JP4204335B2 - Vehicle power supply control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle power supply control device, and in particular, a vehicle power supply comprising a first battery directly connected to a generator and a second battery connected to the generator via a voltage controller. The present invention relates to a control device.
[0002]
[Prior art]
Conventionally, a vehicular power supply control device including a plurality of batteries is known (see, for example, Patent Document 1). In this power supply control device, the plurality of batteries are connected to each other via a DC / DC converter. Each battery is charged by recovering the generated energy output from the generator to which the power of the vehicle engine is transmitted.
[0003]
[Patent Document 1]
JP 11-31802 A
[0004]
[Problems to be solved by the invention]
By the way, as the plurality of batteries mounted on the vehicle, for example, batteries having different charge acceptability between a lead battery and a lithium ion battery may be used. In such a configuration, if charging of a lithium ion battery is allowed at all times, a situation occurs in which the power generation energy of the generator is biased toward a lithium ion battery with high charge acceptance, and charging to a lead battery with low charge acceptance is insufficient. Inconvenience can occur.
[0005]
Also, assuming that charging is performed due to insufficient charging of the lithium ion battery while the generator is generating electricity with almost 100% power generation capacity, if the lead battery is in a state of near full charge, lithium A situation occurs in which the insufficient charge of the ion battery is compensated from the stored energy of the lead battery, and the lead battery is frequently discharged. If the lead battery is frequently discharged, the battery of the lead battery tends to rise, the deterioration is promoted, and the life thereof is deteriorated.
[0006]
Therefore, as described in Patent Document 1, in a vehicle power supply control device including a plurality of batteries such as a lead battery and a lithium ion battery, charging a specific battery without considering other batteries is performed. Not appropriate.
[0007]
The present invention has been made in view of the above points, and an object of the present invention is to provide a vehicle power supply control device capable of realizing charging of a specific battery without reducing the performance of other batteries. And
[0008]
[Means for Solving the Problems]
  The object is as described in claim 1, a first battery connected to a generator, a second battery connected to the generator via a voltage controller in parallel with the first battery, A vehicle power supply control device comprising:
  An actual power generation ratio detection means for detecting a ratio of an actual power generation control instruction value to a maximum value of the current power generation control instruction value of the generator;
  Engine rotation speed detection means for detecting the rotation speed of the engine for transmitting power to the generator;
  After the ratio is detected by the actual power generation ratio detection means,Based on the rotation speed of the engine detected by the engine rotation speed detection means,TheThe ratio detected by the actual power generation ratio detection means is, So that the power generation amount of the generator is fixedCorrection means for correcting;
  A second controller that controls the voltage controller so that charging to the second battery is permitted / prohibited based on whether the ratio obtained as a result of correction by the correction means is less than a predetermined ratio; Battery charge control means;
  It is achieved by a vehicle power supply control device comprising:
[0009]
In the present invention, charging of the second battery is permitted / prohibited based on whether or not the ratio of the actual value to the maximum value of the power generation control instruction value at the current time of the generator is less than a predetermined ratio. When the ratio is less than the predetermined ratio, it can be determined that there is a margin in the amount of power that can be generated by the generator, and that no discharge from the first battery connected to the generator has occurred. At this time, if the power generation energy of the generator is recovered as the charging energy of the second battery, the second battery is charged without causing the first battery to discharge and charging the first battery. It will be done without affecting.
[0010]
Further, when the power generation amount to be generated by the generator is fixed, the above-described ratio changes as the engine speed changes. In this way, even though the power generation ratio of the generator has actually changed, if the ratio detected by the actual power generation ratio detection means is used as it is for charging control to the second battery, Due to the fact that the power generation margin is not accurately detected, there may be a disadvantage that charging the second battery cannot be realized without degrading the performance of the first battery.
[0011]
In the present invention, the ratio of the actual power generation control instruction value to the maximum value of the current power generation control instruction value detected by the actual power generation ratio detection means is corrected based on the rotational speed of the engine that transmits power to the generator. Is done. Then, charging to the second battery is permitted / prohibited based on whether or not the corrected ratio is less than a predetermined ratio. Therefore, according to the present invention, the presence / absence determination of the power generation margin of the generator necessary for charging the second battery is accurately performed, and the charging of the second battery reliably reduces the performance of the first battery. Will be realized.
[0012]
  In this case, as described in claim 2, in the vehicular power supply control device according to claim 1, the correction means detects the ratio by the engine speed detection means after the ratio is detected by the actual power generation ratio detection means. What is necessary is just to correct | amend this ratio according to the change of the rotational speed of the said detected engine.
According to a third aspect of the present invention, in the vehicular power supply control device according to the first or second aspect, when the ratio is detected by the actual power generation ratio detecting means, the ratio and the engine rotation speed detecting means are used. Storage means for storing the power generation amount of the generator determined on the basis of the detected rotational speed of the engine, and the correction means, after the ratio is detected by the actual power generation ratio detection means, Based on the rotational speed of the engine detected by the speed detection means, the ratio detected by the actual power generation ratio detection means is fixed to the power generation amount stored in the storage means. It may be corrected as follows.
