JP2013070546A - Charge control device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a charge control device which reduces cost increased by providing a voltage conversion circuit dedicated to a solar cell.SOLUTION: The charge control device includes: a battery 5; a solar cell 1; a charger 3 which converts power from an external power source 20 and power from the solar cell 1 and charges the battery 5; determination means for determining which of the external power source 20 and the solar cell 1 the power to the charger 3 is to be supplied from; and charge control means which selects either power supply from the external power source 20 or power supply from the solar cell 1 on the basis of the determination result of the determination means and controls the charger 3 to charge the battery 5.

Description

  The present invention relates to a charge control device.

  A solar charge collector configured to collect solar charge; and at least a first charge storage configured to receive and store charge from the solar charge collector. A charge storage system, the charge storage system further comprising a power electronics circuit that is selectively connected to at least a second charge storage, the power electronics circuit comprising a voltage converter, There is known a solar cell type hybrid power system configured to send the accumulated charge to the at least second charge accumulator at a predetermined voltage level (Patent Document 1).

Special table 2011-501013 gazette

  However, there is a problem that the cost increases because a converter dedicated to solar cells is required.

  The present invention provides a charge control device that suppresses costs that are increased by providing a voltage conversion circuit dedicated to solar cells.

  The present invention includes a charger that converts power from an external power source and power from a solar cell and charges the battery, and selects either one of power supply from the external power source and power supply from the solar cell, The above problem is solved by charging the battery.

  According to the present invention, in the charger, power conversion is performed according to the selected power supply among the power supply from the external power supply or the power supply from the solar battery. As a result, cost can be suppressed.

It is a block diagram of the charge control apparatus which concerns on embodiment of this invention. It is a perspective view of the charge lid which covers the charge port of FIG. It is a block diagram of the charger of FIG. It is a flowchart which shows the control procedure of the charge control apparatus of FIG. It is a block diagram of the charge control apparatus which concerns on other embodiment of this invention. It is a flowchart which shows the control procedure of the charging control apparatus of FIG. It is a block diagram of the charge control apparatus which concerns on other embodiment of this invention. It is a block diagram of the charger of FIG. It is a block diagram of the charge control apparatus which concerns on other embodiment of this invention. It is a flowchart which shows the control procedure of the charging control apparatus of FIG.

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

<< First Embodiment >>
FIG. 1 is a block diagram showing a charge control device according to an embodiment of the invention. Hereinafter, although the example which applied the charge control apparatus of this example to an electric vehicle is given and demonstrated, the motor control apparatus of this example is applicable also to vehicles other than electric vehicles, such as a plug-in hybrid vehicle, for example.

  As shown in FIG. 1, the charging control device of this example includes a solar cell 1, a switching circuit 2, a charger 3, a charging port 4, a battery 5, an inverter 6, a motor 7, and a battery 8. , A DC / DC converter 9 and a controller 10 are provided. The solar cell 1 is a power device that is provided on a roof panel of a vehicle, for example, and converts solar energy into electric power. The switching unit 2 includes a relay switch including a switch 2 a and a switch 2 b and is connected between the solar cell 1 and the charger 3. The switching unit 2 switches on and off based on a control signal from the controller 10.

  The charger 3 is connected to the switching circuit 2 and the charging port 4 on the input side, and is connected to the battery 5 on the output side. The charger 3 converts the electric power from the solar cell 1 and the electric power from the external power source 20 into charging electric power for charging the battery 5, and supplies the electric power to the battery 5 to charge the battery 5. Further, the charger 3 switches between charging the battery 5 by supplying power from the solar cell 1 or charging the battery 5 by supplying power from the external power source 20 based on a control signal from the controller 10. In addition, when charging the battery 5 by supplying power from the solar cell 1 and supplying power from the external power source 20, a charging line for connecting to the battery 5 from the input of the charger 3 is common, and the charger 3 is It is sufficient that at least one charging circuit is included.

  The charging port 4 is a charging port that can be connected to a charging connector from the outside, and is connected to the charger 3 via wiring. The external power source 20 is a power source for a commercial power system such as a home AC power source. When one end of the charging cord is connected to the external power source 20 and the other end of the charging cord is connected to the charging port 4, the external power source 20 and the charger 3 are in a conductive state. Here, the structure of the charging lid 40 which becomes the lid | cover of the charging port 4 is demonstrated using FIG. FIG. 2 is a perspective view of the charging lid 40.

