JPWO2012137315A1 - Vehicle power supply system - Google Patents

Abstract

A generator (1), a rectifier (2) that rectifies AC power of the generator (1) and outputs it to the power generation bus (A), a battery (4), a power storage device (6), and a power generation bus voltage ( A first DC / DC converter (5) for controlling Va to maintain a predetermined voltage target value, and a second DC / DC converter of a current control type for controlling input or output current to a predetermined current target value ( 7) and a control circuit (8) for controlling the generator (1), the first DC / DC converter (5), and the second DC / DC converter (7), and the control circuit (8) is a second DC / DC converter. The current target value (Iref) of (7) is determined based on at least one of the power generation bus voltage (Va) or the battery bus voltage (Vb), and the input or output current of the second DC / DC converter (7) is determined as the current target. Keep the value (Iref) Controls to, when performing charging or discharging of the power storage device (6), controls the generated power of the generator (1) according to the voltage value of the electric storage device (6).

Description

  The present invention relates to a vehicle power supply system, and more particularly to a vehicle power supply system that can realize active regeneration of braking energy of a vehicle.

  The conventional vehicle power supply system actively regenerates braking energy by setting the power generation voltage of the generator that is driven by the engine and supplies power to the battery to be higher when the vehicle is decelerating than when it is not decelerating. Is going. On the other hand, the power generation voltage of the generator is set to be lower than that during deceleration when the vehicle is not decelerated, thereby reducing the load on the engine and improving fuel consumption (see, for example, Patent Document 1).

JP 2008-67504 A

  However, since the vehicle power supply system of Patent Document 1 is configured to charge the battery by directly supplying the power generated by the generator to the battery, if the power generated by the generator is increased when the vehicle is decelerated. The battery voltage increases, leading to a shortened battery life. Therefore, there has been a problem that braking energy cannot be regenerated positively by increasing the power generated by the generator during deceleration.

  The present invention has been made to solve the above-described problems, and can increase the generated power of the generator while keeping the voltage of each part of the vehicle power supply system appropriate. Provided is a vehicle power supply system capable of actively regenerating braking energy.

A vehicle power supply system according to the present invention includes:
A generator driven by an engine to generate AC power;
A rectifier that rectifies the AC power generated by the generator into DC power and outputs it to the power generation bus;
A battery for supplying electric power to the in-vehicle load via the battery bus;
An electricity storage device for storing electric power generated from the generator;
A first DC / DC converter that has one terminal connected to the power generation bus and the other terminal connected to the battery bus, and is controlled to maintain the voltage of the power generation bus at a predetermined voltage target value;
A current-controlled second DC / DC converter connected to the power generating bus and the other terminal connected to the power storage device and controlled to keep the input or output current at a predetermined current target value;
A control circuit for controlling the generator, the first DC / DC converter, and the second DC / DC converter;
The control circuit determines the current target value of the second DC / DC converter based on at least one of the voltage of the power generation bus and the voltage of the battery bus, and sets the input or output current of the second DC / DC converter as described above. While controlling to keep the current target value,
When charging or discharging the power storage device, the generated power of the generator is controlled according to the voltage value of the power storage device.

  According to the vehicle power supply system of the present invention, it is possible to increase the generated power of the generator while keeping the voltage of each part of the vehicle power supply system appropriate, and to actively regenerate the braking energy of the vehicle.

1 is a circuit block diagram showing a vehicle power supply system according to Embodiment 1 of the present invention. It is a circuit block diagram which shows the example of the generator used for the vehicle power supply system which concerns on Embodiment 1 of this invention, and a rectifier. It is a figure which shows the output characteristic of the generator used for the vehicle power supply system which concerns on Embodiment 1 of this invention. It is a circuit diagram which shows the example of the 1st DC / DC converter used for the vehicle power supply system which concerns on Embodiment 1 of this invention. It is a circuit diagram which shows the example of the 2nd DC / DC converter used for the vehicle power supply system which concerns on Embodiment 1 of this invention. It is a circuit block diagram for demonstrating the relationship between the electric current of each part of the power supply system for vehicles which concerns on Embodiment 1 of this invention, and a voltage. FIG. 3 is a functional block diagram for determining a current target value of a second DC / DC converter in the control circuit of the vehicle power supply system according to Embodiment 1 of the present invention. 5 is a flowchart for controlling a current of a second DC / DC converter in the control circuit of the vehicle power supply system according to Embodiment 1 of the present invention. It is a figure which shows the mode of overvoltage generation | occurrence | production in the vehicle power supply system which concerns on Embodiment 1 of this invention. It is a figure which shows the mode of a voltage drop generation | occurrence | production in the vehicle power supply system which concerns on Embodiment 1 of this invention. It is a figure which shows the mode of overvoltage suppression in the vehicle power supply system which concerns on Embodiment 1 of this invention. It is a figure which shows the mode of a voltage drop suppression in the vehicle power supply system which concerns on Embodiment 1 of this invention. FIG. 3 is a flowchart for determining the generated power control of the generator and the operation of the second DC / DC converter in the control circuit of the vehicle power supply system according to Embodiment 1 of the present invention. FIG. FIG. 6 is a flowchart for determining the generated power control of the generator and the operation of the second DC / DC converter in the control circuit of the vehicle power supply system according to Embodiment 2 of the present invention. FIG. It is a flowchart which controls the electric current of a 2nd DC / DC converter in the control circuit of the vehicle power source system which concerns on Embodiment 3 of this invention. It is a flowchart which defines the electric power generation control of a generator, and operation | movement of a 2nd DC / DC converter in the control circuit of the vehicle power supply system which concerns on Embodiment 3 of this invention.

Embodiment 1 FIG.
1 is a circuit block diagram showing a vehicle power supply system according to Embodiment 1 of the present invention. In FIG. 1, the vehicle power supply system of the present embodiment is driven by an engine (not shown) to generate AC power, and the AC power generated by the generator 1 is rectified to DC power. The rectifier 2 that outputs to the power generation bus A, the battery 4 that supplies power to the in-vehicle load 3 via the battery bus B, the input end of the power generation bus A and the output end of the battery bus B are connected. The first DC / DC converter 5, the electric double layer capacitor 6 as a power storage device for accumulating the power generated by the generator 1, and the input end of the power generation bus A are connected to the output end of the electric double layer capacitor 6. that the first 2DC / DC converter 7, the power generation bus voltages Va, the battery bus voltage Vb, the voltage _{V EDLC} of the electric double layer capacitor 6, electric power generated Pa of the generator 1, the acceleration signal of the vehicle It detects, and a power generator 1, the control circuit 8 for outputting a first 1 DC / DC converter 5 and the 2DC / DC converter 7 respectively command signal to S1, S2, S3. In the example of FIG. 1, the vehicle acceleration signal 9 is used, but any signal that can detect the acceleration / deceleration state of the vehicle may be used.

