JP2012070581A - Power supply device for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply device for a vehicle with a regenerative electric power recovery function, capable of obtaining a sufficient idling stop period even for low regenerative electric power when the vehicle decelerates from a low-speed state.SOLUTION: A power supply device for a vehicle includes: a power generator 11; a load 19; a power storing section 27 connected to the power generator 11 and the load 19 via a DC-DC converter 25; and a control circuit 37. The control circuit 37 controls the DC-DC converter 25 so that the power storing section 27 is charged with regenerative electric power generated by the power generator 11. When the vehicle stops, the control units 37 also controls the DC-DC converter 25 so that the power storing section 27 is charged up to a full charge voltage Vcu with power generated by the power generator 11 by consuming fuel of the engine when a power storing section voltage Vc does not reach the predetermined full charge voltage Vcu or so that an idling stop starts while stopping the engine and the power of the power storing section 27 is supplied to a main power supply 13 and the load 19 when the power storing section voltage Vc reaches the full charge voltage Vcu.

Description

  The present invention relates to a vehicle power supply device capable of recovering regenerative power and having an idling stop function.

  In recent years, vehicles that recover regenerative power and have an idling stop function have been proposed. FIG. 4 shows a schematic diagram of the system configuration of the vehicle power generator in such a vehicle. A generator 101 and a starter 103 are mechanically connected to the vehicle engine (not shown). Thereby, the generator 101 generates electric power that accompanies fuel consumption of the engine and regenerative electric power that does not accompany fuel consumption that occurs during deceleration. The starting device 103 is a starter that starts the engine including after idling stop.

  The generator 101 and the starter 103 are electrically connected to a main power source 105 made of a lead battery and a vehicle device 107. Furthermore, the auxiliary power supply 111 is also electrically connected through the DC / DC converter 109. The auxiliary power source is composed of a lithium battery, a capacitor, or the like.

  A charge amount sensor 113 is connected to each of the main power source 105 and the auxiliary power source 111. The outputs of these charge amount sensors 113 are input to the automatic stop / start ECU 115. The automatic stop / start ECU 115 controls whether or not the engine can be idle-stopped. For this purpose, in addition to the output of the charge amount sensor 113, the DC / DC converter 109, the power generator is used based on signals from the vehicle speed sensor 117 and the navigation device 119. The operation of the power generation control ECU 121 connected to the machine 101 is controlled, and a stop signal and a start signal are transmitted to the engine.

  In such a vehicle power generation device, the automatic stop / start ECU 115 charges the regenerative power predicted by the built-in regenerative power prediction means 123 to the auxiliary power source 111, and the charge amount of the auxiliary power source 111 is a predetermined amount during idling stop. If so, the DC / DC converter 109 is controlled so that power is supplied from the auxiliary power supply 111 to the vehicle device 107. When the discharge amount of the auxiliary power source 111 becomes equal to or greater than the threshold value, power generation with fuel consumption of the engine is performed, and power supply to the vehicle device 107 is continued.

  By the operation as described above, the vehicle discharges the regenerative power stored in the auxiliary power source 111 to the vehicle device 107 during idling stop, thereby effectively using the regenerative power and suppressing fuel consumption of the engine by idling stop. Fuel saving can be achieved.

  As prior art document information related to the invention of this application, for example, Patent Document 1 is known.

Japanese Patent Laid-Open No. 2006-316643

  According to the above-described vehicle power generation device, it is possible to save the fuel consumption of the vehicle. However, if the amount of regenerative power generated by the generator 101 is small, for example, when the vehicle decelerates from a low speed state, the auxiliary power supply 111 cannot be fully charged with regenerative power. In this case, even if the idling stop state occurs and the regenerative power stored in the auxiliary power supply 111 is discharged to the vehicle device 107, the amount of discharge immediately reaches the threshold value, and power generation accompanied by engine fuel consumption is performed. End up. Therefore, the idling stop period is shortened, and the power energy of the main power source 105 consumed by the starter 103 to start the engine is larger than the fuel energy saved in the short idling stop period. There has been a problem that the fuel saving effect may be reduced.

  The present invention solves the above-described conventional problems, and an object thereof is to provide a vehicular power supply device capable of obtaining a sufficient idling stop period even when the regenerative power is low when the vehicle is decelerated from a low speed state. And

  In order to solve the above-described conventional problems, a power supply device for a vehicle according to the present invention includes a power generator that generates power using a vehicle engine, a power storage unit that is electrically connected to the power generator via a DC / DC converter, A main power supply and a load electrically connected to the generator; a power storage unit voltage detection circuit that is electrically connected to the power storage unit and detects a power storage unit voltage (Vc); and the DC / DC converter; A control circuit electrically connected to the power storage unit voltage detection circuit, and the control circuit controls the DC / DC converter so as to charge the power storage unit with regenerative power generated by the generator. If the power storage unit voltage (Vc) does not reach a predetermined full charge voltage (Vcu) when the vehicle is stopped, the fuel consumption of the engine is continued until the full charge voltage (Vcu) is reached. The DC / DC converter is controlled so as to charge the electric power generated by the machine to the power storage unit. When the power storage unit voltage (Vc) reaches the full charge voltage (Vcu), the engine is stopped and the idling stop is performed. The DC / DC converter is controlled so as to supply power of the power storage unit to the main power source and the load.

  In addition, the vehicle power supply device of the present invention includes a generator that generates electric power from a vehicle engine, a power storage unit that is electrically connected to the generator via a DC / DC converter, and an electrical connection to the generator. A main power source and a load that are electrically connected to the power storage unit and detect a power storage unit voltage (Vc), the DC / DC converter, and the power storage unit voltage detection circuit A control circuit that is connected to the power storage unit, wherein the control circuit controls the DC / DC converter to charge the power storage unit with regenerative power generated by the generator, and the vehicle is decelerating while the vehicle is decelerating. If the power storage unit voltage (Vc) does not reach a predetermined full charge voltage (Vcu) when the engine is stopped, the generator is accompanied with fuel consumption of the engine until the full charge voltage (Vcu) is reached. The DC / DC converter is controlled to charge the electric power to be generated to the power storage unit, and when the power storage unit voltage (Vc) reaches the full charge voltage (Vcu), the engine is controlled to stop, The DC / DC converter is controlled so as to supply power of the power storage unit to the main power source and the load.

  According to the vehicle power supply device of the present invention, the fuel consumption of the engine is accompanied until the power storage unit voltage (Vc) reaches the predetermined full charge voltage (Vcu) before the idling stop is started after the vehicle is stopped. Since the electric power generated by the generator is charged in the power storage unit, the power storage unit is fully charged when the idling stop is started. Therefore, even if the vehicle decelerates from the low speed state and the regenerative power cannot be fully charged in the power storage unit, the idling stop is started after the power storage unit is fully charged. It is possible to obtain the effect of reducing fuel consumption.