  The charging lid 40 is constituted by a lid that covers the charging port 4 and is provided in the vehicle. The charging lid 40 is provided with a lock mechanism 41. When the battery 5 is charged by the external power source 20, it is necessary to open the charging lid 40. Then, by releasing the lock mechanism 41 based on the user's operation or the like, the charging lid 40 is opened, and the charging port 4 can be seen. The charging lid 40 is provided with a sensor for detecting the opening / closing of the charging lid 40, and the sensor is constituted by a contact sensor provided in the lock mechanism 41, for example. The contact sensor detects a state in which the charging lid 40 is closed when the lock mechanism 41 is in a locked state, and detects a state in which the charging lid 40 is open when the lock mechanism 41 is in an unlocked state. The detection result is transmitted to the controller 10.

  Returning to FIG. 1, the battery 5 includes a plurality of secondary batteries, serves as a vehicle drive source, and is a high-voltage battery as compared with a battery 8 described later. The battery 5 is connected between the charger 3 and the inverter 6. The battery 5 is charged by the charging power from the charger 2 and drives the motor 7 via the inverter 6. The battery 5 can also supply power to the battery 8 via the DC / DC converter 9.

  The inverter 6 includes a plurality of switching elements such as insulated gate bipolar transistors (IGBTs), and includes a smoothing capacitor and the like. The inverter 6 converts the DC power supplied from the battery 5 into AC power and provides it to each phase of the motor 7 by PWM control of the switching element based on the switching signal transmitted from the controller 10. Further, the inverter 6 converts electric power supplied from the motor 7 by regeneration of the motor 7 and supplies it to the battery 5. The motor 7 is, for example, a three-phase AC motor, and is connected to the inverter 6.

  The battery 8 includes a plurality of secondary batteries, serves as a power source for operating auxiliary equipment such as a vehicle headlight and audio equipment, and is a battery having a lower voltage than the battery 5. The battery 8 is connected to a DC / DC converter 9. The DC / DC converter 9 is connected between the battery 5 and the battery 8, converts electric power from the battery 5, and supplies it to the battery 8.

  The controller 10 includes a determination unit 11 and a charge control unit 12, and is a control unit that controls the entire charge control device of this example. The controller 10 controls on and off of the switches 2 a and 2 b of the switching circuit 2, controls the charger 3, and controls the inverter 6. Further, the controller 10 determines the state of charge (SOC: State of Charge) of the battery 5 and the battery 8 based on detection values of a sensor (not shown) connected to the battery 5 and a sensor (not shown) connected to the battery 8. The battery 5 and the battery 8 are managed by calculation. When driving the motor 7, the controller 10 drives the switching element of the inverter 6 based on externally input torque command, vehicle information such as the accelerator opening, the detected value of the phase current of the motor 7, and the like. For this purpose, a switching signal is generated and transmitted to the switching element of the inverter 6 to control the inverter 6 and drive the motor 7.

  Next, a specific configuration of the charger 3 will be described with reference to FIG. FIG. 3 is a block diagram of the charger 3. The charger 3 includes input terminals 31a and 31b, a full-wave rectifier circuit 32, a boost chopper 33, a DC / DC converter 34, current sensors 35a and 35b, voltage sensors 36a, 36b, and 36c, and boost chopper control. Device 37, a DC / DC converter controller 38, and output terminals 39a and 39b. The input terminals 31a and 31b are connected to the charging port 4 and the switching circuit 2, respectively. The full-wave rectifier circuit 32 is configured by a bridge circuit including four diodes, and is connected between the input terminals 31 a and 31 b and the boost chopper 33. In the diode bridge of the full-wave rectifier circuit 32, an input terminal 31a and an input terminal 31b are connected to a pair of connection points where the anode of one diode and the other anode are connected. The electric power input from the input terminals 31 a and 31 b is rectified by the full-wave rectifier circuit 32 and output to the boost chopper 33.

  The step-up chopper 33 includes a coil and a diode connected in series, and a parallel circuit of a transistor and a diode connected to a connection point between the coil and the diode. The full-wave rectifier circuit 32 and the DC / DC It is connected between the converter 34. The step-up chopper 33 is a power factor correction circuit that adjusts input power, and performs PFC (Power Factor Correction) control based on a control signal from the step-up chopper controller 37. The PFC control is performed when the battery 5 is charged by supplying power from the external power supply 20. Specifically, in accordance with the AC voltage waveform supplied from the external power source 20 and rectified by the full-wave rectifier circuit 32, the input current waveform is adjusted to be a sine wave, so that the power factor approaches 1. The step-up chopper 33 is driven. The step-up chopper 33 improves the power factor of the input power as described above by switching the transistor on and off based on the drive signal from the step-up chopper controller 37.

