JP2011046354A - Drive force distribution control device for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To attain approaching of the timing that protection control of a drive system is released to the timing that the protection control should be released, to reduce damage to the drive system, and to sufficiently exhibit four-wheel driving performance. <P>SOLUTION: A heating value and an atmosphere temperature stored in a non-volatile memory are immediately read out by a heating value correction means when an ignition switch is subsequently turned ON, and the heating value read out from the non-volatile memory is corrected based on difference of the atmosphere temperature when the ignition switch is turned ON, an atmosphere temperature stored when the ignition switch is turned OFF and an atmosphere temperature detected when the ignition switch is turned ON and difference of the atmosphere temperature detected when the ignition switch is turned ON and the detected outside air temperature. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a driving force distribution control device for a vehicle, and in particular, protection control for limiting the torque transmitted to the sub drive shaft by the amount of heat generated by the driving force distribution device can be performed at an appropriate time and is given to the drive system. The present invention relates to a vehicle driving force distribution control device capable of reducing damage.

There is a so-called four-wheel drive vehicle in which a drive system includes a drive force distribution device that distributes a drive force from an engine to main drive wheels and sub drive wheels according to a traveling state. In this vehicle, the heat generation amount of the driving force distribution device is obtained based on the engine speed and the transmission torque, the temperature of the driving force distribution device is estimated from the integrated value of the heat generation amount, and the torque transmitted to the sub drive wheels is calculated. Some have a driving force distribution control device for limiting.
In the vehicle driving force distribution control device, when the ignition switch is turned off and then the ignition switch is turned on, the amount of generated heat is lost and the estimated temperature is cleared. When protection control is performed using this estimated temperature, protection control may not work even if the ignition switch is turned off / on in a short period of time, even though the temperature is originally to be protected. is there. As means for solving this problem, there are those disclosed in Patent Document 1 and Patent Document 2.
Patent Document 1 stores the estimated temperature of the heat generation point when the ignition switch is turned off, obtains the estimated temperature when the ignition switch is turned on from the elapsed time when the ignition switch is turned off and the stored estimated temperature when the ignition switch is turned on next time, Protection control is performed.
Patent Document 2 stores the amount of heat generated by a preset ratio when the ignition switch is turned off, and performs protection control using the amount of heat stored when the ignition switch is turned on the next time.

JP 2007-38798 A JP 2007-131189 A

However, since the driving force distribution control device of Patent Document 1 uses the ignition switch-off elapsed time for protection control, it is necessary to provide a means capable of measuring the time even when the power is shut off by the ignition switch-off. is there.
Further, since the driving force distribution control device of Patent Document 2 stores the heat generation amount reduced by a preset ratio when the ignition switch is turned off, there is the following problem.

(1) Problem 1
In Patent Document 2, each time the ignition switch is turned off / on, the stored heat generation amount decreases by a set ratio. As a result, when the actual temperature of the driving force distribution device is high, when the ignition switch is repeatedly turned off / on, the amount of heat generated is turned on even though the actual temperature of the driving force distribution device is high. Every time it is turned off, it decreases, and in any case, the amount of heat generation becomes less than the threshold value at which the drive system protection control works, and the protection control does not work. For this reason, there is a problem of damaging the drive system.
(2) Problem 2
In Patent Document 2, when the ignition switch is turned off in a state where the amount of heat generation is large and then the ignition is turned on after a long time has passed and the actual temperature of the driving force distribution device is sufficiently lowered, the amount of heat generation depends on the set ratio. Does not fall below the threshold for canceling the protection control of the drive system, and the protection control is activated. For this reason, there is a problem that the four-wheel drive performance is not achieved because the four-wheel drive is not achieved.
(3) Problem 3
In Patent Document 2, when the ignition switch is turned on in a short time after turning off the ignition switch in a state where the heat generation amount is large, the actual temperature of the driving force distribution device is turned on in a high temperature state, Depending on the set ratio, the amount of heat generation will be below the threshold value for canceling the drive system protection control, and protection control will not work. For this reason, there is a problem of damaging the drive system.
(4) Problem 4
In Patent Literature 2, depending on the set ratio, the amount of heat generated when the ignition switch is turned on becomes smaller than the actual temperature of the driving force distribution device, and it takes time until protection control is activated. For this reason, there is a problem that the time for four-wheel drive becomes longer and damages the drive system.
(5) Problem 5
In Patent Document 2, depending on the set ratio, the amount of heat generated when the ignition switch is turned on becomes larger than the actual temperature of the driving force distribution device, and the time until protection control is activated is short. For this reason, there is a problem that the time for four-wheel drive is shortened and the four-wheel drive performance cannot be fully exhibited.

  These are in a trade-off relationship, and any problem will always occur regardless of how the ratio of decreasing the heat generation amount is set.

  The present invention makes it possible to bring the timing when the protection control of the drive system is released closer to the time when the protection control is to be released, reduce the damage to the drive system, and sufficiently exert the four-wheel drive performance. An object of the present invention is to realize a vehicle driving force distribution control device that can perform the above operation.

  The present invention includes a driving force distribution device that distributes the driving force from the engine to the main driving wheel and the sub driving wheel according to the running state of the vehicle, and calculates the heat generation amount of the driving force distribution device. Heat generation in the non-volatile memory capable of electrically rewriting data when the ignition switch is turned off, and protection control means for limiting the torque transmitted to the auxiliary drive wheel by the heat generation amount calculated by the heat generation amount calculation means A calorific value storage means for storing the quantity, and the calorific value stored in the non-volatile memory by the calorific value storage means by the protection control means is immediately read out when the ignition switch is turned on and compared with a set value. When the read calorific value is larger than the set value, the vehicle driving force distribution control device for limiting the torque transmitted to the auxiliary driving wheel detects the outside air temperature. The detection means, the ambient temperature detection means for detecting the ambient temperature of the driving force distribution device, and the atmosphere temperature detected by the ambient temperature detection means when the ignition switch is turned off can be electrically rewritten. An atmospheric temperature storage means for storing in a non-volatile memory; and a heat generation amount correction means for reading and correcting the heat generation amount stored in the nonvolatile memory by the heat generation amount storage means when an ignition switch is turned on. The calorific value stored in the non-volatile memory by the calorific value storage means and the ambient temperature stored in the non-volatile memory by the ambient temperature storage means are immediately read out by the amount correction means when the ignition switch is next turned on. Detected by the ambient temperature detecting means when the ignition switch is turned on. The difference between the ambient temperature and the ambient temperature stored in the non-volatile memory by the ambient temperature storage means when the ignition switch is turned off and the ambient temperature detected by the ambient temperature detection means when the ignition switch is turned on; Based on the difference between the ambient temperature detected by the ambient temperature detection means when the ignition switch is turned on and the ambient temperature detected by the ambient temperature detection means, the amount of heat generated read from the nonvolatile memory is corrected. It is characterized by doing.