  According to the vehicle power supply device of the present invention, when the vehicle has a function of stopping the engine while decelerating, the power storage unit voltage (Vc) is set to a predetermined full charge voltage (Vcu) when the engine stops. Until the engine is stopped, the power storage unit is fully charged when the engine is stopped. Therefore, even if the vehicle decelerates from the low speed state and the regenerative power cannot be fully charged in the power storage unit, the engine is stopped after the power storage unit is fully charged, so a sufficient idling stop period is obtained. This makes it possible to achieve fuel savings.

1 is a block circuit diagram of a vehicle power supply device according to Embodiment 1 of the present invention. FIG. 4 is a time-dependent change diagram of various characteristics of the vehicle power supply device according to Embodiment 1 of the present invention, where (a) is a time-dependent change diagram of the vehicle speed v, (b) is a time-dependent change diagram of the power storage unit voltage Vc, and (c) is a power generation. Change of machine status over time FIG. 6 is a time-dependent change diagram of various characteristics of the vehicle power supply device according to Embodiment 2 of the present invention, where (a) is a time-dependent change diagram of vehicle speed v, (b) is a time-dependent change diagram of power storage unit voltage Vc, and (c) is power generation. Change of machine status over time System configuration schematic diagram of a conventional vehicle power generator

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a block circuit diagram of a vehicle power supply device according to Embodiment 1 of the present invention. 2 is a time-dependent change diagram of various characteristics of the vehicle power supply device according to the first embodiment of the present invention. FIG. 2A is a time-dependent change diagram of the vehicle speed v, and FIG. 2B is a time-dependent change diagram of the power storage unit voltage Vc. , (C) shows a time-dependent change diagram of the generator state. In FIG. 1, thick lines indicate power system wirings, and thin lines indicate signal system wirings. In the first embodiment, a case where the vehicle power supply device is applied to a vehicle having an idling stop function and a regenerative power recovery function will be described.

  In FIG. 1, a generator 11 that generates electric power from a vehicle engine (not shown) is electrically connected to a main power supply 13 and a starter 15. Here, the generator 11 is configured to obtain an output voltage of 14.5V. Moreover, the main power supply 13 is comprised with a lead battery, and the open circuit voltage is 12V. The starter 15 is mechanically connected to the engine and starts the engine.

  The generator 11 is electrically connected to a load 19. Here, the load 19 is an electrical component mounted on the vehicle. A power storage device 21 is electrically connected to the load 19. Therefore, as shown in FIG. 1, the generator 11, the main power supply 13, the starter 15, and the load 19 are all electrically connected to the power storage device 21.

  Next, a detailed configuration of the power storage device 21 will be described.

  The input / output terminal 23 of the power storage device 21 electrically connected to the load 19 is electrically connected to the power storage unit 27 via the DC / DC converter 25. Here, the DC / DC converter 25 charges the regenerative power generated by the generator 11 in the power storage unit 27 or the regenerative power stored in the power storage unit 27 when the regenerative power is not generated. In the first embodiment, a bidirectional type is used. The regenerative electric power is defined below as electric power obtained by driving the generator 11 without consuming fuel by the engine during deceleration or braking. In addition, when the regenerative power discharged from the power storage unit 27 is supplied to the main power supply 13, the regenerative power can be effectively used, so the main power supply in a state where the regenerative power of the power storage unit 27 is charged. 13 is treated as part of the load 19.

  The power storage unit 27 has a configuration in which four electric double layer capacitors having a rated voltage of 2.5 V are connected in series. Therefore, the full charge voltage Vcu of the power storage unit 27 is 10V. In addition, the power storage unit 27 determines the lower limit voltage Vck as 5 V in advance in order to suppress overdischarge of the electric double layer capacitor. Therefore, the DC / DC converter 25 controls charging / discharging of the power storage unit 27 in a range where the power storage unit voltage Vc ranges from the lower limit voltage Vck (= 5 V) to the full charge voltage Vcu (= 10 V).

  The configuration of the power storage unit 27 described above is merely an example, and the number of the electric double layer capacitors may be changed, or a series-parallel connection or a parallel connection may be used according to a required power specification. Further, the full charge voltage Vcu is not limited to 10 V, and for example, the number of electric double layer capacitors connected in series to a voltage value in consideration of a predetermined margin with respect to the rated voltage (four in the first embodiment). A value obtained by multiplying by may be defined as the full charge voltage Vcu. Similarly, the lower limit voltage Vck is not limited to 5 V, and may be determined to a value such as 5.5 V or 6 V with a large margin, for example, depending on the characteristics of the electric double layer capacitor to be used. .

  Note that the negative electrode of the power storage unit 27 is electrically connected to the ground of the vehicle via a ground terminal 29.

  An input / output voltage detection circuit 31 and an input / output current detection circuit 33 are connected to the input / output terminal 23 on the load 19 side of the DC / DC converter 25. Here, the input / output voltage detection circuit 31 has a function of detecting and outputting the input / output voltage Vb at the input / output terminal 23 with respect to the ground. Specifically, a series circuit of two resistors (not shown) is connected between the input / output terminal 23 and the ground, and an input / output voltage is applied from the connection point of the two resistors. A voltage proportional to Vb is output. The input / output voltage detection circuit 31 is not limited to the above-described configuration. For example, an A / D converter having an input allowable voltage of 20 V may be directly connected to the input / output terminal 23.

  The input / output current detection circuit 33 detects and outputs the input / output current I flowing through the input / output terminal 23 when the power storage unit 27 is charged / discharged by the DC / DC converter 25. The voltage across the shunt resistor (not shown) provided between the power supply 23 and the DC / DC converter 25 is detected. The input / output current detection circuit 33 is not limited to the configuration described above, and may be configured to detect magnetically with, for example, a Hall element.

  On the other hand, a power storage unit voltage detection circuit 35 is electrically connected between the DC / DC converter 25 and the power storage unit 27. The power storage unit voltage detection circuit 35 can detect and output the power storage unit voltage Vc. The power storage unit voltage detection circuit 35 has the same configuration as the input / output voltage detection circuit 31.

