JP4876773B2 - Power supply - Google Patents

Description

  The present invention relates to a power supply apparatus that supplementarily supplies power from a power storage unit to a load.

  In recent years, automobiles equipped with an idling stop function for stopping the engine drive when the vehicle stops and an electric power steering for reducing the engine load have been put on the market in order to consider the environment and improve fuel efficiency. In addition, hybrid systems and electric turbo systems for actively supplementing engine driving are expected to become popular in the future. Furthermore, a regenerative braking system that recovers braking energy as electric energy has been proposed for braking the vehicle.

  In this way, the power required by automobiles in the future tends to increase significantly, but it is difficult to supply a large amount of power only with a battery that is a conventional power supply source, so the system cannot be operated sufficiently. There was sex.

  On the other hand, for example, Patent Document 1 proposes a power supply device as an auxiliary power supply for a regenerative brake system. A block circuit diagram of such a power supply apparatus is shown in FIG. A constant voltage source 101 made of a battery is connected to a power storage unit 105 made of a secondary battery via a bidirectional DC / DC converter 103. The power storage unit 105 is also connected to a multi-phase induction machine for power generation and vehicle drive assistance (not shown). Therefore, the power storage unit 105 is configured to have a higher voltage than the constant voltage source 101 in order to charge power from the multiphase induction machine or drive the multiphase induction machine as a motor.

  The bidirectional DC / DC converter 103 includes a smoothing capacitor 106, a choke coil 107, a first switching element 109, a second switching element 111, and a control unit 113 wired as shown in FIG. It is a configuration.

  Next, the operation of the power supply device will be described. Electric energy generated by vehicle braking is charged in power storage unit 105. A part of the charging power may be charged to the constant voltage source 101 by driving the bidirectional DC / DC converter 103. As a result, the constant voltage source 101 can always be fully charged.

Next, when the vehicle braking is finished and acceleration is performed, the power of the power storage unit 105 is supplied to the multiphase induction machine in addition to the driving force of the engine to drive the vehicle auxiliary. With such an operation, vehicle braking energy can be regenerated and used as auxiliary power, so that a highly efficient vehicle can be realized.
Japanese Patent No. 1877239

  Such a power supply device can surely use braking energy effectively, so that the efficiency of the vehicle can be improved. However, the secondary battery constituting the power storage unit 105 that has been used in the past is instantaneous as in vehicle braking. Therefore, there is a disadvantage that a sufficient electric power cannot be charged and the charge / discharge cycle life is short. In order to compensate for this, a configuration in which a large-capacity capacitor typified by an electric double layer capacitor is used for the power storage unit 105 instead of the secondary battery has been proposed. Thereby, the shortcomings of the secondary battery can be compensated.

  However, when a capacitor is used for the power storage unit 105 in the configuration of the conventional power supply device, if the power storage unit 105 is almost fully charged at the end of use of the vehicle and the ignition switch is turned off in this state, a high voltage is applied to the capacitor. Will be left as it is applied. Capacitors have the property of shortening the life when left in a high voltage state close to the rating, so using a capacitor in a conventional power supply configuration shortens the life of the capacitor and impairs the reliability of the power supply. There was a problem.

  The present invention solves the above-described conventional problems, and an object thereof is to provide a power supply device that can ensure high reliability.

  In order to solve the conventional problem, a power supply device according to the present invention includes a bidirectional DC / DC converter having one end connected to a connection point between a constant voltage source and a load, and the other end of the bidirectional DC / DC converter. When the power supply device is stopped, the power storage device is discharged until the voltage of the power storage unit is substantially equal to the voltage of the constant voltage source, and the power supply device is stopped. A voltage is applied from the constant voltage source to the power storage unit so as to maintain the voltage of the power storage unit after being discharged when stopping. Thereby, while the power supply device is stopped, the power storage unit is left in a state where the voltage is lower than that in the fully charged state, so that the life of the power storage unit can be extended accordingly. As a result, the object can be achieved.

  The power supply device of the present invention includes a step-down DC / DC converter connected to a power generation unit, a constant voltage source connected to the step-down DC / DC converter, and a connection point between the step-down DC / DC converter and the power generation unit. The power storage unit is connected to the battery, and when stopping, the power storage unit is discharged until the voltage of the power storage unit becomes substantially equal to the voltage of the constant voltage source. A voltage is applied from the constant voltage source to the power storage unit so as to maintain the voltage of the power storage unit. This also allows the power storage unit to be left in a state where the voltage is lower than the fully charged state while the power supply device is stopped, so that the life of the power storage unit can be extended accordingly. As a result, the object can be achieved.

  The power supply device of the present invention is connected to a step-up DC / DC converter connected to a constant voltage source, a load connected to the step-up DC / DC converter, and a connection point between the step-up DC / DC converter and the load. The power storage unit is discharged until the voltage of the power storage unit becomes substantially equal to the voltage of the constant voltage source when stopping, and while the power is being stopped, A voltage is applied from the constant voltage source to the power storage unit so as to maintain the voltage of the power storage unit. This also allows the power storage unit to be left in a state where the voltage is lower than the fully charged state while the power supply device is stopped, so that the life of the power storage unit can be extended accordingly. As a result, the object can be achieved.

