximum power of the charger 1. When the charge amount detection unit 32 detects that the charge amount of the battery 301c has reached full charge, the charger control unit 31 ends the charge control of the battery 301.

  Here, under the constant voltage charging control shown in FIG. 2, unlike the present example, when time-division charging is performed to supply the maximum power of the charger 1 to each of the batteries 301 a to 301 c at regular intervals (comparative example). The charging time of the batteries 301a to 301c and the charging time of the batteries 301a to 301c by the charging control of this example will be described with reference to FIG. FIG. 3 shows the time characteristics of the charging current, graph a shows the characteristics of the charging current flowing through the battery 301a of this example, graph b shows the characteristics of the charging current flowing through the battery 301a of this example, and graph c shows this example. The graph d shows the characteristics of the charging current flowing in the batteries 301a to 301c in the comparative example. In addition, the charge amount of the batteries 301a to 301c at the start of charging is lower than the full charge, and is the same charge amount.

  As shown in FIG. 3, in the comparative example, charging is started, and until the time t2, the maximum power of the charger 1 is set to one battery at a certain time in the order of 301b and 301c starting from the battery 301a. Repeat the time-division power supply to supply power, and at time t2, when all the charge amounts of the batteries 301a to 301c reach the charge amount that gradually decreases the charge power, each of the batteries 301a to 301c The charging power becomes lower than the maximum power. Then, the charging power of each of the batteries 301a to 301c is reduced stepwise, and at time t5, the batteries 301a to 301c reach full charge and the charging is finished.

  On the other hand, in this example, since charging is started and the charging amount of the battery 301a reaches a charging amount that gradually decreases the charging power at time t1, the charging power of the battery 301a is reduced from the maximum power to reduce the power. The reduced power is distributed to the charging power of the battery 301b. After time t1, the charging power of the battery 301b is increased stepwise while the charging power of the battery 301a is decreased stepwise. When the battery 301a reaches full charge, the charging power of the battery 301b is maximized. At time t2, since the charge amount of the battery 301b reaches a charge amount that gradually decreases the charge power, the charge power of the battery 301b is lowered from the maximum power, and the reduced power is used as the charge power of the battery 301c. To distribute. After time t2, the charging power of the battery 301c is increased stepwise while the charging power of the battery 301b is decreased stepwise. When the battery 301b reaches full charge, the charging power of the battery 301c is maximized. At time t3, the charge amount of the battery 301c reaches a charge amount that gradually decreases the charge power, so the charge power of the battery 301c is reduced from the maximum power. Thereafter, the charging power of the battery 301c is decreased stepwise, and when the battery 301c reaches full charge at time t4, the charging in this example is terminated.

  Comparing the graphs a to c of this example and the graph d of the comparative example, in this example, the batteries 301a to 301c are charged using the maximum power of the charger 1 until the time t3. On the other hand, in the comparative example, the charging of the batteries 301a to 301c with the maximum power of the charger 1 is finished at the time t2, which is a time earlier than the time t3, and the power lower than the maximum power of the charger 1 after the time t2. Thus, the batteries 301a to 301c are charged. Therefore, in the comparative example, since the charging time using the maximum power of the charger 1 is short, the time until the charging of all the batteries 301a to 301c is completed (corresponding to the time t5 in FIG. 3) is It becomes longer than the charging end time in the example (corresponding to the time t4 in FIG. 3). That is, in this example, the maximum power of the charger 1 is appropriately distributed and power is simultaneously supplied to the plurality of batteries 301a to 301c. Therefore, the batteries 301a to 301c are charged faster than the comparative example. Can be completed.

  Next, the charging control of this example when one vehicle among the vehicles 300 is connected and another vehicle is connected while the battery 301 is being charged will be described. Hereinafter, it is assumed that the vehicles 300b and 301c are connected to the charging connectors 2b and 2c while the vehicle 300a is connected to the charging connector 2a and the battery 301a is being charged.

  When the vehicle 300b is connected to the charging connector 2b while the battery 301a of the vehicle 300a is being charged, the charger control unit 31 stops charging the battery 301a, and the charge amount detection unit 32 charges the battery 301a when stopped. The amount and the amount of charge of the battery 301b are detected. The priority setting unit 34 compares the charge amount of the battery 301a with the charge amount of the battery 301b, and sets a high priority for a vehicle with a battery with a low charge amount. For example, when the charge amount of the battery 301b is higher than the charge amount of the battery 301a when the vehicle 300b is connected, the priority setting unit 34 sets the priority of the vehicle 300b higher than the priority of the vehicle 300a.

