JP4543622B2 - Driving force distribution control device for four-wheel drive vehicles - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of a driving force distribution control device for a four-wheel drive vehicle that controls torque distribution to front and rear wheels by electronic control.
[0002]
[Prior art]
A conventional driving force distribution control device for a four-wheel drive vehicle has control region map setting means divided into a driving force distribution control region and a differential rotation control region according to the accelerator opening and the vehicle speed, and the detected accelerator opening and When the driving point based on the vehicle speed is the driving force distribution control area on the control area map, the driving force distribution control is executed by the large torque command, and the driving point is the differential rotation control area on the control area map. A technique for executing differential rotation control based on a torque command corresponding to a speed difference between a main drive wheel and a slave drive wheel is known (see, for example, Patent Document 1).
[0003]
[Patent Document 1]
JP, 2001-225658, A [Problems to be solved by the invention]
However, in the conventional driving force distribution control device for a four-wheel drive vehicle, the control specifications are determined only by the accelerator opening and the vehicle speed. Even in a driving scene that does not require continuous large torque transmission, as long as the operating point exists in the driving force distribution control region, the driving force distribution control is continuously executed, and the sliding engagement is performed with high torque. There is a problem that the durability and reliability (for example, unit oil temperature and gear system fatigue strength) of the torque distribution actuator is reduced.
[0004]
The present invention has been made paying attention to the above-mentioned problem, and is capable of improving the durability and reliability of the torque distribution actuator by suppressing unnecessary torque transmission to the torque distribution actuator. An object is to provide a power distribution control device.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, in the present invention,
Torque provided in the drive system that calculates the target transmission torque to one of the front and rear wheels so that the front and rear wheel torque distribution according to the vehicle condition is obtained, and obtains the calculated target transmission torque. In a driving force distribution control device for a four-wheel drive vehicle equipped with a torque distribution controller that commands a distribution actuator,
The torque distribution controller
Driving force distribution control means for outputting a command to transmit a large torque to the driven wheel for the purpose of securing the starting performance;
An accelerator release operation detecting means for detecting an accelerator release operation;
First driving force distribution control prohibiting means for prohibiting the driving force distribution control after a first set time required for transition from vehicle start to steady travel has elapsed;
A second driving force distribution control prohibiting means for prohibiting the driving force distribution control until a second set time required from turning on to turning off by detecting an accelerator release operation;
It was set as the means which has.
[0006]
Here, the “driving force distribution control means” means, for example, feed-forward control based on target transmission torque characteristics set by an engine torque equivalent value such as accelerator opening, transmission output shaft torque, engine output shaft torque, A means for outputting a command for transmitting a large torque to the driven wheels for the purpose of securing the starting performance.
[0007]
【The invention's effect】
Therefore, in the driving force distribution control device for a four-wheel drive vehicle of the present invention, after the first set time required for the first driving force distribution control prohibiting means to shift from vehicle start to steady running, Improving the durability and reliability of the torque distribution actuator by prohibiting the driving force distribution control that transmits large torque to the driven wheels for the purpose of securing the starting performance and suppressing unnecessary torque transmission to the torque distribution actuator Can do.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment for realizing a driving force distribution control device for a four-wheel drive vehicle according to the present invention will be described based on a first example shown in the drawings.
[0009]
(First embodiment)
First, the configuration will be described.
FIG. 1 is an overall system diagram showing a four-wheel drive vehicle based on a rear wheel drive to which a drive force distribution control device for a four-wheel drive vehicle of the first embodiment is applied.
[0010]
As shown in FIG. 1, the drive system of the four-wheel drive vehicle includes an engine 1, an automatic transmission 2, a rear propeller shaft 3, a rear differential 4, rear drive shafts 5 and 6, a left rear wheel 7, a right rear wheel 8, A truss clutch 9 (torque distribution actuator), a front propeller shaft 10, a front differential 11, front drive shafts 12 and 13, a left front wheel 14 and a right front wheel 15 are provided.
The left and right rear wheels 7 and 8 correspond to main drive wheels, and the left and right front wheels 14 and 15 correspond to slave drive wheels.
[0011]
The engine 1 is subjected to fuel injection control or the like according to a command from the engine controller 16, and the automatic transmission 2 is subjected to gear shift control or the like according to a command from the automatic transmission controller 17.