  According to the power supply device of the present invention, since the life of the power storage unit can be extended, a power supply device that can ensure high reliability can be realized.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block circuit diagram of a power supply device according to Embodiment 1 of the present invention. FIG. 2 is a detailed circuit diagram of the power storage unit when the power storage elements of the power supply device according to Embodiment 1 of the present invention are connected in series. FIG. 3 is a detailed circuit diagram of the power storage unit when the power storage elements of the power supply device according to Embodiment 1 of the present invention are connected in series-parallel. In the first embodiment, a case of a power supply device used as an auxiliary power supply for a vehicle will be described, for example.

  In FIG. 1, a constant voltage source 1 composed of a battery is connected to a load 3 composed of various electrical systems that require power from an auxiliary power source. One end of a bidirectional DC / DC converter 5 corresponding to a charge / discharge circuit is connected to a connection point between the constant voltage source 1 and the load 3. The other end of the bidirectional DC / DC converter 5 is connected to a power storage unit 7 made of an electric double layer capacitor.

  Here, details of the bidirectional DC / DC converter 5 will be described.

  The bidirectional DC / DC converter 5 boosts the voltage on the constant voltage source 1 side and outputs it to the power storage unit 7 side, and steps down the voltage on the power storage unit 7 side and outputs it to the constant voltage source 1 side or the load 3 side. Can be performed. As a specific configuration, a smoothing capacitor 9 is connected between the input / output terminal of the bidirectional DC / DC converter 5 connected to the constant voltage source 1 and the ground. The input / output terminal is connected to the power storage unit 7 via the choke coil 11 and the first switching element 13. A second switching element 15 is connected to a connection point between the choke coil 11 and the first switching element 13 between the ground. The first switching element 13 and the second switching element 15 are on / off controlled by the control unit 17. Note that switching between step-up and step-down of the bidirectional DC / DC converter 5 is performed by a signal from a vehicle-side external control circuit (hereinafter referred to as an external ECU) (not shown). Since both the first switching element 13 and the second switching element 15 are composed of FETs, the first body diode 19 and the second body diode 21 indicated by the dotted lines in FIG. 1 are formed.

  Next, the detailed structure of the electrical storage part 7 is demonstrated, referring FIG. 2, FIG.

  The power storage unit 7 has a configuration in which a plurality of power storage elements are connected in series or in series-parallel, and FIG. 2 shows the case of series connection and FIG. 3 shows the case of series-parallel connection. Note that which connection or how many connections should be made may be appropriately determined according to the power specifications required by the load 3. In the first embodiment, it is assumed that the rated full charge voltage (for example, 30 V) of the power storage unit 7 is higher than the rated voltage (for example, 14 V) of the constant voltage source 1.

  A voltage balance circuit 29 configured by, for example, a Zener diode 25 and a resistor 27 connected in series is connected to both ends of the power storage element 23 corresponding to the series connection in the power storage element 23. Specifically, in the case of FIG. 2, since all the storage elements 23 are connected in series, the voltage balance circuit 29 is connected to both ends of each storage element 23. On the other hand, in the case of FIG. 3, the portion corresponding to the series connection is a vertical connection point (series connection point) in FIG. That is, since the horizontal connection points (parallel connection points) are all at the same voltage, it is not necessary to provide the voltage balance circuit 29 for each storage element 23 of the equal voltage. Therefore, the voltage balance circuit 29 may be provided only at one end of any one of the equipotential (lateral) storage elements 23, that is, at both ends (series connection points) of the portion corresponding to the series connection. .

  The voltage balance circuit 29 is for adjusting the voltage across the storage element 23 to be equal to each other, and is adjusted so that the voltage across the storage element 23 is equalized by the resistor 27 having the same resistance value. Here, since the Zener diode 25 is connected in series to the resistor 27, the Zener diode 25 is turned on only when the set voltage is higher than the set voltage so that the voltage balance is adjusted. This adjustment will be described based on a specific example.

  For example, in the configuration of FIG. 2, if the rated voltage of the power storage element 23 is 2.5V, the set voltage for turning on the Zener diode 25 may be 2.5V or less as a precondition. Further, since the full charge voltage of the power storage unit 7 is 30 V, which is about twice the rated voltage 14 V of the constant voltage source 1 (battery), the number of the power storage elements 23 is 12 (= 30 V / 2.5 V). .

  Here, as will be described later, while the power supply device is stopped, the power storage unit 7 receives the voltage drop ΔV (= 0.7 V) of the first body diode 19 from the voltage Vb (= 14 V) of the constant voltage source 1. The subtracted voltage Vc (= 13.3 V) is always applied. If the zener diode 25 is on at this time, the current flows through the resistor 27 although the voltage balance between the power storage elements 23 can be obtained, the leakage current increases and the loss increases. Therefore, in order to avoid this, the set voltage at which the Zener diode 25 is turned on is set to be substantially equal to the applied voltage Vc to the power storage unit 7 during the stop period of the power supply device. That is, the set voltage of the Zener diode 25 was 1.1 V (≈13.3 V / 12 pieces). This value satisfies the precondition (2.5 V or less) of the set voltage described above. As a result, when the voltage across the storage element 23 becomes 1.1 V or more, the Zener diode 25 is turned on, and a current flows through the resistor 27, whereby the voltage balance of each storage element 23 can be adjusted.