The vehicle driving force distribution control device according to the present invention protects the driving system by limiting the torque transmitted to the auxiliary driving shaft because the driving system may be damaged when the amount of heat generated by the driving force distribution device increases. I have to.
A conventional vehicle driving force distribution control device stores a heat generation amount reduced by a preset ratio in a nonvolatile memory capable of electrically rewriting data when an ignition switch is turned off. For this reason, when the conventional driving force distribution control device for a vehicle repeats turning on / off of the ignition switch, the stored calorific value is stored every time the ignition switch is turned on / off even though the driving force distribution device is at a high temperature. As a result, the threshold value decreases below the threshold at which protection control for protecting the drive system is activated, and the protection control does not work. As a result, the drive system may be damaged.
According to the vehicle driving force distribution control device of the present invention, the protection control should be released when the protection control is released by accurately calculating the heat generation amount of the driving force distribution device when the ignition switch is turned on. It becomes possible to approach the time, and damage to the drive system can be reduced.
The conventional vehicle driving force distribution control device is set when the ignition switch is turned on after a long time has passed and the temperature of the driving force distribution device is sufficiently lowered after the ignition switch is turned off while the stored heat generation amount is large. Depending on the ratio, the stored heat generation amount does not fall below the threshold value for canceling the protection control that protects the drive system, the protection control remains active, and the four-wheel drive state does not occur.
According to the vehicle driving force distribution control device of the present invention, the protection control should be released when the protection control is released by accurately calculating the heat generation amount of the driving force distribution device when the ignition switch is turned on. It becomes possible to approach the time, and the four-wheel drive performance can be exhibited sufficiently.
The conventional driving force distribution control device for a vehicle protects the driving system by limiting the torque transmitted to the auxiliary driving shaft because the driving system may be damaged when the amount of heat generated by the driving force distribution device increases. It has become.
A conventional vehicle driving force distribution control device stores a heat generation amount reduced by a preset ratio in a nonvolatile memory in which data can be electrically rewritten when an ignition switch is turned off. The conventional vehicle driving force distribution control device is set when the ignition switch is turned on only after a short period of time after the ignition switch is turned off while the stored calorific value is large. Depending on the ratio, the stored heat generation amount becomes lower than the threshold value for releasing the protection control for protecting the drive system, and the protection control does not work. As a result, the drive system may be damaged.
According to the vehicle driving force distribution control device of the present invention, the protection control should be released when the protection control is released by accurately calculating the heat generation amount of the driving force distribution device when the ignition switch is turned on. It becomes possible to approach the time, and damage to the drive system can be reduced.
In the conventional vehicle driving force distribution control device, depending on the set ratio, the stored heat generation amount becomes smaller than the actual heat generation amount of the driving force distribution device when the ignition switch is turned on. This may take time and damage the drive system.
The vehicle driving force distribution control device according to the present invention corrects the amount of heat generated by the driving force distribution device when the ignition switch is turned on and accurately calculates the protection control when the protection control is released. It becomes possible to approach the power time, and damage to the drive system can be reduced.
In the conventional vehicle driving force distribution control device, depending on the set ratio, the stored heat generation amount becomes larger than the actual heat generation amount of the driving force distribution device when the ignition switch is turned on. The time is shortened and the four-wheel drive state is released immediately.
According to the vehicle driving force distribution control device of the present invention, the protection control should be released when the protection control is released by accurately calculating the heat generation amount of the driving force distribution device when the ignition switch is turned on. It becomes possible to approach the time, and the four-wheel drive performance can be exhibited sufficiently.

1 is a system configuration diagram of a vehicle driving force distribution control device. FIG. (Example) It is a figure which shows the emitted-heat amount correction coefficient 1 by the atmospheric temperature of the driving force distribution apparatus at the time of ON of an ignition switch. (Example) It is a figure which shows the emitted-heat amount correction coefficient 2 by the difference of the atmospheric temperature of the driving force distribution apparatus at the time of ON and OFF of an ignition switch. (Example) It is a figure which shows the emitted-heat amount correction coefficient 3 by the difference of the atmospheric temperature and external temperature of a driving force distribution apparatus at the time of ON of an ignition switch. (Example) It is a figure which shows the transmission torque maximum value by the emitted-heat amount. (Example) It is a flowchart of control by the driving force distribution control apparatus of a vehicle. (Example) (A) is the time chart of the conventional control in Problem 1, (B) is the time chart of the control of this invention with respect to Problem 1. (Example) (A) is the time chart of the conventional control in Problem 2, and (B) is the time chart of the control of this invention with respect to Problem 2. (Example) (A) is a time chart of the conventional control in Problem 3, and (B) is a time chart of the control of the present invention for Problem 3. (Example) (A) is the time chart of the conventional control in the problem 4, (B) is the time chart of the control of this invention with respect to the problem 4. (Example) (A) is the time chart of the conventional control in the problem 5, (B) is the time chart of the control of this invention with respect to the problem 5. (Example)

The present invention immediately reads the heat generation amount and the ambient temperature of the driving force distribution device stored in the nonvolatile memory when the ignition switch is turned on next time, and the ambient temperature of the driving force distribution device when the ignition switch is turned on. The difference between the ambient temperature of the driving force distribution device when the ignition switch is turned off and the ambient temperature of the driving force distribution device when the ignition switch is turned on, and the driving force distribution device when the ignition switch is turned on By correcting the amount of heat read from the non-volatile memory based on the difference between the ambient temperature and the outside air temperature, the amount of heat generated by the driving force distribution device is corrected when the ignition switch is turned on and accurately calculated. The time when the protection control is released can be made closer to the time when the protection control should be released.
Embodiments of the present invention will be described below with reference to the drawings.

