JP2015076959A - Power system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power system capable of feeding to a specific power storage device among a plurality of power storage devices.SOLUTION: In a power system 1, power generated by an alternator 10 is supplied to a first power storage device 17 and a second power storage device 18. A switch 11 is provided on a feeding path feeding power from the alternator 10 to the first power storage device 17, whereas a switch 13 is provided on a feeding path for feeding power from the alternator 10 to the second power storage device 18. The switch 11 connects or intercepts the feeding path for feeding power from the alternator 10 to the first power storage device 17, whereas the switch 13 connects or intercepts the feeding path for feeding power from the alternator 10 to the second power storage device 18.

Description

  The present invention relates to a power supply system in which electric power generated by a generator is supplied to a load and a power storage device.

  As a power supply system mounted on a vehicle, it has two power storage devices that store DC regenerative power generated by an alternator (generator) by converting the kinetic energy of the vehicle into electric power, and the alternator and the two power storage devices supply power to the load. A power supply system has been proposed (see, for example, Patent Document 1).

  FIG. 19 is a block diagram showing a main configuration of a conventional power supply system. In the conventional power supply system 9 as described in Patent Document 1, one end of the alternator 90 is connected to the positive electrode of the power storage device 91 and one end of each of the starter 92, the load 93, and the switch 94. The other end of the switch 94 is connected to the positive electrode of the power storage device 95 and one end of the load 96. The other end of each of the alternator 90, the starter 92, and the loads 93 and 96 and the negative electrode of each of the power storage devices 91 and 95 are grounded.

  Alternator 90 generates DC regenerative power when the engine is operating, and supplies the generated regenerative power to power storage devices 91 and 95 and loads 93 and 96. Regenerative power generated by the alternator 90 is supplied to the power storage device 95 and the load 96 via the switch 94. When the alternator 90 is not generating power, the power storage devices 91 and 95 supply power to the loads 93 and 96.

The starter 92 is a motor for starting the engine. The power storage device 91 is, for example, a lead storage battery, and mainly supplies power to a starter 92 that requires a large amount of current. The power storage device 95 is a lithium battery, for example, and mainly supplies power to the loads 93 and 96. In the conventional power supply system 9, overcharge and overdischarge of the power storage device are prevented by controlling on / off of the switch 94.
As described above, the conventional power supply system 9 performs power storage and power feeding using the two power storage devices 91 and 95 having different output characteristics.

JP 2011-234479 A

  However, in the conventional power supply system 9, when power is supplied from the alternator 90 to the second power storage device 95, power is always supplied to the power storage device 91. For this reason, even when the power storage rate of power storage device 95 is less than the upper limit threshold value, power storage device 91 is overcharged when the power storage rate of power storage device 91 is equal to or greater than the upper limit threshold value. No power can be supplied to 95.

  Therefore, even if the alternator 90 can generate regenerative power, the alternator 90 cannot generate regenerative power when the power storage rate of the power storage device 91 is equal to or greater than the upper threshold, and the conventional power supply The system 9 has a problem that it cannot perform efficient charging.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a power supply system capable of supplying power to a specific power storage device among a plurality of power storage devices.

  The power supply system according to the present invention is provided in each of a plurality of power supply paths that supply power from the generator to each of the plurality of power storage devices in a power supply system in which power generated by the generator is supplied to the plurality of power storage devices. And a plurality of switches for connecting and blocking each of the plurality of power feeding paths.

In the present invention, the generator supplies the generated power to the plurality of power storage devices. The plurality of switches are provided separately for each of a plurality of power supply paths that supply power from the generator to each of the plurality of power storage devices, and connect and disconnect the corresponding power supply paths.
For this reason, for example, the switch provided in the power supply path from the generator to the power storage device to be supplied with power is turned on, and the switch provided in the power supply path from the generator to the power storage device that should not be supplied with power is turned off. By doing so, it is possible to supply power to a specific power storage device among the plurality of power storage devices.

  The power supply system according to the present invention includes a determination unit that determines whether or not a storage rate of each of the plurality of power storage devices is less than a threshold, and when the power generator generates power, from the power generator, One or a plurality of switches provided respectively in one or a plurality of power supply paths to which power is supplied to each of the one or a plurality of power storage devices determined by the determination means to be less than the threshold value are turned on, and the determination is made from the generator. And an on / off means for turning off one or a plurality of switches respectively provided in one or a plurality of power supply paths to which power is supplied to each of the one or a plurality of power storage devices determined to be equal to or greater than the threshold. To do.

In the present invention, it is determined whether or not the power storage rate of each of the plurality of power storage devices is less than the threshold value. In the case where the generator is generating electric power, one generator is provided in each of one or a plurality of power supply paths that supply power from the generator to each of the one or more power storage devices that are determined to have a power storage rate less than the threshold. Alternatively, a plurality of switches are turned on. Further, when the generator is generating electric power, the generator is provided separately for each of one or a plurality of power supply paths that supply power to each of the one or a plurality of power storage devices that are determined to have a storage rate equal to or higher than the threshold value. Turn off one or more switches.
Accordingly, one or more power storage devices having a power storage rate less than the threshold value are charged without charging one or more power storage devices having a power storage rate equal to or higher than the threshold value.