[0013]
  Claims4As claimed in claim 1.Any one of 3In the vehicle power supply control device described above, when the detection period of the ratio by the actual power generation ratio detection unit is longer than the detection period of the engine rotation speed by the engine rotation speed detection unit, the actual power generation Since the engine rotation speed is detected at least once during the timing at which the ratio is detected, the power generation ratio detected immediately before can be corrected based on the detected engine rotation speed.
[0014]
  Claims5Claims 1 to4The power supply control device for a vehicle according to any one of claims 1 to 3, wherein the generator is a generator with a regulator that outputs a current-carrying duty of a field coil with respect to a power generation control instruction voltage, and the actual power generation ratio detection means includes the power generation The ratio may be detected based on the energization duty output from the machine.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows a configuration diagram of a system including a vehicle power supply control device 10 according to an embodiment of the present invention. As shown in FIG. 1, in the present embodiment, the vehicle power supply control device 10 includes two secondary batteries 12 and 14. The secondary battery 12 is a lead battery having a voltage of about 12-14V, while the secondary battery 14 is a lithium ion battery having a voltage of about 14-16V. Hereinafter, the secondary battery 12 is referred to as a lead battery 12, and the secondary battery 14 is referred to as a lithium ion battery 14, respectively.
[0016]
An engine starter 18 is connected to the lead battery 12 and the lithium ion battery 14 via a changeover switch 16. The engine starter 18 is connected to an engine (not shown) that is a power source of the vehicle. The engine starter 18 has a function 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 that is selectively connected via the changeover switch 16.
[0017]
The engine is also provided with an alternator (alternator) 20 that generates electricity by rotating the engine. The alternator 20 is connected to an engine electronic control unit (hereinafter referred to as engine ECU) 22. The engine ECU 22 is connected to a sensor 24 that outputs signals according to various states of the vehicle including the engine speed per unit time (that is, the engine speed) NE and the vehicle speed and acceleration / deceleration. The engine ECU 22 detects the state of the vehicle such as the engine speed NE and the vehicle speed or acceleration / deceleration every T2 (ms) based on the output signal of the sensor 24. Then, a target voltage to be generated by the alternator 20 is calculated based on various vehicle conditions, and a command signal is supplied to the alternator 20 so that the target voltage is generated.
[0018]
The alternator 20 has a stator coil wound around the stator as a three-phase coil, and a field coil wound around the rotor, and rectifies and outputs a three-phase alternating current output from the stator coil, and a switching circuit. It is a generator with a regulator which incorporated the IC regulator comprised by this. This IC regulator has a function for maintaining the voltage generated by the alternator 20 constant. Specifically, when the voltage generated by the alternator 20 is smaller than the target voltage related to the command signal from the engine ECU 22, the IC regulator causes an excitation current to flow through the field coil by turning on the switching circuit. On the other hand, when the generated voltage of the alternator 20 is larger than the target voltage, the switching circuit is turned off to stop the supply of the excitation current to the field coil. Stop the coil from generating current. Thereby, the voltage generated by the alternator 20 is maintained at the target voltage.
[0019]
The engine ECU 22 is connected to a contact point between the field coil of the alternator 20 and the IC regulator. When the switching circuit of the IC regulator is turned on, an on signal indicating the energization state of the field coil, that is, the power generation state of the alternator 20 is supplied to the engine ECU 22. When the switching circuit of the IC regulator is turned off, an off signal indicating the non-energized state of the field coil, that is, the non-power generating state of the alternator 20 is supplied to the engine ECU 22.
[0020]
Based on the on / off signal supplied from the field coil of the alternator 20, the engine ECU 22 performs an on / off ratio per cycle time of the alternator 20 for each T1 (> T2) (ms), specifically, one The on-time ratio (energization duty;%) F-Duty within the cycle time is detected. This F-Duty indicates the ratio of the power generation amount that is actually generated with respect to the maximum power generation amount that the alternator 20 can generate based on the current engine speed and the like.
[0021]
The alternator 20 is directly connected to the lead battery 12 and the auxiliary machine 26 mounted on the vehicle. The auxiliary machine 26 is, for example, an air conditioner, audio, ABS system, electric oil pump, meters, defogger, wiper, power window, etc., and operates upon receiving electric power. The alternator 20 can charge the lead battery 12 and operate the auxiliary machine 26 by supplying the lead battery 12 or the auxiliary machine 26 with the power generation energy converted from the kinetic energy generated by the rotation of the engine.
[0022]
The lithium battery 14 is connected to the lead battery 12 via a DC-DC converter (hereinafter referred to as a DC / DC converter) 30 that functions as a voltage controller. The DC / DC converter 30 boosts the voltage on the lead battery 12 side according to the switching operation of the built-in power transistor and supplies it to the lithium ion battery 14 side, or steps down the voltage on the lithium ion battery 14 side to lead battery. Supply to the 12 side. In such a configuration, since the alternator 20 is connected to the lithium ion battery 14 via the DC / DC converter 30, the lithium ion battery 14 is charged by supplying the generated energy to the lithium ion battery 14 during power generation. Can do.