  Then, the charging power setting unit 33 sets the maximum power of the charger 1 as the charging power for the battery 301 of the vehicle with the higher priority. In addition, the charging power setting unit 33 responds to the charging amount of the battery 301 when the battery 301 of the vehicle with the higher priority is already fully charged and is charged with power lower than the maximum power of the charger 1. Set the charging power. At this time, since the charger 1 has a surplus power, the charge power setting unit 33 sets the surplus power for the battery of the vehicle with the lower priority as the charge power.

  Furthermore, when the vehicles 300a and 300b are connected to the charging connectors 2a and 2b, and the vehicle 300c is connected to the charging connector 2c while charging at least one of the batteries 301a and 301b, the charger control unit 31 The charging of the battery 301a is stopped, and the charge detection unit 32 detects the charge of the battery 301a and the battery 301b and the charge of the battery 301c at the time of the stop. The priority setting unit 34 compares the amount of charge of each of the batteries 301a to 301c, and sets so that the priority of the vehicle with a battery with a lower charge amount becomes higher.

  Then, the charging power setting unit 33 sets the maximum power of the charger 1 as charging power for the battery 301 of the vehicle having the highest priority. Further, the charging power setting unit 33 is such that the battery 301 of the vehicle with the highest priority is already near full charge, and the battery of the vehicle with the second highest priority is already close to full charge. When charging with power lower than the maximum power of the charger 1, charging power corresponding to the amount of charge of the battery 301 is set. At this time, since the charger 1 has a surplus power, the charge power setting unit 33 sets the surplus power for the battery 301 of the vehicle having the third lowest priority as the charge power. As a result, even when the vehicle 300 is connected to one of the charging connectors 2a to 2c and the vehicle 300 is connected to another connector during charging, this example corresponds to the amount of charge of the battery 301. Thus, the priority is set and the maximum power of the charger 1 is appropriately distributed, and the power is simultaneously supplied to the plurality of batteries 301a to 301c.

  Next, the control procedure of the charging apparatus 100 of this example is demonstrated using FIG. FIG. 4 is a flowchart showing a control procedure of the charging apparatus 100 of this example. In step S1, control unit 3 newly connects vehicle 300 to charging connectors 2a to 2c and starts charging based on the connection state of charging connectors 2a to 2c or the operation information of operation panel 5 by the user. Whether there is a vehicle to be detected is detected. And when there exists a charge start vehicle, it changes to step S2. The control in step S1 is a control process that substantially functions when another vehicle is being charged and a new vehicle is connected to the connector.

  In step S2, the charge amount detection unit 32 detects the charge amount of the battery of the newly connected vehicle. In step S3, the control unit 3 determines whether there is a vehicle that is being charged. If there is no vehicle being charged, only the newly connected vehicle is connected to any one of the charging connectors 2a to 2c, and the charging power setting unit 33 newly connects in step S31. The charging power of the battery 301 of the vehicle 300 thus set is set to the maximum power of the charger 1, and the charger control unit 31 charges the battery 301 with the set charging power, and the process proceeds to step S10. In step S31, when the charge amount of the battery 301 of the newly connected vehicle 300 has reached a charge amount that gradually decreases the charge power from the maximum power, the charge power setting is made in step S31. The unit 33 sets charging power corresponding to the amount of charge.

  Returning to step S3, when there is a vehicle being charged, the charger control unit 31 temporarily stops the charging control of the battery 301, and the charge amount detection unit 32 detects the charge amount of the battery 301 being stopped. (Step S4). In step S5, the priority setting unit 34 sets the priority of each vehicle 300 such that the priority becomes higher as the charge amount of the battery 301 of the vehicle 300 connected to the charging connectors 2a to 2c is lower. To do. In step S <b> 6, the charging power setting unit 33 supplies the maximum power of the charger 1 to the battery 301 of the vehicle 300 having the highest priority among the priorities set in the priority setting unit 34. Set as.

  In step S <b> 7, charging power setting unit 33 sets charging power based on the amount of charge of battery 301. That is, when the charge amount of the battery 301 of the vehicle 300 has not reached the charge amount that gradually decreases the charge power from the maximum power, the maximum power set by the charge power setting unit 33 in step S6 is not changed. . On the other hand, when the charge amount of the battery 301 of the vehicle 300 has reached a charge amount that gradually decreases the charge power from the maximum power, the charge power setting unit 33 sets the charge power lower than the maximum power according to the charge amount. To reset. In step S <b> 8, the control unit 3 compares the maximum power of the charger 31 with the charging power set by the charging power setting unit 33 and determines whether or not the output power of the charger 1 has a margin. To do.