  The DC / DC converter 25, the input / output voltage detection circuit 31, the input / output current detection circuit 33, and the power storage unit voltage detection circuit 35 are electrically connected to the control circuit 37 by signal system wiring. The control circuit 37 includes a microcomputer and peripheral circuits such as a memory. The control circuit 37 stores the input / output voltage Vb from the input / output voltage detection circuit 31, the input / output current I from the input / output current detection circuit 33, and the storage unit voltage detection circuit 35. Each partial voltage Vc is read. Therefore, the control circuit 37 sets the control signal cont to DC / DC so that the input / output voltage Vb and the storage unit voltage Vc are set to desired set values in the range where the input / output current I is within a predetermined upper limit value in order to prevent overcurrent. By outputting to DC converter 25, charging / discharging of power storage unit 27 is controlled. Furthermore, the control circuit 37 is electrically connected to the vehicle control circuit 41 via the external terminal 39, and the voltage and current values of the power storage device 21 such as various voltage / current values are exchanged with the vehicle control circuit 41 by the data signal data. Various data such as data and data indicating the state of the vehicle are transmitted and received. Therefore, the control circuit 37 can also control the DC / DC converter 25 (for example, start / stop of the DC / DC converter 25 and charge / discharge switching) based on the data signal data of the vehicle control circuit 41. The data signal data is generated in accordance with the vehicle communication standard. Further, the generator 11 and the starter 15 are controlled by the vehicle control circuit 41. However, since the description of the signal system wiring becomes complicated, these signal system wirings are omitted in FIG.

  Next, the operation of such a vehicle power supply device will be described with reference to FIG. In FIG. 2, the horizontal axis indicates time t. In addition, the vertical axis in FIG. 2A represents the vehicle speed v, the vertical axis in FIG. 2B represents the power storage unit voltage Vc, and the vertical axis in FIG. 2C represents the state of the generator 11.

  First, as shown in FIG. 2A, at time t0, the vehicle is traveling at a constant speed at a vehicle speed v equal to or higher than a predetermined vehicle speed vk. Here, the predetermined vehicle speed vk is a vehicle speed v that can fully charge the power storage unit 27 that has been discharged to the lower limit voltage Vck with only the regenerative power generated by the generator 11 when the vehicle decelerates. In the first embodiment, the predetermined vehicle speed vk is determined in advance as 40 km / h. Therefore, at time t0, the vehicle is traveling at a vehicle speed v of 40 km / h or higher.

  At this time, the control circuit 37 reads the power storage unit voltage Vc from the power storage unit voltage detection circuit 35, and discharges the power of the power storage unit 27 to the main power supply 13 and the load 19 until the lower limit voltage Vck is reached. To control. This is because, since the vehicle speed v is equal to or higher than the predetermined vehicle speed vk, even if the electric power remaining in the power storage unit 27 is discharged to the lower limit voltage Vck, the power storage unit 27 is fully charged with the regenerative power generated at the next deceleration. Therefore, the remaining electric power of the power storage unit 27 is discharged in order to effectively use it.

  By such an operation, the storage unit voltage Vc decreases with time from time t0 to time t1, as shown in FIG. 2 (b). At this time, since the power is supplied from the power storage unit 27 to the main power supply 13 and the load 19, the generator 11 does not need to generate power. Therefore, while the power storage unit 27 is discharged, the control circuit 37 outputs a data signal data indicating that the power storage unit 27 is being discharged to the vehicle control circuit 41. In response to this, the vehicle control circuit 41 controls to stop the power generation of the generator 11. As a result, as shown in FIG. 2C, the state of the generator 11 is stopped from time t0 to time t1. Thereby, although the generator 11 is mechanically driven by the engine but does not generate power, the mechanical burden on the engine is reduced, and fuel consumption can be reduced.

  When power storage unit voltage Vc reaches lower limit voltage Vck as shown in FIG. 2B at time t1, control circuit 37 controls DC / DC converter 25 so that power storage unit 27 is no longer discharged. Specifically, the DC / DC converter 25 is controlled so that the power storage unit voltage Vc maintains the lower limit voltage Vck. Thereby, the overdischarge of the electrical storage part 27 can be suppressed. By such an operation, the power supply from the power storage unit 27 to the main power supply 13 and the load 19 is stopped, so that the vehicle control circuit 41 receives information from the control circuit 37 that the power storage unit voltage Vc has reached the lower limit voltage Vck. When the signal data is received, the generator 11 is immediately switched to the fuel consumption power generation state as shown in FIG. The fuel-consuming power generation is defined as a state in which the generator 11 is driven to generate power when the engine consumes fuel. By such an operation, the power of the generator 11 is supplied to the main power supply 13 and the load 19 at time t1, and therefore the operation of the load 19 can be continued.

  Thereafter, the vehicle starts decelerating at time t2. Accordingly, the vehicle speed v decreases with time as shown in FIG. As a result, the engine is brought into a fuel cut state by the vehicle control circuit 41, and the vehicle travels inertially. Therefore, the generator 11 at this time is in a regenerative power generation state without fuel consumption as shown in FIG. Become. Therefore, the control circuit 37 controls the DC / DC converter 25 so as to charge the power storage unit 27 with the regenerative power generated by the generator 11. As a result, as shown in FIG. 2B, the power storage unit voltage Vc increases with time from time t2 to time t3.

  When power storage unit voltage Vc reaches full charge voltage Vcu as shown in FIG. 2B at time t3, control circuit 37 controls so that power storage unit 27 is no longer charged. Specifically, the DC / DC converter 25 is controlled so that the power storage unit voltage Vc maintains the full charge voltage Vcu. As a result, as shown in FIG. 2B, the power storage unit voltage Vc becomes the full charge voltage Vcu after time t3. However, at time t3, the vehicle is decelerating as shown in FIG. 2 (a) and the generator 11 is in the regenerative power generation state as shown in FIG. 2 (c). The regenerative power generated up to is supplied to the main power supply 13 and the load 19. Therefore, the regenerative power from time t3 to time t4 is also effectively used.

  At time t4, as shown in FIG. 2A, the vehicle speed v reaches the fuel cut end vehicle speed vf. Here, the fuel cut end vehicle speed vf is a vehicle speed when fuel cut is ended and fuel is reinjected in order to maintain the idling speed of the engine, and is determined by the type of the engine, the vehicle type, and the like. In the first embodiment, the fuel cut end vehicle speed vf is determined in advance as 10 km / h. Therefore, the vehicle control circuit 41 resumes fuel injection of the engine at time t4. As a result, as shown in FIG. 2C, the generator 11 is in the fuel consumption power generation state from time t4 to time t5. At this time, since the vehicle continues to decelerate, the power storage unit voltage Vc continues to maintain the full charge voltage Vcu as shown in FIG.

  At time t5, as shown in FIG. 2A, the vehicle speed v becomes 0 km / h, and the vehicle stops. At this time, as shown in FIG. 2B, the storage unit voltage Vc has reached the full charge voltage Vcu, so the control circuit 37 stops the engine with respect to the vehicle control circuit 41 and starts idling stop. To control. Thereby, since the drive of the generator 11 is also stopped, as shown in FIG.2 (c), the generator 11 will be in the state of a power generation stop. Further, the control circuit 37 starts the idling stop and controls the DC / DC converter 25 so as to supply the power of the power storage unit 27 to the main power supply 13 and the load 19. Thereby, since the regenerative power can be supplied to the main power source 13 and the load 19 during the idling stop, the regenerative power can be effectively used and fuel can be saved by the idling stop. Thus, the fuel consumption of the vehicle can be reduced.