[0023]
The auxiliary machine 26 described above is connected to the alternator 20, the lead battery 12, and the lithium ion battery 14. The auxiliary machine 26 is supplied with electric power from the alternator 20 and the batteries 12 and 14 when the vehicle is driven by the engine, and is supplied with electric power from the lead battery 12 or the lithium ion battery 14 while the engine is stopped. The auxiliary machine 26 includes an auxiliary machine that can be supplied with power when the vehicle ignition switch is in the accessory state or the IG on state, such as audio and car navigation, an electric oil pump, ABS, air conditioner, etc. There is an auxiliary machine that can be supplied with electric power when the ignition switch is in the IG on state.
[0024]
A power system electronic control unit (hereinafter referred to as power system ECU) 32 is connected to the DC / DC converter 30. The engine ECU 22 described above is connected to the power supply system ECU 32, and the engine speed NE and F-Duty detected by the engine ECU 22 are supplied. The engine ECU 22 detects the engine speed NE every T2 (<T1) and detects F-Duty every T1, so that the power supply system ECU 32 determines the engine speed NE from the engine ECU 22 every T2. Moreover, F-Duty is received for every T1. The power supply system ECU 32 includes the lead battery 12 including the alternator 20 based on the engine speed NE and F-Duty supplied from the engine ECU 22, the voltage between terminals of the batteries 12 and 14, the charge / discharge current, the temperature, and the like. The DC / DC converter 30 is driven so that power transfer between the battery and the lithium ion battery 14 is performed appropriately.
[0025]
The changeover switch 16 is also connected to the power supply system ECU 32. The changeover switch 16 has a function of selectively switching the battery connected to the engine starter 18 between the lead battery 12 and the lithium ion battery 14 in accordance with a command from the power supply system ECU 32. The power supply system ECU 32 selects a battery connected to the engine starter 18 based on the rules described later, and controls the changeover switch 16 so that the battery is selected.
[0026]
An operating state detection device (not shown) is further connected to the power supply system ECU 32. The driving state detection device is configured to determine whether or not the engine is in a warm-up state, whether or not the travel distance or vehicle speed after starting the engine has reached a certain value, whether or not the driver has operated a brake, the shift position of the transmission, and When the vehicle is an A / T vehicle, it is detected whether or not the brake pedal force has reached a certain value, and when the vehicle is an M / T vehicle, it is detected whether or not the clutch pedal is operated. The power supply system ECU 32 determines whether or not the vehicle is in a stopped state (a state in which the speed is substantially “0”) based on the detection result of the driving state detection device, shifts the engine from the driving state to the stopped state, and Thereafter, it is determined whether or not an execution condition for control for shifting from the stopped state to the operating state (hereinafter referred to as idling stop control) is satisfied.
[0027]
Next, the operation of the vehicle power supply control device 10 of this embodiment will be described.
[0028]
In this embodiment, when the ignition switch is operated from the off state to the accessory state by the vehicle driver while the engine is stopped, the auxiliary machine 26 that should operate in the accessory state is activated by receiving power supply from the lead battery 12. It becomes possible. Further, when the ignition switch is operated from the accessory state to the IG on state, the auxiliary machine 26 that should operate in the IG on state is in an operable state by receiving power supply from the lead battery 12.
[0029]
Further, when the ignition switch is operated from the IG on state to the starter on state, power supply from the lead battery 12 to each auxiliary machine 26 is stopped, and the engine starter 18 is connected to the lead battery 12 via the changeover switch 16. And the power supply from the lead battery 12 is enabled. In this case, the engine starter 18 rotates the engine, and the engine changes from the stopped state to the started state. When the engine is started and is in an operation state, the operation state continues even when the ignition switch shifts from the starter-on state to the IG-on state.
[0030]
After the engine is started and in the driving state, the engine ECU 22 determines the target voltage of the alternator 20 (for example, in the idling state and the steady running state in advance only when the vehicle is in the idle state, the steady running state, and the deceleration state). By setting Vt1 to Vt2 and Vt3) which is higher than this range in the deceleration state, the alternator 20 converts the kinetic energy of the engine into electric energy and generates electric power. In this case, each auxiliary machine 26 becomes operable with the power generation voltage of the alternator 20 and the lead battery 12 is charged, or the charge voltage of the alternator 20 is boosted by driving the DC / DC converter 30 to lithium. The ion battery 14 is charged. At this time, when the lithium ion battery 14 is fully charged, the driving of the DC / DC converter 30 is prohibited in order to prevent the lithium ion battery 14 from being overcharged. The power supply to the 14 side is stopped.