  The step-up chopper 33 also has an MPPT (Maximum Power Point Tracking) control function that tracks the maximum power point of the solar cell 1. The MPPT control is performed when the battery 5 is charged by supplying power from the solar cell 1. In the MPPT control, the operating point of the input voltage is manipulated while maintaining the output voltage substantially constant by the smoothing capacitor 301 connected to the output side of the boost chopper 33. The operation of the operating point of the input voltage is adjusted by the duty ratio of the switching waveform of the transistor, and the duty ratio is set by the boost chopper controller 37. That is, the step-up chopper 33 performs MPPT control by driving the transistor based on the switching signal having the duty ratio set by the step-up chopper controller 37.

  The DC / DC converter 34 is an insulating converter including a transformer, and is connected between the step-up chopper 33 and the output terminals 39a and 39b. The DC / DC converter 34 is a circuit that converts the output power of the step-up chopper 33 so that the charging power is suitable for charging the battery 5. The output terminals 39a and 39b are connected to the battery 5 and the DC / DC converter 9. The current sensor 35a and the voltage sensor 36a are connected between the full-wave rectifier circuit 32 and the boost chopper 33, and detect the input current and input voltage of the boost chopper 33, respectively. The voltage sensor 36 c is connected between the boost chopper 33 and the DC / DC converter 34 and detects the output voltage of the boost chopper 33. The current sensor 35b and the voltage sensor 36b are connected between the DC / DC converter 34 and the output terminals 39a and 39b, and detect the output current and output voltage of the charger 3.

  The step-up chopper controller 37 and the DC / DC converter controller 38 control the step-up chopper 33 and the DC / DC converter 34 based on the signal transmitted from the controller 10, respectively. When a signal to charge the battery 5 is supplied from the controller 10 by supplying power from the external power supply 20, the boost chopper controller 37 uses the detection voltage of the voltage sensor 36a and the detection current of the current sensor 35a. Then, a switching signal for PFC control is generated and transmitted to the step-up chopper 33 to adjust the input power. Further, the DC / DC converter controller 38 receives the charging power command value transmitted from the controller 10, and sets the detection voltage of the voltage sensors 36b and 36c and the detection current of the current sensor 35b so as to follow the charging power command value. The switching signal is generated and transmitted to the DC / DC converter 34 to be converted into electric power corresponding to the charging power command value.

  When the controller 10 transmits a signal to charge the battery 5 by supplying power from the external power supply 20, the boost chopper controller 37 detects the detection voltages of the voltage sensors 36a and 36c and the detection of the current sensor 35a. Using the current, a switching signal for MPPT control is generated and transmitted to the step-up chopper 33 to optimize the power point of the solar cell 1. The DC / DC converter controller 38 generates a switching signal using the detection voltages of the voltage sensors 36 b and 36 c and converts it into a voltage suitable for the charging power of the battery 5.

  Next, the control content of the charging control apparatus of this example will be described. First, the determination unit 11 of the controller 10 will be described. The determination unit 11 determines whether power to the charger 3 is supplied from the external power supply 20 or from the solar cell 1. The determination unit 11 detects the opening / closing of the charging lid 40 from the output value of the contact sensor provided in the lock mechanism 41. When the charging lid 40 is open, power is supplied from the external power source 20 by connecting the charging connector to the charging port 4, so that the determination unit 11 uses the power to the charger 3 as the external power source. When supplied from 20, it is determined. On the other hand, when the charging lid 40 is closed, the charging connector is not connected to the charging port 4, so that the determination unit 11 determines that the power to the charger 3 is supplied from the solar cell 1. To do.

  The charge control unit 12 selects one of the power supply from the external power source 20 and the power supply from the solar cell 1 based on the determination result of the determination unit 11, and switches the switching circuit according to the selected power supply. 2 and the charger 3 are controlled, and the battery 5 is charged. That is, when the determination unit 11 determines that the power to the charger 3 is supplied from the external power source 20, the charge control unit 12 selects the power supply from the external power source 20 and switches the switching circuit 2. 2a and 2b are turned off, a signal for PFC control is transmitted to the boost chopper controller 37, and a signal for causing the DC / DC converter controller 38 to convert the output power by the PFC control into the charging power of the battery 5 is transmitted. Send. Since the switches 2 a and 2 b of the switching circuit 2 are turned off, even if the battery 5 is charged with the power of the external power source 20, the power of the external power source 20 is not supplied to the solar cell 1. On the other hand, when the determination unit 11 determines that power to the charger 3 is supplied from the solar cell 1, the charge control unit 12 turns on the switches 2 a and 2 b of the switching circuit 2, Is supplied to the step-up chopper controller 37, and a signal for causing the DC / DC converter controller 38 to convert the output power by the MPPT control into the charging power of the battery 5 is transmitted. Send.