  Therefore, in general, the voltage balance circuit 29 sets the number of voltage balance circuits 29 to n (n = 12 in the above specific example) and the voltage of the power storage unit 7 while the power supply is stopped to Vc (the above specific example). Assuming that Vc = 13.3V in the example, when the voltage between both ends of the power storage element 23 corresponding to the series connection is approximately Vc / n or more (13.3V / 12 pieces≈1.1V or more in the above specific example), An operation of discharging the element 23 is performed. Therefore, the voltage balance circuit 29 is not limited to the configuration in which the Zener diode 25 and the resistor 27 are connected in series as long as the above operation can be performed. However, the voltage of the first embodiment is simplified due to the simplicity of the circuit configuration. A balance circuit 29 is preferred.

  Next, the operation of such a power supply device will be described.

  First, the case where the use of the vehicle is terminated and the power supply device is stopped will be described. Before turning off the ignition switch (not shown) of the vehicle, the power storage unit 7 is fully charged so that power can be supplied to the load 3 at any time. At this time, the voltage Vc of the power storage unit 7 is higher than the rated voltage Vb of the constant voltage source 1. In this state, when the ignition switch is turned off, an external ECU (not shown) sends a signal for causing the bidirectional DC / DC converter 5 to perform a step-down operation to the control unit 17. In response to this, the bidirectional DC / DC converter 5 performs an operation of stepping down the voltage Vc of the power storage unit 7 and outputting it to the constant voltage source 1 side. The driving power of the bidirectional DC / DC converter 5 at this time is supplied from the power storage unit 7. As a result, the voltage Vc of the power storage unit 7 can be lowered and the power consumption of the constant voltage source 1 can be suppressed.

  When the bidirectional DC / DC converter 5 operates, the power storage unit 7 is discharged, and the constant voltage source 1 is charged with the electric power. This is because the load 3 is also turned off when the ignition switch is turned off, so that the power output from the bidirectional DC / DC converter 5 does not reach the load 3 and the constant voltage source 1 is charged. The Thus, by discharging the electric power of the power storage unit 7 and charging the constant voltage source 1, the following two effects can be obtained.

  1) The life of the power storage element 23 constituting the power storage unit 7 is shortened when left in a fully charged state. Therefore, when the power supply device is stopped, the life can be extended by discharging below the rated voltage, and high reliability is obtained. It is done.

  2) Since the constant voltage source 1 is charged with the electric power discharged from the power storage unit 7, the waste of power can be prevented, and the power storage unit 7 supplies power for maintaining the voltage to the power storage unit 7 during a stop period to be described later. This can be partially covered by the discharged power, improving efficiency.

  Next, the control unit 17 monitors the voltage Vc of the power storage unit 7 and the voltage Vb of the constant voltage source 1 while the power storage unit 7 is being discharged. Eventually, when the voltage Vc of the power storage unit 7 becomes substantially equal to the voltage Vb of the constant voltage source 1, the step-down operation of the bidirectional DC / DC converter 5 is stopped. The reason why the voltage Vc is set to be substantially equal to the voltage Vb as the stop condition is as follows.

  First, as a result of discharging the power storage unit 7 when the power supply device is stopped, the voltage Vc is substantially equal to the voltage Vb (14V) of the constant voltage source 1 but slightly larger, for example, 15V, the first body diode 19 is turned off. Thus, the voltage of the constant voltage source 1 is not applied to the power storage unit 7. However, the voltage across the storage element 23 is 1.25V (= 15V ÷ 12), which is larger than the set voltage (1.1V) of the Zener diode 25, so that the Zener diode 25 is turned on. As a result, a current flows from each power storage element 23 to the resistor 27, and the voltage at both ends decreases. As a result, the voltage Vc of the power storage unit 7 will eventually drop, so the first body diode 19 is turned on, a voltage obtained by subtracting the voltage drop ΔV from the voltage Vb of the constant voltage source 1 is applied, and the voltage is maintained. become.

  On the other hand, it is assumed that the voltage Vc is substantially the same as the voltage Vb (14 V) of the constant voltage source 1 but is slightly smaller, for example, 13 V as a result of discharging the power storage unit 7 when the power supply device is stopped. At this time, since the first body diode 19 is turned on, a voltage obtained by subtracting the voltage drop ΔV from the voltage Vb of the constant voltage source 1 is applied, and the power storage unit 7 is charged until the voltage is reached and then maintained. become.

  From the above, it can be seen that the voltage Vc of the power storage unit 7 is maintained and controlled at a constant value, so that it is not necessary to make the voltage Vc of the power storage unit 7 exactly equal to the voltage Vb of the constant voltage source 1 at the time of discharging. .