[0012]
The front / rear differential limiting system that controls the engagement of the transfer clutch 9 includes a front / rear differential limiting actuator 19 and a differential limiting controller 20 (torque distribution controller) that outputs a fastening command or a release command to the front / rear differential limiting actuator 19. ).
[0013]
As the transfer clutch 9, for example, a hydraulic multi-plate clutch, an electromagnetic multi-plate clutch, or the like is applied, and it has a front-rear differential limiting function that limits the differential between the left and right rear wheels 7 and 8 and the left and right front wheels 14 and 15 by fastening. . That is, the left and right rear wheels 7 and 8 and the left and right front wheels 14 and 15 are driven by a torque distribution action in which the driving torque is transmitted from the left and right rear wheels 7 and 8 to the left and right front wheels 14 and 15 by fastening the transfer clutch 9. Limit 15 differentials.
[0014]
Information from an accelerator opening sensor 21 (accelerator opening detecting means), a longitudinal acceleration sensor 22, a mode changeover switch 23, and the like is input to the differential limiting controller 20. The mode changeover switch 23 is means for manually switching between the 2WD fixed mode, the 4WD fixed mode, and the auto mode. When the 4WD fixed mode of the mode switch 23 is selected, the differential limiting action for the front and rear wheels is strongest. When the auto mode of the mode changeover switch 23 is selected, for example, if the clutch engagement torque applied according to the front-rear wheel rotational speed difference, the accelerator opening degree, the front-rear acceleration, etc. is large, the differential allowance for the front and rear wheels is small and strong. The differential limiting action is exhibited, and the differential allowable amount of the front and rear wheels gradually increases as the clutch engagement torque decreases.
[0015]
As shown in FIG. 1, an anti-lock brake system that brakes the wheels 7, 8, 14, and 15 with brake hydraulic pressure includes a brake pedal 30, a booster 31, a master cylinder 32, master cylinder hydraulic pipes 33 and 34, ABS actuator 35, left rear wheel wheel cylinder hydraulic pipe 36, right rear wheel wheel cylinder hydraulic pipe 37, left front wheel wheel cylinder hydraulic pipe 38, right front wheel wheel cylinder hydraulic pipe 39, left rear wheel wheel cylinder 40, right A rear wheel wheel cylinder 41, a left front wheel wheel cylinder 42, a right front wheel wheel cylinder 43, and a brake controller 44 are provided.
[0016]
The ABS actuator 35 is constituted by an oil pump, a hydraulic pressure control valve, and the like, and during normal braking, each wheel 7, via two brake hydraulic pressure systems divided corresponding to the master cylinder hydraulic pressure pipes 33, 34. Brake fluid pressure is supplied to 8,14,15. At the time of ABS operation, the brake fluid pressure is controlled by three modes of pressure reduction, holding, and pressure increase so as to suppress braking lock of each wheel 7, 8, 14, and 15.
[0017]
The brake controller 44 includes a brake lamp switch 45, a left front wheel speed sensor 46 (vehicle speed detection means), a right front wheel speed sensor 47 (vehicle speed detection means), a left rear wheel speed sensor 48, a right rear wheel speed sensor 49, and the like. Information is entered.
[0018]
The engine controller 16, the automatic transmission controller 17, the differential limit controller 20, and the brake controller 44 are connected to each other by a bidirectional communication line 50 for exchanging information. It is supplied to the differential limiting controller 20 through the communication line 50.
[0019]
Next, the operation will be described.
[0020]
[Torque distribution control processing]
FIG. 2 is a flowchart showing the flow of torque distribution control processing executed by the differential limiting controller 20 of the first embodiment. Each step will be described below.
[0021]
In step S1, the accelerator opening degree ACC and the vehicle speed V are read, and the process proceeds to step S2.
Here, the accelerator opening ACC is calculated based on a sensor signal from the accelerator opening sensor 21. The vehicle speed V is calculated from an average value of the left front wheel speed and the right front wheel speed based on sensor signals from the left front wheel speed sensor 46 and the right front wheel speed sensor.
[0022]
In step S2, it is determined whether or not the accelerator opening ACC calculated in step S1 is equal to or less than the value of the accelerator release region. If YES, the process proceeds to step S9, and if NO, the process proceeds to step S3 (accelerator). Foot release operation detection means).