  The AC power generated by the generator 1 is converted to DC power by the rectifier 2, converted to DC voltage suitable for the battery 4 by the first DC / DC converter 5, and then supplied to the battery 4. The second DC / DC converter 7 performs an operation of charging the electric double layer capacitor 6 with the DC power of the power generation bus A and an operation of supplying the DC power stored in the electric double layer capacitor 6 to the power generation bus A.

  The battery 4 is a secondary battery such as a lead storage battery or a nickel / cadmium storage battery, and the rated voltage is 14 V, for example.

  The electric double layer capacitor 6 as an electricity storage device plays a role of leveling the power supplied to the battery 4 by accumulating the generated power from the generator 1 or supplementing the power shortage of the battery 4. . In addition, as an electrical storage device, not only the electric double layer capacitor 6 like this example but a lithium ion battery, a nickel metal hydride storage battery, etc. can also be used.

FIG. 2 is a circuit block diagram showing an example of the generator and rectifier of this embodiment.
The generator 1 is, for example, a Landel type AC generator including a claw pole type rotor 12 having a field winding 11, a stator 14 having a three-phase AC winding 13, and a regulator circuit 15. The claw pole type rotor 12 of the generator 1 is connected to the engine 100.
The regulator circuit 15 includes a switching element (MOSFET) 16 and a diode 17. The drain terminal of the switching element (MOSFET) 16 is connected to the anode terminal of the diode 17, the source terminal is grounded, and the gate drive signal from the control circuit 8 is input to the gate terminal. The cathode terminal of the diode 17 is connected to the power generation bus A that connects the output terminal 2 a of the rectifier 2 and the input terminal of the first DC / DC converter 5. Further, both ends of the field winding 11 are connected to the cathode terminal of the diode 17 and the connection point between the anode terminal of the diode 17 and the drain terminal of the switching element (MOSFET) 16, respectively.
The rectifier 2 is a three-phase full-wave rectifier circuit composed of a bridge circuit in which three diode pairs formed by connecting two diodes 21 in series are connected in parallel, and is induced in the three-phase AC winding 13 of the generator 1. The rectified AC power is rectified to DC power.

FIG. 3 is a diagram illustrating the relationship between the rotational speed of the rotor of the generator 1 and the generated power Pa when the power generation bus voltage Va is 14 V (solid line), 28 V (one-dot chain line), and 42 V (dotted line).
In FIG. 3, when the power generation bus voltage Va is constant (Va = 14V, 28V, 42V), the generated power Pa is zero when the rotational speed is equal to or lower than a predetermined minimum value (Rs = R1, R2, R3), and the rotational speed. Increases above a predetermined minimum value, the generated power Pa converges to a constant value while increasing. When the power generation bus voltage Va is high (for example, Va = 42V), the convergence value of the generated power when the rotational speed is high is higher than when the power generation bus voltage Va is low (for example, Va = 14V), but when the rotational speed is lower than a predetermined value. The generated power Pa becomes lower. Further, when the power generation bus voltage Va is high, the generated power Pa becomes zero at a higher rotational speed than when the power generation bus voltage Va is low.

  The first DC / DC converter 5 includes a constant input voltage type DC / DC converter that maintains an input terminal at a predetermined target voltage, or a constant buck-boost ratio type DC / DC that maintains an input / output voltage ratio at a predetermined target voltage ratio. Use a converter. The first DC / DC converter 5 may be a DC / DC converter with bidirectional power transfer. Here, the side connected to the power generation bus A is called “input side”, and the side connected to the battery bus B is called “output side”. The target voltage and the target voltage ratio of the first DC / DC converter 5 are switched so that the power generation bus voltage Va is, for example, any one of 14V, 28V, and 42V.

  As the constant input voltage type DC / DC converter, a general DC / DC converter main circuit such as a step-down chopper circuit can be used, and feedback control is performed so as to keep the voltage at the input terminal at the target voltage. In addition, as a constant buck-boost ratio type DC / DC converter that maintains an input / output voltage ratio at a predetermined target voltage ratio, a DC / DC converter that is controlled to maintain a switching duty ratio of a step-down chopper circuit at a predetermined value, or The DC / DC converter disclosed in International Publication No. WO2008-032424 can be used.

  FIG. 4 is a circuit diagram showing a DC / DC converter described in International Publication No. WO2008-032424. This DC / DC converter includes smoothing capacitors (Cs1) to (Cs4), switching elements (Mos1L, Mos1H) to (Mos4L, Mos4H), energy transfer capacitors (Cr12) to (Cr14), and reactors (Lr12) to (Lr12) to ( Lr14), and by transferring charges between the capacitors using the LC resonance of the series resonators (LC12) to (LC14) by the on / off operation of the switching element, the voltage ratio between the input and output terminals In this method, (V1: V2) is maintained at an integer ratio. Although this converter has a restriction that the voltage ratio between the input and output terminals is an integer ratio, it does not require a large reactor as compared with a general DC / DC converter such as a chopper type, so it is small and very high efficiency can be obtained. There is a feature. The details of the operation of this converter are described in detail in the above-mentioned publication, so the description thereof is omitted here.

  Here, when (change in input voltage) / (change in input current) is considered as the input impedance of the first DC / DC converter 5, the first DC / DC converter 5 makes the input voltage constant regardless of the input current. Since it is intended to maintain, it can be regarded as a DC / DC converter with a low input impedance.

  On the other hand, the second DC / DC converter 7 is a current control type DC / DC converter that controls its input current or output current. In the present embodiment, second DC / DC converter 7 controls the input current or the output current so as to keep battery bus voltage Vb at a predetermined battery bus voltage target value V2ref. Since the second DC / DC converter 7 needs to perform both charging and discharging operations on the electric double layer capacitor 6, a DC / DC converter in which the power transfer is bidirectional is an essential requirement. Here, one of the input / output terminals, that is, the side connected to the power generation bus A is called “input side” for convenience, and the side connected to the electric double layer capacitor 6 is called “output side”, and does not necessarily represent the direction of power transfer. Not.