  Further, in addition to the above control, the controller 10 controls the DC / DC converter 9 to output the power of the battery 5 to the battery 8 and performs control to charge the power of the battery 8 with the power of the battery 5.

  The control procedure of the charge control device of this example will be described with reference to FIG. FIG. 4 is a flowchart showing a control procedure of the charge control device of this example. In step S <b> 1, the determination unit 11 detects whether or not the charging lid 40 is open from the contact sensor of the lock mechanism 41. If it is detected that the charging lid 40 is open, the determination unit 11 determines in step S2 that the power to the charger 3 is supplied from the external power source 20. On the other hand, when it is detected that the charging lid 40 is closed, the determination unit 11 determines that power to the charger 3 is supplied from the solar cell 1 in step S3.

  In step S <b> 4, the charging control unit 12 determines whether the determination unit 11 has determined that power to the charger 3 is supplied from the external power supply 20. When it is determined that the power to the charger 3 is supplied from the external power source 20, in step S5, the charging control unit 12 turns off the switches 2a and 2b of the switching circuit 2, and in step S6, The charger 3 is controlled to perform charging control using the external power source 20. When the controller 10 reaches full charge from the SOC of the battery 5, the charging control is terminated.

  Returning to step S4, if it is determined that the power to the charger 3 is supplied from the solar battery 1, in step S7, the charging control unit 12 turns on the switches 2a and 2b of the switching circuit 2, In step S6, the charger 3 is controlled to perform charging control using the solar cell 1. When the controller 10 reaches full charge from the SOC of the battery 5, the charging control is terminated.

  As described above, in this example, the determination unit 11 determines whether the power to the charger 3 is supplied from the external power source 20 or the solar cell 1, and based on the determination result, The charging control unit 12 selects one of power supply from the external power source 20 and power supply from the solar cell 1 to control the charger 3 and charge the battery 5. As a result, the charger 3 that charges the battery 5 using the external power source 20 and the charger that charges the battery 5 using the solar cell 1 are shared by the charger 3, and then the power from the external power source 20 is used. Since charging of the battery 5 and charging of the battery 5 with electric power from the solar cell 1 can be respectively performed, a converter dedicated to charging by the solar cell 1 can be omitted, and cost can be suppressed. Further, in this example, by omitting a converter dedicated to charging by the solar cell 1, a space can be secured and the degree of layout freedom can be increased.

  Further, in this example, on and off of the switches 2 a and 2 b of the switching circuit 2 are controlled based on the determination result by the determination unit 11. Thereby, when charging the battery 5 with the electric power from the external power source 20, the switches 2a and 2b can be opened so that the output power from the external power source 20 is not applied to the solar cell 1. Protection can be achieved. Moreover, since it is not always necessary to connect a protective diode to the solar cell 1, the number of parts can be reduced.

  Further, in this example, since the switches 2a and 2b are provided, the output of the solar battery 1 and the output of the external power supply 20 are not simultaneously connected on the input side of the charger 3, so that the charging control of the external power supply 20 and the solar battery 1 are performed. The charge control can be selected and performed.

  In this example, a sensor for detecting opening and closing of the charging lid 40 is provided, and when it is detected that the charging lid 40 is open, it is determined that power is supplied from the external power source 20. Thus, in this example, charging control by the external power source 20 and charging control by the solar cell 1 can be selected and performed in correspondence with opening / closing of the charging lid 40.

  Further, in this example, when it is determined that the power to the charger 3 is supplied from the external power source 20, the boost chopper 33 is controlled by PFC control, and the power to the charger 3 is supplied from the solar cell 1. If it is determined that the boost chopper 33 is to be performed, the boost chopper 33 is controlled by MPPT control. Thereby, the electric power generation control of the solar cell 1 can be performed using the circuit common to the charger 3, and as a result, an increase in space can be suppressed while suppressing costs.

  In this example, the DC / DC converter 9 is commonly used when the battery 5 is charged by the power supply from the external power source 20 and the power supply from the solar cell 1. Thereby, by omitting a converter dedicated to charging by the solar cell 1, a space can be secured and the degree of layout freedom can be increased.