  Since the idling stop is started at time t5 and the power of the power storage unit 27 is discharged, the power storage unit voltage Vc decreases with time until time t6 as shown in FIG. From time t5 to time t6 is an idling stop period as shown in FIG.

  When power storage unit voltage Vc reaches lower limit voltage Vck as shown in FIG. 2B at time t6, control circuit 37 stops discharging as in time t1, and power storage unit voltage Vc maintains lower limit voltage Vck. Thus, the DC / DC converter 25 is controlled. However, at this time, as shown in FIG. 2 (a), the vehicle speed v remains 0 km / h and the vehicle is stopped. Therefore, the control circuit 37 does not supply power to the load 19 at time t6. A data signal data is transmitted to the vehicle control circuit 41 so as to restart the engine. In response to this, the vehicle control circuit 41 restarts the engine, so that the generator 11 enters the fuel consumption power generation state as shown in FIG. As a result, the power of the generator 11 is supplied to the main power supply 13 and the load 19.

  In the first embodiment, the engine is restarted from time t6 to time t7 when the vehicle starts to travel again. However, this keeps the engine stopped, and the load 19 is The power supply 13 may be configured to supply power. In this case, as indicated by the thick dotted line in FIG. 2C, the generator 11 is in a power generation stop state from time t6 to time t7. By controlling in this way, the idling stop period can be made longer, so that fuel can be saved accordingly. However, since the main power supply 13 supplies power for driving the starter 15 at the end of the idling stop, if the idling stop period is prolonged and the power consumption of the load 19 is large, the burden on the main power supply 13 increases and the starter 15 increases. 15 may be difficult to drive. Further, the durability of the main power supply 13 is also lowered. Further, in order to continue the operation of the load 19 even if a steep voltage drop occurs when the starter 15 is driven, it is necessary to provide a voltage stabilizing circuit (not shown) in the load 19. Therefore, in the first embodiment, when the power storage unit voltage Vc reaches the lower limit voltage Vck, the idling stop is ended and the engine is restarted even when the vehicle is stopped. In the case where the main power supply 13 has a large capacity and a sufficient charge amount, durability is ensured, and the voltage stabilizing circuit is provided in the load 19, the idling stop is also performed from time t6 to time t7. It is better to continue.

  The vehicle starts to travel again at time t7, and the vehicle speed v increases as shown in FIG. At time t8, the vehicle travels at a constant speed at a vehicle speed v that is greater than the fuel cut end vehicle speed vf and less than the predetermined vehicle speed vk. Since the vehicle is accelerating or traveling at a constant speed from time t7 to time t9, the power storage unit voltage Vc continues to maintain the lower limit voltage Vck as shown in FIG. 2B, as shown in FIG. Thus, the generator 11 remains in the fuel consumption power generation state.

  The vehicle decelerates at time t9, and the vehicle speed v decreases with time as shown in FIG. As a result, the generator 11 enters the regenerative power generation state as shown in FIG. 2C, and the control circuit 37 controls the DC / DC converter 25 so as to charge the power storage unit 27 with the regenerative power. These operations are the same as at time t2. As a result, the power storage unit voltage Vc increases with time from time t9 as shown in FIG.

  Thereafter, at time t10, as shown in FIG. 2A, the vehicle speed v reaches the fuel cut end vehicle speed vf. As a result, the engine is driven with fuel consumption similarly to the time t4, so that the generator 11 is in the fuel consumption power generation state as shown in FIG. However, at time t10, power storage unit voltage Vc has not reached full charge voltage Vcu. Therefore, the control circuit 37 continues to charge the power storage unit 27 even when the generator 11 is in the fuel consumption power generation state.

  When time t11 is reached, the vehicle speed v becomes 0 km / h as shown in FIG. 2A, and the vehicle stops. At this time, as shown in FIG. 2B, the power storage unit voltage Vc remains at the full charge voltage Vcu. It has not reached. Therefore, the control circuit 37 originally starts the idling stop at time t11, but here, without performing the idling stop, the power storage unit voltage Vc is kept in the fuel consumption power generation state. Charging by the generator 11 of the power storage unit 27 is continued until the full charge voltage Vcu is reached.

  When the power storage unit voltage Vc reaches the full charge voltage Vcu as shown in FIG. 2B at time t12, the control circuit 37 instructs the vehicle control circuit 41 to stop the engine and start the idling stop. The DC / DC converter 25 is controlled so that the power of the power storage unit 27 is supplied to the main power supply 13 and the load 19. This operation is the same as at time t5.

  For these reasons, during the period from when the vehicle stops at time t11 to when the power storage unit voltage Vc reaches the full charge voltage Vcu at time t12, the engine fully charges the power storage unit 27 even with fuel consumption. That means you are working. The reason for performing such an operation is as follows.

  When the vehicle speed v is low, such as from time t8 to time t9, the regenerative power that can be actually collected by the power storage unit 27 is limited to the period from time t9 to time t10. It can be seen from FIG. 2B that the power storage unit voltage Vc at time t10 is extremely lower than the full charge voltage Vcu. When the idling stop is started in this state, the power of the power storage unit 27 is immediately consumed by the load 19, and the idling stop can be performed only for a short period.

  On the other hand, when the idling stop is started after the power storage unit 27 is fully charged as in the first embodiment, the idling stop can be continued for a maximum period. Here, since the power storage unit 27 is composed of the electric double layer capacitor and can be rapidly charged, the power storage unit 27 is fully charged in a short period of time. Therefore, the power storage unit 27 is fully charged with fuel consumption from time t10 to time t12. In the case of the first embodiment, the amount of fuel required for charging is substantially equal to the amount of fuel that can be saved by performing the idling stop for 5 seconds. Therefore, in general, when the vehicle waits for a signal or the like, the vehicle does not stop frequently within 5 seconds. Therefore, it is possible to save fuel by extending the idling stop period by fully charging the power storage unit 27 even with fuel consumption. Note that the above-described period of 5 seconds is an example, and changes depending on the type of the vehicle, the power consumption of the load 19, and the like.

  Summarizing the effects described above, the idling stop is started after the power storage unit 27 is fully charged even if the vehicle decelerates from the low speed state and the regenerative power cannot be sufficiently charged to the power storage unit 27. As a result, a sufficient idling stop period can be obtained, and fuel consumption can be reduced.

  Next, from time t12 to time t13, as shown in FIG. 2B, the power storage unit voltage Vc decreases with time, and when the voltage reaches the lower limit voltage Vck at time t13, the control circuit 37 causes the vehicle control circuit 41 to On the other hand, the engine is controlled to be restarted. As a result, the idling stop is completed. This operation is the same as at time t6.