  When the charging power set by the charging power setting unit 33 is lower than the maximum power of the charger 1, it is determined that the output power of the charger 1 has a surplus power, and in step S9, the charging power setting unit 33 The charging power corresponding to the surplus power is distributed to the battery 301 of the vehicle 300 having the next highest priority. Note that the vehicle 300 with the next highest priority is the vehicle 300 with the second highest priority after the vehicle 300 for which the maximum power is set in step S6. On the other hand, when the charging power set by the charging power setting unit 33 is the maximum power of the charger 1, it is determined that the output power of the charger 1 has no remaining power, and the process proceeds to step S10. In step S <b> 10, the charger control unit 31 charges the battery 301 with the charging power set and distributed by the charging power setting unit 33.

  In step S11, the charge amount detection unit 32 detects the charge amount of the battery 301 being charged in a predetermined cycle, detects whether or not the battery 301 being charged has reached full charge, and the control unit 3 detects whether or not charging is forcibly ended by a user operation or the like, and the control unit 3 determines whether or not there is a vehicle that has ended charging. If there is a vehicle that has finished charging, in step S12, the control unit 3 waits for charging, which is connected to the other vehicle 300 being charged or the charging connectors 2a to 2c but is not charging. It is determined whether there is a vehicle 300 inside. Then, when there is a vehicle 300 being charged or a vehicle 300 waiting for charging, the control unit 3 temporarily stops charging (step S13). At the time of step S13, charging of the battery that has been fully charged in step S10 has been completed, and the control process after step S14 is a control process related to the vehicle 300 being charged or the vehicle 300 being charged. .

  In step S14, the charge amount detection unit 32 detects the charge amount of the battery 301 of the vehicle 300 that has stopped charging, and proceeds to step S5. Since the charging amount of the vehicle 300 waiting for charging has already been detected in the control process of step S2, the charging amount detection unit 32 of the battery 301 of the vehicle 300 waiting for charging is determined in the control process of step S13. The amount of charge need not be detected. And in step S5 which is control after the control process of step S14, the priority of the vehicle 300 in charge standby and the vehicle 300 which stopped charging is set again, and the control process after step S6 is the same as the above. To be done.

  Returning to step S12, if there is no vehicle being charged or no vehicle waiting to be charged, in step S15, the control unit 3 ends the charging by the charger 1 and ends the control of this example.

  Returning to step S11, if there is no vehicle that has finished charging, the process returns to step S1, and the control processing subsequent to step S1 is performed in the same manner as described above. Returning to step S1, if there is no charge start vehicle, the battery 301 is continuously charged by moving to step S7.

  As described above, in this example, power from the AC power supply 200 is distributed to the plurality of batteries 301, and charging priority is set for the charger 1 that charges the plurality of batteries 301 and the vehicle 300. The priority setting unit 34, the charging power setting unit 33 that sets the charging power of the battery 301 of the vehicle 300 with high priority to a power higher than the charging power of the battery 301 of the vehicle 300 with low priority, and the charger 1 And a charger control unit 31 that controls and supplies the set charging power to a plurality of batteries 301 at the same time. Thereby, in this example, since high charge electric power is distributed with respect to the vehicle 300 with high priority, charge time can be shortened. Further, in this example, power is supplied to a plurality of batteries 301 at the same time according to the priority, and the batteries 301 are charged, so that the power that can be output from the charger 1 is not wasted and the charging time is reduced. It can be shortened.

  Further, in a conventional system that controls power in a time-sharing manner as in the prior art, charging is interrupted and resumed in a short time in the middle of charging, so that there are many voltage fluctuations and the battery 301 may be deteriorated. On the other hand, in this example, since the number of times of interruption and resumption of charging is reduced compared to the conventional case, voltage fluctuation can be suppressed and deterioration of the battery 301 can be suppressed.

  In this example, the charging power setting unit 33 sets the maximum power of the charger 1 as the charging power for the battery 301 of the vehicle 300 having the highest priority among the plurality of vehicles 300. Thereby, for example, when the battery 301 is already charged, even if the vehicle 300 is connected to the charging connectors 2a to 2c later, if the priority of the already charged vehicle is high, the battery 301 is already charged. Since the charging of the battery 301 that has been performed is not postponed, it is possible to prevent delaying the charging time of a vehicle having a high priority.

  Moreover, in this example, when the charging power setting unit 33 sets charging power lower than the maximum power of the charger 1 for the battery 301 of one vehicle 300 among the plurality of vehicles 300, the other vehicles Charging power is set for 300 batteries 301. Thereby, in this example, when the charge amount of the battery 301 having a high priority is increased and the charge power of the battery 301 is reduced, the surplus power of the charger 1 is assigned as the charge power of the other battery 301. In addition, the utilization efficiency of the power that can be output from the charger 1 can be increased, and the charging of the other battery 301 can be promoted. As a result, the charging time can be shortened.