  The power supply system according to the present invention includes a first load fed from each of the plurality of power storage devices via each of the plurality of switches, and a plurality of connection nodes between the power storage device and the switches in each of the plurality of power supply paths. A second load to which one end is connected, a disconnection between the first load and the second load in each of the plurality of power storage devices, or a detection unit that detects a failure, and the detection unit includes the plurality of power storage devices And an off means for turning off the plurality of switches when the disconnection or failure is detected for at least one of them.

In the present invention, the first load is fed from each of the plurality of power storage devices via each of the plurality of switches, and one end of the second load is a plurality of connection nodes between the power storage devices and the switches in each of the plurality of power feeding paths. Connected to. For each of the plurality of power storage devices, a disconnection or failure between the first load and the second load is detected. The failure of the power storage device is an open or short circuit of the connection terminal. When at least one of the plurality of power storage devices detects non-contact or failure, the plurality of switches are turned off.
As a result, power is not supplied to the first load but supplied to the second load by another power storage device that is not disconnected or failed from the first load and the second load. Therefore, it is possible to continue supplying power to the second load for a long time in an emergency situation where at least one of the plurality of power storage devices is disconnected or malfunctioned.

  The power supply system according to the present invention includes a current detection unit that detects input / output currents of each of the plurality of power storage devices, and a voltage detection unit that detects output voltages of the plurality of power storage devices, and the detection unit includes: The non-connection or failure is detected based on the current detected by the current detection unit or the voltage detected by the voltage detection means.

In the present invention, the input / output current of each of the plurality of power storage devices is detected, and the output voltage of each of the plurality of power storage devices is detected. Based on the detected current or the detected voltage, a disconnection or failure between the first load and the second load in the power storage device to be detected is detected.
For this reason, disconnection or failure between the first load and the second load in each of the plurality of power storage devices is reliably detected.

  The power supply system according to the present invention includes a plurality of diodes that prevent current from flowing from the second load to each of the plurality of connection nodes.

In the present invention, the plurality of diodes prevent current from flowing from the second load to the plurality of connection nodes between the switch and the power storage device in each of the plurality of power feeding paths.
For this reason, even when one of the plurality of power storage devices has a short circuit failure, the output terminal of the other power storage device is not short-circuited, and power is reliably supplied from the other power storage device to the second load.

  The power supply system according to the present invention is characterized in that when the detection means detects the non-connection or failure of at least one of the plurality of power storage devices, the power supply system includes notification means for notifying the non-connection or failure. .

  In the present invention, at least one of the plurality of power storage devices is notified when disconnection or failure between the first load and the second load is detected. It can be recognized.

  The power supply system according to the present invention is mounted on a vehicle, and the second load is an electrical device necessary for stopping the vehicle.

In the present invention, the system is mounted on a vehicle. In addition, when at least one of the plurality of power storage devices detects disconnection or failure between the first load and the second load, the other does not cause disconnection or failure between the first load and the second load. The second load fed from the power storage device is an electrical device necessary for stopping the vehicle.
For this reason, the driver | operator can stop a vehicle safely when a disconnection or a failure arises about at least one of the plurality of power storage devices.

  According to the present invention, since a switch is provided for each of a plurality of power supply paths for supplying power from the generator to each of the plurality of power storage devices, power can be supplied to a specific power storage device in the plurality of power storage devices.

1 is a block diagram illustrating a configuration of a main part of a power supply system according to Embodiment 1. FIG. It is a flowchart which shows the procedure of the operation | movement which a control part performs. It is a flowchart which shows the procedure of the operation | movement which a control part performs. It is a flowchart which shows the procedure of the operation | movement which a control part performs. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. 10 is a flowchart illustrating a procedure of an operation executed by a control unit in the second embodiment. 10 is a flowchart illustrating a procedure of an operation executed by a control unit in the second embodiment. 10 is a flowchart illustrating a procedure of an operation executed by a control unit in the second embodiment. 10 is a flowchart illustrating a procedure of an operation executed by a control unit in the second embodiment. It is explanatory drawing for demonstrating the electric power feeding to 1st load or 2nd load. It is a block diagram which shows the principal part structure of the conventional power supply system.

Hereinafter, the present invention will be described in detail with reference to the drawings illustrating embodiments thereof.
(Embodiment 1)
FIG. 1 is a block diagram showing a main configuration of the power supply system according to the first embodiment. The power supply system 1 is mounted on a vehicle, and includes an alternator 10, switches 11, 12, 13, and 14, a first load 15, a second load 16, a first power storage device 17, a second power storage device 18, a starter 19, A voltage detection unit 20, a current detection unit 21, a notification unit 22, a timer 23, a control unit 24, and diodes D1 and D2 are provided.

  One end of the alternator 10 is connected to one end of each of the switches 11, 12, 13 and the first load 15. The other end of each of the switches 11, 12 is the positive electrode of the first power storage device 17, one end of the starter 19, and a diode. It is connected to the anode of D1. The other end of the switch 13 is connected to one end of the switch 14 and the anode of the diode D2. The cathodes of the diodes D 1 and D 2 are connected to one end of the second load 16. The other end of the switch 14 is connected to the positive electrode of the second power storage device 18. The other ends of the alternator 10, the first load 15, the second load 16, and the starter 19 and the negative electrodes of the first power storage device 17 and the second power storage device 18 are grounded.