  From time t13 to time t14, the vehicle speed v is 0 km / h as shown in FIG. 2 (a), but the generator 11 is in the fuel consumption power generation state as shown in FIG. 2 (c). Electric power is supplied from the generator 11 to the main power supply 13 and the load 19. However, during this period, if the main power source 13 has a large capacity and durability, the engine is stopped as described from time t6 to time t7, and the power of the main power source 13 is supplied to the load 19. It is good also as a structure which supplies. In this case, as indicated by the thick dotted line in FIG. 2 (c), the generator 11 is also in the power generation stop state during the period from time t13 to time t14.

  When the vehicle starts running again at time t14, the vehicle speed v increases as shown in FIG. At this time, since the generator 11 is in the fuel consumption power generation state as shown in FIG. 2 (c) and the vehicle is accelerating, the power storage unit voltage Vc is lower than the lower limit as shown in FIG. 2 (b). The voltage Vck is maintained.

  At time t15, the vehicle speed v reaches the predetermined vehicle speed vk as shown in FIG. As a result, the power storage unit 27 can be fully charged with the regenerative power generated during the subsequent deceleration, so that the control circuit 37 can store the power storage unit 27 if the vehicle speed v of the vehicle is equal to or higher than the predetermined vehicle speed vk. The DC / DC converter 25 is controlled so as to discharge the electric power to the main power source 13 and the load 19, but the power storage unit voltage Vc remains at the lower limit voltage Vck at time t15 as shown in FIG. 2B. Therefore, in this case, in order to suppress overdischarge, the power storage unit 27 is not discharged even if the vehicle speed v is equal to or higher than the predetermined vehicle speed vk.

  Thereafter, at time t16, as shown in FIG. 2A, the vehicle speed v becomes constant at a value larger than the predetermined vehicle speed vk, and the vehicle runs at a constant speed. The power storage unit voltage Vc and the generator state at this time are maintained as they are at time t15.

  When the vehicle speed v decreases and the vehicle starts to decelerate at time t17 as shown in FIG. 2A, the vehicle control circuit 41 performs the fuel cut. As a result, the generator 11 is in the regenerative power generation state as shown in FIG. Therefore, the control circuit 37 controls the DC / DC converter 25 so as to charge the power storage unit 27 with the regenerative power.

  Thereafter, at time t18, as shown in FIG. 2B, the power storage unit voltage Vc reaches the full charge voltage Vcu. At time t19, when the vehicle speed v reaches the fuel cut end vehicle speed vf as shown in FIG. 2A, the generator 11 is changed to the fuel consumption power generation state as shown in FIG. 2C. At time t20, as shown in FIG. 2A, the vehicle speed v becomes 0 km / h, and the idling stop is started. Thereby, as shown in FIG. 2 (c), the generator 11 is in the power generation stop state, and the electric power of the power storage unit 27 is supplied to the main power supply 13 and the load 19, and the power storage unit as shown in FIG. 2 (b). The voltage Vc decreases. Since the series of operations from time t17 to time t20 are the same as the operations from time t2 to time t5, respectively, detailed description of the operations is omitted.

  Next, at time t21, the vehicle speed v increases as shown in FIG. 2A, and the vehicle starts to accelerate. Therefore, since the engine restarts at time t21, the generator 11 enters the fuel consumption power generation state as shown in FIG. Therefore, electric power with fuel consumption is generated from the generator 11. On the other hand, as shown in FIG. 2B, the power storage unit voltage Vc is a voltage value between the lower limit voltage Vck and the full charge voltage Vcu at time t21. Therefore, although the regenerative power stored in the power storage unit 27 can be supplied to the main power supply 13 and the load 19, the vehicle speed v immediately after time t21 is small, so that even if the vehicle is decelerated immediately thereafter, sufficient regeneration is achieved. Electric power may not be obtained. As a result, if the power of the power storage unit 27 is continuously supplied, the power storage unit 27 is fully charged by power generation accompanied by fuel consumption of the generator 11 from time t10 to time t12. Therefore, since the idling stop cannot be performed during that time, it is necessary to shorten the period from time t10 to time t12 in order to save fuel as much as possible.

  For this reason, in the first embodiment, the control circuit 37 does not discharge the power of the power storage unit 27 to the main power supply 13 and the load 19 if the vehicle speed v of the vehicle is less than the predetermined vehicle speed vk. The DC / DC converter 25 is controlled to maintain the power storage unit voltage Vc at the voltage value at the time t12. While the vehicle speed v is less than the predetermined vehicle speed vk, the power of the generator 11 is supplied to the main power supply 13 and the load 19. By controlling in this way, the power storage unit voltage Vc maintains the voltage value at the time when the vehicle starts to accelerate (here, time t21), so that the vehicle subsequently decelerates and supplies the regenerative power to the power storage unit 27. When charged, the battery is fully charged in a short period of time. Therefore, the period during which the power storage unit 27 is fully charged by the power generation accompanying the fuel consumption of the generator 11 can be minimized, so that the idling stop period can be lengthened accordingly.

  After that, as shown in FIG. 2A at time t22, when the vehicle speed v becomes equal to or higher than the predetermined vehicle speed vk, the control circuit 37 controls the DC / DC converter 25 so that the electric power of the power storage unit 27 is discharged. This is because the power storage unit 27 can be fully charged only by the regenerative power generated when the vehicle is decelerated, even if the power storage unit voltage Vc is the lower limit voltage Vck if the vehicle speed is equal to or higher than the predetermined vehicle speed vk. This is because the power of the unit 27 is discharged and supplied to the main power supply 13 and the load 19 for effective use. As a result of such control, as shown in FIG. 2B, the power storage unit voltage Vc decreases with time after time t22. Moreover, since the electric power from the electrical storage part 27 is obtained, the generator 11 will be in a power generation stop state as shown in FIG.2 (c). As a result, the mechanical burden on the engine of the generator 11 is reduced, so that fuel efficiency can also be reduced from this point.

  At time t23, as shown in FIG. 2A, the vehicle speed v becomes constant at a predetermined vehicle speed vk or higher. At this time, as shown in FIG. 2B, the power storage unit voltage Vc has not reached the lower limit voltage Vck, and therefore the power storage unit 27 continues to discharge. Thereby, as shown in FIG.2 (c), the generator 11 maintains the said electric power generation stop state. The state at time t23 is the same as that at time t0. Thereafter, by appropriately repeating such an operation, the idling stop period can be made as long as possible while effectively using the regenerative power, so that the fuel consumption of the entire vehicle can be reduced.

  With the above configuration and operation, even if the vehicle decelerates from the low speed state and the regenerative power cannot be sufficiently charged in the power storage unit 27, the idling stop is started after the power storage unit 27 is fully charged. A sufficient idling stop period can be obtained, thereby realizing a vehicle power supply apparatus that can save fuel.