  In this example, the priority setting unit 34 sets the highest priority for the vehicle 300 including the battery 301 having the lowest charge amount among the charge amounts of the battery 301 detected by the charge amount detection unit 32. To do. As a result, charging power is preferentially distributed to the battery 301 of the vehicle 300 having a low charge amount, so that it is possible to prevent the charging time from being increased only for a specific vehicle.

  In this example, the priority setting unit 34 may set the priority of the vehicle 300 according to the charging time of the battery 301. Moreover, the charging apparatus 100 of this example is not a vehicle, and it is good also considering the apparatus containing a battery etc. as charging object.

  The priority setting unit 34 corresponds to the “priority setting unit” of the present invention, the charging power setting unit 33 corresponds to the “charging power setting unit” of the present invention, and the charger control unit 31 corresponds to the “charger of the present invention. The charge amount detection unit 32 corresponds to the “control means” and the “charge amount detection means” of the present invention.

<< Second Embodiment >>
FIG. 5 is a table showing the relationship between the priority of the vehicle and the power distribution ratio included in the control unit of the charging apparatus according to another embodiment of the invention. In this example, priority setting control and power distribution control are different from those of the first embodiment described above. Since the configuration other than this is the same as that of the first embodiment described above, the description thereof is incorporated as appropriate.

  In the charging apparatus 100 of this example, the priority is determined in advance according to the vehicle 300. Information on the priority determined in advance is stored in, for example, an ID authentication card for using the charging system of the present example, and the user holds the ID authentication card over the ID authentication unit 4 so that the ID authentication unit 4 acquires priority information together with user ID information. Alternatively, a personal identification number when using the charging system of this example is assigned to each user, and a priority is also assigned corresponding to the personal identification number. And when a user inputs a personal identification number with the operation panel 5, the control part 3 acquires the priority information of the said user's vehicle 300, determining the utilization permission of the charging device 100 of this example.

  A case where the priority is determined in advance according to the vehicle 300 will be described. For example, when the charging device 100 of this example is provided in a city hall as an example of a public facility, it is divided into three stages so that the priorities become lower in the order of I, II, III, and the highest priority. Emergency vehicles such as ambulances and fire trucks are assigned to I vehicles, vehicles owned by the city hall are assigned to the second highest priority II vehicles, and vehicles with the lowest priority III are generally used. A vehicle is assigned. When the emergency vehicle is connected to the charging connector 2a, the priority setting unit 34 is acquired by the priority information acquired by the ID authentication unit 4 or the operation of the operation panel 5 of the user of the emergency vehicle. The priority of the vehicle connected to the charging connector 2a is set to the highest priority I based on the priority information.

  Next, a case where priority is determined in advance according to the user will be described. For example, the charging device 100 of this example is provided in a facility such as a service area on an expressway, and a charging system is adopted as the charging system of this example. In order to use the charging system of this example, the user needs to pay a system usage fee such as a set annual fee, and the user is divided into four stages according to the annual fee to be paid. The priority is set to be lower in the order of I, II, III, and IV. For example, the user who paid the highest annual fee is equivalent to priority I, the user who paid the second highest annual fee is equivalent to priority II, and the user who paid the third highest annual fee is priority III The user who paid the lowest annual fee is equivalent to priority IV. For example, the user owns the ID authentication card classified according to the paid annual membership fee. When the user has an ID authentication card corresponding to the priority II, the user connects the vehicle 300 to the charging connector 2b and holds the ID authentication card over the ID authentication unit 4 to thereby set the priority setting unit. 34 sets the priority of the vehicle 300 connected to the charging connector 2a to the second highest priority II. Thus, the priority is determined in advance according to the user or the vehicle 300.

Moreover, in this example, the ratio of the electric power distributed to the battery 301 is preset according to the connection state of the charging connectors 2a to 2c and the priority of the connected vehicle 300. The table shown below is stored. For the vehicle priorities “1 to 3” shown in FIG. 5, the highest priority is the level “1”, the second highest priority is the level “2”, and the third highest priority is the level “3”. It is said. In addition, for the A car, B car, and C car in FIG. 5, the vehicles 300a to 300c connected to the charging connectors 2a to 2c are arranged in order of priority, and are represented as A car, B car, and C car in descending order of priority. ing. For example, when a priority II vehicle 300a, a priority I vehicle 300b, and a priority III vehicle 300c are connected to the charging connectors 2a to 2c, respectively, the priority I is level “
1 ”, priority III becomes level“ 2 ”, vehicle 300b with priority I becomes vehicle A, vehicle 300a with priority II becomes vehicle B, and vehicle 300c with priority II becomes vehicle C. This corresponds to category c of 5.