Here, the value of the accelerator release region is set to a small value close to zero in consideration of the error of the accelerator opening sensor 21. Note that an accelerator switch or the like may be used instead of the determination of the accelerator release operation based on the accelerator opening ACC.
[0023]
In step S3, whether or not the operating point based on the accelerator opening ACC and the vehicle speed V exists in the driving force distribution control region on the control region map divided into the driving force distribution control region and the differential rotation control region shown in FIG. If YES, the process proceeds to step S4. If NO, the process proceeds to step S8.
Here, the control area map shown in FIG. 3 is stored and set in advance in the memory of the differential limiting controller 20 (control area map setting means).
[0024]
In step S4, whether or not the first timer value T1 that is started from the time when it is determined in step S3 that it is present in the driving force distribution control region is equal to or longer than the first set time Ta required to shift from vehicle start to steady running. If YES, the process proceeds to step S7. If NO, the process proceeds to step S5.
Here, the first set time Ta is set to a time required for shifting from vehicle start to steady running, for example, 1 minute to 2 minutes at the longest.
[0025]
In step S5, the first timer value T1 is incremented by 1 for each control period, and the process proceeds to step S6.
[0026]
In step S6, the torque command value to the slave drive wheel by feedforward control according to the engine torque equivalent value, the torque command value to the slave drive wheel by feedback control according to the speed difference between the master drive wheel and the slave drive wheel, The command value by the select high is set as the target transmission torque, and a command for obtaining this target transmission torque is commanded to the front-rear differential limiting actuator 19 to return (driving force distribution control means).
Here, the “engine torque equivalent value” refers to, for example, the accelerator opening, the transmission output shaft torque, the engine output shaft torque, and the like, and the “torque command value to the driven wheels by feedforward control” Based on the target transmission torque characteristic set by the engine torque equivalent value, it is a command for transmitting a large torque to the driven wheels for the purpose of ensuring the starting performance.
[0027]
In step S7, if it is determined in step S4 that the first timer value T1 is equal to or longer than the first set time Ta required for shifting from vehicle start to steady running, the first timer value T1 is reset, and step S8 is performed. Migrate to
Here, the flow of transition from step S4 to step S7 to step S8 corresponds to the first driving force distribution control prohibiting means.
[0028]
In step S8, when it is determined in step S3 that it is a differential rotation control region, or when the first timer value T1 is reset in step S7, the driven wheel according to the speed difference between the driven wheel and the driven wheel. The torque to be transmitted to is set as the target transmission torque, and a command for obtaining this target transmission torque is commanded to the front-rear differential limiting actuator 19 to return (differential rotation control means).
[0029]
In step S9, when it is determined in step S2 that the accelerator release operation is being performed, the second timer value T2 that is started from the accelerator release operation determination time is from turning on to detecting turning off of the accelerator releasing operation. It is determined whether or not it is the second set time Td required for the process. If YES, the process proceeds to step S12. If NO, the process proceeds to step S10.
Here, the second set time Td is the time from the accelerator return at the start of the curve (accelerator OFF) to the accelerator depressing at the exit of the curve (accelerator ON) when turning on a normal road surface, for example, It is set to about 10 seconds.
[0030]
In step S10, the second timer value T2 is incremented by 1 for each control period, and the process proceeds to step S11.
[0031]
In step S11, when the second timer value T2 is added in step S10, the torque transmitted to the driven wheels according to the speed difference between the main driven wheels and the driven wheels is set as the target transmission torque. A command to obtain torque is commanded to the front-rear differential limiting actuator 19 and the process returns to step S9.
Here, the flow of repeating step S9 → step S10 → step S11 corresponds to the second driving force distribution control prohibiting means.
[0032]
In step S12, if it is determined in step S9 that the second timer value T2 that is started from the accelerator release operation determination time is greater than or equal to the second set time Td, the second timer value T2 is reset and the process proceeds to return. .
[0033]
[Torque distribution control function]
The torque distribution control action is based on the time chart shown in FIG. 4, taking as an example the case where the vehicle has entered a curve after running continuously uphill after starting on a slope with a tight mountain road. explain.
[0034]
First, when the accelerator is depressed and the vehicle starts at time t0, the flow proceeds to step S1, step S2, step S3, step S4, step S5, step S6 in the flowchart of FIG. Front and rear wheel torque distribution control is executed with the command value by the select high of force distribution control and differential rotation control as the target transmission torque.