[0031]
In addition, after the vehicle engine is started and in a driving state, the power supply system ECU 32 determines whether or not the vehicle is operated based on the presence / absence of a brake operation by the driving state detection device, the brake depression force, the presence / absence of a clutch operation, the shift position of the transmission, and the like. Whether or not the idling stop control execution condition is satisfied based on the vehicle stop state, the engine warm-up state, and the travel distance or vehicle speed history after the engine is started. Determine whether or not. As a result, when the execution condition of the idling stop control is satisfied, the execution of fuel injection, ignition, etc. is stopped without the driver shifting the ignition switch from the IG on state to the off state, and the engine is stopped from the operating state. It is moved to.
[0032]
When the engine is stopped by the idling stop control, the ignition switch is maintained in the IG on state. When the engine is stopped, the alternator 20 cannot generate power. Therefore, when the engine is stopped by the idling stop control, the power supply system ECU 32 subsequently drives the DC / DC converter 30 to permit the discharge from the lithium ion battery 14 in order to secure the power supply to the auxiliary machine 26. To do. In this case, the auxiliary devices 26 such as an air conditioner, a power steering device, and meters are ready to operate upon receiving power supply from the lithium ion battery 14 via the DC / DC converter 30.
[0033]
When the engine is stopped by the idling stop control, the power supply system ECU 32 switches the changeover switch 16 to the lithium ion battery 14 side in order to secure power supply from the lithium ion battery 14 to the engine starter 18. In this case, the battery connected to the engine starter 18 is switched from the lead battery 12 to the lithium ion battery 14, and the engine starter 18 can be started by receiving power supply from the lithium ion battery 14.
[0034]
When the engine is stopped by the idling stop control, the power supply system ECU 32 uses the driving state detection device to change the shift position of the transmission from the “N” range to “D” when the vehicle is an AT vehicle. The idling stop control release condition is determined based on whether or not the vehicle has shifted to the range or “R” range or whether or not the brake operation has been released, and whether or not the clutch pedal has been depressed if the vehicle is an MT vehicle. It is determined whether or not it is established. As a result, when the release condition for the idling stop control is satisfied, the engine starter 18 is activated without the driver shifting the ignition switch from the IG on state to the starter on state, the engine is started, and the operation state is Resumed. Hereinafter, this engine start is referred to as restart, and on the other hand, as usual, engine start by turning on the ignition switch is referred to as normal start.
[0035]
As described above, in the vehicle of the present embodiment, after the engine is in an operating state, idling stop control for stopping unnecessary engine operation while the vehicle is stopped is executed. In this case, it is avoided that the engine is unnecessarily maintained in the operating state. For this reason, according to the present embodiment, the engine can be operated efficiently, and the fuel efficiency of the vehicle can be improved.
[0036]
In this embodiment, at the time of engine start (normal start) based on the driver's intention by the ignition operation, the engine starter 18 is supplied with electric power from the lead battery 12 as described above, and the engine is started. On the other hand, when the engine is started (restarted) by the idling stop control, the switch 16 switches the battery connected to the engine starter 18 to the lithium ion battery 14 so that the engine starter 18 supplies power from the lithium ion battery 14. In response, the engine is started and the engine is started.
[0037]
According to such a configuration, since the lead battery 12 having a high output (output density) that can be taken out per unit mass per unit time at the normal start of the engine is used, the startability of the engine is surely ensured even when it is cold. In addition, since the lithium ion battery 14 having high energy (energy density) that can be taken out per unit mass when the engine is restarted is used, the lead battery 12 can be used even when idling stop control in which the engine is frequently started and stopped is performed. The deterioration of the engine is not promoted, and the startability of the engine is reliably ensured. Therefore, according to the present embodiment, even when the engine is started due to the driver's ignition operation, or even when the engine is started due to the idling stop control, the deterioration of the lead battery 12 is not promoted reliably. In addition, the engine can be started without relatively increasing the capacity of the lead battery 12.
[0038]
By the way, generally, the lead battery 12 and the lithium ion battery 14 of the present embodiment are batteries having different charge acceptability. Specifically, the charge acceptability of the lithium ion battery 14 is higher than that of the lead battery 12. Therefore, if the charging of the lithium ion battery 14 is allowed at all times, the power generation energy of the alternator 20 may be biased toward the lithium ion battery 14 having a high charge acceptability, so that the lead battery 12 having a low charge acceptability may be charged. There may be inconveniences that become insufficient.
[0039]
In addition, since it is necessary to charge the lead battery 12 excluding the charging of the lithium ion battery 14 or to supply power to the auxiliary machine 26, the alternator 20 generates power with almost 100% power generation capacity. In some cases, the F-Duty is almost 100% because the energized state of the field coil continues for a long time. If the charging is executed due to insufficient charging of the lithium ion battery 14 in such a state, the power generation energy of the alternator 20 cannot cover the insufficient charging of the lithium ion battery, so that the lead battery 12 is almost fully charged. In such a case, there occurs a situation where the insufficient charge of the lithium ion battery is compensated from the stored energy of the lead battery 12, and the lead battery 12 is frequently discharged. In this case, the battery of the lead battery 12 easily rises, the deterioration is promoted, and the life thereof is deteriorated.