  As shown in FIG. 5, the ratio of the distributed power is set to be higher as the priority is higher. Moreover, when the vehicle 300 with the same priority is connected to the plurality of charging connectors 2a to 2c, the power distribution ratio is equally allocated. Further, among the vehicles connected to the charging connectors 2a to 2c, when the priority of the plurality of vehicles 300 is the same and higher than the priority of the other vehicles 300, the batteries 301 of the plurality of vehicles 300 are used. The distribution ratio to is the same and is higher than the distribution ratio to the battery 301 of the other vehicle 300. Further, among the vehicles connected to the charging connectors 2a to 2c, when the priority of the plurality of vehicles 300 is the same and is lower than the priority of the other vehicles 300, the batteries 301 of the plurality of vehicles 300 are used. The distribution ratio to is the same and lower than the distribution ratio to the battery 301 of the other vehicle 300.

  When the priority setting unit 34 sets the priority according to the vehicle 300, the charging power setting unit 33 refers to the stored table shown in FIG. 5 and distributes corresponding to the priority of the connected vehicle 300. Extract percentage. And charging power setting part 33 sets each charging power of batteries 301a-301c of vehicles 300a-300c so that the maximum power of charger 1 may be distributed according to the extracted distribution ratio.

  Next, with reference to FIGS. 1 and 5 to 7, two specific examples will be described, and the control content of the charging apparatus 100 of this example will be described. 6 and 7 are graphs showing time characteristics of charging power of the batteries 301a to 301c. 6 and 7, a is the charging power characteristic of the battery 301 a, b is the charging power characteristic of the battery 301 b, c is the charging power characteristic of the battery 301 c, and d is the output power of the charger 1. The characteristics are shown. Further, the percentage corresponds to the distribution ratio in FIG. 5, and 100% corresponds to the maximum power of the charger 1.

  As a first example, the vehicles 300a to 300c have the same priority I, and when the vehicles 300a to 300c are connected to the charging connectors 2a to 2c, the charging amount of the battery 301a is the highest, and the charging amount of the battery 301b. Is the second highest and the charge amount of the battery 301c is the lowest. Further, it is assumed that charging of the batteries 301a to 301c is started at the same time.

  In the first example, when the vehicles 300a to 300c are connected to the charging connectors 2a to 2c, the priorities of the vehicles 300a to 300c correspond to the category a in FIG. Therefore, as illustrated in FIG. 6, the control unit 3 sets the charging power corresponding to 33% to the batteries 301 a to 301 c by the charging power setting unit 33, respectively, and charges the batteries 301 a to 301 c. At time t1, since the battery 301a is almost fully charged, the charging power of the battery 301a is decreased and the charging power of the batteries 301b and 301c is increased. At time t2, the charging power to the battery 301a is set to zero, and the charging of the battery 301a is terminated. At time t2, the priorities of the vehicles 300b and 300c to be charged correspond to the category e in FIG. The control unit 3 sets the charging power corresponding to 50% to the batteries 301b and 301c by the charging power setting unit 33, and charges the batteries 301b and 301c. At time t3, since the battery 301a is nearly fully charged, the charging power of the battery 301b is reduced and the charging power of the battery 301c is increased. At time t4, the battery 301b reaches full charge, the charging power to the battery 301b is reduced to zero, and the charging of the battery 301b is terminated. At the time t4, the priority of the vehicle 300c to be charged corresponds to the category d in FIG. The control unit 3 sets the charging power corresponding to 100% to the battery 301 c by the charging power setting unit 33 and charges the battery 301 c with the maximum power of the charger 1. At time t5, the battery 301b reaches full charge, the charging power to the battery 301b is reduced to zero, and charging of the battery 301b is terminated.

  As a second example, vehicle 300a has priority I, vehicles 300b and 300c have the same priority II, and the amount of charge of battery 301a when vehicles 300a-300c are connected to charging connectors 2a-2c. Is the highest, the charge amount of the battery 301b is the second highest, and the charge amount of the battery 301c is the lowest. Further, it is assumed that charging of the batteries 301a to 301c is started at the same time.