  In order to extend the life of the power storage unit 7, it is conceivable that the power storage unit 7 is completely discharged. However, the power storage unit 7 is discharged to 13.3V as in the case of the complete discharge. In some cases, there was no significant difference in the life of the electricity storage element 23, and therefore it is not necessary to discharge completely. Further, if the battery is completely discharged, the next time the vehicle is started, the voltage difference between the voltage Vc of the power storage unit 7 and the voltage Vb of the constant voltage source 1 becomes large, so that an inrush current flows. The element may break beyond the rated current. On the other hand, by maintaining the voltage Vc of the power storage unit 7 substantially equal to the voltage Vb of the constant voltage source 1 as in the first embodiment, the inrush current at the time of startup can be extremely suppressed, and high reliability can be obtained. .

  Next, when the discharge of power storage unit 7 is completed, bidirectional DC / DC converter 5 stops its operation. As a result, the first switching element 13 and the second switching element 15 are turned off. However, since the first body diode 19 and the second body diode 21 are respectively formed, the power supply device is stopped. Also, the voltage Vb of the constant voltage source 1 is applied to the power storage unit 7 via the first body diode 19. However, since there is a voltage drop ΔV due to the first body diode 19, the voltage Vc applied to the power storage unit 7 as described above is a voltage (13.3 V) obtained by subtracting the voltage drop ΔV from the voltage Vb of the constant voltage source 1. It becomes. Since the second body diode 21 is reversely connected to the constant voltage source 1, no current flows through the second body diode 21.

  In this way, while the power supply device is stopped due to the end of use of the vehicle, a voltage is applied from the constant voltage source 1 to the power storage unit 7 so as to always maintain the voltage Vc of the power storage unit 7 after being discharged when stopped. The This is based on the following operation.

  During the stop period of the power supply device, the voltage across each storage element 23 decreases due to natural discharge. Thus, when the voltage between both ends is lower than the set voltage (1.1 V) of the Zener diode 25, the Zener diode 25 is turned off. As a result, the voltage-reduced power storage element 23 is charged by the voltage Vc applied to the power storage unit 7. As this charging power, a part of the power charged in the constant voltage source 1 is used when the power supply apparatus is stopped, so that it is possible to prevent inrush current while reducing waste of discharging power. . Further, when the balance between the voltages at both ends of the power storage element 23 is substantially equal, the voltage at both ends of the power storage element 23 is lower than the set voltage of the Zener diode 25 and all the Zener diodes 25 are turned off. Is no longer consumed.

  By repeating such an operation, the voltage Vc of the power storage unit 7 is always maintained.

  In the first embodiment, the power storage unit 7 is discharged by the bidirectional DC / DC converter 5, but the power storage unit 7 may be discharged by the balance circuit 29 connected in parallel to the power storage element 23.

  Next, a case where the vehicle is restarted will be described.

  When the ignition switch is turned on to restart the vehicle, the power supply device is activated, and an external ECU on the vehicle side sends a signal for performing a boosting operation for charging the power storage unit 7 to 30 V to the control unit 17. In response to this, the power supply device boosts the voltage Vb of the constant voltage source 1 by the bidirectional DC / DC converter 5 and starts charging until the voltage of the power storage unit 7 reaches 30V. At that time, since the voltage of the power storage unit 7 is already 13.3 V, the inrush current can be greatly reduced as compared with the case where the fully discharged power storage unit 7 is charged. Therefore, deterioration of the bidirectional DC / DC converter 5 and the power storage unit 7 can be reduced, and high reliability can be obtained. Furthermore, since the power storage unit 7 is charged to 13.3 V in advance, the time until full charge can be shortened.

  When charging of power storage unit 7 is completed, bidirectional DC / DC converter 5 stops its operation. At this time, the first body diode 19 is turned off because Vc> Vb, and the power charged in the power storage unit 7 is not supplied to the constant voltage source 1 or the load 3.

  Thereafter, when the voltage of the constant voltage source 1 falls below a predetermined value, for example, when the constant voltage source 1 becomes abnormal or the load 3 instantaneously consumes a large current, the external ECU performs a step-down operation on the control unit 17. Send a signal to do. In response, the bidirectional DC / DC converter 5 steps down the voltage Vc of the power storage unit 7 to the rated voltage (14V) of the constant voltage source 1 and supplies it to the load 3. At this time, a part of the electric power is also supplied to the constant voltage source 1, but since the load 3 consumes a larger current, most of the electric power of the power storage unit 7 is supplied to the load 3.

  When the large current consumption of the load 3 is completed, the bidirectional DC / DC converter 5 performs a boosting operation for fully charging the power storage unit 7 again. Since this operation is the same as when the vehicle is restarted, description thereof is omitted. By repeating such an operation while the vehicle is in use, the power storage unit 7 prepares to supply power to the load 3 at any time.

  The operation after the end of vehicle use is as described above.