  The voltage detection unit 20 is connected to each positive electrode of the first power storage device 17 and the second power storage device 18. The control unit 24 is connected to the voltage detection unit 20, the current detection unit 21, the notification unit 22, and the timer 23, respectively.

  The alternator 10 functions as a generator. When a power generation instruction is input from the control unit 24, the alternator 10 generates regenerative power by converting kinetic energy of a vehicle on which the power supply system 1 is mounted into electric power. Specifically, the alternator 10 generates AC power and rectifies the generated AC power into DC power. The regenerative power generated by the alternator 10 is rectified power. The alternator 10 stops the generation of regenerative power when a stop instruction is input from the control unit 24.

  The regenerative power generated by the alternator 10 is supplied to the first load 15, the second load 16, the first power storage device 17 and the second power storage device 18. Alternator 10 directly supplies regenerative power to first load 15, supplies regenerative power to first power storage device 17 via switch 11, and supplies regenerative power to second power storage device 18 via switches 13 and 14. To do. The alternator 10 supplies regenerative power to the second load 16 via the switch 11 and the diode D1, and via the switch 13 and the diode D2.

The first power storage device 17 is, for example, a lead storage battery, and stores regenerative power supplied from the alternator 10 via the switch 11. The first power storage device 17 supplies the stored power to the first load 15 via the switch 11 and also to the second load 16 via the diode D1. Further, the electric power stored in the first power storage device 17 is supplied to the starter 19.
The starter 19 is a motor for starting the engine, and operates using the electric power stored in the first power storage device 17.

  The second power storage device 18 is a lithium battery, an electric double layer capacitor, or the like, and stores regenerative power supplied from the alternator 10 via the switches 13 and 14. The second power storage device 18 supplies the stored power to the first load 15 via the switches 14 and 13 and also supplies the second load 16 via the switch 14 and the diode D2.

  The first load 15 is supplied with power from the first power storage device 17 through the switch 11, and supplied with power from the second power storage device 18 through the switches 14 and 13. As described above, the first load 15 is supplied with power from a plurality of (two) power storage devices, that is, the first power storage device 17 and the second power storage device 18 through the switches 11 and 13, respectively. The first load 15 is supplied with regenerative power from the alternator 10.

  One end of the second load 16 is connected to a connection node between the first power storage device 17 and the switch 11 in a plurality of (two) power supply paths that supply power from the alternator 10 to each of the first power storage device 17 and the second power storage device 18. The second power storage device 18 and the connection node between the switches 13 are connected. The second load 16 is supplied with the power stored in the first power storage device 17 through the diode D1, and is supplied with the power stored in the second power storage device 18 through the switch 14 and the diode D2. The second load 16 is further supplied with regenerative power from the alternator 10 as described above.

The second load 16 is an electric device necessary for stopping the vehicle, and the first load 15 is an electric device other than the electric device.
For this reason, when a load is added to the power supply system 1 in addition to the first load 15 and the second load 16 due to the development of the vehicle type or the addition of options, the load other than the electric equipment necessary for stopping the vehicle is the first. It can be connected in the same way as the load 15, and redesign of the circuit is unnecessary.

  As described above, the power supply system 1 includes a plurality (two) of diodes D1 and D2. The diode D1 prevents a current from flowing from the second load 16 to a connection node between the switch 11 and the first power storage device 17, and the diode D2 prevents the switch 13 and the second power storage device from the second load 16. The current is prevented from flowing to the connection node between 18.

  The switches 11, 12, 13, and 14 are semiconductor switches or mechanical relays, and are turned on / off by the control unit 24. The switches 11 and 13 are provided separately in a plurality (two) of power feeding paths that feed power from the alternator 10 to the first power storage device 17 and the second power storage device 18, respectively. Connect and disconnect each.

  The switches 11 and 12 are off and on while the vehicle is parked with the IG (ignition) switch off. For this reason, dark current is supplied from the first power storage device 17 to the first load 15 via the switch 12. The switches 11 and 12 are turned on and off when the alternator 10 supplies power to the second load 16 and the first power storage device 17 and when the first power storage device 17 supplies power to the first load 15 in operation. . Since the current passing through the switch 11 is larger than the current passing through the switch 12, a smaller switch than the switch 11 can be used as the switch 12.

  The switch 12 is turned on when a voltage lower than a predetermined voltage is applied from the control unit 24, specifically, when a voltage is not applied from the control unit 24, and a voltage equal to or higher than the predetermined voltage from the control unit 24. This switch is turned off when is applied.

  In the power supply system 1 connected as described above, the switch provided in the power supply path from the alternator 10 to the power storage device to be fed in the first power storage device 17 and the second power storage device 18 is turned on. Therefore, it is possible to supply power to a specific power storage device by turning off a switch provided in a power supply path to the power storage device that should not be supplied with power.

  By turning on the switches 11, 13, and 14 and turning off the switch 12, regenerative power can be supplied from the alternator 10 to the first power storage device 17 and the second power storage device 18. By turning off the switches 11 and 12 and turning on the switches 13 and 14, regenerative power can be supplied from the alternator 10 to the second power storage device 18 without supplying power to the first power storage device 17. By turning on the switch 11 and turning off the switches 12, 13, and 14, regenerative power can be supplied from the alternator 10 to the first power storage device 17 without supplying power to the second power storage device 18.