  In the second example, when the vehicles 300a to 300c are connected to the charging connectors 2a to 2c, the priorities of the vehicles 300a to 300c correspond to the category c in FIG. Therefore, as shown in FIG. 7, the control unit 3 sets the charging power corresponding to 70% for the battery 301a and the charging power corresponding to 15% for each of the battery 301b and the battery 301c by the charging power setting unit 33. Then, the batteries 301a to 301c are charged. At time t1, since the battery 301a is almost fully charged, the charging power of the battery 301a is decreased and the charging power of the batteries 301b and 301c is increased. At time t2, the charging power to the battery 301a is set to zero, and the charging of the battery 301a is terminated. At time t2, the priorities of the vehicles 300b and 300c to be charged correspond to the category e in FIG. The control unit 3 sets the charging power corresponding to 50% to the batteries 301b and 301c by the charging power setting unit 33, and charges the batteries 301b and 301c. At time t3, since the battery 301a is nearly fully charged, the charging power of the battery 301b is reduced and the charging power of the battery 301c is increased. At time t4, the battery 301b reaches full charge, the charging power to the battery 301b is reduced to zero, and the charging of the battery 301b is terminated. At the time t4, the priority of the vehicle 300c to be charged corresponds to the category d in FIG. The control unit 3 sets the charging power corresponding to 100% to the battery 301 c by the charging power setting unit 33 and charges the battery 301 c with the maximum power of the charger 1. At time t5, the battery 301b reaches full charge, the charging power to the battery 301b is reduced to zero, and charging of the battery 301b is terminated.

  Next, the control procedure of the charging apparatus 100 of this example will be described with reference to FIG. FIG. 8 is a flowchart showing a control procedure of the charging apparatus 100 of this example. In step S101, control unit 3 detects whether or not vehicle 300 is newly connected to charging connectors 2a to 2c and charging starts based on the connection state of charging connectors 2a to 2c and the like. . And when there exists a charge start vehicle, it changes to step S102. In step S102, the control unit 3 detects the charge amount of the battery 301 of the newly connected vehicle 300 by the charge amount detection unit 32, and the information authenticated by the ID authentication unit 4 or the operation panel of the user The priority information is acquired from the information based on the operation 5.

  In step S103, control unit 3 determines whether there is a vehicle that is being charged. If no vehicle is being charged, in step S1031, the charging power setting unit 33 sets the charging power of the battery 301 of the newly connected vehicle 300 to the maximum power of the charger 1, and the process proceeds to step S107. The

  On the other hand, if there is a vehicle that is being charged in step S103, the charger control unit 31 temporarily stops the charge control of the battery 301, and the charge amount detection unit 32 determines the charge amount of the battery 301 that is being charged. It detects (step S104). In step S105, the priority setting unit 34 sets the priority of the vehicle 300 from the acquired priority information. In step S <b> 106, charging power setting unit 33 refers to the set priority and the table shown in FIG. 5, extracts a power distribution ratio, and distributes the distribution to each battery 301 a to 301 c of vehicle 300. Charging power corresponding to the ratio is set for each.

  In step S <b> 107, the charger control unit 31 charges the battery 301 based on the charge amount of the battery 301. If charging is possible with the charging power set in S107 from the charging amount of the battery 301 of the vehicle 300, the battery 301 is charged with the charging power set by the charging power setting unit 33 in step S107. On the other hand, when charging cannot be performed with the charging power set in S107 from the charging amount of the battery 301 of the vehicle 300 and charging is performed with power lower than the charging power, the charging power setting unit 33 sets in step S107. The battery 301 is charged with lower power than the charged power. At this time, the reduced power may be distributed to other batteries 301 based on the charge amount.

  In step S108, the charge amount detection unit 32 detects the charge amount of the battery 301 being charged at a predetermined cycle, detects whether or not the battery 301 being charged has reached full charge, and the control unit 3 detects whether or not charging is forcibly ended by a user operation or the like, and the control unit 3 determines whether or not there is a vehicle that has ended charging. If there is a charging-completed vehicle, in step S109, the control unit 3 determines whether there is another vehicle 300 that is being charged or a vehicle 300 that is waiting to be charged. Then, when there is a vehicle 300 being charged or a vehicle 300 waiting for charging, the control unit 3 temporarily stops charging (step S110). In step S111, the charge amount detection unit 32 detects the charge amount of the battery 301 of the vehicle 300 that has stopped charging, and proceeds to step S105.

  Returning to step S109, if there is no vehicle that is being charged or waiting for charging, in step S112, the control unit 3 ends the charging by the charger 1, and ends the control of this example.

  Returning to step S108, if there is no vehicle that has finished charging, the process returns to step S101, and the control processing after step S101 is performed in the same manner as described above. Returning to step S101, when there is no charge start vehicle, the battery 301 is continuously charged by moving to step S107.

  As described above, in this example, the priority setting unit 34 sets the priority based on the user's operation on the operation panel 5. Thereby, according to the rank previously set to the user or the vehicle 300, a priority can be set and electric power can be distributed.