[0035]
In step S4, until the time t1 when it is determined that the first timer value T1 is equal to or longer than the first set time Ta required for the transition from vehicle start to steady running, step S1 → Steps S2 → S3 → Step S4 → Step S5 → Step S6 are repeated, and front and rear wheel torque distribution control is executed with the command value by the selection high of driving force distribution control and differential rotation control as the target transmission torque. Is done.
[0036]
Therefore, for example, the larger the accelerator opening ACC, the larger the transmission torque is transmitted to the left and right front wheels 14 and 15, which are driven wheels, and the engine torque is distributed to the four wheels 7, 8, 14, and 15 at substantially equal distribution. Thus, it is possible to run on a continuous uphill road with high driving performance that suppresses the driving slip of the left and right rear wheels 7 and 8.
[0037]
In step S3, when it is determined that the first timer value T1 is equal to or longer than the first set time Ta regardless of the determination that the current range is the driving force distribution control region, in the flowchart of FIG. The flow proceeds from step S1, step S2, step S3, step S4, step S7, and step S8. In step S8, the left and right rear wheels 7 and 8 (main drive wheels) and the left and right front wheels 14 and 15 (secondary drive wheels). Front and rear wheel torque distribution control is executed with the torque transmitted to the left and right front wheels 14 and 15 as a target transmission torque according to the speed difference.
[0038]
Therefore, the torque transmitted to the left and right front wheels 14 and 15 is switched from the driving force distribution control to the differential rotation control at the time t1, unlike the conventional control specification in which the driving force distribution control is continued until the time t4. For example, when the transfer clutch 9 is a hydraulic clutch unit, excessive oil temperature rise is prevented, and gears, chains, etc. are connected to the unit torque transmission path to the left and right front wheels 14, 15. If so, the fatigue strength is ensured, and the durability and reliability of the transfer clutch 9 can be improved.
[0039]
Next, when the accelerator release operation is performed at time t3 just before entering the curve of the mountain road with a steep slope, the flow proceeds from step S1 to step S2 to step S9 to step S10 to step S11 in the flowchart of FIG. Thus, in step S11, the torque transmitted to the left and right front wheels 14 and 15 according to the speed difference between the left and right rear wheels 7 and 8 (main drive wheels) and the left and right front wheels 14 and 15 (secondary drive wheels) is set to the target transmission torque. The wheel torque distribution control is continued as it is.
[0040]
Unlike the conventional control specification in which the driving force distribution control is started at the time t5, in step S9, the second timer value T2 is equal to or longer than the second set time Td required from turning on to turning off. Until the time t7 is determined, in the flowchart of FIG. 2, the flow of steps S1, S2, S9, S10, and S11 is repeated, and the front and rear wheel torque distribution control by the differential rotation control is continued. The
[0041]
Therefore, in the actual driving scene, since the accelerator is frequently turned ON / OFF, the time zone from the accelerator OFF operation (t3) to the second set time Td (t7) is set, that is, the dead zone of the driving force distribution control. By setting the time zone, the frequency of transmitting a large torque to the driven wheels can be suppressed by frequent driving force distribution control, and the durability and reliability of the transfer clutch 9 can be improved.
[0042]
Then, when the accelerator is depressed again at time t6 when the curve is exited, and it is determined that the driving force distribution control region is at time t7, step S1 → step S2 → step in the flowchart of FIG. The flow proceeds from S3 to step S4 to step S5 to step S6. In step S6, front and rear wheel torque distribution control is performed in which the command value by the selection high of the driving force distribution control and the differential rotation control is the target transmission torque. .
[0043]
Next, the effect will be described.
In the driving force distribution control device for a four-wheel drive vehicle of the first embodiment, the effects listed below can be obtained.
[0044]
(1) Transfer clutch 9 provided in a drive system that distributes engine torque to left and right front wheels 14 and 15 and left and right rear wheels 7 and 8, and left and right front wheels 14 and 15 that provide front and rear wheel torque distribution according to vehicle conditions In the drive force distribution control device for a four-wheel drive vehicle, comprising: a differential limit controller 20 that calculates a target transmission torque and commands the transfer clutch 9 to obtain a calculated target transmission torque. The controller 20 outputs a driving force distribution control means for outputting a command for transmitting a large torque to the driven wheels for the purpose of ensuring the starting performance, and after the first set time Ta required for shifting from the vehicle start to the steady running. And a first driving force distribution control prohibiting means for prohibiting the driving force distribution control, so that the transfer clutch 9 which is a torque distribution actuator is unnecessary. By suppressing torque transmission, the durability and reliability of the transfer clutch 9 can be improved.