  Further, since the alternator 10 is directly connected to the first load 15, power is supplied from the alternator 10 to the first load 15 even when the switches 11 and 13 are broken down. In addition, since no switch, for example, a semiconductor switch, is provided in the power supply path from the alternator 10 to the first load 15, there is no power loss and no heat generation in the switch.

The voltage detection unit 20 detects the output voltage of each of the first power storage device 17 and the second power storage device 18, and the detected voltage is read by the control unit 24. The voltage detection unit 20 functions as voltage detection means.
The current detection unit 21 detects input / output currents of the first power storage device 17 and the second power storage device 18 using a current sensor, and the detected current is read by the control unit 24. The current detection unit 21 functions as a current detection unit.
The current detection unit 21 may not detect the input / output currents of the first power storage device 17 and the second power storage device 18 using current sensors. For example, the current detection unit 21 may detect the input / output current of the first power storage device 17 from the voltage across the resistor connected between the other end of the switch 11 and the positive electrode of the first power storage device 17. Similarly, the current detection unit 21 detects, for example, the input / output current of the second power storage device 18 from the voltage across the resistor connected between the other end of the switch 14 and the positive electrode of the second power storage device 18. Good.

The notification unit 22 indicates that at least one of the first power storage device 17 and the second power storage device 18 is disconnected from the first load 15 and the second load 16 or has failed according to an instruction from the control unit 24. Inform. As an example, the notification unit 22 performs notification by displaying a message on a display unit (not shown). As another example, the notification unit 22 performs notification by turning on a lamp (not shown). Further, the notification unit 22 may notify by voice.
As a failure of the first power storage device 17 (or the second power storage device 18), a short circuit between the positive electrode and the negative electrode in the first power storage device 17 (or the second power storage device 18) and an open circuit between the positive electrode and the negative electrode are assumed. The
The timer 23 starts and ends timing in accordance with instructions from the control unit 24, and the time measured by the timer 23 is read by the control unit 24.

The control unit 24 receives travel information, a prior signal, first power storage rate information, second power storage rate information, and IG switch information. The travel information is information related to the travel of the vehicle and indicates at least one of the vehicle speed, the accelerator pedal depression amount, and the brake pedal depression amount. The prior signal is a signal that is input in advance when the starter 19 is operated to start the engine after the vehicle has stopped idling and the engine has stopped. The first power storage rate information indicates the power storage rate of the first power storage device 17, and the second power storage rate information indicates the power storage rate of the second power storage device 18. The IG switch information indicates whether the IG switch is off or on.
Hereinafter, the power storage rate of the first power storage device 17 is referred to as a first power storage rate, and the power storage rate of the second power storage device 18 is referred to as a second power storage rate.

  When first power storage device 17 (or second power storage device 18) is a capacitor, when a predetermined rate of withstand voltage, for example, 80% of voltage is applied to first power storage device 17 (or second power storage device 18). The power amount stored in the first power storage device 17 (or the second power storage device 18) is set in advance to be the power amount when the first power storage rate (or the second power storage rate) is 100%.

  The control unit 24 outputs a power generation instruction or a stop instruction to the alternator 10 based on the input travel information, first power storage rate information, and second power storage rate. Further, the control unit 24 switches based on the travel information, the advance signal, the first storage rate information, the second storage rate information, the IG switch information, the voltage detected by the voltage detection unit 20 and the current detected by the current detection unit 21. 11, 12, 13, 14 are turned on / off.

In addition, the control unit 24 performs the first load 15 and the first load on each of the first power storage device 17 and the second power storage device 18 based on the voltage detected by the voltage detection unit 20 or the current detected by the current detection unit 21. 2 Disconnection or failure with the load 16 is detected.
For this reason, the control part 24 can detect the disconnection or failure of the first load 15 and the second load 16 in the first power storage device 17 and the second power storage device 18 respectively. The control unit 24 functions as a detection unit.
Hereinafter, the non-connection of the first power storage device 17 (or the second power storage device 18) with the first load 15 and the second load 16 is also referred to as the non-connection of the first power storage device 17 (or the second power storage device 18). To do.

  When the switch 11 is on, the control unit 24 sets the first power storage device 17 to the first load 15 and the second load when the input / output current of the first power storage device 17 read from the current detection unit 21 is zero amperes. The load 16 is not connected, or it is determined that the failure is an open circuit between the positive electrode and the negative electrode of the first power storage device 17. In addition, when the switch 11 is on, the control unit 24 causes the first power storage device 17 to short-circuit when the input / output current of the first power storage device 17 read from the current detection unit 21 is equal to or greater than the threshold current. It is determined that The threshold current is sufficiently larger than the input / output current of the first power storage device 17 when the first power storage device 17 operates normally and the switch 11 is on.

  When the switch 11 is off and the output voltage of the first power storage device 17 read from the voltage detection unit 20 is less than the positive threshold voltage close to zero volts, the control unit 24 turns off the first power storage device 17. Determine connection or failure. Here, the failure includes an open failure and a short-circuit failure of the first power storage device 17.

  Similar to the first power storage device 17, the control unit 24 detects the disconnection or failure of the second power storage device 18. Here, the fact that the switch 11 is on corresponds to both the switches 13 and 14 being on, and the fact that the switch 11 is off corresponds to both the switches 13 and 14 being off and the first power storage. Device 17 corresponds to second power storage device 18.