  In the first embodiment, the default vehicle speed vk is 40 km / h and the fuel cut end vehicle speed vf is 10 km / h. However, the present invention is not limited to these values, and the capacity of the power storage unit 27 is not limited to these values. Depending on the power generation amount of the regenerative power and the like, the fuel cut end vehicle speed vf may be determined as an optimum value according to the type of engine, the vehicle type, and the like.

  Furthermore, the default vehicle speed vk is not limited to a constant value, and the default vehicle speed vk may be varied based on the power storage unit voltage Vc. That is, if the power storage unit voltage Vc is high, the power storage unit 27 can be fully charged by the regenerative power during deceleration even if the regenerative power is small, so the default vehicle speed vk may be lowered. Therefore, the correlation between the storage unit voltage Vc and the predetermined vehicle speed vk that can fully charge the storage unit 27 is obtained in advance and stored in the memory built in the control circuit 37, so that the storage unit voltage Vc is obtained. Thus, the predetermined vehicle speed vk can be varied. As a result, in the first embodiment, as shown from time t21 to time t22 in FIG. 2B, the power storage unit 27 is controlled not to be discharged until the vehicle speed v reaches 40 km / h. By varying the vehicle speed vk, it is possible to lengthen the period during which the power storage unit 27 is discharged. Therefore, if the predetermined vehicle speed vk is varied, the control of the control circuit 37 becomes complicated, and depending on the type of the microcomputer, it is necessary to be able to perform high-speed processing, but the regenerative power can be used more effectively.

  Alternatively, the predetermined vehicle speed vk may not be provided, and the regenerative power stored in the power storage unit 27 may be controlled to be discharged to the main power supply 13 and the load 19 only during the idling stop period. In this case, since the period during which the power storage unit voltage Vc is high increases, the power storage unit 27 is connected with fuel consumption even though the vehicle is stopped as from time t11 to time t12 in FIGS. The charging period can be shortened. However, since the regenerative power is not used during acceleration or constant speed traveling of the vehicle, the regenerative power is not effectively used as much as in the first embodiment when the vehicle continues to travel for a long period of time. Accordingly, the setting or non-setting of the default vehicle speed vk may be appropriately determined according to the traveling state of the vehicle.

  In the first embodiment, as shown at time t6 and time t13 in FIGS. 2B and 2C, the engine is restarted when the power storage unit voltage Vc reaches the lower limit voltage Vck during the idling stop. Then, power is generated by the generator 11 with fuel consumption, and the power storage unit voltage Vc is controlled to maintain the lower limit voltage Vck. However, this may be the operation described below.

  That is, when the storage unit voltage Vc reaches a predetermined lower limit voltage Vck while the idling stop is being performed, the control circuit 37 starts the engine with the power of the main power supply 13 and the generator 11 generated thereby. The DC / DC converter 25 is controlled to charge the power storage unit 27 with electric power. Thereafter, when the power storage unit voltage Vc reaches the full charge voltage Vcu, control is performed so that the idling stop is resumed, and the DC / DC converter 25 is controlled so as to supply the power of the power storage unit 27 to the main power supply 13 and the load 19. To do. These operations are repeated while the vehicle is in use and stopped. The use of the vehicle is defined as an ignition (not shown) of the vehicle being on. By controlling in this way, fuel consumption can be reduced when the vehicle has been stopped for a long time during use. That is, the power storage unit 27 of the first embodiment can be charged from the lower limit voltage Vck to the full charge voltage Vcu in 5 seconds as described above. Furthermore, power can be supplied to the main power supply 13 and the load 19 for about 1 minute (when power consumption is 100 W) in a fully charged state. For these reasons, when the power storage unit voltage Vc reaches the lower limit voltage Vck, the engine is restarted and the power storage unit 27 is fully charged by the generator 11 even with fuel consumption, and then the engine is stopped. Control that discharges the electric power of power storage unit 27 again, compared with the configuration in which the electric power of power storage unit 27 is discharged only once while the vehicle is in use and stopped, as in the first embodiment. Since the period during which the vehicle is stopped can be made longer, further fuel saving can be achieved. In addition, as described above, such control is performed by extending the idling stop period by fully charging the power storage unit 27 even if the fuel is consumed as long as the engine can be stopped for 5 seconds or more. Based on the ability to reduce consumption.

  However, when the power consumption is large or the capacity of the power storage unit 27 is small, the fuel saving effect may not be obtained even if the power storage unit 27 is repeatedly charged and discharged while the vehicle is in use. Therefore, the control circuit 37 may determine whether or not to repeatedly charge and discharge the power storage unit 27 by grasping the power consumption, the capacity decrease due to the deterioration of the power storage unit 27, and the like. In addition, since repeated charging / discharging of the power storage unit 27 places a burden on the starter 15, it may be desirable not to repeatedly charge / discharge depending on the durability of the starter 15.

(Embodiment 2)
FIG. 3 is a time-dependent change diagram of various characteristics of the vehicle power supply device according to Embodiment 2 of the present invention. FIG. 3A is a time-dependent change diagram of the vehicle speed v, and FIG. , (C) shows a time-dependent change diagram of the generator state.

  In the second embodiment, the vehicle has a function of stopping the engine while the vehicle is decelerating in addition to the idling stop function and the regenerative power recovery function while the vehicle is stopped as described in the first embodiment. This additional function performs the following operations.

  First, in the configuration of the first embodiment, when the vehicle speed v reaches the fuel cut end vehicle speed vf during deceleration of the vehicle, the vehicle reinjects fuel into the engine in order to maintain the engine idling speed. Thereby, an engine stall is avoided.

  On the other hand, in the configuration of the second embodiment, when the vehicle speed v reaches the fuel cut end vehicle speed vf during deceleration of the vehicle, the vehicle stops the engine with a clutch (not shown) as neutral. Thereby, in the first embodiment, the idling stop is started from the state in which the vehicle is stopped. However, in the second embodiment, when the vehicle speed v reaches the fuel cut end vehicle speed vf, the engine is stopped. The idling stop is started from that point. Therefore, since the period during which the engine is stopped is longer than that in the first embodiment, the fuel consumption can be further improved. The vehicle that stops the operation of the engine while traveling is described in, for example, Japanese Patent Application Laid-Open Nos. 11-257121 and 2007-177870.

  In the second embodiment, a case where a vehicle power supply device is applied to the vehicle described above will be described.

  First, the configuration of the vehicle power supply device is the same as that shown in FIG.

  Next, operations that characterize the vehicle power supply device according to the second embodiment will be described with reference to FIG. Note that the time-dependent change diagram of the vehicle speed v shown in FIG. 3 (a) is the same as FIG. 2 (a). Further, the time t on the horizontal axis in FIG. 3 indicates the same state as in FIG.

  In FIG. 3, since the operation from time t0 to time t3 is the same as that in FIG. 2, detailed description thereof is omitted.