1 to 11 show an embodiment of the present invention. In FIG. 1, 1 is a vehicle, 2 is an engine, 3 is a transmission, 4 is a front differential, 5R and 5L are front right and left front axles, 6R and 6L are main front wheels and front right and left front wheels, 7 is a transfer, 8 is a propeller shaft, 9 is a driving force distribution device, 10 is a rear side differential, 11R and 11L are right rear axles and left rear axles, and 12R and 12L are right rear wheels and left rear wheels which are auxiliary driving wheels.
The vehicle 1 converts the driving force of the engine 2 horizontally mounted on the front side by the transmission 3 and transmits it to the front differential 4 to drive the right front and left front wheels 6R and 6L by the right front and left front axles 5R and 5L. Further, the vehicle 1 takes out a part of the driving force output from the transmission 3 by the transfer 7 and transmits it to the rear differential 10 via the propeller shaft 8 and the driving force distribution device 9, to the right rear and left rear. The right rear and left rear wheels 12R and 12L are driven by the axles 11R and 11L. Therefore, this vehicle 1 is a so-called four-wheel drive vehicle.
The driving force distribution device 9 applies the driving force from the engine 2 to the front right and left front wheels 6R and 6L as main driving wheels and the right rear and left rear wheels 12R and sub driving wheels according to the traveling state of the vehicle 1. Distribute to 12L. The driving force distribution device 9 includes an electronically controllable clutch 13 and a coil 14 that determines the fastening force of the clutch 13. The coil 14 is connected to the control means 16 of the driving force distribution control device 15. . The driving force distribution device 9 is driven by the driving current which is a control signal from the control means 16 to determine the fastening force of the clutch 13, and the driving force corresponding to the driving current is applied to the right rear and auxiliary driving wheels. It is transmitted to the left rear wheels 12R and 12L.
The control means 16 of the driving force distribution control device 15 includes an engine control device that controls the engine 2 through the CAN communication line 17, a transmission control device that controls the transmission 3, a brake control device that controls the brake system, and the like. Various control devices 18 are connected. The control means 16 of the driving force distribution control device 15 is necessary for controlling the driving force distribution device 9 from various control devices 18 such as engine speed, throttle opening, vehicle speed, gear position, wheel rotation speed, and the like. Various vehicle information is input through the CAN communication line 17.
An ignition switch signal is input to the control means 16 of the driving force distribution control device 15.
The driving force distribution control device 15 calculates the driving force transmitted to the right rear and left rear wheels 12R and 12L, which are auxiliary driving wheels, based on various vehicle information input from the various control devices 18 by the control means 16. The engagement force of the clutch 13 is determined by controlling the drive current that flows through the coil 14 of the drive force distribution device 9 according to the drive force. As a result, the driving force distribution control device 15 applies the driving force from the engine 2 to the right front / left front wheels 6R, 6L as the main driving wheels and the right rear / left rear as the auxiliary driving wheels according to the traveling state of the vehicle 1. Distribute to wheels 12R and 12L.

The driving force distribution control device 15 includes a control unit 16 that generates a heat generation amount calculation unit 19 that calculates a heat generation amount of the driving force distribution device 9 and a right side that is a sub drive wheel based on the heat generation amount calculated by the heat generation amount calculation unit 19. The calorific value calculation means 19 calculates the protection control means 20 for limiting the torque transmitted to the rear and left rear wheels 12R and 12L, and the non-volatile memory 21 that can electrically rewrite data when the ignition switch is turned off. And a calorific value storage means 22 for storing the generated calorific value.
The calorific value stored in the nonvolatile memory 21 by the calorific value storage means 22 is read out immediately by the protection control means 20 when the ignition switch is turned on and compared with a set value (threshold value). When the read heat generation amount is larger than the set value (threshold value), the protection control means 20 limits the torque transmitted to the right rear and left rear wheels 12R and 12L, which are auxiliary drive wheels. By controlling the drive current that flows through the coil 14, protection control of the drive force distribution device 9 is performed.

In this driving force distribution control device 15, the control means 16 has an outside air temperature detection means 23 for detecting the outside air temperature, an atmosphere temperature detection means 24 for detecting the atmosphere temperature of the driving force distribution device 9, and an ignition switch turned off. Sometimes, the ambient temperature storage means 25 that stores the ambient temperature of the driving force distribution device 9 detected by the ambient temperature detection means 24 in the nonvolatile memory 21 that can electrically rewrite data, and the calorific value storage means 22. A heat generation amount correction means 26 is provided for reading and correcting the heat generation amount of the driving force distribution device 9 stored in the nonvolatile memory 21 when the ignition switch is turned on.
The calorific value of the driving force distribution device 9 stored in the nonvolatile memory 21 by the calorific value storage unit 22 and the ambient temperature of the driving force distribution device 9 stored in the nonvolatile memory 21 by the ambient temperature storage unit 25 are the calorific value. The correction means 26 immediately reads out the next time the ignition switch is turned on.
The calorific value correction means 26 includes a non-volatile memory 21 by the atmosphere temperature storage means 25 when the ignition switch is turned off and the atmosphere temperature of the driving force distribution device 9 detected by the atmosphere temperature detection means 24 when the ignition switch is turned on. The difference between the ambient temperature of the driving force distribution device 9 stored in the memory and the ambient temperature of the driving force distribution device 9 detected by the ambient temperature detection means 24 when the ignition switch is turned on, and the atmosphere when the ignition switch is turned on Based on the difference between the ambient temperature of the driving force distribution device 9 detected by the temperature detector 24 and the ambient temperature detected by the ambient temperature detector 23, the ignition switch read from the nonvolatile memory 21 is turned off. Correct the amount of heat generated when
The corrected heat generation amount is compared with a set value (threshold value) by the protection control means 20. When the corrected heat generation amount is larger than the set value (threshold value), the protection control means 20 limits the torque transmitted to the right rear and left rear wheels 12R and 12L, which are auxiliary drive wheels. By controlling the drive current that flows through 14, protection control of the drive force distribution device 9 is performed.
In this way, the driving force distribution control device 15 calculates the heat generation amount of the driving force distribution device 9 and performs protection control using the calculated heat generation amount, and acquires the ambient temperature of the driving force distribution device 9. Means for acquiring the outside air temperature, means for storing the heat generation amount and the ambient temperature of the driving force distribution device 9 in the storage medium when the ignition switch is turned off, and means for correcting the stored heat generation amount when the ignition switch is turned on. ing. The driving force distribution control device 15 stores the amount of heat generated by the driving force distribution device 9 and the ambient temperature when the ignition switch is turned off, and the outside air temperature, the ambient temperature of the driving force distribution device 9 and the stored driving force when the ignition switch is turned on. A correction coefficient is obtained from the ambient temperature of the distribution device 9, and an initial value of the heat generation amount is determined from the stored heat generation amount of the driving force distribution device 9 and the correction coefficient. Using this initial value, the driving force distribution device 9 calculates a heat generation amount and performs protection control of the driving force distribution device 9.