  In this example, the priority setting unit 34 sets the priority based on the information authenticated by the ID authentication unit 4. Thereby, according to the rank previously set to the user or the vehicle 300, a priority can be set and electric power can be distributed.

  In this example, in order to increase the utilization efficiency of the maximum power of the charger 1, the charging power of the battery 301 of any one of the plurality of vehicles 300 is made lower than the charging power based on the distribution ratio. Although the charging power of the battery 301 of the other vehicle 300 is increased, the charging power of the battery 301 of the other vehicle 300 may not be increased. For example, in the charging apparatus 100, a long-time charging mode in which the battery 301 is continuously charged with low power with respect to the maximum power of the charger 1 is set, and the user operates the operation panel 5 to set the long-time charging mode. When set, the battery 301 is charged with a constant charging power regardless of the priority of the vehicle 300.

  The long-time charging mode will be described with reference to FIG. FIG. 9 is a graph showing the time characteristics of the charging power in the charging device 100 equipped with the long-time charging mode. Assuming that the vehicles 300a to 300c have the same priority I, and when the vehicles 300a to 300c are connected to the charging connectors 2a to 2c, the charge amount of the battery 301a and the charge amount of the battery 301b are the same charge amount, It is assumed that the amount of charge of the battery 301c is higher. When the long-time charging mode is set, the charging power setting unit 33 fixes the distribution ratio of the charging power of the battery 301 to 10% when charging the battery 301 that is the target of the long-time mode. . Further, it is assumed that the user of the vehicle 300c selects the long-time charging mode.

  In this case, when the vehicles 300a to 300c are connected to the charging connectors 2a to 2c, the priorities of the vehicles 300a to 300c correspond to the category a in FIG. However, since the long-time charging mode is set for the vehicle 300c, the charging power setting unit 33 sets 10% charging power for the battery 301c. The remaining 90% of the charging power is distributed to the batteries 301a and 301b. Then, charging is started, and at time t1, since the batteries 301a and 301b are almost fully charged, the charging power of the batteries 301a and 301b is reduced. On the other hand, the charging power to the battery 301c is maintained. At time t2, the charging power to the batteries 301a and 301b is set to zero, and the charging of the batteries 301a and 301b is finished. Then, the charging power corresponding to 10% is continuously supplied to the battery 301c, and at time t3, the battery 301c reaches full charge, and the charging control of this example is finished.

  The power distribution ratio with respect to the priority shown in FIG. 5 is merely an example, and is not limited to the categories a to j. The number of categories may be increased, and the pattern of the distribution ratio may be increased. Further, when the number of charging connectors 2a to 2c is four or more, the power distribution ratio pattern with respect to the priority shown in FIG. 5 may be increased.

  Note that the power source of the charging apparatus 100 is not necessarily an AC power source, and may be a DC power source.

  The ID authentication unit 4 corresponds to “user authentication means” of the present invention.

<< Third Embodiment >>
FIG. 10 is a flowchart showing a control procedure of the charging apparatus according to another embodiment of the invention. In this example, priority setting control is different from that of the first embodiment described above. Since the configuration other than this is the same as that of the first embodiment described above, the description of the first embodiment or the second embodiment is incorporated as appropriate.

  The priority setting unit 34 sets the highest priority for the vehicle 300 connected to the charging connectors 2a to 2c earliest among the vehicles 300 connected to the charging connectors 2a to 2c, and the charging connectors 2a to 2c. Set the priority in the order of connection.

  Next, the control procedure of the charging apparatus 100 of this example will be described with reference to FIG. The control contents of steps S1, S3, S4, S6-15, and S31 in FIG. 10 are the same as the control contents of steps S1, S3, S4, S6-15, and S31 shown in FIG. Description is omitted.

  If there is a charging start vehicle in step S1, in step 202, the control unit 3 records the connection order of the vehicles newly connected to the charging connectors 2a to 2c. For example, when the vehicle 300b is connected to the charging connector 2c while the vehicle 300a is already connected to the charging connector 2a, the control unit 3 records the connection order of the vehicle 300b as the second. Note that the control unit 3 may record the connection order by recording the connection time and the connection time.

  After step S4, in step S205, the priority setting unit 34 sets the priority of the vehicle 300 based on the connection order recorded in step S202, and the process proceeds to step S6.

  As described above, in this example, the priority setting unit 34 sets the highest priority for the vehicle 300 including the battery 301 connected to the charger 1 earliest via the charging connectors 2a to 2c. To do. Thereby, even when the vehicle 300a is already connected to the charging connectors 2a to 2c and charging is started and the vehicle 300 is connected to the charging connectors 2a to 2c and charging is performed later, the charging is already performed. Since the charging time of the battery 301 does not become unduly long, an apparatus that is highly convenient for the user can be provided.