As the second DC / DC converter 7 of the current control type, for example, as shown in FIG. 5, a general DC / DC converter main circuit such as a step-up / down chopper circuit that is feedback-controlled so as to keep the input current at the target current. Can be applied.
In the second DC / DC converter 7 shown in FIG. 5, the input current I2i detected by the current detector 70 is compared with the input current target value Iref by the subtractor 71, and the deviation Ie is output to the PID calculator 72. The PID calculator 72 performs a PID calculation based on the deviation Ie and outputs a duty signal as an operation amount. The PWM generator 73 generates a PWM signal according to the duty signal from the PID calculator 72. The PWM signal is input to the gates of switching elements Q1H, Q1L, Q2H, and Q2L such as FETs and IGBTs through a gate drive amplifier, and controls on / off of the switching elements Q1H, Q1L, Q2H, and Q2L.

Since the second DC / DC converter 7 acts to keep the input current constant regardless of the input voltage, it can be regarded as a DC / DC converter having a high input impedance.
Here, as the second DC / DC converter 7, the current flowing through the input terminal is maintained at a predetermined target value, but the relationship between the input current and the output current of the second DC / DC converter 7 is the input / output voltage and The output current may be controlled instead of controlling the input current of the second DC / DC converter 7 because it is determined in a one-to-one relationship with the efficiency of the DC / DC converter.

  When the generator 1 and the rectifier 2, the first DC / DC converter 5, and the second DC / DC converter 7 are connected to the power generation bus A, the internal impedance of the generator 1 and the rectifier 2 is the first DC / DC converter 5. The second DC / DC converter 7 also has a high input impedance as described above. For this reason, the power generation bus voltage Va can be set to a predetermined value only by the first DC / DC converter 5 having the lowest input impedance.

  That is, by using a constant input voltage type DC / DC converter as the first DC / DC converter 5, it is possible to keep the power generation bus voltage Va at a predetermined voltage. By using the ratio type DC / DC converter, the power generation bus voltage Va can be maintained at a predetermined ratio times the battery bus voltage Vb. Thus, the power generation bus voltage Va can be uniquely determined because the first DC / DC converter 5 having a low input impedance is connected to the power generation bus A which is one circuit connection point.

  On the other hand, when the rotation speed and field current of the rotor of the generator 1 are determined to be predetermined values, the generated power Pa of the generator 1 is determined according to the characteristics shown in FIG. Furthermore, when the power generation bus voltage Va is set by the first DC / DC converter 5 as described above, the power generation current Ia output to the power generation bus A is also determined.

  As described above, the power generation bus voltage Va is set to a predetermined value by the first DC / DC converter 5 in advance, and the second DC / DC converter 7 is in a state where the power generation current Ia output to the power generation bus A is determined accordingly. When the input current I2i of the second DC / DC converter 7 is set to a predetermined value, the output current I2o of the second DC / DC converter 7, that is, the current flowing through the electric double layer capacitor 6, and the input current I1i and output current I1o of the first DC / DC converter 5 are All can be determined uniquely. This will be described in more detail with reference to FIG.

First, it is assumed that the power generation bus voltage Va is predetermined by the first DC / DC converter 5 as described above. The generated power Pa of the generator 1 at this time is determined to be a predetermined value according to the power generation bus voltage Va, the rotational speed Rs of the rotor of the generator 1 and the field current Idf from the relationship shown in FIG. The output current Ia of the generator 1 is
Ia = Pa / Va (1)
It becomes.

Here, it is assumed that the input current of the second DC / DC converter 7 is set to I2i. Then, the output current I2o of the second DC / DC converter 7 includes an input voltage (power generation bus voltage) Va, an output voltage (charging voltage of the electric double layer capacitor 6) V _EDLC, and an efficiency η2 of the second DC / DC converter 7. Is determined as follows.
When power is transferred from the input side to the output side of the second DC / DC converter 7, that is, when the electric double layer capacitor 6 is charged, the output current I2o is
I2o = (Va × I2i × η2) / V _EDLC (2)
It becomes.
Conversely, when power is transferred from the output side of the second DC / DC converter 7 to the input side, that is, when the electric double layer capacitor 6 is discharged, the output current I2o is:
I2o = (Va × I2i) / (V _EDLC × η2) (3)
It becomes.
The charging voltage V _EDLC (t) of the electric double layer capacitor 6 is determined by the following equation from the history of the capacitor capacitance C, the initial voltage V _EDLC 0, and the output current I 2 o of the second DC / DC converter 7.
V _EDLC (t) = {∫ (I2o (t) / C) dt} + V _EDLC 0 (4)

On the other hand, the input current I1i of the first DC / DC converter 5 is
I1i = Ia-I2i (5)
It becomes.
The output current I1o of the first DC / DC converter 5 is determined as follows by the battery bus voltage Vb and the efficiency η1 of the first DC / DC converter 5.
When power is transferred from the input side to the output side of the first DC / DC converter 5, that is, when the current flows from the power generation bus A to the battery bus B, the output current I1o is
I1o = (Va × I1i × η1) / Vb (6)
It becomes.
Conversely, when power is transferred from the output side of the first DC / DC converter 5 to the input side, that is, when the current flows from the battery bus B to the power generation bus A, the output current I1o is:
I1o = (Va × I1i) / (Vb × η1) (7)
It becomes.

Furthermore, if the total current flowing through the in-vehicle load 3 is IL, the current Ib flowing out from the battery 4 is
Ib = IL-I1o (8)
It becomes.
The battery bus voltage Vb is substantially the internal voltage Vb0 of the battery 4, but accurately depends on the internal resistance Rb and the battery current Ib of the battery 4,
Vb = Vb0−Rb × Ib (9)
It becomes.

  As described above, the first DC / DC converter 5 is set so that the power generation bus voltage Va becomes a predetermined value, and the power generation current Ia output to the power generation bus A is determined accordingly. By controlling the value of the input current I2i of the DC converter 7, it is possible to simultaneously control the current flowing through each part of the vehicle power supply system. That is, by setting the input current I2i to an appropriate value, the output current I2o of the second DC / DC converter 7, the input current I1i and output current I1o of the first DC / DC converter 5, and the battery current Ib are controlled.