The driving force distribution control device 15 calculates the heat generation amount as follows when the ignition switch is turned on.
(1) When the ignition switch is turned off, the amount of heat generated by the driving force distribution device 9 and the ambient temperature are stored.
(2) The heat generation amount correction coefficient 1 is calculated from the current ambient temperature of the driving force distribution device 9 when the ignition switch is turned on. As shown in FIG. 2, the heat generation amount correction coefficient 1 is set to be smaller as the ambient temperature of the driving force distribution device 9 is higher.
(3) The heat generation amount correction coefficient 2 is calculated from the difference between the current ambient temperature of the driving force distribution device 9 when the ignition switch is turned on and the ambient temperature of the driving force distribution device 9 stored when the ignition switch is turned off. As shown in FIG. 3, the heat generation amount correction coefficient 2 is set so as to increase as the difference in the atmospheric temperature of the driving force distribution device 9 increases.
(4) The heat generation amount correction coefficient 3 is calculated from the current ambient temperature of the driving force distribution device 9 and the current outside air temperature when the ignition switch is turned on. As shown in FIG. 4, the heat generation amount correction coefficient 3 is set to be smaller as the difference between the ambient temperature of the driving force distribution device 9 and the outside air temperature is larger.
(5) The heat generation amount of the driving force distribution device 9 is calculated from the heat generation amount of the driving force distribution device 9 stored when the ignition switch is turned off and the calculated heat generation amount correction coefficients 1, 2, and 3.
(6) The calculated heat generation amount is used for protection control of the driving force distribution control device 15 as the heat generation amount of the driving force distribution device 9 when the ignition switch is turned on. As shown in FIG. 5, the maximum transmission torque value of the driving force transmitted by the driving force distribution device 9 is set to be smaller as the heat generation amount is larger.

  In the driving force distribution control device 15, the heat generation amount correction coefficient 1, the heat generation amount correction coefficient 3 are a decrease function, and the heat generation amount correction coefficient 2 is an increase function, so that the heat generation amount actually decreases when the ignition switch is turned on. If it is not (when the ignition switch is turned on immediately after the ignition switch is turned off, etc.), the calorific value is not reduced, but when the ignition switch is actually turned on, the calorific value is actually lowered (after the ignition switch is turned off, For example, when the ignition switch is turned on after a long time, the amount of heat generated can be reduced. In other words, the driving force distribution control device 15 can calculate the amount of heat generation according to the vehicle situation immediately after the ignition switch is turned on, and can exhibit sufficient drive system protection and four-wheel drive performance. .

Next, the operation will be described.
As shown in FIG. 6, when the control starts (101), the driving force distribution control device 15 determines whether the ignition switch that is determination 1 is on (102). If this determination (102) is NO, the heat generation amount and the ambient temperature of the driving force distribution device 9 are stored in the nonvolatile memory 21 of the storage medium (103) when the ignition switch is turned off (103), and the control is ended (104). ).
If the determination (102) is YES, after the ignition switch (determination 2) is turned on, it is determined whether this is the first routine of this control (105).

If this determination (105) is YES, processing (106) to processing (111) are executed. (1) In the process (106), the atmospheric temperature difference is calculated from the atmospheric temperature of the driving force distribution device 9 when the ignition switch is turned on and the atmospheric temperature of the driving force distribution device 9 stored when the ignition switch is turned off.
Atmosphere temperature difference = Ambient temperature stored when ignition switch is turned off−Ambient temperature when ignition switch is turned on.
(2) In the process (107), from the ambient temperature of the driving force distribution device 9 when the ignition switch is turned on and the ambient temperature when the ignition switch is turned on, the ambient temperature outside temperature difference is calculated as follows:
Ambient temperature outside air temperature difference = driving force distribution device atmosphere temperature-outside air temperature is calculated.
(3) In the process (108), the heat generation amount correction coefficient 1 is calculated from the ambient temperature of the driving force distribution device 9 when the ignition switch is turned on.
(4) In the process (109), the heat generation amount correction coefficient 2 is calculated from the atmospheric temperature difference obtained in the process (106).
(5) In the process (110), the heat generation amount correction coefficient 3 is calculated from the ambient temperature outside air temperature difference obtained in the process (107).
(6) In the processing (111), the heat generation amount is calculated from the heat generation amount of the driving force distribution device 9 stored when the ignition switch is turned off and the calculated heat generation amount correction coefficients 1, 2, and 3.
Heat generation amount = heat generation amount stored when the ignition switch is turned off × {1- (heat generation amount correction coefficient 1 + heat generation amount correction coefficient 2 + heat generation amount correction coefficient 3)}
It is calculated from the following formula.

After execution of the processing (106) to processing (111), and when the determination (105) is NO, processing (112) to processing (116) are executed to control the driving force distribution device 9.
(1) In process (112), the transmission torque of the driving force transmitted by the driving force distribution device 9 is calculated from various vehicle information.
(2) In the process (113), the instantaneous value of the heat generation amount is calculated from the differential rotation of the driving force distribution device 9 and the transmission torque, and the heat generation amount is integrated.
(3) In the process (114), the maximum transmission torque value of the driving force distribution device 9 is calculated from the integrated heat generation amount.
(4) In the process (115), the calculated transmission torque is limited to the maximum transmission torque value.
(5) In process (116), a drive current is calculated from the calculated transmission torque. The driving force distribution control device 15 causes the calculated driving current to flow to the driving force distribution device 9 and controls the driving force to be distributed.