[0040]
Therefore, it is not appropriate to charge the lithium ion battery 14 without considering the lead battery 12 in the configuration of the present embodiment in order to secure the performance of the lead battery 12. Therefore, the system of the present embodiment realizes the charging of the lithium ion battery 14 without degrading the performance of the lead battery 12.
[0041]
FIG. 2 is a diagram showing the relationship between the rotation speed rpm of the alternator 20 and the generated current of the alternator 20 using the current-carrying duty F-Duty of the field coil in the alternator 20 as a parameter. As shown in FIG. 2, even if the rotation speed of the alternator 20 is the same, the power generation current generated by the alternator 20 increases as the energization duty F-Duty of the field coil increases. The energization duty F-Duty of the field coil increases as the generated current needs to be increased in order to charge the lead battery 12 and supply power to the auxiliary machine 26.
[0042]
When the field coil energization duty F-Duty is not 100%, the alternator 20 does not need to exhibit 100% of the power generation capacity with respect to the rotation speed, and has not actually demonstrated it and still generates power. It can be determined that there is a margin, and it is not necessary to discharge the lead battery 12, and it can be determined that the lead battery 12 is not actually discharged.
[0043]
Accordingly, if the charging duty of the field coil F-Duty is not 100% in a state where the lithium ion battery 14 is not charged, the charging of the lithium ion battery 14 is started. Since the surplus is supplied to the lithium ion battery 14, the lithium ion battery 14 can be charged. Further, if the charging duty of the field coil F-Duty is 100%, if the charging of the lithium ion battery 14 is prohibited, the lead battery 12 is discharged in order to charge the lithium ion battery 14. Can be avoided.
[0044]
FIG. 3 shows a flowchart of an example of a control routine executed by the power supply system ECU 32 in the vehicle power supply control device 10 of this embodiment in order to realize the above function. The routine shown in FIG. 3 is a routine that is repeatedly activated at every T2 that is the same as the detection cycle of the engine speed NE. When the routine shown in FIG. 3 is started, first, the process of step 100 is executed.
[0045]
In step 100, it is determined whether or not the F-Duty of the alternator 20 is less than a predetermined value F0. The predetermined value F0 is a high energization duty value at which it can be determined that the alternator 20 is generating a power generation amount that is approximately the same as the maximum power generation amount that can be generated at the present time, and is set to 95%, for example.
[0046]
When F-Duty <F0 is satisfied, it can be determined that the alternator 20 has a power generation amount that can further generate power corresponding to the current target voltage. In this case, it is appropriate to allocate the surplus power generation energy to charge the lithium ion battery 14. Therefore, when such a positive determination is made, the process of step 102 is executed next. On the other hand, if F-Duty <F0 does not hold, it can be determined that the alternator 20 does not have a power generation amount that can further generate power corresponding to the current target voltage. If charging of the lithium ion battery 14 is permitted in such a case, the lead battery 12 is discharged, and a situation occurs in which the stored energy is applied to the charging of the lithium ion battery 14. Accordingly, if such a negative determination is made, the process of step 104 is executed next.
[0047]
In step 102, a process for charging the lithium ion battery 14 is performed by driving the DC / DC converter 30. When the processing of this step 102 is executed, the power generation energy of the alternator 20 is collected as charging energy in the lithium ion battery 14 and the lithium ion battery 14 is charged. When the processing of step 102 is completed, the current routine is terminated.
[0048]
In step 104, the DC / DC converter 30 is not driven, and a process for prohibiting charging of the lithium ion battery 14 is executed. When the processing of step 104 is executed, power supply from the alternator 20 side to the lithium ion battery 14 is not performed thereafter. When the process of step 104 is completed, the current routine is terminated.
[0049]
According to the routine shown in FIG. 3, when the energization duty F-Duty of the field coil of the alternator 20 is equal to or greater than a predetermined value, the power generation amount of the alternator 20 is substantially the same as the maximum power generation amount that can be generated at the present time. On the other hand, the charging duty F-Duty of the field coil is less than a predetermined value so that the lithium ion battery 14 is not charged, and the power generation amount of the alternator 20 has reached the maximum power generation amount that can be generated at the present time. If not, the DC / DC converter 30 can be controlled so that the lithium ion battery 14 is charged.
[0050]
If the power generation amount of the alternator 20 does not reach the maximum power generation amount that can be generated at the present time, the alternator 20 has a power generation margin with respect to the power supply to the load such as the lead battery 12 and the auxiliary machine 26. The battery 12 is not discharged. For this reason, in the above configuration, charging of the lithium ion battery 14 is performed without causing discharge from the lead battery 12.
[0051]
Moreover, if the power generation margin of the alternator 20 is used as the charging energy of the lithium ion battery 14, the lithium ion battery 14 is charged in a state where the lead battery 12 is sufficiently charged. Due to the charging, there is no inconvenience that the lead battery 12 is not sufficiently charged. That is, in the above configuration, the charging of the lithium ion battery 14 is performed without adversely affecting the charging of the lead battery 12.