  Note that the sensor that detects opening and closing of the charging lid 40 is not necessarily the above contact sensor, and a sensor such as an infrared sensor may be used. Further, the determination unit 11 does not necessarily have to determine the state of power supply based on the detection signal of opening / closing of the charging lid 40, for example, whether or not a charging cord connected to the external power source 20 is connected to the charging port 4. Depending on whether or not.

  The determination unit 11 corresponds to the “determination unit” of the present invention, the charging control unit 12 is the “charging control unit”, the switches 2a and 2b are the “first switching unit”, and the charging lid 40 is the “lid body”. The contact sensor provided in the lock mechanism 41 corresponds to “opening / closing detection means”, and the step-up chopper 33 corresponds to “power factor correction circuit”.

<< Second Embodiment >>
FIG. 5 is a block diagram of a charging control apparatus according to another embodiment of the invention. In this example, the switches 2c and 2d, the diode 51, and the voltage sensor 52 are provided and part of the control of the controller 10 is different from the first embodiment described above. Since the other configuration is the same as that of the first embodiment described above, the description thereof is incorporated.

  As shown in FIG. 5, the switching circuit 2 includes switches 2 a to 2 d, and the switches 2 c and 2 d are connected between the solar cell 1 and the battery 8. The switches 2c and 2d are switched on and off based on a control signal from the controller 10. When the switches 2c and 2d are turned on, output power is supplied from the solar cell 1 to the battery 8, and the battery 8 is charged. A diode 51 is connected to one of the output lines of the solar cell 1. The diode 51 is a protection circuit for the solar cell 1, and is a backflow prevention diode for preventing current from the battery 8 from flowing into the solar cell 1 when the switches 2 c and 2 d are in an on state. The voltage sensor 52 is connected to the input side of the charger 3 and detects an input voltage to the charger 3.

  The controller 10 detects the driving state of the vehicle based on vehicle information such as a shift lever. When the determination unit 11 determines that the vehicle is running, the charging control unit 12 turns off the switches 2a and 2b, turns on the switches 2c and 2d, and supplies the power of the solar cell 1 to the battery 8. The battery 8 is charged. In addition, when the detection voltage of the voltage sensor 52 is an AC voltage, the determination unit 12 determines that the power to the charger 3 is supplied from the external power source 20, and the detection voltage of the voltage sensor 52 is not an AC voltage. Is determined that the power to the charger 3 is supplied from the solar cell 1. That is, since the power output from the solar cell 1 is a direct current and the power output from the external power supply 20 is an alternating current, the battery 5 is detected by detecting whether the input power of the charger 3 is an alternating current. It is possible to determine the supply source of the charging power to.

  When the determination unit 11 determines that power to the charger 3 is supplied from the external power source 20, the charge control unit 12 selects power supply from the external power source 20 and switches the switching circuit 2. 2a and 2b are turned off, the switches 2c and 2d are turned on, a signal for PFC control is transmitted to the step-up chopper controller 37, and the output power by the PFC control is supplied to the DC / DC converter controller 38 as the charging power of the battery 5. Send a signal to convert to. Thereby, the battery 8 is charged with the electric power of the solar cell 1 while charging the battery 5 with the electric power of the external power source 20. On the other hand, when the determination unit 11 determines that power to the charger 3 is supplied from the solar cell 1, the charge control unit 12 turns on the switches 2a and 2b of the switching circuit 2 and switches 2c and 2d. Is turned off, the power supply from the solar cell 1 is selected, a signal for MPPT control is transmitted to the step-up chopper controller 37, and the output power by MPPT control is charged to the DC / DC converter controller 38 to charge the battery 5. A signal for converting to electric power is transmitted. Thereby, the battery 5 is charged with the electric power of the solar cell 1.

  Next, the control procedure of the charging control apparatus of this example will be described with reference to FIG. FIG. 6 is a flowchart showing a control procedure of the charge control device of this example. In step S <b> 11, the determination unit 11 detects whether or not the input voltage to the charger 3 is an AC voltage from the detection voltage of the voltage sensor 52. When the input voltage is an AC voltage, in step S12, the determination unit 11 determines that the power to the charger 3 is supplied from the external power source 20 to the high voltage battery 5.

  On the other hand, when the input voltage is not an AC voltage, in step S13, the determination unit 11 detects whether or not the shift lever is in the P (parking) range. If the shift lever is in the P range, in step S14, the determination unit 11 determines that power to the charger 3 is supplied from the solar cell 1 to the high voltage battery 5. If the shift lever is not in the P range, the determination unit 11 determines that power is supplied from the solar cell 1 to the low voltage battery 8 in step S15.

