JP2004222475A - Power controller for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power controller for a vehicle which can prevent the deterioration of the drive efficiency of a DC/DC converter caused by the charge and discharge of an accessory battery during idling stop or the drop of the life of the accessory battery. <P>SOLUTION: This power controller 10 is to be used in a vehicle for executing idle stop. The controller is equipped with a first battery 14 which supplies a specified accessory 26 with power during idle stop, a DC/DC converter 22 which is interposed between the first battery 14 and the specified accessory 26, a second battery 12 which is connected to the first battery 14 via the DC/DC converter 22, a control unit 24 which controls the output voltage 13 on the secondary battery side of, at least, the DC/DC converter 22, and a current sensor 40 which detects the current value of the second battery 12. The control unit 24 varies the output voltage 13 of the DC/DC converter 22, so that the current value detected by a current sensor 40 may be roughly zero, during idle stop. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a power supply control device for a vehicle including a plurality of batteries, and more particularly to a power supply control device for a vehicle that can prevent charging and discharging of an auxiliary battery during idle stop.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a power supply control device for a hybrid vehicle including a generator, a low-voltage battery (auxiliary battery) and a high-voltage battery interconnected via a DC / DC converter, a DC power supply is used during cruise traveling or engine idling. It is known to control the amount of power generated by a generator according to the amount of input / output power of a / DC converter (for example, Patent Document 1). In this conventional technique, when the state of charge (SOC) of the high-voltage battery is within a predetermined range, the amount of power generated by the generator is set to be equal to the amount of input / output power of the DC / DC converter, and the state of charge of the high-voltage battery (SOC) is set. When the SOC is smaller than the predetermined range, the power generation amount of the generator is set to a value higher than the input / output power amount of the DC / DC converter in order to promote charging of the high-voltage battery.
[0003]
[Patent Document 1]
JP-A-11-318002
[Problems to be solved by the invention]
By the way, in recent years, it has been proposed to perform an idle stop for automatically stopping an engine when a vehicle is temporarily stopped at an intersection or the like to reduce exhaust gas and improve fuel efficiency. Since power is not generated by the generator during such an idle stop, the various auxiliary devices operate using a main battery provided separately from the auxiliary battery as a power source in consideration of the life of the auxiliary battery (lead battery). I do. That is, at the time of the idle stop, by instructing the target output voltage of the auxiliary battery side terminal of the DC / DC converter, the voltage of the main battery is reduced to the target output voltage by the DC / DC converter and output to various auxiliary machines. You.
[0005]
However, depending on the indicated value of the target output voltage of the auxiliary battery side terminal of the DC / DC converter and the state of charge of the auxiliary battery, the auxiliary battery is charged / discharged, and the following inconvenience occurs. . That is, when the auxiliary battery is charged, the electric energy stored in the main battery via the DC / DC converter during traveling or the like is stored again in the auxiliary battery via the DC / DC converter, There is a problem that the driving efficiency of the DC / DC converter is deteriorated. On the other hand, when the auxiliary battery is discharged, electric power is supplied from the auxiliary battery to various auxiliary machines, so that there is a problem that the life of the auxiliary battery is reduced.
[0006]
Accordingly, the present invention is directed to a vehicle for a vehicle capable of preventing deterioration of the drive efficiency of the DC / DC converter due to charging and discharging of the auxiliary battery during idle stop, deterioration of fuel efficiency and reduction of the life of the auxiliary battery. It is intended to provide a power control device.
[0007]
[Means for Solving the Problems]
An object of the present invention is to provide a power supply control device used in a vehicle that executes an idle stop, as described in claim 1,
A first battery for supplying power to a predetermined accessory during the idle stop;
A DC / DC converter interposed between the first battery and the predetermined accessory;
A second battery connected to the predetermined accessory and connected to the first battery via the DC / DC converter;
A control unit that controls an output voltage of at least the second battery of the DC / DC converter;
A current sensor for detecting a current value of the second battery,
The control unit variably controls an output voltage of the DC / DC converter so that a current value detected by the current sensor becomes substantially zero during idle stop. Is done.