  Since the input current I2i of the second DC / DC converter 7 can be controlled by controlling the current of each part of the power supply system according to the set value as described above, the second DC / DC converter The input current target value Iref for 7 is determined by various factors of each part of the power supply system. Conversely, if the power distribution downstream of the first DC / DC converter 5 is determined, the input current I2i of the second DC / DC converter 7 is naturally determined accordingly.

  Therefore, in the present embodiment, the second DC / DC is considered so that the battery bus voltage Vb is always kept constant in consideration of the life of the battery 4 and a necessary input voltage that does not cause an overload in the vehicle load 3. Based on the detected battery bus voltage Vb, the output power value Pa of the generator 1, and the power generation bus voltage Va, the input current target value Iref of the converter 7 is determined according to the following procedures (a) to (d). decide.

(A) In consideration of the life of the battery 4 and the input voltage required for the in-vehicle load 3, feedback control is performed so that the battery bus voltage Vb is kept constant at a predetermined battery bus voltage target value V2ref without changing as much as possible. Therefore, first, an output current target value I1ot of the first DC / DC converter 5 for keeping the battery bus voltage Vb constant is determined.
(B) Next, based on the ratio between the power generation bus voltage Va detected by a voltage detector (not shown) and the battery bus voltage Vb, that is, the step-up / step-down ratio of the first DC / DC converter 5, the above-described equation (6) Using the relationship, the output current target value I1ot of the first DC / DC converter 5 determined in the procedure (a) is converted into the input current target value I1it of the first DC / DC converter 5.
(C) Subsequently, from the generated power Pa obtained based on the rotation speed Rs of the rotor of the generator 1 and the field current Idf and the detected power generation bus voltage Va, based on the above-described equation (1). The generated current Ia of the generator 1 is obtained.
(D) Then, the input current target value Iref of the second DC / DC converter 7 is calculated from the input current target value I1it and the generated current Ia obtained in the steps (b) and (c), respectively, as follows: Ask for.
Iref = I1it−Ia (10)
In short, the above steps (a) to (d) are performed so that the output current target value I1ot of the first DC / DC converter 5 is set to the second DC / DC converter 7 so that the battery bus voltage Vb is always kept constant. This corresponds to conversion to the input current target value Iref.

FIG. 7 is an example of a block diagram of control functions executed in the control circuit 8 in order to realize the procedures (a) to (d).
First, the battery bus voltage Vb detected by the voltage detector (not shown) is compared with the battery bus voltage target value V2ref by the first subtractor 80, and the voltage deviation Ve is input to the voltage control PID controller 81. . The voltage control PID controller 81 obtains the output current target value I1ot of the first DC / DC converter 5 based on the voltage deviation Ve (the above procedure (a)).
Next, the accumulator 82 obtains the input current target value I1it of the first DC / DC converter 5 from the product of the output current target value I1ot and Vb / (Va × η1) based on the above-described equation (6) (above-mentioned Procedure (b)).
On the other hand, based on the rotational speed Rs of the rotor of the generator 1, the field current value Ifd of the generator 1, and the power generation bus voltage Va detected by a voltage detector (not shown), these values and the generator 1 The generated power Pa output from the generator 1 is obtained using a LUT (Look Up Table) 83 in which the relationship with the generated power Pa is set and registered in advance. Next, the generated power Ia is obtained by dividing the generated power Pa by the power generation bus voltage Va using the divider 84 (the above procedure (c)).
Further, the second subtracter 85 is used to derive the input current target value Iref of the second DC / DC converter 7 based on the equation (10) (the above procedure (d)).
Then, this input current target value Iref is input to the control block of the second DC / DC converter 7 shown in FIG. 5, and feedback control is performed so that the input current value I2i becomes the input current target value Iref.
In this way, the input current target value Iref of the second DC / DC converter 7 is determined, and feedback control is performed so that the input current I2i of the second DC / DC converter 7 becomes the input current target value Iref, whereby the battery bus voltage Vb can be made asymptotic to the battery bus voltage target value V2ref to be kept substantially constant.

  FIG. 8 is a control flowchart for determining the current of the second DC / DC converter 7. As described above, the second DC / DC converter 7 is configured to maintain the battery bus voltage Vb at a predetermined battery bus voltage target value V2ref. It is a flowchart for controlling an electric current. The control routine shown in FIG. 8 is repeatedly executed in the control circuit 8 at regular intervals. Specifically, the fixed period is the same as the switching period of the switching element of the second DC / DC converter 7 or about several times the switching period. The cycle of the control routine of FIG. 8 and the switching cycle of the second DC / DC converter 7 may be synchronous or asynchronous.

  In FIG. 8, when the control routine is started, a second DC / DC converter instruction signal is acquired from a generated power control flowchart described later (S101). Next, it is determined whether the second DC / DC converter instruction signal is an operation instruction signal (S102). If the instruction signal is an operation instruction signal in S102, the process proceeds to S103, and if not, the process proceeds to S109. In S103, the control circuit 8 samples the battery bus voltage Vb with a voltage detector (not shown). In S104, the control circuit 8 obtains a voltage deviation Ve between the battery bus voltage target value V2ref and the battery bus voltage Vb. Here, the battery bus voltage target value V2ref is determined based on the rated voltage of the battery 4. For example, in the case of a lead storage battery with a rated voltage of 12.6V, the battery bus voltage target value V2ref is about 14V. Next, in S <b> 105, the control circuit 8 performs a PID calculation or the like on the voltage deviation Ve to calculate an input current target value Iref of the second DC / DC converter 7. The above calculation process is as described based on FIG.

Next, in S106, the control circuit 8 samples the input current value I2i of the second DC / DC converter 7. In S107, the control circuit 8 obtains a current deviation Ie between the input current target value Iref of the second DC / DC converter 7 and the input current value I2i of the second DC / DC converter 7. Next, in S108, the control circuit 8 performs a PID calculation on the current deviation Ie to calculate an operation amount (duty signal). Then, the control circuit 8 performs pulse width modulation based on the operation amount (duty signal) (S110). Then, the control circuit 8 outputs a gate signal to the switching element of the second DC / DC converter 7 (S111). These operations are as described with reference to FIG.
If the second DC / DC converter instruction signal is not an operation instruction signal but a stop instruction signal in S102, the operation amount (duty signal) is set to 0 in S109.