[0045]
(2) The differential restriction controller 20 detects the accelerator release operation detecting step S2 for detecting the accelerator release operation, and until a second set time Td required from turning on to turning out by detecting the accelerator releasing operation has elapsed. Has a second driving force distribution control prohibiting means for prohibiting the driving force distribution control, so that the frequency of transmitting a large torque to the driven wheels can be suppressed by becoming the driving force distribution control. The durability and reliability of the transfer clutch 9 can be improved.
[0046]
(3) The differential limiting controller 20 responds to the driving force distribution control means for outputting a command for transmitting a large torque to the driven wheels for the purpose of ensuring the starting performance, and the speed difference between the main driving wheels and the driven wheels. Differential rotation control means for outputting a command for transmitting torque to the driven wheel, and the driving force distribution control prohibiting means switches to the differential rotation control when the driving force distribution control is prohibited. Even if the driving force distribution control by is prohibited, the occurrence of driving slip due to the accelerator depressing operation can be minimized.
[0047]
(4) An accelerator opening sensor 21 that detects the accelerator opening ACC, left and right front wheel speed sensors 46 and 47 that detect the vehicle speed V, a driving force distribution control area and a differential rotation control area based on the accelerator opening ACC and the vehicle speed V And the first driving force distribution control prohibiting means of the differential limit controller 20 is continuously connected by driving force distribution control after starting of the vehicle based on selection of the driving force distribution control region. When the elapsed time of the driving state reaches the first set time Ta required for the transition from the vehicle start to the steady traveling, the differential rotational control is forcibly performed. The differential rotation control after waiting for the first set time Ta when traveling on an uphill road where the selection of the driving force distribution control area is continued while ensuring the transition to the differential rotation control before reaching the first set time Ta by The transition to can be ensured.
[0048]
(5) The accelerator opening sensor 21 for detecting the accelerator opening ACC, the left and right front wheel speed sensors 46, 47 for detecting the vehicle speed V, the driving force distribution control area and the differential rotation control area according to the accelerator opening ACC and the vehicle speed V. And the second driving force distribution control prohibiting means of the differential limiting controller 20 is moved to the driving force distribution control region by depressing the accelerator when an accelerator release operation is detected. Even when the vehicle enters, only the differential rotation control is executed until the second set time Td required from the turning on to the exit from the turning based on the detection of the accelerator release operation, so that the degree of freedom in selecting the driving force distribution control and the differential rotation control is increased. The frequency of transmitting large torque to the driven wheels can be suppressed by ensuring the driving force distribution control while ensuring.
[0049]
(6) The driving force distribution control means is a slave drive by a torque command value to a slave drive wheel by feedforward control according to an engine torque equivalent value and a feedback control by a speed difference between the master drive wheel and the slave drive wheel. For example, if the torque command value in the differential rotation control is larger than the torque command value based on the accelerator opening, due to a large wheel spin at the start By selecting the torque command value in the control, higher start acceleration performance can be achieved.
[0050]
As mentioned above, although the drive force distribution control apparatus of the four-wheel drive vehicle of this invention has been demonstrated based on 1st Example, it is not restricted to this 1st Example about a concrete structure, Claims Modifications and additions of the design are permitted without departing from the spirit of the invention according to the claims.
[0051]
For example, in the first embodiment, an example of application to a four-wheel drive vehicle based on a rear wheel drive is shown, but it can also be applied to a four-wheel drive vehicle based on a front wheel drive base.
[0052]
In the first embodiment, when driving force distribution control is prohibited, an example of switching to differential rotation control is shown. However, when driving force distribution control is prohibited, the torque distribution actuator (transfer clutch) is released and the two-wheel drive state is entered. It may be an example to do.
[Brief description of the drawings]
FIG. 1 is an overall system diagram showing a driving force distribution control device for a four-wheel drive vehicle according to a first embodiment;
FIG. 2 is a flowchart showing a flow of torque distribution control processing executed by a differential limiting controller of the first embodiment apparatus;
FIG. 3 is a diagram showing a control area map set in the differential limiting controller of the first embodiment apparatus;
FIG. 4 is a time chart showing a torque distribution control operation executed by the differential limiting controller of the first embodiment apparatus when traveling on a steep uphill road.