[0008]
In the present invention, the first battery (main battery) supplies power to a predetermined auxiliary device during idle stop in order to prevent the life of the second battery (auxiliary battery) from being shortened. At this time, the control unit controls the output voltage on the second battery side of the DC / DC converter. According to the present invention, the output voltage on the second battery side of the DC / DC converter is variably controlled so that the current value of the second battery becomes zero, thereby charging the second battery during idle stop. Discharge can be prevented. As a result, it is possible to reliably prevent the drive efficiency of the DC / DC converter from deteriorating due to the charging / discharging of the second battery during the idle stop, and the fuel efficiency and the service life of the second battery from lowering.
[0009]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
[0010]
FIG. 1 is a system configuration diagram of a vehicle power supply control device 10 according to one embodiment of the present invention. As shown in FIG. 1, the vehicle power supply control device 10 mainly includes an electronic control unit 24 (hereinafter, referred to as “ECU 24”) configured by a microcomputer, and includes two batteries 12 and 14. I have. In the present embodiment, the battery 12 is a lead battery (auxiliary battery) having a voltage of about 12V, while the battery 14 is a lithium ion battery (main battery) having a voltage of about 14.4V. The lead battery 12 has a higher output per unit volume (output density; unit is W / l) than the lithium ion battery 14, while the energy per unit volume (energy density; unit is Wh / l) is a low battery.
[0011]
A starter 18 is connected to the lead battery 12 and the lithium ion battery 14 via a changeover switch 16. The starter 18 is attached to an engine that functions as a power source of the vehicle. The starter 18 functions as a starting device that starts the engine from a stopped state using electric power supplied from the lead battery 12 or the lithium ion battery 14 connected via the changeover switch 16. Specifically, the starter 18 operates using the lead battery 12 as a power source during normal engine startup, and operates using the lithium ion battery 14 as a power source when restarting the engine after the end of idle stop.
[0012]
The vehicle power supply control device 10 also includes a current sensor 40. The current sensor 40 detects the current value of the lead battery 12 at a predetermined sampling cycle. The detection signal of the current sensor 40 is supplied to the ECU 24 in the sampling cycle. The ECU 24 controls the DC / DC converter 22 based on the detection value of the current sensor 40 as described later.
[0013]
An electronic control unit 49 (hereinafter, referred to as “EFI · ECU 49”) is connected to the engine. The EFI-ECU 49 confirms whether or not various idle stop permission conditions (for example, conditions relating to the engine cooling water temperature, conditions relating to the temperature of the battery, and conditions relating to the engine speed) are satisfied, and finally executes the idle stop. It is determined whether or not the condition is satisfied. When the idle stop execution condition is finally satisfied, execution of fuel injection, ignition, and the like is stopped without the driver shifting the ignition switch from the IG on state to the off state, and the engine shifts from the operation state to the stop state. Is done.
[0014]
During idle stop, that is, while the engine is temporarily stopped, the EFI-ECU 49 shifts the shift position of the transmission from the “N” range to the “D” range or the “R” range when the vehicle is an AT vehicle. It is determined whether or not the condition for releasing the idle stop is satisfied based on whether or not the shift has been performed, whether or not the brake operation has been released, and if the vehicle is an MT vehicle, whether or not the clutch pedal has been depressed. . As a result, when the condition for canceling the idle stop is satisfied, the starter 18 is activated without the driver shifting the ignition switch from the IG ON state to the starter ON state, and the engine is restarted.
[0015]
The vehicle power supply control device 10 also includes a DC generator (alternator) 20 that generates electric power by rotation of the engine. The EFI-ECU 49 controls the voltage generated by the DC generator 20 in accordance with the running state of the vehicle in order to improve fuel efficiency. Specifically, at the time of steady running or idle operation, the generated voltage of the DC generator 20 is adjusted within a range of, for example, 12.5 V to 13.5 V. Further, when the vehicle is decelerated, the generated voltage of the DC generator 20 is adjusted to a larger value (for example, 14.5 V) than during steady running or during idling. In addition, at the time of vehicle acceleration, the generated voltage of the DC generator 20 becomes zero (that is, no power is generated), as during idle stop (that is, during engine stop).