  On the other hand, the control circuit 8 controls the generated power of the generator 1 so that the battery bus voltage Vb converges to the battery bus voltage target value V1ref of the generator. The battery bus voltage target value V1ref of the generator 1 is set higher by a voltage value α than the battery bus voltage target value V2ref of the second DC / DC converter 7 when the vehicle is decelerated, and the second DC / DC converter 7 is set during acceleration of the vehicle. The voltage is set lower than the battery bus voltage target value V2ref by the voltage value β. Thereby, the generated power of the generator 1 can be charged to the battery 4 and the electric double layer capacitor 6 when the vehicle is decelerated, and the stored electric power of the electric double layer capacitor 6 can be charged to the battery 4 when the vehicle is accelerated. . The voltage values α and β described above may be positive voltage values that are larger than the resolution of the detection function of the control circuit 8.

Here, when the voltage V _EDLC of the electric double layer capacitor 6 reaches a predetermined upper limit value V _MAX , charging of the electric double layer capacitor 6 is stopped in order to prevent deterioration of the capacitor. Further, when the voltage V _EDLC of the electric double layer capacitor 6 reaches a predetermined lower limit value V _MIN , the discharge of the electric double layer capacitor 6 is stopped in order to increase the utilization efficiency.

When the voltage V _EDLC of the electric double layer capacitor 6 reaches the upper limit value V _MAX and the second DC / DC converter 7 is stopped and charging of the electric double layer capacitor 6 is stopped, the generator 1 and the control circuit 8 are configured. The phenomenon shown in FIG. 9 occurs due to the response delay of the feedback system. That is, surplus power P _OVER is generated due to a response delay of the generator 1 as shown in FIG. 9A, and the battery bus voltage Vb rises in the period T1 as shown in FIG. The life of the load 3 and the battery 4 is shortened. In FIG. 9, Pa is the generated power of the generator 1, P _EDLC is the charging power of the electric double layer capacitor 6, and P _LOAD is the power supplied to the load side.

Further, when the voltage V _EDLC of the electric double layer capacitor 6 reaches the lower limit value V _MIN and the second DC / DC converter 7 is stopped to stop discharging the electric double layer capacitor 6, the generator 1 and the control circuit 8 are configured. Due to the delayed response of the feedback system, the phenomenon shown in FIG. 10 occurs. That is, an insufficient power P _UNDER due to a response delay of the generator 1 occurs as shown in FIG. 10 (a), and the battery bus voltage Vb decreases during the period T2 as shown in FIG. 10 (b), resulting in a low voltage state. The stable operation of the in-vehicle load 3 is hindered. In FIG. 10, Pa is power generated by the generator 1, P _EDLC is discharge power of the electric double layer capacitor 6, and P _LOAD is power supplied to the load side.

Therefore, in the present embodiment, a first threshold value V _MAX-1 lower than the upper limit value V _MAX and a second threshold value V _MIN-1 higher than the lower limit value V _MIN are prepared for the voltage V _EDLC of the electric double layer capacitor 6. To do.
When the voltage V _EDLC of the electric double layer capacitor 6 exceeds the first threshold value V _MAX−1 , the battery bus voltage target value V1ref (= V2ref + α) of the generator 1 is changed to the battery bus voltage target value of the second DC / DC converter 7. It is assumed that it matches V2ref. That is, α is set to 0. Thereby, the battery bus voltage value Vb converges to the battery bus voltage target value V2ref with the time constant of the feedback system composed of the generator 1 and the control circuit 8 as shown in FIG. The current target value Iref of the second DC / DC converter 7 is a value obtained by performing PID calculation on the deviation Ve between the battery bus voltage Vb and the battery bus voltage target value V2ref. Is maintained at 0, the current target value Iref of the second DC / DC converter 7 becomes 0. As a result, charging of the electric double layer capacitor 6 is stopped, and it is possible to prevent an excess of generated power due to a response delay of a feedback system constituted by the generator 1 and the control circuit 8.

Similarly, when the voltage V _EDLC of the electric double layer capacitor 6 falls below the second threshold value V _MIN−1 , the battery bus voltage target value V1ref (= V2ref−β) of the generator 1 is changed to the battery of the second DC / DC converter 7. The bus voltage target value V2ref is made to coincide. That is, β is set to 0. As a result, the battery bus voltage value Vb converges to the battery bus voltage target value V2ref with the time constant of the feedback system constituted by the generator 1 and the control circuit 8 as shown in FIG. The current target value Iref of the second DC / DC converter 7 is a value obtained by performing PID calculation on the deviation Ve between the battery bus voltage Vb and the battery bus voltage target value V2ref. When maintained at 0, the current target value Iref of the second DC / DC converter 7 becomes 0. As a result, discharging of the electric double layer capacitor 6 is stopped, and it is possible to prevent a shortage of generated power due to a response delay of a feedback system composed of the generator 1 and the control circuit 8.

  FIG. 13 is a flowchart for determining the generated power control of the generator and the operation of the second DC / DC converter according to this embodiment. The control routine of FIG. 13 is repeatedly performed at regular intervals. Specifically, the fixed period is set to about 1/10 of the time constant required for the feedback control system constituted by the generator 1 and the control circuit 8. Although it is not necessary to synchronize the cycle of the control routine of the generated power of the generator 1 shown in FIG. 13 and the cycle of the control routine of the current control of the second DC / DC converter 7 shown in FIG. 8, they may be synchronized. Further, the control flowcharts of FIGS. 13 and 8 may be cascaded as one control flowchart.

The flowchart of FIG. 13 is executed by the control circuit 8. When the control routine is started, the control circuit 8 determines whether the vehicle is decelerating or other than decelerating based on the acceleration signal (S201). If the vehicle decelerates, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or greater than the first threshold value V _MAX-1 (S202). When the voltage value V _EDLC is equal to or greater than the first threshold value V _MAX−1 , the battery bus voltage target value V1ref of the generator 1 is matched with the battery bus voltage target value V2ref of the second DC / DC converter 7 (S203). When the voltage value V _EDLC is not equal to or greater than the first threshold value V _MAX−1 , the battery bus voltage target value V1ref of the generator 1 is set as the battery bus voltage target value V2ref + α of the second DC / DC converter 7 (S204).
Subsequently, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or higher than the upper limit value V _MAX (S205). When the voltage value V _EDLC is equal to or higher than the upper limit value V _MAX , a stop instruction signal is sent as an instruction signal to the second DC / DC converter 7 (S206). When the voltage value V _EDLC is not equal to or higher than the upper limit value V _MAX , an operation instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S207).
Next, the control circuit 8 performs the generated power control of the generator 1 (S208).