  With the above configuration and operation, while the power supply device is stopped, the power storage unit 7 is discharged until the voltage Vc of the power storage unit 7 becomes substantially equal to the voltage Vb of the constant voltage source 1, thereby allowing the power storage unit 7 to be left unattended. The voltage Vc of the power storage device 23 can be maintained to such an extent that it does not affect the life of the power storage device 23, so that the life of the power storage device 23 can be extended and a power supply device that can ensure high reliability can be realized.

(Embodiment 2)
FIG. 4 is a block circuit diagram of the power supply device according to the second embodiment of the present invention. In the second embodiment, for example, regenerative electric power generated by vehicle braking is charged to a power storage unit composed of an electric double layer capacitor capable of rapid charging / discharging and charged to a constant voltage source such as a battery when the vehicle is not braked. A power supply device for a regenerative braking system is described.

  4, the same components as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted. That is, the structural features in the second embodiment are as follows.

  1) Instead of the load 3, for example, a power generation unit 31 that converts braking energy into electrical energy is connected to the power storage unit 7.

  2) Instead of the bidirectional DC / DC converter 5, a step-down DC / DC converter 33 from the power storage unit 7 to the constant voltage source 1 was used.

  3) Accordingly, the second switching element 15 is a diode.

  4) A diode 34 is provided for preventing a backflow of current from the constant voltage source 1 or the power storage unit 7 to the power generation unit 31.

  With the above configuration, the power generation unit 31 is also connected to the step-down DC / DC converter 33. In addition, the structure of the electrical storage part 7 is the same as FIG. 2 or FIG.

  Next, the operation of such a power supply device will be described.

  First, the case where the use of the vehicle is terminated and the power supply device is stopped will be described. Before turning off the ignition switch (not shown) of the vehicle, the voltage Vc of the power storage unit 7 is higher than the voltage Vb of the constant voltage source 1. This is because the step-down DC / DC converter 33 from the power storage unit 7 to the constant voltage source 1 is connected. Note that the voltage Vc of the power storage unit 7 is the maximum charging voltage of the power storage unit 7 because, for example, immediately after the vehicle is stopped, electric energy by braking is stored in the power storage unit 7 in a fully charged state. On the other hand, when the ignition switch is turned off after a while after the vehicle stops, the power of the power storage unit 7 charged by the power generation unit 31 during that time is supplied to the constant voltage source 1 by the step-down DC / DC converter 33. Since the battery is charged, the voltage Vc of the power storage unit 7 decreases to the voltage Vb of the constant voltage source 1 over time. Therefore, the voltage Vc of the power storage unit 7 before turning off the ignition switch is not uniquely determined.

  When the ignition switch is turned off in this state, an external ECU (not shown) sends a signal for operating the step-down DC / DC converter 33 to the control unit 17. The driving power of the step-down DC / DC converter 33 at this time is supplied from the power storage unit 7 as in the first embodiment. When step-down DC / DC converter 33 receives a signal from the external ECU, it measures voltage Vc of power storage unit 7. As a result, if the control unit 17 determines that the voltage Vc is substantially equal to the voltage Vb of the constant voltage source 1, the step-down DC / DC converter 33 is not operated. Note that a step-down DC / DC converter 33 is connected between the constant voltage source 1 and the power storage unit 7, and a voltage drop due to the internal resistance and the first body diode 19 occurs. As a condition that the voltage Vb is substantially equal to the voltage Vb, the voltage Vc is different from the voltage Vb by 1 V or less.

  On the other hand, when the voltage Vc and the voltage Vb do not satisfy the substantially equal condition (Vc> Vb + 1), the voltage Vc of the power storage unit 7 is stepped down and output to the constant voltage source 1 side. As a result, the power storage unit 7 is discharged, and the electric power is charged into the constant voltage source 1 via the step-down DC / DC converter 33. In this way, by discharging the power of the power storage unit 7 and charging the constant voltage source 1, the voltage of the power storage element 23 is lowered from the fully charged state as in the first embodiment, and the life can be extended. Efficiency can also be improved by charging the constant voltage source 1 with the discharge power of 7.

  Next, the control unit 17 monitors the voltage Vc of the power storage unit 7 and the voltage Vb of the constant voltage source 1 while the power storage unit 7 is being discharged. Eventually, when the voltage Vc satisfies a condition substantially equal to the voltage Vb, the operation of the step-down DC / DC converter 33 is stopped. The reason why the voltage Vc of the power storage unit 7 is set to be substantially equal to the voltage Vb of the constant voltage source 1 as the operation stop condition of the step-down DC / DC converter 33 is as described in the first embodiment. This is because the voltage Vc of the power storage unit 7 does not need to be exactly equal to the voltage Vb of the constant voltage source 1 at the time of discharging because the voltage Vc of FIG.

  Next, when the discharge of the power storage unit 7 is completed and the step-down DC / DC converter 33 stops operating, the first switching element 13 and the second switching element 15 are turned off. Since the first body diode 19 is formed, the voltage Vb of the constant voltage source 1 is applied to the power storage unit 7 via the first body diode 19 even while the power supply device is stopped. However, since there is a voltage drop ΔV due to the first body diode 19, the voltage Vc applied to the power storage unit 7 is a voltage obtained by subtracting the voltage drop ΔV from the voltage Vb of the constant voltage source 1 as described in the first embodiment. (13.3V). Since the second switching element 15 made of a rectifying element is reversely connected to the constant voltage source 1, no current flows through the second switching element 15.