  2 to 4 are flowcharts showing a procedure of operations executed by the control unit 24. 5 to 13 are explanatory diagrams for explaining power feeding to the first load 15 or the second load 16. Each of FIGS. 5 to 13 shows a configuration of the power supply system 1 excluding the voltage detection unit 20, the current detection unit 21, the notification unit 22, the timer 23, and the control unit 24, and arrows indicating the current flow. Has been.

  First, the control unit 24 determines whether or not the IG switch of the vehicle is on based on the input IG switch information (step S1). When the control unit 24 determines that the IG switch is not on, that is, is off (S1: NO), the control unit 24 turns off the switches 11, 13, and 14 (step S2), and turns on the switch 12 (step S3). ).

  When the IG switch is off and the vehicle is parked, the control unit 24 executes steps S2 and S3, so that the dark current is generated from the first power storage device 17 via the switch 12 as shown in FIG. The load 15 flows. Also in the second load 16, dark current flows from the first power storage device 17 to the second load 16 via the diode D1.

  After executing Step S <b> 3, the control unit 24 returns the process to Step S <b> 1, and the first power storage device 17 continues to flow dark current through the first load 15 and the second load 16 until the IG switch is turned on.

  When it determines with the IG switch being ON (S1: YES), the control part 24 determines whether the prior signal was input (step S4). When it determines with the prior signal having been input (S4: YES), the control part 24 turns off the switches 11 and 12 (step S5), and turns on the switches 13 and 14 (step S6).

  When the starter 19 is operated, the control unit 24 to which the advance signal is input executes steps S5 and S6, whereby the first power storage device 17 supplies power to the starter 19 as shown in FIG. 18 does not supply power to the starter 19. The first power storage device 17 supplies power to the second load 16 through the diode D1 in addition to the starter 19. The second power storage device 18 supplies power to the first load 15 via the switches 13 and 14 and supplies power to the second load 16 via the switch 14 and the diode D2. As a result, the starter 19 starts the engine, and the alternator 10 can generate power.

  After executing Step S6, the control unit 24 causes the timer 23 to start measuring time (Step S7), and determines whether or not the time measured by the timer 23 is equal to or longer than a predetermined time (Step S8). The predetermined time is a time sufficient for the starter 19 to start the engine after the advance signal is input to the control unit 24.

  When it is determined that the timed time is less than the predetermined time (S8: NO), the control unit 24 returns the process to step S8 and waits until the timed time becomes equal to or longer than the predetermined time. When it is determined that the measured time is equal to or longer than the predetermined time (S8: YES), the control unit 24 causes the timer 23 to finish measuring time (step S9).

  When it is determined that the advance signal is not input (S4: NO), or after executing step S9, the control unit 24 may generate regenerative power based on the input travel information. It is determined whether or not it is possible (step S10). In step S10, the control unit 24 determines that regenerative power can be generated when the input travel information indicates, for example, depression of the brake pedal and deceleration of the vehicle, and regenerative power is generated in other cases. It is determined that power cannot be generated. The determination in step S10 is not based on the first power storage rate and the second power storage rate.

  When it is determined that the regenerative power cannot be generated (S10: NO), the control unit 24 determines whether the second storage rate indicated by the input second storage rate information is a lower limit threshold, for example, 30% or less. It is determined whether or not (step S11). When it is determined that the second power storage rate is equal to or lower than the lower limit threshold value (S11: YES), the control unit 24 outputs a power generation stop instruction to the alternator 10 (step S12), and turns off the switches 12 and 14 (step S13). ), The switches 11 and 13 are turned on (step S14).

When the second power storage rate of the second power storage device 18 is equal to or lower than the lower limit threshold, the control unit 24 executes steps S13 and S14, so that as shown in FIG. Power is supplied to the second load 16 and the second power storage device 18 is not discharged. Thereby, the overdischarge of the 2nd electrical storage apparatus 18 is prevented.
The first load 15 is supplied with power from the first power storage device 17 via the switch 11, and the second load 16 is supplied with the first load via the diode D1, and via the switches 11 and 13 and the diode D2. Electric power is supplied from the power storage device 17.

When it is determined that the regenerative power can be generated (S10: YES), the control unit 24 has both the first storage rate and the second storage rate indicated by the first storage rate information and the second storage rate information, respectively. Then, it is determined whether or not the upper limit threshold is higher than the lower limit threshold, for example, 80% or more (step S15).
When the second power storage rate exceeds the lower limit threshold (S11: NO), or when it is determined that both the first power storage rate and the second power storage rate are equal to or higher than the upper limit threshold (S15: YES). Then, a power generation stop instruction is output to the alternator 10 (step S16). Then, the control unit 24 turns off the switches 11 and 12 (step S17) and turns on the switches 13 and 14 (step S18).