  As shown in FIG. 3A at time t31, when the vehicle speed v reaches the fuel cut end vehicle speed vf, the control circuit 37 detects the power storage unit voltage Vc and compares it with the full charge voltage Vcu. Here, as shown in FIG. 3 (b), the power storage unit voltage Vc reaches the full charge voltage Vcu at the time t31, so the control circuit 37 controls the data signal data for the vehicle to stop the engine. Transmit to circuit 41. In response to this, the vehicle control circuit 41 performs the operation of stopping the engine by setting the clutch to neutral. As a result, the generator 11 is also stopped, so that the generator 11 is in a power generation stopped state at time t31 as shown in FIG. However, since the control circuit 37 transmits the data signal data so as to stop the engine, the control circuit 37 controls the DC / DC converter 25 so as to discharge the regenerative power stored in the power storage unit 27 to the main power supply 13 and the load 19. The load 19 can be continuously operated. With such an operation, as shown in FIG. 3B, the power storage unit voltage Vc decreases with time after time t31.

  At time t32, as shown in FIG. 3A, the vehicle speed v becomes 0 km / h. However, since the engine is already stopped at time t31, the control circuit 37 continues to stop the engine even at time t32.

  At time t33, as shown in FIG. 3B, the power storage unit voltage Vc reaches the lower limit voltage Vck. Thereby, the control circuit 37 transmits the data signal data to the vehicle control circuit 41 so as to restart the engine. This operation is the same as time t6 in FIG. As a result, power can be supplied from the generator 11 to the main power supply 13 and the load 19 after time t33. As described in the first embodiment, control may be performed so that the power of the main power supply 13 is supplied to the load 19 without restarting the engine at time t33. In this case, the state of the generator 11 is the operation indicated by the thick dotted line in FIG.

  Due to the operation from time t31 to time t33 described above, the idling stop period is a period from time t31 when the engine stops while the vehicle decelerates to time t33 when the engine restarts. When this period is compared with the idling stop period from time t5 to time t6 in the first embodiment, in this second embodiment, the idling stop period corresponds to starting from time t4 in FIG. The idling stop starts earlier than in the first mode. However, since the vehicle is stopped longer than the period from when the power storage unit voltage Vc reaches the full charge voltage Vcu to the lower limit voltage Vck, the discharge from the power storage unit 27 has the same current to the main power supply 13 and the load 19. Then, the discharge period is the same as that of the first embodiment. Therefore, the description here is based on the premise that the currents in the first embodiment and the second embodiment are the same. Therefore, the idling stop is faster in the second embodiment than in the first embodiment. The discharge period, that is, the idling stop period is the same only by starting and ending.

  An example in which the idling stop period in the vehicle of the second embodiment is extended and fuel consumption can be reduced will be described from time t37 to time t39, which will be described later.

  Next, since the operation from time t7 to time t9 in FIG. 3 is the same as that in the first embodiment, description thereof is omitted.

  In a state where the regenerative power is charged in the power storage unit 27 at time t9, when time t34 is reached, the vehicle speed v reaches the fuel cut end vehicle speed vf as shown in FIG. Here, the control circuit 37 determines whether or not the power storage unit voltage Vc has reached the full charge voltage Vcu, but the power storage unit voltage Vc has not reached the full charge voltage Vcu at time t34 as shown in FIG. 3B. . Therefore, originally, as described at time t31, the engine is stopped while the vehicle is decelerating, and the idling stop is started. In order to reach the voltage Vcu, a data signal data is transmitted to the vehicle control circuit 41 so as to reinject fuel into the engine. As a result, the engine consumes fuel and is driven, and the generator 11 enters the fuel consumption power generation state as shown in FIG. Therefore, the control circuit 37 controls the DC / DC converter 25 so as to charge the power storage unit 27 with the electric power generated by the generator 11 with the fuel consumption of the engine until the power storage unit voltage Vc reaches the full charge voltage Vcu. .

  Thereafter, at time t35, as shown in FIG. 3A, the vehicle speed v becomes 0 km / h, and the vehicle stops. However, as shown in FIG. 3B, the power storage unit voltage Vc does not reach the full charge voltage Vcu even at this time. Therefore, even when the vehicle speed v becomes 0 km / h, the control circuit 37 continues to drive the engine, and charges the power storage unit 27 with the electric power accompanying the fuel consumption generated by the generator 11. This operation is the same as time t11 in the first embodiment.

  With these operations, as shown in FIG. 3B, the power storage unit voltage Vc increases from time t34 to time t36. When power storage unit voltage Vc reaches full charge voltage Vcu at time t36, control circuit 37 transmits data signal data to vehicle control circuit 41 so as to stop the engine, and includes main power supply 13 and load 19 The DC / DC converter 25 is controlled so as to supply the electric power of the power storage unit 27 to the power source. By these operations, as shown in FIG. 3C, the generator 11 is in a power generation stop state, and the idling stop is started from time t36. Further, as shown in FIG. 3B, the power storage unit voltage Vc decreases with time after time t36. The operation at time t36 is the same as that at time t12 in FIG.

  By such an operation, a period from time t34 to time t35 when the engine is normally stopped (period in which the engine is stopped while the vehicle is decelerating) and a period from time t35 to time t36 (the vehicle is stopped). The operation of charging the power storage unit 27 without stopping the engine is performed if the power storage unit voltage Vc does not reach the full charge voltage Vcu even during the engine stop period). Similar to 1, it is possible to obtain a sufficient idling stop period even when the regenerative power cannot be sufficiently recovered at the time of low speed deceleration.

  In the second embodiment, the power storage unit voltage Vc even if the power storage unit 27 is charged with the power generated by the generator 11 during the period from time t34 to time t35 when the engine is stopped. Has been described for the case where the power storage unit 27 is charged with the generated power accompanied by fuel consumption even during the period from time t35 to time t36 when the vehicle is stopped without reaching the full charge voltage Vcu. When the power storage unit voltage Vc reaches the full charge voltage Vcu within the period up to t35, the control circuit 37 stops the engine and starts the idling stop at that time, and from the power storage unit 27 to the main power supply 13 and the load 19 Control to discharge to.

  Next, since the operation from time t13 to time t18 in FIG. 3 is the same as that of the first embodiment, description thereof is omitted.

  If the vehicle speed v reaches the fuel cut end vehicle speed vf at time t37 as shown in FIG. 3A, the control circuit 37 is decelerating because the power storage unit voltage Vc reaches the full charge voltage Vcu. While stopping and starting the idling stop, the DC / DC converter 25 is controlled so that the regenerative power stored in the power storage unit 27 from time t37 to time t38 is discharged to the main power supply 13 and the load 19. Accordingly, the power storage unit voltage Vc decreases with time as shown in FIG. This operation is the same as at time t31.

  Thereafter, as shown in FIG. 3 (a), the vehicle speed v becomes 0 km / h at time t38, but the engine is already stopped at time t37, so the stopped state is maintained as it is. This operation is also the same as at time t32.