  In this way, while the power supply device is stopped due to the end of use of the vehicle, a voltage is applied from the constant voltage source 1 to the power storage unit 7 so as to always maintain the voltage Vc of the power storage unit 7 after being discharged when stopped. The Since this operation is the same as in the first embodiment, a detailed description of the operation is omitted, but it is possible to prevent inrush current while reducing waste of discharge power.

  By repeating such an operation, the voltage Vc of the power storage unit 7 is always maintained.

  In the second embodiment, the power of power storage unit 7 may be discharged by balance circuit 29 connected in parallel to power storage element 23 as in the first embodiment.

  Next, a case where the vehicle is restarted will be described. When the ignition switch is turned on to restart the vehicle, the power supply device is activated, but the power storage unit 7 needs to rapidly charge and recover the electric power generated in the power generation unit 31 by vehicle braking. Unlike form 1, the power storage unit 7 is not charged during restart. Therefore, at this time, the step-down DC / DC converter 33 does not operate, and a voltage is continuously applied from the constant voltage source 1 to the power storage unit 7.

  Next, it is assumed that a brake operation is performed while the vehicle is traveling. As a result, the power generation unit 31 for recovering the braking energy operates to convert the braking energy into electric energy and output it. As a result, the voltage of the power generation unit 31 becomes higher than the voltage of the constant voltage source 1 and the power storage unit 7, so that the diode 34 is turned on and the power of the power generation unit 31 is supplied to the power storage unit 7. As a result, the power storage unit 7 is composed of an electric double layer capacitor capable of rapid charging / discharging, and thus is charged at high speed. At this time, since the power storage unit 7 is charged to a voltage substantially equal to that of the constant voltage source 1 in advance, the power generation voltage of the power generation unit 31 can be increased as compared with the state where the power storage unit 7 is completely discharged. As a result, necessary generated power can be obtained from the beginning. When the power generation unit 31 is generating power, the step-down DC / DC converter 33 steps down the voltage Vc of the power storage unit 7 and charges the constant voltage source 1.

  Next, it is assumed that the brake operation of the vehicle is finished and the power supply from the power generation unit 31 is stopped. As a result, the voltage of the power generation unit 31 becomes 0 V, and the power storage unit 7 is charged by the power generation unit 31 during the brake operation, so that the diode 34 is turned off. Thereafter, the step-down DC / DC converter 33 continues to step down the voltage Vc of the power storage unit 7 and charges the constant voltage source 1.

  The electric power stored in the power storage unit 7 is supplied to the constant voltage source 1 by the step-down DC / DC converter 33 until the voltage Vc of the power storage unit 7 becomes substantially equal to the voltage Vb of the constant voltage source 1. Since the control unit 17 monitors the voltage Vc and the voltage Vb, the control unit 17 stops the operation of the step-down DC / DC converter 33 when both are substantially equal. As a result, the power storage unit 7 is maintained at a voltage substantially equal to the voltage Vb of the constant voltage source 1 in the same manner as when the vehicle is used. By repeating such an operation while the vehicle is in use, the power storage unit 7 prepares so that the power of the power generation unit 31 can be charged at any time. As a result, braking energy can be recovered without waste, and the efficiency of the vehicle can be improved.

  The operation after the end of vehicle use is as described above.

  With the above configuration and operation, while the power supply device is stopped, the power storage unit 7 is discharged until the voltage Vc of the power storage unit 7 becomes substantially equal to the voltage Vb of the constant voltage source 1, thereby allowing the power storage unit 7 to be left unattended. The voltage Vc of the power storage device 23 can be maintained to such an extent that it does not affect the life of the power storage device 23, so that the life of the power storage device 23 can be extended and a power supply device that can ensure high reliability can be realized.

(Embodiment 3)
FIG. 5 is a block circuit diagram of a power supply device according to Embodiment 3 of the present invention. In the third embodiment, for example, a power supply device for electric power steering of a vehicle will be described.

  5, the same components as those in FIGS. 1 and 4 are denoted by the same reference numerals, and detailed description thereof is omitted. That is, the structural features of the third embodiment with respect to the configuration of the second embodiment are as follows.

  1) The power generation unit 31 is connected to the power storage unit 7 in place of the load 3 which is an electric power steering system.

  2) Instead of the step-down DC / DC converter 33, a step-up DC / DC converter 35 from the constant voltage source 1 to the power storage unit 7 was used.

  3) Accordingly, the first switching element 13 is a diode, and the second switching element 15 is an FET similar to that of the first embodiment.

  4) The diode 34 was abolished.

  With the above configuration, the load 3 is also connected to the step-up DC / DC converter 35. In addition, the structure of the electrical storage part 7 is the same as FIG. 2 or FIG.

  Next, the operation of such a power supply device will be described.