  After execution of the processes (112) to (116), the process returns to the determination (102).

The operation of the driving force distribution control device 15 will be described.
The following four patterns are listed as main operation patterns.
(1) When there is a difference in the ambient temperature of the driving force distribution device 9 between when the ignition switch is turned off and when the ignition switch is turned on, the ambient temperature and the outside temperature of the driving force distribution device 9 when the ignition switch is turned on There is also a difference.
(2) When there is a difference in the ambient temperature of the driving force distribution device 9 between when the ignition switch is turned off and when the ignition switch is turned on, the ambient temperature and the outside air temperature of the driving force distribution device 9 when the ignition switch is turned on There is not much difference.
(3) When the ignition switch is turned off and when the ignition switch is turned on, there is not much difference in the ambient temperature of the driving force distribution device 9, and the ambient temperature and the outside air temperature of the driving force distribution device 9 when the ignition switch is turned on There is a difference in the state.
(4) When the ignition switch is turned off and when the ignition switch is turned on, there is not much difference in the ambient temperature of the driving force distribution device 9, and the ambient temperature and the outside air temperature of the driving force distribution device 9 when the ignition switch is turned on There is not much difference.

As a specific example of the operation pattern (1), normal use such as taking a short break after four-wheel drive running and starting running again is applicable. During four-wheel drive traveling, the driving force distribution device 9 generates heat and the temperature rises. During traveling, the processing of the control content shown in (113) of FIG. 6 is performed to calculate the heat generation amount. After driving the vehicle 1 to some extent, the ignition switch is turned off. At this time, the processing of the control content shown in (103) of FIG. 6 is performed, and the heat generation amount and the ambient temperature of the driving force distribution device 9 are stored in the nonvolatile memory 21. While the ignition switch is off, the driving force distribution device 9 is naturally cooled by the outside air temperature, and the temperature decreases.
After a short break, turn on the ignition switch. At this time, the processing of the control contents shown in (106) to (111) of FIG. 6 is performed only once. First, control content processing shown in (106) of FIG. 6 is performed. Since the temperature of the driving force distribution device 9 is lowered while the ignition switch is off, the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 is turned off / on has a value.
Next, control content processing shown in (107) of FIG. 6 is performed. Since the off time of the ignition switch is not so long, the ambient temperature of the driving force distribution device 9 does not drop to the outside air temperature, and the ambient temperature outside temperature difference of the driving force distribution device 9 has a value.
Next, the process of the control content shown in (108) of FIG. 6 is performed. The heat generation amount correction coefficient 1 is determined from the ambient temperature of the driving force distribution device 9 when the ignition switch is on. As shown in FIG. 2, the heat generation amount correction coefficient 1 is set to be larger at 0 degrees or less, so that the value of the heat generation amount correction coefficient 1 is 0 during normal use. The calorific value correction coefficient 1 indicates the current state of the driving force distribution device 9.
Next, the processing of (109) control contents in FIG. 6 is performed. The heat generation amount correction coefficient 2 is determined from the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 is turned off / on. As shown in FIG. 3, the heat generation amount correction coefficient 2 takes 0 to 0.5 depending on the amount of the atmospheric temperature difference of the driving force distribution device 9. The longer the OFF time of the ignition switch, the more the driving force distribution device 9 is cooled, and the heat generation correction coefficient 2 is increased. That is, the heat generation amount correction coefficient 2 indicates how much the driving force distribution device 9 has been cooled while the ignition switch is off.
Next, the process of the control content shown in (110) of FIG. 6 is performed. The heat generation amount correction coefficient 3 is determined from the ambient temperature outside air temperature difference of the driving force distribution device 9. As shown in FIG. 4, the heat generation amount correction coefficient 3 is set so as to increase as the amount of the ambient temperature / outside air temperature difference of the driving force distribution device 9 decreases. During normal use, the value of the heat generation amount correction coefficient 3 is zero. The calorific value correction coefficient 3 indicates whether the driving force distribution device 9 has been completely cooled.
Next, the process of the control content shown in (111) of FIG. 6 is performed. Since the calorific value correction coefficient 1 and the calorific value correction coefficient 3 each have a value of 0 and the calorific value correction coefficient 2 has a value of 0 to 0.5, the calorific value is calculated from the following formula: ×
(1- (heat generation correction coefficient 1 + heat generation correction coefficient 2 + heat generation correction coefficient 3)}
This is 0.5 to 1 times the amount of heat generated when the ignition switch is off.
If the driving force distribution device 9 is not cooled down very much while the ignition switch is off, the amount of heat generated when the ignition switch is off remains the same, and if it is cooled to some extent, it is 0.5 times the amount of heat generated when the ignition switch is off. Become. With the calorific value calculated in this process as an initial value, the process shifts to four-wheel drive control by the drive force distribution device 9 having the control contents shown in (112) to (116) of FIG. Since the heat generation amount is appropriately calculated according to the heat generation amount when the ignition switch is turned off and the ignition switch off time, the protection control of the driving force distribution device 9 can be appropriately performed.