[0052]
Therefore, according to the vehicle power supply control device 10 of the present embodiment, the charging of the lithium ion battery 14 can be realized without degrading the performance of the lead battery 12. For this reason, according to the present embodiment, it is possible to suppress the battery rise of the lead battery 12 due to the charging of the lithium ion battery 14, and to prevent the deterioration and the life deterioration.
[0053]
In this embodiment, the determination of whether or not the power generation amount of the alternator 20 has reached the maximum power generation amount that can be generated at the present time, that is, whether or not the alternator 20 has a power generation margin is determined by the alternator 20. This is performed based on the energization duty F-Duty of the field coil. Whether or not the alternator 20 has a power generation margin can be determined based on whether or not the lead battery 12 directly connected to the alternator 20 is discharged, in addition to the duty of the field coil. Specifically, when the discharge from the lead battery 12 occurs, it can be determined that the alternator 20 has no power generation margin. On the other hand, when the discharge from the lead battery 12 does not occur, the alternator 20 has a power generation margin. It can be judged that there is. However, the method of determining whether or not the alternator 20 has a power generation margin based on the presence or absence of discharge of the lead battery 12 allows the discharge from the lead battery 12 temporarily, but the performance of the lead battery 12 It will cause a decline.
[0054]
On the other hand, in the vehicle power supply control device 10 of the present embodiment, as described above, whether or not the alternator 20 has a power generation margin is determined based on the energization duty F-Duty of the field coil of the alternator 20. Done. In this case, in determining whether the alternator 20 has a power generation margin, it is possible to avoid discharging the lead battery 12 even temporarily. Therefore, according to the vehicle power supply control device 10 of the present embodiment, whether or not the alternator 20 needs to generate power necessary for charging the lithium ion battery 14 is determined without allowing the lead battery 12 to discharge. It is possible.
[0055]
By the way, in the present embodiment, as described above, the engine ECU 22 detects the engine speed NE every T2, and also detects the F-Duty every T1, so that the power supply system ECU 32 receives the engine ECU 22 from the engine ECU 22 every T2. The engine speed NE is received and the F-Duty is received every T1 (> T2). That is, the detection cycle of F-Duty is about T1 / T2 times longer than the detection cycle of engine speed NE. For this reason, in the power supply system ECU 32, a situation occurs in which the detected F-Duty does not change even though the detected engine speed NE changes.
[0056]
In general, when the power generation amount to be generated by the alternator 20 is fixed, the current-carrying duty F-Duty of the field coil of the alternator 20 changes as the engine speed NE changes. Therefore, although the energization duty F-Duty of the field coil of the alternator 20 actually changes with the change of the engine speed NE, the F-Duty supplied from the engine ECU 22 remains as it is. If the alternator 20 is used for charging control, it is not possible to accurately determine whether the alternator 20 has a power generation margin. As a result, charging of the lithium ion battery 14 reduces the performance of the lead battery 12. Inconveniences that cannot be realized without doing so may occur.
[0057]
Therefore, the system of the present embodiment is characterized in that it accurately determines whether there is a power generation margin of the alternator 20 necessary for realizing the charging of the lithium ion battery 14 without degrading the performance of the lead battery 12. is doing. Hereinafter, the characteristic part of a present Example is demonstrated.
[0058]
As described above, in the power supply system ECU 32, a situation occurs in which the detected F-Duty does not change even though the detected engine speed NE changes. In this embodiment, the power supply system ECU 32 maps the relationship between the rotational speed rpm of the alternator 20 and the generated current of the alternator 20 using the current-carrying duty F-Duty of the field coil in the alternator 20 as a parameter, as shown in FIG. Remember as. Since the relationship between the rotational speed of the alternator 20 and the engine rotational speed is fixed to a predetermined pulley ratio, the power supply system ECU 32 determines the rotational speed per unit time of the alternator 20 based on the engine rotational speed NE, that is, the alternator 20 The rotation speed rpm can be calculated.
[0059]
When power supply system ECU 32 detects the F-Duty supplied from engine ECU 22, it executes the routine shown in FIG. 3 using the detected value, and at the same time, detects the F-Duty and the engine rotation detected at the time of detection. Based on the relationship with the rotational speed rpm of the alternator 20 determined from the number NE, the power generation amount (power generation current) of the alternator 20 is stored in the built-in memory. After detecting the F-Duty from the engine ECU 22, the power supply system ECU 32 calculates the rotational speed rpm of the alternator 20 based on the engine rotational speed NE every time the engine rotational speed NE is detected, and the calculated rotational speed. As shown in FIG. 2, the change in F-Duty after detection of F-Duty from the engine ECU 22 is fixed to the power generation amount stored in the built-in memory based on the rpm value. To estimate. Then, by correcting the F-Duty from the engine ECU 22 by the estimated change, the energization duty F-Duty of the field coil of the alternator 20 that is determined to be actually generated is calculated, and the calculated value is used. The above-described routine shown in FIG. 3 is executed. Hereinafter, such processing is repeatedly executed.
[0060]
In the above configuration, after the F-Duty from the engine ECU 22 is detected in the power supply system ECU 32, every time the engine speed NE from the engine ECU 22 is detected with a detection cycle shorter than the detection cycle of the F-Duty. The energization duty estimated to be actually generated in the field coil of the alternator 20 is calculated.