  As described above, the control unit 24 is not capable of generating regenerative power and the second power storage rate exceeds the lower limit threshold, or can generate regenerative power. When both the power storage rate and the second power storage rate are equal to or higher than the upper limit threshold value, steps S17 and S18 are executed. As shown in FIG. 8, the control unit 24 executes steps S17 and S18 to supply power from the second power storage device 18 to the first load 15 and the second load 16, and from the first power storage device 17 via the diode D1. Then, power is supplied to the second load 16. The first load 15 is supplied with power from the second power storage device 18 via the switches 14 and 13, and the second load 16 is supplied with power from the second power storage device 18 via the switch 14 and the diode D2. The

  When it is determined that the first power storage rate and the second power storage rate are not equal to or higher than the upper limit threshold value (S15: NO), the control unit 24 outputs a power generation instruction to the alternator 10 (step S19). Thereby, the alternator 10 generates regenerative power. Next, the control unit 24 determines whether or not both the first and second storage rates indicated by the input first and second storage rate information are less than the upper limit threshold (step S20). ). When it is determined that the first power storage rate and the second power storage rate are both lower than the upper limit threshold value (S20: YES), the control unit 24 turns off the switch 12 (step S21) and turns on the switches 11, 13, and 14. (Step S22).

  When the alternator 10 generates regenerative power and both the first power storage rate and the second power storage rate are less than the upper limit threshold, the control unit 24 executes steps S21 and S22, as shown in FIG. Supplies regenerative power to the first load 15, the second load 16, the first power storage device 17 and the second power storage device 18. The first load 15 is directly supplied with regenerative power from the alternator 10, and the second load 16 is supplied with regenerative power from the alternator 10 via the switch 11 and the diode D1, and via the switch 13 and the diode D2. Supplied. Regenerative power is supplied from the alternator 10 to the first power storage device 17 via the switch 11, and regenerative power is supplied to the second power storage device 18 from the alternator 10 via the switches 13 and 14.

  When it is determined that both the first power storage rate and the second power storage rate are not less than the upper limit threshold (S20: NO), the control unit 24 determines whether the first power storage rate is less than the upper limit threshold (step S23). ). When it is determined that the first power storage rate is less than the upper threshold value, that is, the second power storage rate is equal to or higher than the upper threshold value (S23: YES), the control unit 24 turns off the switches 12 and 14 (step S24). The switches 11 and 13 are turned on (step S25).

  When the alternator 10 generates regenerative power and the first power storage rate is less than the upper limit threshold, the control unit 24 executes steps S24 and S25, so that the alternator 10 generates the regenerative power as shown in FIG. The load 15, the second load 16, and the first power storage device 17 are supplied. The first load 15, the second load 16, and the first power storage device 17 receive regenerative power in the same manner as when the alternator 10 generates regenerative power and both the first power storage rate and the second power storage rate are less than the upper limit threshold. Supplied. No regenerative power is supplied to the second power storage device 18.

  When it is determined that the first power storage rate is equal to or higher than the upper limit threshold, that is, the second power storage rate is lower than the upper threshold (S23: NO), the control unit 24 turns off the switches 11 and 12 (step S26). The switches 13 and 14 are turned on (step S27).

  When the alternator 10 generates regenerative power and the second power storage rate is less than the upper limit threshold, the control unit 24 executes steps S26 and S27, so that the alternator 10 generates the regenerative power first as shown in FIG. This is supplied to the load 15, the second load 16, and the second power storage device 18. The first load 15, the second load 16, and the second power storage device 18 receive regenerative power in the same manner as when the alternator 10 generates regenerative power and both the first power storage rate and the second power storage rate are less than the upper limit threshold. Supplied. No regenerative power is supplied to the first power storage device 17.

  As described above, the control unit 24 determines whether the power storage rates of the first power storage device 17 and the second power storage device 18 are less than the upper limit threshold based on the input first power storage rate information and second power storage rate information. Determine whether or not. The control unit 24 also functions as a determination unit.

  Further, as described above, when the alternator 10 is generating electric power according to the output of the power generation instruction, the control unit 24 determines whether the storage rate from the alternator 10 is within the first power storage device 17 and the second power storage device 18. A switch provided in one or a plurality of power supply paths for supplying power to the power storage device determined to be less than the upper threshold is turned on. In the same situation, the control unit 24 supplies one or a plurality of power supplies that are supplied from the alternator 10 to the power storage device that is determined to have a power storage rate that is equal to or higher than the upper limit threshold among the first power storage device 17 and the second power storage device 18. A switch provided in the route is turned off. Thereby, in the 1st electrical storage apparatus 17 and the 2nd electrical storage apparatus 18, an electrical storage rate is less than an upper limit threshold value without charging one or more electrical storage apparatuses whose electrical storage rate is more than an upper limit threshold value. The power storage device can be charged. Therefore, one or a plurality of power storage devices having a power storage rate equal to or higher than the upper limit threshold will not be overcharged. The control unit 24 also functions as on / off means.

  After executing any one of steps S14, S18, S22, S25, and S27, the control unit 24 performs the first operation based on the voltage detected by the voltage detection unit 20 or the current detected by the current detection unit 21. It is determined whether or not a disconnection or failure of the power storage device 17 has been detected (step S28). When it is determined that the disconnection or failure of the first power storage device 17 is detected (S28: YES), the control unit 24 turns off the switches 11, 12, and 13 (step S29) and turns on the switch 14 (step S30). ) Instructing the notification unit 22 notifies the disconnection or failure of the first power storage device 17 (step S31).

When the disconnection or failure of the first power storage device 17 occurs, the control unit 24 executes the switches S29 and S30, so that the second power storage device 18 passes through the switch 14 and the diode D2 as shown in FIG. Power is supplied to the second load 16 and power is not supplied to the first load 15.
The control part 24 complete | finishes a process, after performing step S31.