[0016]
The load 26 and the lead battery 12 are connected to the DC generator 20, and the lithium-ion battery 14 is connected via a DC / DC converter 22. The electric energy generated by the DC generator 20 is used as a power source for the load 26 and used for charging the lead battery 12 and / or the lithium ion battery 14.
[0017]
The DC generator 20 and the lead battery 12 are connected to the load 26, and the lithium ion battery 14 is connected to the load 26 via the DC / DC converter 22. The load 26 includes various auxiliary machines and a so-called by-wire system such as an accelerator and a brake. Auxiliary equipment includes headlamps, fog lamps, cornering signal lamps, corner lamps, etc., air conditioners such as air conditioners, audio, car navigation, ABS systems, oil pumps, meters, defoggers, wipers, power windows, etc. Is included. Each auxiliary device and each by-wire system are mainly supplied with power from the DC generator 20 when the engine is operating, while they are mainly supplied with power from the lithium ion battery 14 when the engine is stopped such as during idle stop.
[0018]
The DC / DC converter 22 is a bidirectional DC / DC converter, which boosts the voltage of the lead battery 12 and supplies it to the lithium ion battery 14 according to the switching operation of a built-in power transistor. The voltage on the side is reduced and supplied to the lead battery 12 side.
[0019]
The control performed by the ECU 24 on the DC / DC converter 22 includes a direction instruction of the DC / DC converter 22, an instruction of a target output voltage of the lead battery side terminal 13 of the DC / DC converter 22, and an instruction of the DC / DC converter 22. And an instruction to stop the operation of the DC / DC converter 22.
[0020]
Specifically, the ECU 24 generates two types of direction instruction signals (that is, a direction in which the voltage on the lead battery 12 side is boosted and supplied to the lithium ion battery 14 side, or the voltage on the lithium ion battery 14 side is stepped down. The operation direction of the DC / DC converter 22 is controlled by selectively supplying the DC / DC converter 22 with the direction of supply to the lead battery 12).
[0021]
Further, the ECU 24 supplies the DC / DC converter 22 with the target output voltage of the Li-side terminal 15 (in this example, the target output voltage within the range of 14.5 V to 15.5 V). The output voltage of the Li-side terminal 15 is controlled. When the target output voltage of the Li side terminal 15 of the DC / DC converter 22 is instructed, the DC / DC converter 22 boosts the voltage of the lead battery 12 to the target output voltage and outputs it to the lithium ion battery 14 side. . Thereby, charging of the lithium ion battery 14 according to the target output voltage is realized.
[0022]
The control of the output voltage of the Li-side terminal 15 is executed at the time of steady running of the vehicle, at the time of idling of the engine, and at the time of deceleration of the vehicle (at the time of regenerative braking operation). At this time, also on the lead battery 12 side, charging depending on the target output voltage of the Li side terminal 15 and the generated voltage of the DC generator 20 is realized.
[0023]
On the other hand, the ECU 24 supplies the DC / DC converter 22 with the target output voltage of the Pb side terminal 13 (the target output voltage in the range of 13.0 V to 13.5 V in this example). The output voltage of the Pb side terminal 13 is controlled. When a target output voltage of the Pb side terminal 13 of the DC / DC converter 22 is instructed, the DC / DC converter 22 reduces the voltage of the lithium ion battery 14 to the target output voltage and outputs the voltage to the lead battery 12 side. . Thereby, on the lithium ion battery 14 side, discharge depending on the target output voltage of the Pb side terminal 13 is realized.
[0024]
The control of the output voltage of the Pb side terminal 13 is executed during the idle stop. That is, during the idle stop, the lithium ion battery 14 functions as a power source of the load 26 instead of the lead battery 12 in order to prevent the life of the lead battery 12 from being shortened.