  In step S <b> 16, the charging control unit 12 determines whether or not the determination unit 11 has determined that power to the charger 3 is supplied from the external power supply 20. If it is determined that electric power is supplied from the external power supply 20, the charging control unit 12 turns off the switches 2a and 2b of the switching circuit 2 in step S17, and the charging control unit 12 in step S18 Then, the switches 2c and 2d of the switching circuit 2 are turned on, and in step S19, the charger 3 is controlled to perform charging control using the external power source 20, and the controller 10 is fully charged from the SOC of the battery 5 and the battery 8. When it reaches, the charging control is terminated.

  Returning to step S <b> 16, if it is not determined by the determination unit 11 that the power to the charger 3 is supplied from the external power supply 20, the charge control unit 12 uses the determination unit 11 to supply power to the charger 3. It is determined whether or not it is determined that the high voltage battery 5 is supplied from the solar cell 1 (step S20). If it is determined that power is supplied from the solar cell 1 to the high voltage battery 5, the charging control unit 12 turns off the switches 2c and 2d of the switching circuit 2 in step S21, and in step S22. The charging control unit 12 turns on the switches 2a and 2b of the switching circuit 2 and controls the charger 3 to perform charging control using the solar cell 1 in step S23. The controller 10 controls the SOC of the battery 5. When full charge is reached, the charging control is terminated.

  Returning to step S20, if it is determined that power is not supplied from the solar cell 1 to the high voltage battery 5, in step S24, the charge control unit 12 turns off the switches 2a and 2b of the switching circuit 2, In step S25, the charging control unit 12 turns off the switches 2c and 2d of the switching circuit 2. When the controller 10 reaches full charge from the SOC of the battery 8, the charging control ends.

  As described above, in this example, the voltage sensor 52 is provided on the input side of the charger 3, and when the detected voltage is an AC voltage, it is determined that electric power is supplied from the external power supply 20. Thereby, for example, when a sensor for detecting the input voltage of the charger 3 is provided for controlling the charger 3, etc., the state of power supply can be determined using the sensor. It is not necessary to provide a sensor in the case, and the number of parts can be reduced.

  Moreover, this example charges the battery 5 with the electric power of the solar cell 1 while charging the battery 5 with the electric power of the external power source 20 while the vehicle is stopped. Thereby, at the time of the charge from the external power supply 20 in the daytime, the generated power of the solar cell 1 can be supplied to auxiliary equipment such as a control power supply and an air conditioning fan consumed during the charging. Therefore, it is not necessary to supply power from the battery 5 via the DC / DC converter 9, so that no conversion loss occurs in the DC / DC converter 9 and the total loss during charging can be reduced. Time can also be shortened.

  Moreover, this example detects the state of the vehicle based on whether or not the shift range is the P range, and directly supplies the output of the solar cell 1 to the battery 8, thereby suppressing power consumption to the battery 8 during traveling. Since the total loss can be reduced, the travel distance can be extended.

  The voltage sensor 52 corresponds to the “voltage detection means” of the present invention.

<< Third Embodiment >>
FIG. 7 is a block diagram of a charging control apparatus according to another embodiment of the invention. In this example, the structure which concerns on the input terminals 31a-31c of the charger 3 differs with respect to 1st Embodiment mentioned above. Since the other configuration is the same as that of the first embodiment described above, the description thereof is incorporated.

  As shown in FIGS. 7 and 8, one of the two output wires of the solar cell 1 is connected to one of the two output wires of the external power supply 20, and the two output wires of the solar cell 1 are connected. The other wiring is not connected to the other of the two output wirings of the external power supply 20, and the other wiring is independently connected to the charger 3. One of the two output wires of the solar cell 1 and one of the two output wires of the external power supply 20 are connected to the input terminal 31 a of the charger 3. The other of the two output wires of the solar cell 1 is connected to the input terminal 31 c of the charger 3, and the other of the two output wires of the external power supply 20 is connected to the input terminal 31 b of the charger 3. Has been.

  The input terminal 31a is connected to the connection point between the diode 32a and the diode 32b, the input terminal 31b is connected to the connection point between the diode 32c and the diode 32d, and the input terminal 31c is connected to the output terminal of the full-wave rectification circuit 32. Yes. When the electric power output from the solar cell 1 is input to the charger 3 via the switches 2a and 2b, only the diode 32a among the four diodes 32a to 32d is passed. Thereby, since the output electric power from the solar cell 1 does not pass through the four diodes 32a to 32d, it is possible to suppress a loss when power is converted by the charger 3.