  When it is determined that the disconnection or failure of the first power storage device 17 is not detected (S28: NO), the control unit 24 uses the voltage detected by the voltage detection unit 20 or the current detected by the current detection unit 21. Based on this, it is determined whether or not a disconnection or failure of the second power storage device 18 has been detected (step S32). When it is determined that the disconnection or failure of the second power storage device 18 is detected (S32: YES), the control unit 24 turns off the switches 11 to 14 (step S33) and instructs the notification unit 22 to The disconnection or failure of the power storage device 18 is notified (step S34).

When the connection or failure of the second power storage device 18 occurs, the control unit 24 executes the switch S33, so that the first power storage device 17 is connected to the second load 16 via the diode D1, as shown in FIG. Power is supplied and the first load 15 is not supplied.
The control part 24 complete | finishes a process, after performing step S34.

  Moreover, when it determines with the control part 24 not detecting the disconnection or failure of the 2nd electrical storage apparatus 18 (S32: NO), a process is complete | finished and a process is restarted from step S1.

  As described above, when the control unit 24 detects the disconnection or failure of the first load 15 and the second load 16 in at least one of the first power storage device 17 and the second power storage device 18, the switch 11 , 12 and 13 are turned off, and the notification unit 22 notifies disconnection or failure. As a result, when any one of the first power storage device 17 and the second power storage device 18 is disconnected or failed with the first load 15 and the second load 16, the power storage device that is not disconnected or failed is The first load 15 is not supplied with power, and the second load 16 necessary for stopping the vehicle is supplied with power. Therefore, it is possible to continue supplying power to the second load 16 for a longer time, and the driver can stop the vehicle more safely. In addition, the driver can be made aware of the emergency situation by notifying of disconnection or failure. The control unit 24 also functions as an off unit, and the notification unit 22 functions as a notification unit.

  Furthermore, since the diodes D1 and D2 are provided, even if the failure that has occurred in either the first power storage device 17 or the second power storage device 18 is a short-circuit failure, The output terminal is not short-circuited, and power is reliably supplied to the second load 16.

(Embodiment 2)
In the first embodiment, when the alternator 10 is not capable of generating regenerative power, the second power storage device 18 has the first load 15 and the second load 16 when the second power storage rate exceeds the lower limit threshold. The first power storage device 17 supplies power to the first load 15 and the second load 16 when the second power storage rate is equal to or lower than the lower limit threshold. However, when the alternator 10 is not capable of generating regenerative power, both the first power storage device 17 and the second power storage device 18 may supply power to the first load 15 and the second load 16.

  14 to 17 are flowcharts showing the procedure of the operation executed by the control unit 24 in the second embodiment. The main part configuration of power supply system 1 in the second embodiment is the same as that of power supply system 1 in the first embodiment shown in FIG. Below, the operation | movement which the control part 24 in Embodiment 2 performs is demonstrated.

  Steps S41 to S54 and S63 to S78 executed by the control unit 24 in the second embodiment are the same as steps S1 to S14 and S19 to S34 executed by the control unit 24 in the first embodiment, and thus description thereof is omitted. To do. FIG. 18 is an explanatory diagram for explaining power feeding to the first load 15 or the second load 16. FIG. 18 shows a configuration excluding the voltage detection unit 20, the current detection unit 21, the notification unit 22, the timer 23, and the control unit 24 in the power supply system 1, and arrows indicating the current flow.

  In the second embodiment, when the second power storage rate exceeds the lower limit threshold (S51: NO), the first power storage rate indicated by the input first power storage rate information is the lower limit threshold, for example, 30% or less. It is determined whether or not (step S55). When it is determined that the first power storage rate is equal to or lower than the lower threshold (S55: YES), the control unit 24 outputs a power generation stop instruction to the alternator 10 (step S56), and turns off the switches 11 and 12 (step S57). ), Switches 13 and 14 are turned on (step S58).

When the first power storage rate of the first power storage device 17 is equal to or lower than the lower limit threshold, the control unit 24 executes steps S57 and S58, whereby the first power storage device 17 is connected via the diode D1 as shown in FIG. Power is supplied only to the second load 16, and the second power storage device 18 supplies power to the first load 15 and the second load 16. The electric power of the second power storage device 18 is mainly consumed. Thereby, the overdischarge of the 1st electrical storage apparatus 17 is prevented.
The first load 15 is supplied with power from the second power storage device 18 via the switches 14 and 13, and the second load 16 is supplied with power from the second power storage device 18 via the switch 14 and the diode D2. The

When it is determined that the regenerative power can be generated (S50: YES), the control unit 24 has both the first storage rate and the second storage rate indicated by the first storage rate information and the second storage rate information, respectively. It is determined whether or not the upper limit threshold is exceeded (step S59). When it is determined that the first power storage rate and the second power storage rate are not more than the upper limit threshold value (S59: NO), the control unit 24 executes Step S63.
When the first power storage rate exceeds the lower limit threshold value (S55: NO), or when it is determined that both the first power storage rate and the second power storage rate are equal to or higher than the upper limit threshold value (S59: YES). Then, a power generation stop instruction is output to the alternator 10 (step S60). Then, the control unit 24 turns off the switch 12 (step S61) and turns on the switches 11, 13, and 14 (step S62).