[0025]
The ECU 24 supplies the control signal for stopping the operation of the DC / DC converter 22 to the DC / DC converter 22 or stops the supply of the above-described direction instruction signal to thereby control the DC / DC converter 22. Stop the operation. The operation of the DC / DC converter 22 is stopped when the vehicle is accelerated. That is, during vehicle acceleration (at this time, the generated voltage of the DC generator 20 is zero as described above), the lead battery 12 functions as a power source of the load 26.
[0026]
In this embodiment, as described above, the target output voltage of the lead battery side terminal 13 of the DC / DC converter 22 is instructed to prevent the life of the lead battery 12 from being shortened during the idle stop. The lithium ion battery 14 functions as a power source of the load 26 instead of the battery 12. However, depending on the value of the target output voltage to be instructed, the lead battery 12 is charged or discharged due to the state of charge of the lead battery 12, and the following inconvenience occurs. That is, when the lead battery 12 is charged, the electric energy stored in the lithium-ion battery 14 via the DC / DC converter 22 during normal driving or the like is again stored in the lead battery 12 via the DC / DC converter 22. This causes a problem from the viewpoint of the driving efficiency of the DC / DC converter 22. On the other hand, when the lead battery 12 is discharged, power is supplied from the lead battery 12 to the load 26, so that there is a problem that the life of the lead battery 12 is shortened.
[0027]
On the other hand, in the present embodiment, as described in detail below, the current flowing through the lead battery 12 during the idle stop (that is, the current detection value by the current sensor 40) is monitored, and the DC current is set so that the current becomes zero. The above-described inconvenience is prevented by variably controlling the target output voltage of the lead battery side terminal 13 of the / DC converter 22.
[0028]
FIG. 2 is a flowchart of a process executed by the ECU 24 of the present embodiment to prevent the above-described inconvenience. This processing routine may be executed for each sampling cycle of the current sensor 40, and the ECU 24 is supplied with a detection signal of the current sensor 40 for each sampling cycle.
[0029]
In step 100, a process for determining whether or not the idle stop has been started is executed. As described above, the idle stop is started when various idle stop permission conditions (for example, conditions relating to the engine cooling water temperature, conditions relating to the temperature of the battery, and conditions relating to the engine speed) are satisfied. If the idle stop has been started, the routine proceeds to step 110, while if the idle stop has not been started, the current routine ends without performing any processing thereafter.
[0030]
In step 110, a process of instructing an initial value (for example, 13.3 V) of the target output voltage of the lead battery side terminal 13 of the DC / DC converter 22 is executed. When the process of step 110 is executed, as described above, the switching operation of the power transistor of the DC / DC converter 22 according to the initial value of the target output voltage is performed, and the lead battery side terminal 13 of the DC / DC converter 22 Is set to the initial value of the target output voltage.
[0031]
In the following step 120, a process of determining whether or not the current flowing through the lead battery 12 (ie, the current detection value by the current sensor 40) is greater than zero. Here, the current value of the lead battery 12 assumes that the charging current is positive. If the current flowing through the lead battery 12 is larger than zero, the next indicated value of the target output voltage is set as a value obtained by subtracting δ1 from the last indicated value, and the routine proceeds to step 150. If the current through the lead battery 12 is not greater than zero, go to step 130.
[0032]
In step 130, a process is performed to determine whether the current flowing through the lead battery 12 is smaller than zero. If the current flowing through the lead battery 12 is smaller than zero, the next indicated value of the target output voltage is set as a value obtained by adding δ2 to the previous indicated value, and the routine proceeds to step 150. On the other hand, when the current flowing through the lead battery 12 is not smaller than zero (that is, when the current flowing through the lead battery 12 is zero), the next indicated value of the target output voltage is set to the same value as the previous indicated value ( That is, the instruction value of the target output voltage is held).