  First, the case where the use of the vehicle is terminated and the power supply device is stopped will be described. Before turning off the ignition switch (not shown) of the vehicle, the power storage unit 7 is fully charged so that power can be supplied to the load 3 at any time. At this time, the voltage Vc of the power storage unit 7 is higher than the rated voltage Vb of the constant voltage source 1. This is because the voltage required by the load 3 (electric power steering system) is higher than the rated voltage (for example, 14 V) of the constant voltage source 1. In this state, when the ignition switch is turned off, the step-up DC / DC converter 35 stops operating in conjunction therewith. As a result, power is supplied to the load 3 from the constant voltage source 1 and the power storage unit 7. However, since Vc> Vb as described above, power is supplied from the power storage unit 7 to the load 3. .

  Here, even if the ignition switch is off, the load 3 needs to perform an operation such as driving a steering angle sensor to check the current steering wheel position, and thus consumes a small amount of current. It is a configuration. Thus, the current consumed by the load 3 even when the ignition switch is off is referred to as dark current.

  Accordingly, Vc> Vb at the end of use of the vehicle, so that the dark current to the load 3 is supplied from the power storage unit 7. That is, in the third embodiment, when the power storage unit 7 is discharged when the power supply device is stopped, the discharge current of the power storage unit 7 is consumed as the dark current of the load 3. This is different from the operations in Embodiments 1 and 2 in which the discharge current of power storage unit 7 is charged to constant voltage source 1 when the power supply device is stopped. The reason why the constant voltage source 1 is not charged in the third embodiment is that the step-up DC / DC converter 35 cannot lower the voltage of the power storage unit 7 and supply it to the constant voltage source 1 due to the circuit configuration. . However, since the power of the power storage unit 7 is supplied as a dark current of the indispensable load 3, the point that the power of the power storage unit 7 can be used effectively is the same as in the first and second embodiments.

  When the power of the power storage unit 7 is supplied to the load 3, the voltage Vc of the power storage unit 7 decreases with time and eventually becomes substantially equal to the voltage Vb of the constant voltage source 1. Here, the substantially equal conditions are the same as the conditions described in the second embodiment. However, since the step-up DC / DC converter 35 is connected between the constant voltage source 1 and the power storage unit 7, the voltage Vc of the power storage unit 7 is equal to the voltage drop of the first switching element 13 made of a diode. Since the first switching element 13 is off until it becomes lower than the voltage Vb of 1, power is supplied from the power storage unit 7 to the load 3. Specifically, when the voltage Vb is 14 V and the voltage drop ΔV is 0.7 V, power is supplied from the power storage unit 7 to the load 3 until the voltage Vc becomes 13.3 V (= 14 V−0.7 V). .

  When the voltage Vc reaches 13.3 V, the first switching element 13 is automatically turned on, so that the electric power of the constant voltage source 1 is supplied to the power storage unit 7 and the load 3. Therefore, after that, since the voltage from the constant voltage source 1 is continuously applied to the power storage unit 7, the voltage after the discharge is maintained based on the operation described in the first embodiment. The dark current to the load 3 is supplied from the constant voltage source 1 at this time. By operating in this way, as in the first and second embodiments, the effect of ensuring high reliability by extending the life of the power storage unit 7 and using the discharge power efficiently can be obtained.

  Next, a case where the vehicle is restarted will be described.

  When the ignition switch is turned on to restart the vehicle, the step-up DC / DC converter 35 of the power supply device is activated, and the power storage unit 7 is fully charged as in the first embodiment. At that time, since the voltage Vc of the power storage unit 7 is already 13.3 V, the inrush current can be extremely reduced. Therefore, deterioration of the step-up DC / DC converter 35, the power storage unit 7 and the like can be reduced, and high reliability can be obtained. Furthermore, since the power storage unit 7 is charged to 13.3 V in advance, the time until full charge can be shortened.

  While the power storage unit 7 is being charged, the power from the constant voltage source 1 is also supplied to the load 3, but at this point in time, the load 3 is not operating because it is immediately after turning on the ignition switch. Therefore, in the circuit configuration of FIG. 5, the electric power of the constant voltage source 1 is supplied to the power storage unit 7 except for the dark current to the load 3.

  When charging of power storage unit 7 is completed, boost DC / DC converter 35 stops operating. At this time, since the first switching element 13 is Vc> Vb, the first switching element 13 is turned off, and the power charged in the power storage unit 7 does not flow backward to the constant voltage source 1.

  Thereafter, when the handle is operated, an instantaneous large current required immediately after the load 3 starts to operate is supplied from the power storage unit 7. The voltage Vc of the power storage unit 7 rapidly decreases as the load 3 consumes a large current, and eventually the voltage Vc becomes smaller than the voltage Vb of the constant voltage source 1. As a result, the first switching element 13 is automatically turned on, and the subsequent power supply to the load 3 is performed from the constant voltage source 1. At this point in time, the load 3 has already entered a steady operation and no longer needs to consume a large current, so that the constant voltage source 1 can sufficiently supply power to the load 3. At the same time, since the voltage obtained by subtracting the voltage drop ΔV of the first switching element 13 from the voltage Vb of the constant voltage source 1 is also applied to the power storage unit 7, the voltage Vc of the power storage unit 7 is maintained.