As a specific example of the operation pattern (2), normal use such as stopping the vehicle 1 after four-wheel drive traveling and restarting use the next day is applicable. During four-wheel drive traveling, the driving force distribution device 9 generates heat and the temperature rises. During traveling, the process of the control content shown in (113) of FIG. 6 is performed to calculate the heat generation amount. After driving the vehicle 1 to some extent, the ignition switch is turned off. At this time, the processing of the control content shown in (103) of FIG. 6 is performed, and the heat generation amount and the ambient temperature of the driving force distribution device 9 are stored in the nonvolatile memory 21. While the ignition switch is off, the driving force distribution device 9 is naturally cooled by the outside air temperature, and the temperature decreases.
On the next day, turn on the ignition switch. At this time, the processing of the control contents shown in (106) to (111) of FIG. 6 is performed only once. First, control content processing shown in (106) of FIG. 6 is performed. Since the temperature of the driving force distribution device 9 is lowered while the ignition switch is off, the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 is turned off / on has a value.
Next, control content processing shown in (107) of FIG. 6 is performed. Since the ignition switch has been turned off for a long time, the ambient temperature of the driving force distribution device 9 is sufficiently lowered and has the same value as the outside air temperature. Therefore, the ambient temperature / outside air temperature difference of the driving force distribution device 9 is zero.
Next, the process of the control content shown in (108) of FIG. 6 is performed. As shown in FIG. 2, the heat generation amount correction coefficient 1 is set to be larger at 0 degrees or less, so that the value of the heat generation amount correction coefficient 1 is 0 during normal use. At this time, since sufficient time has passed since the ignition switch was turned off, the ambient temperature of the driving force distribution device 9 is the same as the outside air temperature. In a cold region where the outside air temperature is 0 degrees or less, the value of the calorific value correction coefficient 1 is 0 to 0.5.
Next, the process of the control content shown in (109) of FIG. 6 is performed. As shown in FIG. 3, the heat generation amount correction coefficient 2 takes 0 to 0.5 depending on the amount of the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 is turned on / off.
Next, the process of the control content shown in (110) of FIG. 6 is performed. Since the ambient temperature of the driving force distribution device 9 is the same value as the outside air temperature, the ambient temperature outside temperature difference of the driving force distribution device 9 is 0 degrees. As shown in FIG. 4, the value of the heat generation amount correction coefficient 3 is 0.2.
Next, the process of the control content shown in (111) of FIG. 6 is performed. Since the heat generation amount correction coefficient 1 is 0, the heat generation amount correction coefficient 2 is 0 to 0.5, and the heat generation amount correction coefficient 3 is 0.2, the heat generation amount is 0.3 of the heat generation amount when the ignition switch is turned off. The amount is about 0.8 times. If the calorific value is large, the calorific value when the ignition switch is off is 0.3 times (0 times in cold regions), and if the calorific value is small, the calorific value when the ignition switch is off 0.8 times (0.3 times in cold districts). With the calorific value calculated in this process as an initial value, the process shifts to four-wheel drive control of the control contents shown in (112) to (116) of FIG. Since the heat generation amount is appropriately calculated according to the heat generation amount when the ignition switch is turned off and the outside air temperature, the four-wheel drive control can be appropriately performed.

A specific example of the operation pattern (3) is a case where the ignition switch is turned off immediately after the ignition switch is turned on in a high temperature state where protection control works. When the ignition switch is turned off, the processing of the control content shown in (103) of FIG. 6 is performed, and the heat generation amount and the ambient temperature of the driving force distribution device 9 are stored in the nonvolatile memory 21.
Immediately after turning off the ignition switch, turn on the ignition switch. At this time, the processing of the control contents shown in (106) to (111) of FIG. 6 is performed only once. First, control content processing shown in (106) of FIG. 6 is performed. Since the ignition switch was immediately turned on, the ambient temperature of the driving force distribution device 9 did not change, and the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 was turned off / on was zero.
Next, control content processing shown in (107) of FIG. 6 is performed. Since the ambient temperature of the driving force distribution device 9 is high, the ambient temperature outside temperature difference of the driving force distribution device 9 takes a large value.
Next, the process of the control content shown in (108) of FIG. 6 is performed. Since the ambient temperature of the driving force distribution device 9 is in a high temperature state, the value of the heat generation amount correction coefficient 1 is 0 as shown in FIG.
Next, the process of the control content shown in (109) of FIG. 6 is performed. Since the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 is turned off / on is 0 degree, the heat generation amount correction coefficient 2 is 0 as shown in FIG.
Next, the process of the control content shown in (110) of FIG. 6 is performed. As shown in FIG. 4, the difference between the ambient temperature and the outside air temperature of the driving force distribution device 9 is a large value, so the value of the heat generation amount correction coefficient 3 is 0.
Next, the process of the control content shown in (111) of FIG. 6 is performed. Since each of the heat generation amount correction coefficient 1, the heat generation amount correction coefficient 2, and the heat generation amount correction coefficient 3 has a value of 0, the heat generation amount is one time the heat generation amount when the ignition switch is turned off. When the ignition switch is turned off / on in a short time while the ambient temperature of the driving force distribution device 9 is high, the amount of generated heat is not reduced. With the calorific value calculated in this process as an initial value, the process shifts to four-wheel drive control of the control contents shown in (112) to (116) of FIG. Since the heat generation amount is appropriately calculated in accordance with the heat generation amount when the ignition switch is turned off and the heat generation amount when the ignition switch is turned on, protection control of the driving force distribution device 9 can be appropriately performed.

A specific example of the operation pattern (4) is a case where the ignition switch is turned off and the ignition switch is turned on immediately in a state where the driving force distribution device 9 is not generating heat, such as not running. When the ignition switch is turned off, the processing of the control content shown in (103) of FIG. 6 is performed, and the heat generation amount and the ambient temperature of the driving force distribution device 9 are stored in the nonvolatile memory 21.
Immediately after turning off the ignition switch, turn on the ignition switch. At this time, the processing of the control contents shown in (106) to (111) of FIG. 6 is performed only once. First, control content processing shown in (106) of FIG. 6 is performed. Since the ignition switch was immediately turned on, there is no change in the ambient temperature of the driving force distribution device 9, and the atmospheric temperature difference of the driving force distribution device 9 is 0 degrees.
Next, control content processing shown in (107) of FIG. 6 is performed. Since the ambient temperature of the driving force distribution device 9 is the same as the outside air temperature, the ambient temperature outside temperature difference of the driving force distribution device 9 is 0 degrees.
Next, the process of the control content shown in (108) of FIG. 6 is performed. Since the ambient temperature of the driving force distribution device 9 is the same as the outside air temperature, the value of the heat generation correction coefficient 1 is 0 as shown in FIG. It takes a value of 0 to 0.5 in cold regions.
Next, the process of the control content shown in (109) of FIG. 6 is performed. Since the atmospheric temperature difference when the ignition switch of the driving force distribution device 9 is turned off / on is 0 degree, the heat generation amount correction coefficient 2 is 0 as shown in FIG.
Next, the process of the control content shown in (110) of FIG. 6 is performed. As shown in FIG. 4, since the ambient temperature / outside air temperature difference of the driving force distribution device 9 is 0 degrees, the value of the heat generation amount correction coefficient 3 is 0.2.
Next, the process of the control content shown in (111) of FIG. 6 is performed. Since the heat generation correction coefficient 1 and the heat generation correction coefficient 2 are both 0 and the heat generation correction coefficient 3 is 0.2, the heat generation amount is 0.8 times the heat generation amount when the ignition switch is turned off (in a cold region) Is 0.3). With the calorific value calculated in this process as an initial value, the process shifts to four-wheel drive control of the control contents shown in (112) to (116) of FIG. Since the heat generation amount is appropriately calculated according to the heat generation amount when the ignition switch is turned off and the outside air temperature, the four-wheel drive control can be appropriately performed.