On the other hand, if the vehicle is not decelerated in S201, the control circuit 8 determines whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or less than the second threshold value V _MIN-1 (S210). When the voltage value V _EDLC is equal to or less than the second threshold value V _MIN−1 , the battery bus voltage target value V1ref of the generator 1 is matched with the battery bus voltage target value V2ref of the second DC / DC converter 7 (S211). When the voltage value V _EDLC is not less than or equal to the second threshold value V _MIN−1 , the battery bus voltage target value V1ref of the generator 1 is set as the battery bus voltage target value V2ref−β of the second DC / DC converter 7 (S212).
Subsequently, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or lower than the lower limit value V _MIN (S213). When the voltage value V _EDLC is equal to or lower than the lower limit value V _MIN , a stop instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S214). If the voltage value V _EDLC is not less than or equal to the lower limit value V _MIN , an operation instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S215).
Next, the control circuit 8 performs the generated power control of the generator 1 (S208).

  The generated power control of S208 controls the generated power of the generator 1 so that the battery bus voltage Vb becomes the battery bus voltage target value V1ref of the generator 1. When the generator 1 is an AC generator as shown in FIG. 2, for example, a control signal is output from the control circuit 8 to the gate terminal of the switching element 16 of the regulator circuit 15 to perform on / off control of the switching element 16. The generated power of the generator 1 is controlled by changing the field current of the magnetic winding 11.

  As described above, according to the present embodiment, it is possible to increase the generated power of the generator while keeping the voltage of each part of the vehicle power supply system appropriate, and to actively regenerate the braking energy of the vehicle. .

  In particular, when charging or discharging of the electric double layer capacitor 6 is terminated, it is possible to prevent excessive or insufficient generated power due to a response delay of a feedback system composed of the generator 1 and the control circuit 8.

Embodiment 2. FIG.
In the vehicle power supply system according to Embodiment 2 of the present invention, when the vehicle is not decelerating, the battery bus voltage target value of the generator is set to a value lower than the battery bus voltage target value of the second DC / DC converter by a predetermined value. When the voltage value of the double layer capacitor becomes the lower limit value, the discharge of the second DC / DC converter is stopped. Since operations and configurations other than those described above are the same as those of the vehicle power supply system according to the first embodiment, description thereof will be omitted.

FIG. 14 is a flowchart for determining the generated power control of the generator and the operation of the second DC / DC converter in the control circuit for the vehicle power supply system according to Embodiment 2 of the present invention.
The control routine of FIG. 14 is repeatedly performed at regular intervals. Specifically, the fixed period is set to about 1/10 of the time constant required for the feedback control system constituted by the generator 1 and the control circuit 8. The cycle of the control routine for the generated power of the generator 1 shown in FIG. 14 and the cycle of the control routine for the current control of the second DC / DC converter 7 shown in FIG. 8 need not be synchronized, but may be synchronized. Further, the control flowcharts of FIGS. 14 and 8 may be cascaded as one control flowchart.

The flowchart of FIG. 14 is executed by the control circuit 8. When the control routine is started, the control circuit 8 determines whether the vehicle is decelerating or other than decelerating based on the acceleration signal (S301). If the vehicle is decelerated, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or greater than the first threshold value V _MAX-1 (S302). When the voltage value V _EDLC is equal to or greater than the first threshold value V _MAX−1 , the battery bus voltage target value V1ref of the generator 1 is matched with the battery bus voltage target value V2ref of the second DC / DC converter 7 (S303). When the voltage value V _EDLC is not equal to or higher than the first threshold value V _MAX−1 , the battery bus voltage target value V1ref of the generator 1 is set as the voltage target value V2ref + α (S304).
Subsequently, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or higher than the upper limit value V _MAX (S305). If the voltage value V _EDLC is greater than or equal to the upper limit value V _MAX , a stop instruction signal is sent as an instruction signal to the second DC / DC converter 7 (S306). When the voltage value V _EDLC is not equal to or higher than the upper limit value V _MAX , an operation instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S307).
Next, the control circuit 8 performs the generated power control of the generator 1 (S208).

On the other hand, if the vehicle is not decelerated in S301, the control circuit 8 sets the battery bus voltage target value V1ref of the generator 1 to the battery bus voltage target value V2ref-β of the second DC / DC converter 7 (S310). Next, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is lower than the lower limit value V _MIN (S311). When the voltage value V _EDLC is less than or equal to the lower limit value V _MIN , a stop instruction signal is sent as an instruction signal to the second DC / DC converter 7 (S312). When the voltage value V _EDLC is not less than or equal to the lower limit value V _MIN , an operation instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S313).
Next, the control circuit 8 performs the generated power control of the generator 1 (S308).

  The generated power control of S308 is to control the generated power of the generator 1 so that the battery bus voltage Vb becomes the battery bus voltage target value V1ref of the generator 1. When the generator 1 is an AC generator as shown in FIG. 2, for example, a control signal is output from the control circuit 8 to the gate terminal of the switching element 16 of the regulator circuit 15 to perform on / off control of the switching element 16. The generated power of the generator 1 is controlled by changing the field current of the magnetic winding 11.

  As described above, according to the present embodiment, it is possible to increase the generated power of the generator while keeping the voltage of each part of the vehicle power supply system appropriate, and to actively regenerate the braking energy of the vehicle. .

  In particular, when charging of the electric double layer capacitor 6 is terminated, it is possible to prevent an excessive amount of generated power due to a response delay of a feedback system composed of the generator 1 and the control circuit 8.

Embodiment 3
In the first embodiment, the target voltage of the generator and the second DC / DC converter is set to the battery bus voltage, but in this embodiment, the target voltage of the generator and the second DC / DC converter is set to the power generation bus voltage. . Since the configuration of the vehicle power supply system according to the present embodiment is the same as that of the first embodiment, the description thereof is omitted.