DESCRIPTION OF SYMBOLS 100 ... Charging apparatus 1 ... Charger 11 ... AC / DC converter 12 ... Feeding wiring 13, 13a-13c ... DC / DC converter 2a-2c ... Charging connector 3 ... Control part 31 ... Charger control part 32 ... Charge amount detection part 33 ... Charging power setting unit 34 ... Priority setting unit 4 ... ID authentication unit 5 ... Operation panel 200 ... AC power supply 300, 300a-300c ... Vehicle 301, 301a-301c ... Battery

Claims (7)

In a charging device for charging a battery,
Priority setting means for setting the priority of charging for a plurality of charging targets,
Charging power setting means for setting the charging power of the battery included in the charging target having a high priority to a power higher than the charging power of the battery included in the charging target having the low priority;
Charger control means for simultaneously supplying the charging power set by the charging power setting means to the plurality of batteries from a power source;
Charge amount detecting means for detecting the charge amounts of the plurality of batteries,
The charging power setting means sets the maximum power of the charging device as charging power for a battery to be charged with the highest priority among the plurality of charging objects, and the charge amount detecting means sets the plurality of charging power detection means. When it is detected that one of the batteries is approaching full charge, the charge power of the one battery is reduced while gradually reducing the charge power of the one battery. The charging device is characterized in that the charging of the one battery and the other battery is continued by distributing to the charging power of the other battery. Priority setting means for setting the priority of charging for a plurality of charging targets,
Charging power setting means for setting the charging power of the battery included in the charging target having a high priority to a power higher than the charging power of the battery included in the charging target having the low priority;
Charger control means for simultaneously supplying the charging power set by the charging power setting means to the plurality of batteries from a power source;
Charge amount detecting means for detecting the charge amounts of the plurality of batteries,
The charge power setting means is configured to gradually reduce the charge power of the one battery while gradually reducing the charge power of the one battery when the charge amount detection means detects that one of the plurality of batteries is approaching full charge. Distributing the electric power corresponding to the reduced charging power of the battery to the charging power of the other battery among the plurality of batteries, thereby continuing the charging of the one battery and the other battery,
The priority setting means includes:
The charging apparatus characterized in that the priority is set to the highest for the charging target including the battery with the lowest charge amount among the charge amounts of the plurality of batteries detected by the charge amount detection means. The priority setting means includes:
Claim 1, characterized in that said one of the charging amount of the plurality of battery detected by the charge amount detection means, with respect to the charging target including a lowest charge level of the battery, to the highest setting the priority The charging device described in 1. The priority setting means includes:
Wherein the plurality of charging target, charging device according to claim 1, wherein with respect to the charging target including earliest battery connected to said charging device, to the highest setting the priority. The priority setting means includes:
It said plurality of based on a user's manipulation to be charged, the charging device according to claim 1, characterized in that to set the priority. Priority setting means for setting the priority of charging for a plurality of charging targets,
Charging power setting means for setting the charging power of the battery included in the charging target having a high priority to a power higher than the charging power of the battery included in the charging target having the low priority;
Charger control means for simultaneously supplying the charging power set by the charging power setting means to the plurality of batteries from a power source;
Charge amount detection means for detecting the charge amounts of the plurality of batteries,
User authentication means for authenticating each of the plurality of users to be charged,
The charge power setting means is configured to gradually reduce the charge power of the one battery while gradually reducing the charge power of the one battery when the charge amount detection means detects that one of the plurality of batteries is approaching full charge. Distributing the electric power corresponding to the reduced charging power of the battery to the charging power of the other battery among the plurality of batteries, thereby continuing the charging of the one battery and the other battery,
The priority setting means includes:
The charging apparatus, wherein the priority is set based on information authenticated by the user authentication means. Setting the priority of charging for each of a plurality of charging targets;
A power setting step of setting the charging power of the battery included in the charging target having a high priority to a power higher than the charging power of the battery included in the charging target having the low priority;
Supplying charging power set by the power setting step from a power source to the plurality of batteries simultaneously;
A charge amount detecting step of detecting a charge amount of each of the plurality of batteries,
The power setting step sets the maximum power of the charging device as the charging power for the battery to be charged with the highest priority among the plurality of charging targets, and the charging amount detecting step sets the plurality of batteries. When it is detected that one of the batteries is approaching full charge, the charging power of the one battery is reduced while gradually reducing the charging power of the one battery. A charging method characterized by continuing to charge the one battery and the other battery by distributing the charging power of the other battery.

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