  In this way, the driving force distribution control device 15 immediately reads the heat generation amount and the ambient temperature of the driving force distribution device 9 stored in the nonvolatile memory 21 when the ignition switch is turned on next time, and the ignition switch is turned on. The difference between the ambient temperature of the driving force distribution device 9 at the time, the atmospheric temperature of the driving force distribution device 9 when the ignition switch is turned off, and the ambient temperature of the driving force distribution device 9 when the ignition switch is turned on, The driving force distribution device 9 is corrected by correcting the amount of heat read from the nonvolatile memory 21 based on the difference between the ambient temperature of the driving force distribution device 9 and the outside air temperature when the ignition switch is turned on. The amount of heat generated is corrected when the ignition switch is turned on and accurately calculated, and when the protection control should be released It can be brought close to become.

  Thereby, the driving force distribution control device 15 can improve the conventional problems 1 to 5. Hereinafter, specific effects will be described with reference to FIGS.

7A and 7B show the difference between the conventional control in the case of Problem 1 and the control of the present plan.
In FIG. 7A, in the conventional control, every time the ignition switch is turned off, the heat generation amount of the driving force distribution device 9 decreases by a set ratio, and a difference from the actual heat generation amount is produced. As a result, in FIG. 7A, the protection control is released at a time (tb) considerably earlier than the time (ta) when the protection control of the driving force distribution device 9 should be released, and the drive system is damaged. Will give.
On the other hand, in FIG. 7B, in the case of the control of the present invention, the ambient temperature of the driving force distribution device 9 decreases with time, so that the heat generation amount correction coefficient 1 is changed every time the ignition switch is repeatedly turned off / on. It will decrease. Further, the ambient temperature / outside air temperature difference of the driving force distribution device 9 also decreases with time. Therefore, the heat generation amount correction coefficient 3 increases every time the ignition switch is repeatedly turned off / on. In general, the amount of heat released is large at high temperatures and decreases as the temperature decreases. Therefore, every time the ignition switch is repeatedly turned off / on, the atmospheric temperature difference of the driving force distribution device 9 decreases, and the heat generation amount correction coefficient 2 decreases.
From the above, the driving force distribution control device 15 according to the present invention reduces the stored heat generation by the proportion corresponding to the situation when the ignition switch is turned on. In FIG. The time (ta) when the protection control of the device 9 should be released can be brought closer to the time (tb) when the protection control is actually released, and damage to the drive system can be reduced.

8A and 8B show the difference between the conventional control in the case of Problem 2 and the control of the present plan.
In FIG. 8A, since the conventional control reduces the heat generation amount by a set ratio when the ignition switch is turned off, the stored heat generation amount becomes larger than the threshold when the heat generation amount is large. When sufficient time has passed in this state and the ambient temperature of the driving force distribution device 9 has sufficiently decreased, the protection control is activated when the ignition switch is turned on. As a result, the protection control is not released until the time (tb) that is considerably later than the time (ta) at which the protection control of the driving force distribution device 9 should be released, and the protection control is actually performed even though the normal control may be performed. The four-wheel drive performance cannot be fully exhibited.
On the other hand, in FIG. 8B, in the case of the control of the present plan, the ignition switch was turned on while the ambient temperature of the driving force distribution device 9 was sufficiently lowered. The difference between the ambient temperature and the outside temperature of the force distribution device 9 is small, and the heat generation amount correction coefficient 1, the heat generation amount correction coefficient 2, and the heat generation amount correction coefficient 3 are all large values. Therefore, the calculated calorific value greatly decreases from the stored calorific value and becomes a value close to the actual calorific value.
From the above, the driving force distribution control device 15 of the present invention can bring the timing (ta) when the protection control of the driving force distribution device 9 should be released closer to the timing (tb) when the protection control is actually released. It is possible to reduce the state of the protection control state in spite of the state in which the normal control may be performed, and the four-wheel drive performance can be sufficiently exhibited.

9A and 9B show the difference between the conventional control in the case of Problem 3 and the control of the present plan.
In FIG. 9 (A), the conventional control reduces the heat generation amount by a set ratio when the ignition switch is turned off. Therefore, if the reduction ratio is set to a large value, the stored heat generation amount exceeds the threshold value. Becomes smaller. When the ignition switch is immediately turned on in this state, the protection control is released although the ambient temperature of the driving force distribution device 9 has not sufficiently decreased. As a result, the protection control is released at a time (tb) that is considerably earlier than the time (ta) at which the protection control of the driving force distribution device 9 is to be released, and the protection control must actually be performed. Since the normal control is performed regardless of the state, the drive system is damaged.
On the other hand, in FIG. 9B, in the case of the control of the present invention, the ignition switch was turned on while the ambient temperature of the driving force distribution device 9 was high. The difference between the ambient temperature and the outside air temperature of the force distribution device 9 is large, and the heat generation amount correction coefficient 1, the heat generation amount correction coefficient 2, and the heat generation amount correction coefficient 3 are all small values. Therefore, the calculated calorific value does not decrease much from the stored calorific value, and becomes a value close to the actual calorific value.
From the above, the driving force distribution control device 15 of the present invention can bring the timing (ta) when the protection control of the driving force distribution device 9 should be released closer to the timing (tb) when the protection control is actually released. This makes it possible to reduce damage to the drive system.