  When the operation of the load 3 is completed, the step-up DC / DC converter 35 performs an operation for fully charging the power storage unit 7 again. Since this operation is the same as when the vehicle is restarted, description thereof is omitted. By repeating such an operation while the vehicle is in use, the power storage unit 7 prepares to supply power to the load 3 at any time.

  The operation after the end of vehicle use is as described above.

  The step-up DC / DC converter 35 has been stopped when the charging of the power storage unit 7 is completed, but this may be continuously operated.

  With the above configuration and operation, while the power supply device is stopped, the power storage unit 7 is discharged until the voltage Vc of the power storage unit 7 becomes substantially equal to the voltage Vb of the constant voltage source 1, thereby allowing the power storage unit 7 to be left unattended. The voltage Vc of the power storage device 23 can be maintained to such an extent that it does not affect the life of the power storage device 23, so that the life of the power storage device 23 can be extended and a power supply device that can ensure high reliability can be realized.

  In the first to third embodiments, an example in which an electric double layer capacitor is used as the power storage element 23 is shown, but this may be another capacitor such as an electrochemical capacitor. Furthermore, although the case of the power supply device for vehicles was described, it is applicable also to other power supply devices.

  Since the power supply device according to the present invention can ensure high reliability by extending the life of the power storage unit, the power supply device is useful as a power supply device that supplementarily supplies power from the power storage unit to a load.

1 is a block circuit diagram of a power supply device according to Embodiment 1 of the present invention. Detailed circuit diagram of power storage unit when power storage elements of power supply device according to Embodiment 1 of the present invention are connected in series Detailed circuit diagram of power storage unit when power storage element of power supply device according to embodiment 1 of the present invention is in series-parallel connection Block circuit diagram of a power supply apparatus according to Embodiment 2 of the present invention Block circuit diagram of a power supply device according to Embodiment 3 of the present invention Schematic block circuit diagram of the main parts of a conventional power supply device

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Constant voltage source 3 Load 5 Bidirectional DC / DC converter 7 Power storage part 23 Power storage element 25 Zener diode 27 Resistor 29 Voltage balance circuit 31 Power generation part 33 Step-down DC / DC converter 35 Step-up DC / DC converter

Claims (9)

A constant voltage source;
A load connected to the constant voltage source;
A bidirectional DC / DC converter having one end connected to a connection point of the constant voltage source and the load;
A power storage unit connected to the other end of the bidirectional DC / DC converter;
Discharging the power storage unit until the voltage of the power storage unit is substantially equal to the voltage of the constant voltage source when stopping;
A power supply device in which a voltage is applied from the constant voltage source to the power storage unit so as to maintain the voltage of the power storage unit after being discharged when stopped. The power supply device according to claim 1, wherein the bidirectional DC / DC converter charges the constant voltage source with the discharge power of the power storage unit when discharging the power storage unit when stopping. The power supply device according to claim 2, wherein driving power of the bidirectional DC / DC converter when discharging the power storage unit when stopping is supplied from the power storage unit. A power generation unit;
A step-down DC / DC converter connected to the power generation unit;
A constant voltage source connected to the step-down DC / DC converter;
The step-down DC / DC converter and a power storage unit connected to a connection point of the power generation unit,
Discharging the power storage unit until the voltage of the power storage unit is substantially equal to the voltage of the constant voltage source when stopping;
A power supply device in which a voltage is applied from the constant voltage source to the power storage unit so as to maintain the voltage of the power storage unit after being discharged when stopped. 5. The power supply device according to claim 4, wherein the step-down DC / DC converter charges the discharge power of the power storage unit to a constant voltage source when discharging the power storage unit when stopping. 6. The power supply device according to claim 5, wherein driving power of the step-down DC / DC converter when discharging the power storage unit when stopping is supplied from the power storage unit. A constant voltage source;
A step-up DC / DC converter connected to the constant voltage source;
A load connected to the step-up DC / DC converter;
The step-up DC / DC converter and a power storage unit connected to the connection point of the load,
Discharging the power storage unit until the voltage of the power storage unit is substantially equal to the voltage of the constant voltage source when stopping;
A power supply device in which a voltage is applied from the constant voltage source to the power storage unit so as to maintain the voltage of the power storage unit after being discharged when stopped. The load is configured to consume dark current,
The power supply device according to claim 7, wherein when discharging the power storage unit when stopping, the discharge current of the power storage unit is consumed as the dark current of the load. The power storage unit has a plurality of power storage elements connected in series or in series and parallel,
A voltage balance circuit is connected to both ends of the electric storage element corresponding to the series connection,
When the number of the voltage balance circuits is n and the voltage of the power storage unit is Vc while the voltage balance circuit is stopped, the voltage balance circuit has a voltage across the power storage element corresponding to a series connection of approximately Vc / n. The power supply device according to claim 1, 4, or 7, wherein the power storage element is discharged when the above is reached.

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