[0061]
FIG. 4 shows a flowchart of an example of a control routine executed by the power supply system ECU 32 in the vehicle power supply control device 10 of the present embodiment in order to realize the above function. The routine shown in FIG. 4 is a routine that is repeatedly started every T2 that is the same as the detection period of the engine speed NE. When the routine shown in FIG. 4 is started, first, the process of step 150 is executed.
[0062]
In step 150, it is determined whether or not an F-Duty to be supplied from the engine ECU 22 has been received. As a result, if an affirmative determination is made, the process of step 152 is executed next. On the other hand, if a negative determination is made, the process of step 154 is executed next.
[0063]
In step 152, a process of updating the energization duty F-Duty of the field coil of the alternator 20 to the F-Duty from the engine ECU 22 received in step 150 is executed. When the processing of step 152 is executed, thereafter, the routine shown in FIG. 3, that is, the charging control of the lithium ion battery 14 is executed using the updated energization duty F-Duty. . When the processing of step 152 is completed, the current routine is terminated.
[0064]
In step 154, it is determined whether or not the engine speed NE to be supplied from the engine ECU 22 has been received. As a result, if a negative determination is made, the current routine is terminated without any further processing. On the other hand, if an affirmative determination is made, the process of step 156 is executed next.
[0065]
In step 156, first, the rotational speed rpm of the alternator 20 is calculated based on the engine rotational speed NE received from the engine ECU 22 received in step 154, and based on the calculated rotational speed rpm value, A change in the F-Duty after the detection of the F-Duty is estimated with reference to a map as shown in FIG. 2, and a process for correcting the F-Duty from the engine ECU 22 by the estimated change is executed. When the processing of step 156 is executed, the routine shown in FIG. 3, that is, the charging control of the lithium ion battery 14 is executed using the energization duty F-Duty obtained as a result of the correction. The Rukoto. When the processing of step 156 is completed, the current routine is terminated.
[0066]
According to the routine shown in FIG. 4, immediately after the F-Duty from the engine ECU 22 is detected, the detected F-Duty value is used as the energization duty F-Duty in the alternator 20, and from the engine ECU 22 The engine rotation from the engine ECU 22 is detected at a detection cycle (T2) shorter than the detection cycle (T1) of the F-Duty from when the energization duty F-Duty in the alternator 20 is detected until the next detection. The value of F-Duty estimated by referring to a predetermined map every time the number NE is detected can be used as the energization duty F-Duty in the alternator 20.
[0067]
In such a configuration, after the F-Duty from the engine ECU 22 is detected in the power supply system ECU 32, it is estimated that it is actually generated in the field coil of the alternator 20 every time the engine speed NE from the engine ECU 22 is detected. The energization duty is calculated. In this calculation, for example, when the detection cycle of the F-Duty in the power supply system ECU 32 is T1 and the detection cycle of the engine speed NE is T2, the energization duty F-Duty in the alternator 20 from the engine ECU 22 is detected. It is performed (T1 / T2-1) times from the detection to the next detection.
[0068]
In general, the energization duty F-Duty in the alternator 20 changes as the engine speed NE changes. Therefore, according to the above configuration, the energization duty F-Duty in the alternator 20 can be accurately calculated even after the F-Duty from the engine ECU 22 is detected until the next detection.
[0069]
The energization duty F-Duty of the field coil of the alternator 20 is used for charging control of the lithium ion battery 14. Specifically, it is determined whether or not there is a power generation margin of the alternator 20 based on the energization duty F-Duty of the field coil, and the lithium ion battery 14 is charged when the alternator 20 has a power generation margin. The DC / DC converter 30 is controlled.
[0070]
Therefore, according to the vehicle power supply control device 10 of the present embodiment, even if the F-Duty to be supplied from the engine ECU 22 is detected as data and is detected next, the engine speed NE Since the energization duty F-Duty in the alternator 20 corresponding to the change of the current is accurately calculated, it is possible to accurately determine whether or not the alternator 20 has a power generation margin necessary for charging the lithium ion battery 14. ing. For this reason, in the present embodiment, the charging of the lithium ion battery 14 is realized without deteriorating the performance of the lead battery 12 reliably.
[0071]
On the contrary, in the present embodiment, even when the F-Duty to be supplied from the engine ECU 22 is detected as data and until it is detected next, it corresponds to the change in the engine speed NE. Since the energization duty F-Duty in the alternator 20 is accurately calculated, in order to improve the accuracy of the F-Duty, the communication / supply cycle of the F-Duty value from the engine ECU 22 to the power supply system ECU 32, that is, F- It is not necessary to set the duty detection cycle to the same level as the communication / supply cycle (detection cycle) of the engine speed NE.
[0072]
Therefore, according to the vehicle power supply control device 10 of the present embodiment, the energization duty F-Duty in the alternator 20 can be accurately calculated with a simple configuration without improving the performance of the engine ECU 22 and the power supply system ECU 32. Thus, it is possible to charge the lithium ion battery 14 without deteriorating the performance of the lead battery 12 without fail.