[0033]
In step 150, a process of instructing the next instruction value of the target output voltage of the DC / DC converter 22 is executed. When the process of step 150 is executed, the switching operation of the power transistor of the DC / DC converter 22 is performed according to the next instruction value of the target output voltage, as described above, and the lead battery side terminal of the DC / DC converter 22 is operated. 13 is set to the next instruction value of the target output voltage.
[0034]
The processes in steps 120 to 150 are repeatedly executed until it is determined in the following step 160 that the idle stop has been completed.
[0035]
In the present embodiment, the values of δ1 and δ2 decremented and incremented in steps 120 and 130 may be constant values, but need not necessarily be the same values. The values of δ1 and δ2 may be values obtained by multiplying the absolute value of the current value of the lead battery 12 (current detection value by the current sensor 40) by a predetermined gain. In this case, the predetermined gain need not be a constant value, but may be a value corresponding to the absolute value of the current value of the lead battery 12. Alternatively, the values of δ1 and δ2 may be determined based on the learning result of the amount of change in the current value with respect to the past values of δ1 and δ2, or may be determined according to the rate of change of the current value for each routine. Is also good.
[0036]
FIG. 3 is a diagram showing the relationship between the current of the lead battery 12 and the target output voltage of the DC / DC converter 22 obtained as a result of the processing of FIG. As shown in FIG. 3, the current value of the lead battery 12 that has been discharged at the start of the control (t = 0) is finally substantially reduced by the above-described variable control of the target output voltage of the DC / DC converter 22. Converges to zero. Therefore, according to the present embodiment, the feedback control is performed so that the current value of the lead battery 12 becomes zero, so that the drive efficiency of the DC / DC converter 22 is deteriorated, the fuel efficiency is reduced, and the life of the lead battery 12 is reduced. The drop can be prevented reliably.
[0037]
In the above embodiment, the “first battery” described in the claims corresponds to the lithium-ion battery 14, and the “second battery” corresponds to the lead battery 12.
[0038]
Although the preferred embodiment of the present invention has been described in detail, the present invention is not limited to the above-described embodiment, and various modifications and substitutions can be made to the above-described embodiment without departing from the scope of the present invention. Can be added.
[0039]
For example, although the above-described embodiment relates to a power supply control device including two batteries, that is, a lead battery 12 and a lithium ion battery 14, the present invention particularly specifies the number and type of batteries. Instead, the present invention can be applied to any power supply control device having two or more batteries. For example, the present invention is also applicable to a power supply control device for a hybrid vehicle including a high-voltage hybrid battery and a lead battery.
[0040]
【The invention's effect】
According to the present invention, in a vehicle power supply control device including a plurality of batteries, by feeding back the current of an auxiliary battery and variably controlling a target output voltage of a DC / DC converter so that the current becomes zero, It is possible to reliably prevent the drive efficiency of the DC / DC converter from deteriorating and the fuel efficiency and the life of the auxiliary battery from being lowered.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of a vehicle power supply control device according to an embodiment of the present invention.
FIG. 2 is a flowchart of a process executed by an ECU according to the embodiment.
FIG. 3 is a diagram illustrating a relationship between a current of a lead battery and a target output voltage of a DC / DC converter.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Vehicle power control device 12 Lead battery 14 Lithium ion battery 16 Changeover switch 18 Starter 20 DC generator 22 DC / DC converter 24 Electronic control unit 26 Load 40 Current sensor 49 EFI · ECU

Claims (1)

A power supply control device used in a vehicle that executes an idle stop,
A first battery for supplying power to a predetermined accessory during the idle stop;
A DC / DC converter interposed between the first battery and the predetermined accessory;
A second battery connected to the predetermined accessory and connected to the first battery via the DC / DC converter;
A control unit that controls an output voltage of at least the second battery of the DC / DC converter;
A current sensor for detecting a current value of the second battery,
The power supply control device, wherein the control unit variably controls an output voltage of the DC / DC converter so that a current value detected by the current sensor becomes substantially zero during idle stop.

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