  As described above, in this example, one terminal among the plurality of terminals of the solar cell 1 is a connection point between the anode terminal of one of the plurality of diodes 32a to 32d and the cathode terminal of the other diode 32c. The other terminal among the plurality of terminals of the solar cell 1 is connected to the output terminal of the full-wave rectifier circuit 32. Thereby, the loss at the time of converting the output electric power of the solar cell 1 with the charger 3 can be suppressed, and the generated electric power of the solar cell 1 can be used for charging the battery 5 efficiently.

<< 4th Embodiment >>
FIG. 9 is a block diagram of a charging control apparatus according to another embodiment of the invention. This example differs from the first embodiment described above in that the switches 2e and 2f and the timer 13 are provided and a part of the control of the controller 10 is different from the first embodiment described above in the present example. Since the other configuration is the same as that of the first embodiment described above, the description thereof is incorporated.

  As shown in FIG. 9, the switching circuit 2 includes switches 2 a, 2 b, 2 e, and 2 f, and the switches 2 e and 2 f are connected between the solar cell 1 and the battery 8. The switches 2e and 2f are switched on and off based on a control signal from the controller 10. When the switches 2 e and 2 f are turned on, output power is supplied from the external power supply 20 to the charger 3.

  The controller 10 includes a timer 13. The timer 13 is a timer for managing the charging start time. When the charging start time is set by the user, the timer 13 stores the time. Then, when the current time becomes the charging start time, the timer 13 sends a charging command for charging the battery 5 to the determination unit 11. The determination unit 11 determines that the battery 5 is charged by supplying power from the external power source 20 when the charging command is received, and supplies power from the solar cell 1 when the charging command is not received. Is determined to charge the battery 5.

  When the determination unit 11 determines that the power to the charger 3 is supplied from the external power source 20, the charge control unit 12 selects the power supply from the external power source 20, and the switch 2a, 2b is turned off, switches 2e and 2f are turned on, a signal for PFC control is transmitted to the step-up chopper controller 37, and the output power by the PFC control is changed to the charging power of the battery 5 to the DC / DC converter controller 38. Send a signal to convert. On the other hand, when the determination unit 11 determines that power to the charger 3 is supplied from the solar cell 1, the charge control unit 12 turns on the switches 2a and 2b of the switching circuit 2 and switches 2e and 2f. Is turned off, the power supply from the solar cell 1 is selected, a signal for MPPT control is transmitted to the step-up chopper controller 37, and the output power by MPPT control is charged to the DC / DC converter controller 38 to charge the battery 5. A signal for converting to electric power is transmitted. As a result, even when a charging cord connected to the external power source 20 is connected to the charging port 4, the switches 2e and 2f are turned off and the switches 2a and 2b are turned on unless a charging command is input. . Therefore, for example, when the charging start time is set so as to charge the battery 5 using nighttime power and the charging cord is connected to the charging port 4 in advance, the battery is operated by the solar cell 1 in the daytime period. 5 can be charged, and the electricity bill can be reduced.

  In addition, when charging the battery 5 with the power of the external power supply 20 from the state in which the switches 2a and 2b are on, the charging control unit 12 turns off the switches 2a and 2b and then turns on the switches 2e and 2f. Start charging. Thereby, it controls so that the electric power from the external power supply 20 is not applied to the solar cell 1.

  The control procedure of the charge control device of this example will be described with reference to FIG. FIG. 10 is a flowchart showing a control procedure of the charge control device of this example. In addition, since control of step S2 to S8 shown in FIG. 10 is the same as that of step S2 to S8 shown in FIG. 4, description is abbreviate | omitted. In step S <b> 10, the charging control unit 12 determines whether or not a charging command is input from the timer 13. When the charging command is input, the process proceeds to step S2, and when the charging command is not input, the process proceeds to step S3.

  As described above, in this example, the switches 2e and 2f are provided between the external power source 20 and the charger 3. As a result, even when the external power source 20 and the charging port 4 are connected, by turning off the switches 2e and 2f between the external power source 20 and the charger 3, the charger 3 and the solar cell 1 The battery 5 can be charged from the solar cell 1 by turning on the switches 2a and 2b.

  Further, in this example, when a charging command for charging the battery 5 is input, it is determined that the power to the battery 5 is supplied from the external power source 20. Thus, even when the charging port 4 and the external power source 20 are connected, the generated power of the solar cell 1 is charged into the battery 5 by switching to the connection with the solar cell 1 until a charging start command is input. be able to.