[0073]
In the above embodiment, the lead battery 12 is a “first battery” described in the claims, and the lithium ion battery 14 is a “second battery” described in the claims. In the “voltage controller” described in the claims, the energization duty of the field coil of the alternator 20 is “the actual power generation control instruction value relative to the maximum value of the current power generation control instruction value in the claims”. The engine speed NE per unit time corresponds to the “ratio” and the “engine speed” described in the claims.
[0074]
In the above embodiment, the power system ECU 32 detects the energization duty F-Duty of the field coil supplied from the engine ECU 22 so that the “actual power generation ratio detection means” described in the claims is the engine. By detecting the engine speed NE supplied from the ECU 22, the "engine speed detecting means" described in the claims executes the processing of step 156 in the routine shown in FIG. The “second battery charge control means” described in the claims is realized by executing the routine shown in FIG.
[0075]
By the way, in said Example, although it is supposed that the lead battery 12 and the lithium ion battery 14 are used as a battery mounted in a vehicle, this invention is not limited to this, The nickel metal hydride battery etc. were used. It is also possible to apply to the configuration.
[0076]
In the above embodiment, the engine ECU 22 that controls the target voltage of the alternator 20 and the power supply system ECU 32 that controls the DC / DC converter 30 are provided separately, and the field coil of the alternator 20 detected by the engine ECU 22 is provided. The energization duty F-Duty is supplied to the power supply system ECU 32 via the communication line. However, the present invention is not limited to this, and the target voltage of the alternator 20 is controlled and the DC / DC converter 30 is provided. It is also possible to apply a configuration in which only one electronic control unit (ECU) to be controlled is provided and the alternator 20 determines whether there is a power generation margin without communicating the energization duty F-Duty of the field coil. In this configuration as well, the detection cycle of the engine speed NE is, for example, T2, and the detection cycle of the energization duty F-Duty in the alternator 20 is T1, which is longer than the detection cycle of the engine speed NE. .
[0077]
【The invention's effect】
  As mentioned above,BookAccording to the present invention, it is possible to accurately determine whether or not there is a generator margin necessary for charging the second battery, thereby reliably reducing the performance of the first battery and charging the second battery. It can be realized without doing.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a system including a vehicle power supply control device according to an embodiment of the present invention.
FIG. 2 is a diagram showing the relationship between the rotational speed rpm of the generator and the generated current of the generator, using the current duty of the field coil in the generator as a parameter.
FIG. 3 is a flowchart of a control routine executed to control charging of a second battery in the present embodiment.
FIG. 4 is a flowchart of a control routine executed in this embodiment to calculate a current duty of a field coil in the generator.
[Explanation of symbols]
10 Vehicle power supply control device
12 Lead battery
14 Lithium ion battery
20 Alternator
22 Engine ECU
30 DC-DC converter (DC / DC converter)
32 Power supply system ECU
F-Duty energization duty

Claims (5)

A vehicle power supply control device comprising: a first battery connected to a generator; and a second battery connected to the generator via a voltage controller in parallel with the first battery,
An actual power generation ratio detection means for detecting a ratio of an actual power generation control instruction value with respect to a maximum value of the current power generation control instruction value of the generator;
Engine rotation speed detection means for detecting the rotation speed of the engine for transmitting power to the generator;
The subsequent said ratio is detected by the actual generated ratio detecting means, based on the rotational speed of the engine detected by the engine rotational speed detecting means, the ratio detected by the actual generated ratio detecting means, the power generating Correction means for correcting the power generation amount of the machine to be fixed ;
A second controller that controls the voltage controller so that charging to the second battery is permitted / prohibited based on whether the ratio obtained as a result of correction by the correction means is less than a predetermined ratio; Battery charge control means;
A vehicle power supply control device comprising:   The correction means corrects the ratio according to a change in the engine rotation speed detected by the engine rotation speed detection means after the actual power generation ratio detection means detects the ratio. The vehicle power supply control device according to claim 1. Storage means for storing the power generation amount of the generator determined based on the ratio and the engine rotation speed detected by the engine rotation speed detection means when the ratio is detected by the actual power generation ratio detection means With
  The correcting means detects the ratio detected by the actual power generation ratio detecting means based on the engine speed detected by the engine speed detecting means after the ratio is detected by the actual power generation ratio detecting means. 3. The vehicle power supply control device according to claim 1, wherein the ratio is corrected so that the power generation amount of the generator is fixed to the power generation amount stored in the storage means. The detection period of the proportions by the actual generated ratio detecting means, any one of claims 1 to 3, wherein the longer than the detection period of the rotational speed of the engine by the engine rotational speed detecting means Vehicle power supply control device. The generator is a generator with a regulator that outputs an energization duty of a field coil with respect to a power generation control instruction voltage,
The actual generated ratio detection means, the vehicle power supply control device of any one of claims 1 to 4, characterized in that to detect the percentage based on the current duty output from the generator.

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