[Explanation of symbols]
1 Engine 2 Automatic transmission 3 Rear propeller shaft 4 Rear differential 5, 6 Rear drive shaft 7 Left rear wheel 8 Right rear wheel 9 Truss clutch (torque distribution actuator)
DESCRIPTION OF SYMBOLS 10 Front propeller shaft 11 Front differential 12, 13 Front drive shaft 14 Left front wheel 15 Right front wheel 16 Engine controller 17 Automatic transmission controller 19 Front-back differential limiting actuator 20 Differential limiting controller (torque distribution controller)
21 Accelerator opening sensor (accelerator opening detector)
22 Longitudinal acceleration sensor 23 Mode changeover switch 44 Brake controller 46 Front left wheel speed sensor (vehicle speed detection means)
47 Front right wheel speed sensor (vehicle speed detection means)
48 Left rear wheel speed sensor 49 Right rear wheel speed sensor

Claims (5)

A torque distribution actuator provided in a drive system for distributing engine torque to the front and rear wheels;
A torque distribution controller that calculates a target transmission torque to one of the front and rear wheels so as to achieve front and rear wheel torque distribution according to a vehicle state, and commands the torque distribution actuator to obtain the calculated target transmission torque;
In the drive force distribution control device for a four-wheel drive vehicle equipped with
The torque distribution controller
Driving force distribution control means for outputting a command to transmit a large torque to the driven wheel for the purpose of securing the starting performance;
An accelerator release operation detecting means for detecting an accelerator release operation;
First driving force distribution control prohibiting means for prohibiting the driving force distribution control after a first set time required for transition from vehicle start to steady travel has elapsed;
A second driving force distribution control prohibiting means for prohibiting the driving force distribution control until a second set time required from turning on to turning off by detecting an accelerator release operation;
A drive force distribution control device for a four-wheel drive vehicle. In the drive force distribution control device for a four-wheel drive vehicle according to claim 1 ,
The torque distribution controller
Driving force distribution control means for outputting a command to transmit a large torque to the driven wheel for the purpose of securing the starting performance;
Differential rotation control means for outputting a command to transmit torque to the slave drive wheel according to the speed difference between the master drive wheel and the slave drive wheel,
The driving force distribution control prohibiting means switches to differential rotation control when the driving force distribution control is prohibited, and is a four-wheel drive vehicle driving force distribution control device. In the drive force distribution control device for a four-wheel drive vehicle according to claim 2 ,
An accelerator opening detecting means for detecting the accelerator opening;
Vehicle speed detection means for detecting the vehicle speed;
A control area map setting means divided into a driving force distribution control area and a differential rotation control area according to the accelerator opening and the vehicle speed;
The first driving force distribution control prohibiting means of the torque distribution controller shifts the elapsed time of the continuous running state by the driving force distribution control from the vehicle starting to the steady driving after the vehicle starts based on the selection of the driving force distribution control region. A driving force distribution control device for a four-wheel drive vehicle, characterized in that when the first set time required by the time is reached, the control is forcibly shifted to differential rotation control. In the four-wheel drive vehicle driving force distribution control device according to claim 2 ,
An accelerator opening detecting means for detecting the accelerator opening;
Vehicle speed detection means for detecting the vehicle speed;
A control area map setting means divided into a driving force distribution control area and a differential rotation control area according to the accelerator opening and the vehicle speed;
When the accelerator foot release operation is detected, the second drive force distribution control prohibiting means of the torque distribution controller is configured to perform from the turning on to the turning escape by detecting the accelerator foot releasing operation even if the accelerator foot releasing operation is entered. A driving force distribution control device for a four-wheel drive vehicle, wherein only the differential rotation control is executed until a required second set time elapses. The drive force distribution control device for a four-wheel drive vehicle according to any one of claims 1 to 4 ,
The driving force distribution control means includes a torque command value to the driven wheel by feedforward control according to the engine torque equivalent value and a feedback to the driven wheel by feedback control according to the speed difference between the driven wheel and the driven wheel. A driving force distribution control device for a four-wheel drive vehicle, which outputs a torque command value and a command value based on a select high.

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