  The vehicle starts to travel at time t39. As a result, the vehicle speed v increases with time as shown in FIG. At this time, since the vehicle control circuit 41 restarts the engine by the starter 15, the generator 11 performs the fuel consumption power generation as shown in FIG. At this time, since the vehicle speed v is smaller than the predetermined vehicle speed vk, power to the main power supply 13 and the load 19 is supplied from the generator 11, and the control circuit 37 stops the discharge of the power storage unit 27, that is, the power storage unit voltage Vc. Controls the DC / DC converter 25 so as to maintain the value at the time t39. As a result, as shown in FIG. 3B, the power storage unit voltage Vc becomes a constant value after time t39.

  When the stop period of the vehicle is short as from time t38 to time t39, the idling stop period can be made longer in the second embodiment than in the first embodiment. That is, in the first embodiment, the idling stop is performed only during the period in which the vehicle is stopped from time t20 to time t21 in FIG. 2, but in the second embodiment, the vehicle speed v is changed to the fuel cut end vehicle speed vf. Since the engine is stopped from the point in time (time t37), the idling stop can be performed longer for a period from time t37 to time t38 than in the first embodiment. Accordingly, fuel consumption is reduced accordingly, and fuel saving can be achieved.

  Since the operation after time t22 is the same as that of the first embodiment, the description thereof is omitted.

  With the above configuration and operation, even if the engine is stopped while the vehicle is decelerating, if the vehicle decelerates from a low speed state and the regenerative power cannot be sufficiently charged in the power storage unit 27, the power storage unit Since the idling stop is started after 27 is fully charged, a sufficient idling stop period can be obtained, and a vehicle power supply device capable of saving fuel can be realized.

  In the second embodiment, similarly to the first embodiment, when the vehicle is stopped and the idling stop is continued, the power storage unit 27 may be repeatedly charged and discharged.

  Further, the values of the default vehicle speed vk and the fuel cut end vehicle speed vf shown in FIG. 3A are not limited to these, and may be set as appropriate according to various conditions described in the first embodiment. .

  Further, as described in the first embodiment, a configuration in which the default vehicle speed vk is varied based on the power storage unit voltage Vc, a configuration in which the default vehicle speed vk is not provided, and a configuration in which setting and non-setting of the default vehicle speed vk are appropriately determined. You may apply to this Embodiment 2. FIG.

  Further, in the second embodiment, the configuration in which the idling stop is performed even when the vehicle is stopped has been described. However, this is not applied to the vehicle in which the engine is stopped only during deceleration without performing the idling stop while the vehicle is stopped. A power supply device may be applied. Even in this case, since the engine is stopped from the fuel cut end time to the stop time, fuel consumption can be reduced accordingly.

  In the first and second embodiments, the end of the fuel cut is determined based on the vehicle speed v. However, the present invention is not limited to this. For example, the engine speed, the state of the brake pedal or the accelerator pedal, the acceleration of the vehicle, the steering wheel The end of the fuel cut may be determined based on various parameters such as a steering angle or an arbitrary combination of these parameters.

  Moreover, although the said electrical double layer capacitor was used for the electrical storage part 27 in Embodiment 1, 2, other capacitors, such as an electrochemical capacitor, may be used. Moreover, although it is good also as a structure which uses a secondary battery as the electrical storage part 27, since the said secondary battery takes time to fully charge, in order to achieve a fuel-saving further, the said capacitor which can be charged quickly is used. Better.

  Since the vehicle power supply device according to the present invention can obtain a sufficient idling stop period even when the vehicle decelerates from a low speed state and has a small amount of regenerative power, the vehicle power supply device with an idling stop function and a regenerative power recovery function in particular. Useful as such.

DESCRIPTION OF SYMBOLS 11 Generator 13 Main power supply 19 Load 25 DC / DC converter 27 Power storage part 35 Power storage part voltage detection circuit 37 Control circuit

Claims (6)

A generator that generates electricity from the vehicle engine;
A power storage unit electrically connected to the generator via a DC / DC converter;
A main power source electrically connected to the generator, and a load;
A power storage unit voltage detection circuit that is electrically connected to the power storage unit and detects a power storage unit voltage (Vc);
A control circuit electrically connected to the DC / DC converter and the power storage unit voltage detection circuit,
The control circuit controls the DC / DC converter to charge the power storage unit with regenerative power generated by the generator,
If the power storage unit voltage (Vc) does not reach a predetermined full charge voltage (Vcu) when the vehicle stops, the generator is accompanied by fuel consumption of the engine until the full charge voltage (Vcu) is reached. The DC / DC converter is controlled so as to charge the electric power generated by the power storage unit, and when the power storage unit voltage (Vc) reaches the full charge voltage (Vcu), the engine is stopped and the idling stop is started. And a vehicle power supply apparatus configured to control the DC / DC converter so as to supply power of the power storage unit to the main power supply and the load. When the power storage unit voltage (Vc) reaches a predetermined lower limit voltage (Vck) while the idling stop is being performed, the control circuit starts the engine with the power of the main power source, and is generated thereby Controlling the DC / DC converter to charge the power storage unit with the power of the generator;
When the power storage unit voltage (Vc) reaches the full charge voltage (Vcu), control is performed so that the idling stop is resumed, and the DC / DC is supplied to supply power to the main power source and the load. The power supply device for a vehicle according to claim 1, wherein the operation for controlling the DC converter is repeated while the vehicle is stopped in use. A generator that generates electricity from the vehicle engine;
A power storage unit electrically connected to the generator via a DC / DC converter;
A main power source electrically connected to the generator, and a load;
A power storage unit voltage detection circuit that is electrically connected to the power storage unit and detects a power storage unit voltage (Vc);
A control circuit electrically connected to the DC / DC converter and the power storage unit voltage detection circuit,
The control circuit controls the DC / DC converter to charge the power storage unit with regenerative power generated by the generator,
If the power storage unit voltage (Vc) does not reach a predetermined full charge voltage (Vcu) when the engine is stopped while the vehicle is decelerating, fuel consumption of the engine until the full charge voltage (Vcu) is reached. The DC / DC converter is controlled so that the power generated by the generator is charged in the power storage unit, and the engine is stopped when the power storage unit voltage (Vc) reaches the full charge voltage (Vcu). And a vehicle power supply apparatus configured to control the DC / DC converter so as to supply power of the power storage unit to the main power supply and the load. When the vehicle speed (v) of the vehicle is equal to or higher than a predetermined vehicle speed (vk), the control circuit controls the DC / DC converter to discharge the power of the power storage unit to the main power source and the load. The vehicle power supply device according to claim 1 or 3. 5. The vehicle power supply device according to claim 4, wherein the control circuit varies the predetermined vehicle speed (vk) based on the power storage unit voltage (Vc). The vehicular power supply device according to claim 1, wherein the power storage unit includes a capacitor.

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