  In the vehicle power supply system according to the third embodiment, the first DC / DC converter 5 uses a constant step-up / step-down ratio type DC / DC converter that maintains an input / output voltage ratio at a predetermined target voltage ratio N. The current target value Iref of the second DC / DC converter 7 is determined based on the deviation Ve between the power generation bus voltage Va and the power generation bus voltage target value V5ref of the second DC / DC converter 7, and for the generator 1 The generated power is controlled so that the power generation bus voltage Va converges to the power generation bus voltage target value V4ref of the generator 1.

  The power generation bus voltage value Va is determined according to the rotational speed of the rotor of the generator 1. As shown in FIG. 2, the generated power characteristic of the generator 1 can change the maximum generated power by changing the power generation bus voltage Va according to the rotational speed of the rotor. Therefore, specifically, as shown in FIG. 2, when the rotation speed of the rotor of the generator 1 is less than Ra, the power generation bus voltage Va is 14V, and when the rotation speed is Ra or higher and less than Rb, the power generation bus voltage Va is 28V. When the rotational speed is Rb or higher, the power generation bus voltage Va is set to 42V. In this case, the target voltage ratio N of the first DC / DC converter 5 is set so that the power generation bus voltage Va becomes the above-described 14V, 28V, and 42V.

  Similarly to the first DC / DC converter 5, the power generation bus voltage target value V5ref of the second DC / DC converter 7 is set to 14V, 28V, and 42V.

  By using a constant buck-boost ratio type DC / DC converter that keeps the input / output voltage ratio at a predetermined target voltage ratio N as the first DC / DC converter 5, the power generation bus voltage Va is multiplied by the battery bus voltage Vb. Therefore, the fluctuation of the battery bus voltage Vb propagates to the power generation bus voltage Va, and the fluctuation of the power generation bus voltage Va propagates to the battery bus voltage Vb, so that the target voltage of the generator 1 and the second DC / DC converter 7 is generated. Even when the bus voltage is set, the same control as in the first embodiment can be performed.

  That is, in the present embodiment, the target voltage of the generator 1 is set to the power generation bus voltage target value V4ref, and the target voltage of the second DC / DC converter 7 is set to the power generation bus voltage target value V5ref, and the same as in the first embodiment. Then, the generated power control of the generator 1 and the current control of the second DC / DC converter 7 are performed. Hereinafter, both controls will be specifically described.

  FIG. 15 is a flowchart for controlling the current of the second DC / DC converter, and is a flowchart for controlling the current of the second DC / DC converter so as to keep the power generation bus voltage Va at a predetermined power generation bus voltage target value V5ref. . The control routine shown in FIG. 15 is repeatedly executed at regular intervals in the control circuit 8. Specifically, the fixed period is the same as the switching period of the switching element of the second DC / DC converter 7 or about several times the switching period. The cycle of the control routine of FIG. 15 and the switching cycle of the second DC / DC converter 7 may be synchronous or asynchronous.

In FIG. 15, when the control routine is started, a second DC / DC converter instruction signal is acquired from the generated power control flowchart of FIG. 16 described later (S401). Next, it is determined whether the second DC / DC converter instruction signal is an operation instruction signal (S402). If the instruction signal is an operation instruction signal in S402, the process proceeds to S403. If the instruction signal is not an operation instruction signal, the process proceeds to S409. In S403, the control circuit 8 samples the power generation bus voltage Va by a voltage detector (not shown). In S404, the control circuit 8 obtains a voltage deviation Ve between the power generation bus voltage target value V5ref and the power generation bus voltage Va. Next, in S405, the control circuit 8 performs a PID calculation or the like on the voltage deviation Ve and calculates a current target value Iref of the second DC / DC converter 7.
Next, in S406, the control circuit 8 samples the current value I2i of the second DC / DC converter 7. In S407, the control circuit 8 obtains a current deviation Ie between the current target value Iref of the second DC / DC converter 7 and the current value I2i of the second DC / DC converter 7. Next, in S408, the control circuit 8 performs a PID calculation on the current deviation Ie to calculate an operation amount (duty signal). Then, the control circuit 8 performs pulse width modulation based on the operation amount (duty signal) and generates a PWM signal (S410). Then, the control circuit 8 outputs a gate signal to the switching element of the second DC / DC converter 7 (S411).
If the second DC / DC converter instruction signal is not an operation instruction signal but a stop instruction signal in S402, the operation amount (duty signal) is set to 0 in S409.

  FIG. 16 is a flowchart for determining the generated power control of the generator and the operation of the second DC / DC converter according to this embodiment. The control routine of FIG. 16 is repeatedly performed at regular intervals. Specifically, the fixed period is set to about 1/10 of the time constant required for the feedback control system constituted by the generator 1 and the control circuit 8. The period of the control routine for the generated power of the generator 1 shown in FIG. 16 and the period of the control routine for the current control of the second DC / DC converter 7 shown in FIG. 15 need not be synchronized, but may be synchronized. Further, the control flowcharts of FIGS. 16 and 15 may be cascaded as one control flowchart.

The flowchart of FIG. 16 is executed by the control circuit 8. When the control routine is started, the control circuit 8 determines whether the vehicle is decelerating or other than decelerating based on the acceleration signal (S501). If the vehicle decelerates, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or greater than the first threshold value V _MAX-1 (S502). When the voltage value V _EDLC is greater than or equal to the first threshold value V _MAX−1 , the power generation bus voltage target value V4ref of the generator 1 is matched with the power generation bus voltage target value V5ref of the second DC / DC converter 7 (S503). When the voltage value V _EDLC is not equal to or higher than the first threshold value V _MAX−1 , the power generation bus voltage target value V4ref of the generator 1 is set as the power generation bus voltage target value V5ref + α of the second DC / DC converter 7 (S504).
Subsequently, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or higher than the upper limit value V _MAX (S505). If the voltage value V _EDLC is greater than or equal to the upper limit value V _MAX , a stop instruction signal is sent as an instruction signal to the second DC / DC converter 7 (S506). When the voltage value V _EDLC is not equal to or higher than the upper limit value V _MAX , an operation instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S507).
Next, the control circuit 8 performs the generated power control of the generator 1 (S508).