10A and 10B show the difference between the conventional control in the case of Problem 4 and the control of the present plan.
In FIG. 10A, since the conventional control reduces the heat generation amount by a set ratio when the ignition switch is turned off, the stored heat generation amount may be smaller than the actual heat generation amount. In this state, when the ignition switch is turned on and the driving force distribution device 9 travels so as to generate heat, the actual heat generation amount of the driving force distribution device 9 increases to the amount at which protection control should be performed. Regardless, the calculated calorific value has not yet increased to the threshold value at which protection control is performed. As a result, the protection control is not performed until a time (tb) that is considerably later than the time (ta) when the protection control of the driving force distribution device 9 is to be released, and the protection control actually needs to be performed. Regardless of normal control, the drive system will be damaged.
On the other hand, in FIG. 10B, in the case of the control of the present invention, as shown in Problem 1 to Problem 3, the amount of heat generated is calculated according to the state when the ignition switch is off and when the ignition switch is on. Therefore, the value is close to the actual calorific value. Therefore, the driving force distribution control device 15 of the present invention can bring the timing (ta) when the protection control of the driving force distribution device 9 should be released closer to the timing (tb) when the protection control is actually released, Damage to the drive system can be reduced.

11A and 11B show the difference between the conventional control in the case of Problem 5 and the control of the present plan.
In FIG. 11A, since the conventional control reduces the heat generation amount by a set ratio when the ignition switch is turned off, the stored heat generation amount may be larger than the actual heat generation amount. In this state, when the ignition switch is turned on and the driving power distribution device 9 travels so as to generate heat, the actual heat generation amount of the driving force distribution device 9 has not increased to the amount at which protection control should be performed. Regardless, the calculated calorific value is increased to the threshold value at which the protection control is performed. As a result, the protection control is released at a time (tb) that is considerably earlier than the time (ta) at which the protection control of the driving force distribution device 9 should be released. Since the protection control is performed in spite of the good condition, the four-wheel drive performance cannot be fully exhibited.
On the other hand, in FIG. 11B, in the case of the control of the present invention, as shown in Problem 1 to Problem 3, the amount of heat generation is calculated according to the state when the ignition switch is off and when the ignition switch is on. Therefore, the value is close to the actual calorific value. Therefore, the driving force distribution control device 15 of the present invention can bring the timing (ta) when the protection control of the driving force distribution device 9 should be released closer to the timing (tb) when the protection control is actually released, Actually, the state of the protection control state can be reduced in spite of the state in which the normal control is acceptable, and the four-wheel drive performance can be sufficiently exhibited.

In the above-described embodiment, three calorific value correction coefficients are obtained. However, 3 is determined based on the atmospheric temperature of the driving force distribution device 9, the outside air temperature, and the atmospheric temperature difference of the driving force distribution device 9 when the ignition switch is turned on / off. One calorific value correction coefficient may be obtained from the dimension MAP.
Further, the ambient temperature of the driving force distribution device 9 can be used in place of the one having a correlation with the heat generation amount of the driving force distribution device 9 such as the lubricating oil temperature of the rear differential 10.

  The present invention controls the driving force distribution device by estimating the amount of heat generated at the heat generation point, and can be used as long as it can generate heat at the heat generation point regardless of the driving force distribution device. Is possible. For example, the heat generation amount of the motor can be estimated by the amount of current and the energization time, and can be used for heat generation protection control such as electric power steering.

DESCRIPTION OF SYMBOLS 1 Vehicle 2 Engine 3 Transmission 4 Front differential 6R / 6L Right front wheel / left front wheel as main driving wheels 7 Transfer 8 Propeller shaft 9 Driving force distribution device 10 Rear differential 12R / 12L Right rear wheel / left rear as auxiliary driving wheels Wheel 15 Driving force distribution control device 16 Control means 17 CAN communication line 18 Various control devices 19 Heat generation amount calculation means 20 Protection control means 21 Non-volatile memory 22 Heat generation amount storage means 23 Outside air temperature detection means 24 Ambient temperature detection means 25 Atmosphere temperature storage means 25 Means 26 Heat generation amount correction means

Claims (1)

A driving force distribution device that distributes the driving force from the engine to the main driving wheel and the sub driving wheel according to the running state of the vehicle,
A calorific value calculating means for calculating the calorific value of the driving force distribution device;
Protection control means for limiting the torque transmitted to the auxiliary drive wheel by the heat generation amount calculated by the heat generation amount calculation means;
A calorific value storage means for storing the calorific value in a nonvolatile memory capable of electrically rewriting data when the ignition switch is turned off;
The heat generation amount stored in the non-volatile memory by the heat generation amount storage unit is immediately read by the protection control unit when the ignition switch is turned on and compared with a set value. In the case of a large driving force distribution control device for a vehicle that limits the torque transmitted to the auxiliary driving wheels,
An outside air temperature detecting means for detecting the outside air temperature;
Atmospheric temperature detection means for detecting the atmospheric temperature of the driving force distribution device;
Atmospheric temperature storage means for storing the ambient temperature detected by the ambient temperature detection means in a nonvolatile memory capable of electrically rewriting data when the ignition switch is turned off;
A calorific value correction means for reading out and correcting the calorific value stored in the nonvolatile memory by the calorific value storage means when the ignition switch is turned on;
The calorific value stored in the nonvolatile memory by the calorific value storage means and the ambient temperature saved in the nonvolatile memory by the ambient temperature storage means by the calorific value correction means immediately when the ignition switch is turned on next time. Read out,
The ambient temperature detected by the ambient temperature detection means when the ignition switch is turned on; and
The difference between the ambient temperature stored in the non-volatile memory by the ambient temperature storage means when the ignition switch is turned off and the ambient temperature detected by the ambient temperature detection means when the ignition switch is turned on;
Based on the difference between the ambient temperature detected by the ambient temperature detection means when the ignition switch is turned on and the ambient temperature detected by the ambient temperature detection means,
A driving force distribution control device for a vehicle, wherein the heat generation amount read from the nonvolatile memory is corrected.

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