  In this example, the switches 2e and 2f are turned on while the switches 2a and 2b are turned off. Thereby, before connecting the charger 3 and the external power supply 20, the connection between the solar cell 1 and the charger 3 is opened by turning off the switches 2a and 2b between the solar cell 1 and the charger 3 in advance. Thus, the voltage of the external power supply 20 can be prevented from being applied to the solar cell 1. Further, the backflow prevention diode can be omitted from the solar cell 1.

  The switches 2e and 2f correspond to the “second switching element” of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Solar cell 2 ... Switching circuit 2a, 2b, 2c, 2d, 2e, 2f ... Switch 3 ... Charger 31a, 31b, 31c ... Input terminal 32 ... Full wave rectifier circuit 32a, 32b, 32c, 32d ... Diode 33 ... Step-up chopper 34 ... DC / DC converter 35a, 35b ... Current sensor 36a, 36b ... Voltage sensor 37 ... Step-up chopper controller 38 ... DC / DC converter controller 39a, 39b ... Output terminal 301 ... Smoothing capacitor 4 ... Charging port 5 ... Battery 6 ... Inverter 7 ... Motor 8 ... Battery 9 ... DC / DC converter 10 ... Controller 11 ... Discrimination unit 12 ... Charge control unit 13 ... Timer 20 ... External power supply 40 ... Charging lid 41 ... Lock mechanism 51 ... Diode 52 ... Voltage sensor

Claims (11)

Battery,
Solar cells,
A charger that converts power from an external power source and power from the solar cell and charges the battery;
Determining means for determining whether power to the charger is supplied from the external power supply or from the solar cell;
Based on the determination result of the determination means, a charge control means for selecting one of the power supply from the external power source and the power supply from the solar battery, and controlling the charger to charge the battery; A charge control device comprising: Further comprising first switching means connected between the solar cell and the charger;
The charge control means includes
2. The charging control apparatus according to claim 1, wherein the first switching unit is controlled based on a determination result of the determination unit. The charger is
Having a rectifier circuit composed of a bridge circuit of a plurality of diodes;
One terminal of the plurality of terminals of the solar cell is
Connected to a connection point between an anode terminal of one of the plurality of diodes and a cathode terminal of another diode;
Of the plurality of terminals of the solar cell, the other terminal is
The charge control device according to claim 1, wherein the charge control device is connected to an output terminal of the rectifier circuit. Further comprising second switching means connected between the external power source and the charger;
The charge control means includes
The charge control device according to any one of claims 1 to 3, wherein the second switching unit is controlled based on a determination result of the determination unit. A connection terminal with the external power source, and a lid covering the connection terminal,
The discrimination means includes
Open / close detecting means for detecting opening / closing of the lid,
The charge control device according to any one of claims 1 to 4, wherein when it is detected that the lid is open, it is determined that the electric power is supplied from the external power source. . The discrimination means includes
Voltage detecting means for detecting an input voltage to the charger;
When the voltage detected by the voltage detection means is an AC voltage, it is determined that the electric power is supplied from the external power supply. Charge control device. The discrimination means includes
7. The method according to claim 1, further comprising: determining that the electric power is supplied from the external power source when a charging command for charging the battery is input by the electric power from the external power source. The charging control device according to claim 1. First switching means connected between the solar cell and the charger;
Second switching means connected between the external power source and the charger;
The charge control means includes
2. The charging control apparatus according to claim 1, wherein the second switching unit is turned on while the first switching unit is turned off. The discrimination means has a timer,
Based on the detection time by the timer, it is determined whether the power is supplied from the external power source or the power is supplied from the solar cell,
The charge control means includes
When it is determined that the electric power is supplied from the solar cell, the first switching means is turned on, the second switching means is turned off,
When it is determined that the power is supplied from the external power source, the first switching unit is turned off and the second switching unit is turned on.
The charge control apparatus according to claim 8. The charger has a power factor correction circuit that adjusts the power factor of power,
The charge control means includes
When the determination means determines that the power is supplied from the external power supply, the power factor correction circuit is controlled to adjust the input current waveform from the external power supply,
The power point of the solar cell is optimized by controlling the power factor correction circuit when the determining means determines that the power is supplied from the solar cell. Item 10. The charge control device according to any one of Items 1 to 9. The said charger has a DC / DC converter used in common with the electric power supply from the said external power supply, and the electric power supply from the said solar cell, The Claim 1 characterized by the above-mentioned. Charge control device.

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