  As described above, the control unit 24 is not capable of generating regenerative power and can generate regenerative power when the first power storage rate and the second power storage rate exceed the lower limit threshold value. However, if both the first power storage rate and the second power storage rate are greater than or equal to the upper limit threshold, steps S61 and S62 are executed. When the control unit 24 executes steps S61 and S62, power is supplied from the first power storage device 17 and the second power storage device 18 to the first load 15 and the second load 16, as shown in FIG.

The first load 15 is supplied with electric power from the first power storage device 17 via the switch 11 and is supplied with power from the second power storage device 18 via the switches 14 and 13. The second load 16 is supplied with power from the first power storage device 17 via the diode D1, and is also supplied with power from the second power storage device 18 via the switch 14 and the diode D2.
The control unit 24 executes Step S72 after executing any one of Steps S54, S58, S62, S66, S69, and S71.

  Other processes performed by the control unit 24 in the second embodiment are the same as the processes performed by the control unit 24 in the first embodiment as described above. Therefore, the power supply system 1 in the second embodiment also has the same effect as the power supply system 1 in the first embodiment.

  In the first and second embodiments, the voltage and current detected by the voltage detection unit 20 when the first power storage device 17 and the second power storage device 18 are disconnected or malfunctioned from the first load 15 and the second load 16 respectively. The detection may not be performed based on the current detected by the detection unit 21. Further, the upper limit threshold and the lower limit threshold may be different for each of the first power storage device 17 and the second power storage device 18.

  Further, the second load 16 may be connected in the same manner as the first load 15. Even in this case, when the alternator 10 is generating electric power, the switches 11 to 14 are turned on / off as in the first and second embodiments. Thereby, in the 1st electrical storage apparatus 17 and the 2nd electrical storage apparatus 18, the electrical storage rate is less than an upper limit threshold value, without charging the electrical storage rate which is more than an upper limit threshold value, or one or more The power storage device can be charged.

  Furthermore, the number of power storage devices included in the power supply system 1 is not limited to two and may be three or more. In this case, the third and subsequent power storage devices are connected to the first load 15 via two switches and to the second load 16 via a diode and a switch, as with the second power storage device 17. Accordingly, a switch is provided for each of the plurality of power supply paths that supply power from the alternator 10 to each of the plurality of power storage devices, and these switches connect and disconnect each of the plurality of power supply paths.

  In addition, each of the voltage detection unit 20 and the current detection unit 21 detects the current and voltage in the same manner as the current and voltage related to the second power storage device 17. The control unit 24 can supply power to a specific power storage device in the plurality of power storage devices by turning on / off the plurality of switches in the same manner as in the first or second embodiment. The same effects as those of Embodiments 1 and 2 are obtained.

  The disclosed first and second embodiments are examples in all respects and should not be considered as restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

1 Power supply system 10 Alternator (generator)
DESCRIPTION OF SYMBOLS 11, 13 Switch 15 1st load 16 2nd load 17 1st electrical storage apparatus 18 2nd electrical storage apparatus 20 Current detection part (current detection means)
21 Voltage detector (voltage detection means)
22 Notification unit (notification means)
24 Control unit (determination means, on / off means, detection means, off means)
D1, D2 diode

Claims (7)

In a power supply system in which power generated by a generator is supplied to a plurality of power storage devices,
A power supply system comprising: a plurality of switches that are separately provided in a plurality of power supply paths that supply power to each of the plurality of power storage devices from the generator, and that connect and disconnect each of the plurality of power supply paths. Determining means for determining whether or not a storage rate of each of the plurality of power storage devices is less than a threshold;
When the generator is generating power,
From the generator, one or a plurality of switches provided separately for each of one or a plurality of power supply paths to be supplied to each of one or a plurality of power storage devices determined by the determination means to be less than a threshold,
On / off means for turning off one or a plurality of switches respectively provided in one or a plurality of power supply paths for supplying power from the generator to one or a plurality of power storage devices determined by the determination means to be equal to or greater than a threshold value The power supply system according to claim 1, further comprising: A first load fed from each of the plurality of power storage devices via each of the plurality of switches;
A second load having one end connected to a plurality of connection nodes between the power storage device and the switch in each of the plurality of power supply paths;
Detecting means for detecting disconnection or failure of the first load and the second load in each of the plurality of power storage devices;
2. The off means for turning off the plurality of switches when the non-connection or failure is detected for at least one of the plurality of power storage devices. 2. The power supply system according to 2. Current detection means for detecting input / output current of each of the plurality of power storage devices;
Voltage detecting means for detecting an output voltage of each of the plurality of power storage devices,
The said detection means is comprised so that the said non-connection or a failure may be detected based on the electric current which the said current detection part detected, or the voltage which the said voltage detection means detected. Power system. The power supply system according to claim 3, further comprising: a plurality of diodes that prevent current from flowing from the second load to each of the plurality of connection nodes. The said detection means is provided with the alerting | reporting means which alert | reports this non-connection or a failure, when the said non-connection or a failure is detected about at least 1 among these some electrical storage apparatuses. The power supply system as described in any one. Mounted on the vehicle,
The power supply system according to any one of claims 3 to 6, wherein the second load is an electric device necessary for stopping the vehicle.

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