On the other hand, if the vehicle is not decelerated in S501, the control circuit 8 determines whether or not the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or less than the second threshold value V _MIN-1 (S510). When the voltage value V _EDLC is equal to or smaller than the second threshold value V _MIN−1 , the power generation bus voltage target value V4ref of the generator 1 is matched with the power generation bus voltage target value V5ref of the second DC / DC converter 7 (S511). When the voltage value V _EDLC is not less than or equal to the second threshold value V _MIN−1 , the power generation bus voltage target value V4ref of the generator 1 is set as the power generation bus voltage target value V5ref−β of the second DC / DC converter 7 (S512).
Subsequently, it is determined whether the voltage value V _EDLC of the electric double layer capacitor 6 is equal to or lower than the lower limit value V _MIN (S513). When the voltage value V _EDLC is equal to or lower than the lower limit value V _MIN , a stop instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S514). When the voltage value V _EDLC is not less than or equal to the lower limit value V _MIN , an operation instruction signal is sent to the second DC / DC converter 7 as an instruction signal (S515).
Next, the control circuit 8 performs the generated power control of the generator 1 (S508).

  The generated power control of S508 is to control the generated power of the generator 1 so that the generated bus voltage Va becomes the generated bus voltage target value V4ref of the generator 1. When the generator 1 is an AC generator as shown in FIG. 2, for example, a control signal is output from the control circuit 8 to the gate terminal of the switching element 16 of the regulator circuit 15 to perform on / off control of the switching element 16. The generated power of the generator 1 is controlled by changing the field current of the magnetic winding 11.

  As described above, according to the present embodiment, it is possible to increase the generated power of the generator while keeping the voltage of each part of the vehicle power supply system appropriate, and to actively regenerate the braking energy of the vehicle. .

  In particular, when charging or discharging of the electric double layer capacitor 6 is terminated, it is possible to prevent excessive or insufficient generated power due to a response delay of a feedback system composed of the generator 1 and the control circuit 8.

  In addition, the power generation bus voltage can be maintained at a predetermined voltage.

Claims (6)

A generator driven by an engine to generate AC power;
A rectifier that rectifies the AC power generated by the generator into DC power and outputs it to the power generation bus;
A battery for supplying electric power to the in-vehicle load via the battery bus;
An electricity storage device for storing electric power generated from the generator;
A first DC / DC converter that has one terminal connected to the power generation bus and the other terminal connected to the battery bus, and is controlled to maintain the voltage of the power generation bus at a predetermined voltage target value;
A current-controlled second DC / DC converter connected to the power generating bus and the other terminal connected to the power storage device and controlled to keep the input or output current at a predetermined current target value;
A control circuit for controlling the generator, the first DC / DC converter, and the second DC / DC converter;
The control circuit determines the current target value of the second DC / DC converter based on at least one of the voltage of the power generation bus and the voltage of the battery bus, and sets the input or output current of the second DC / DC converter as described above. While controlling to keep the current target value,
A vehicle power supply system configured to control the generated power of the generator according to a voltage value of the power storage device when charging or discharging the power storage device. The control circuit is
Determining the current target value of the second DC / DC converter based on a deviation between the battery bus voltage and the battery bus voltage target value of the second DC / DC converter;
When the vehicle is decelerating, the battery bus voltage target value of the generator is set higher than the battery bus voltage target value of the second DC / DC converter,
When the voltage of the power storage device is equal to or higher than a first threshold, the battery bus voltage target value of the generator is matched with the battery bus voltage target value of the second DC / DC converter,
When the voltage of the power storage device reaches the upper limit, stop charging the power storage device,
2. The vehicle power supply system according to claim 1, wherein the power generated by the generator is controlled so that the battery bus voltage becomes the battery bus voltage target value of the generator. The control circuit is
Determining the current target value of the second DC / DC converter based on a deviation between the battery bus voltage and the battery bus voltage target value of the second DC / DC converter;
When the vehicle is not decelerated, the battery bus voltage target value of the generator is set lower than the battery bus voltage target value of the second DC / DC converter,
When the voltage of the power storage device is equal to or lower than a second threshold value, the battery bus voltage target value of the generator is matched with the battery bus voltage target value of the second DC / DC converter,
When the voltage of the electricity storage device reaches the lower limit, stop discharging the electricity storage device,
2. The vehicle power supply system according to claim 1, wherein the power generated by the generator is controlled so that the battery bus voltage becomes the battery bus voltage target value of the generator. The control circuit is
Determining the current target value of the second DC / DC converter based on a deviation between the battery bus voltage and the battery bus voltage target value of the second DC / DC converter;
When the vehicle is not decelerating, the battery bus voltage target value of the generator is matched with the battery bus voltage target value of the second DC / DC converter,
When the voltage of the electricity storage device reaches the lower limit, stop discharging the electricity storage device,
2. The vehicle power supply system according to claim 1, wherein the power generated by the generator is controlled so that the battery bus voltage becomes the battery bus voltage target value of the generator. The control circuit is
Determining the current target value of the second DC / DC converter based on a deviation between the power generation bus voltage and the power generation bus voltage target value of the second DC / DC converter;
When the vehicle is decelerated, the power generation bus voltage target value of the generator is set higher than the power generation bus voltage target value of the second DC / DC converter,
When the voltage of the power storage device is equal to or higher than a first threshold, the power generation bus voltage target value of the generator is matched with the power generation bus voltage target value of the second DC / DC converter,
When the voltage of the power storage device reaches the upper limit, stop charging the power storage device,
The vehicle power supply system according to claim 1, wherein the power generated by the generator is controlled so that the power generation bus voltage becomes the power generation bus voltage target value of the generator. The control circuit is
A current target value of the second DC / DC converter is determined based on a deviation between the power generation bus voltage and the power generation bus voltage target value of the second DC / DC converter;
When the vehicle is not decelerated, the power generation bus voltage target value of the generator is set lower than the power generation bus voltage target value of the second DC / DC converter,
When the voltage of the power storage device is equal to or lower than a second threshold, the power generation bus voltage target value of the generator is matched with the power generation bus voltage target value of the second DC / DC converter,
When the voltage of the electricity storage device reaches the lower limit, stop discharging the electricity storage device,
The vehicle power supply system according to claim 1, wherein the power generated by the generator is controlled so that the power generation bus voltage becomes the power generation bus voltage target value of the generator.

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