JP6468111B2 - Inertia traveling control method and inertial traveling control device - Google Patents

Description

  The present invention relates to an inertial traveling control method and an inertial traveling control device.

  For example, Patent Document 1 discloses a coasting control execution unit that starts coasting control by disengaging the clutch and lowering the engine speed in an operation state where the engine does not work to the outside, and the vehicle is traveling on a low μ road The low μ road running recognition unit that recognizes that the vehicle is traveling on the low μ road when the low μ road running recognition unit recognizes that the vehicle is running on the low μ road. A coasting control device including a prohibition unit is disclosed.

JP 2012-30711 A

If the coasting control is prohibited by entering the low friction coefficient road while coasting while stopping the fuel supply to the engine of the vehicle and the coasting control is prohibited, the vehicle status changes from the coasting to the normal traveling during the traveling on the low friction coefficient road. Switch to As a result, the behavior of the vehicle changes during traveling on the low friction coefficient road, and the behavior of the vehicle may become unstable.
An object of the present invention is to prevent switching from inertia traveling to normal traveling in a vehicle traveling on a low friction coefficient road.

  In the inertial traveling control method according to one aspect of the present invention, it is determined whether or not it is detected that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient, and it is detected that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient. In such a case, the start of inertial traveling that travels with the fuel supply to the engine of the vehicle stopped is prohibited.

  According to one aspect of the present invention, since the start of inertial travel can be prohibited before entering the low friction coefficient road, switching from inertial travel to normal travel that occurs during travel on the low friction coefficient road can be prevented.

1 is a schematic configuration diagram of a vehicle equipped with an inertial traveling control device according to a first embodiment. 1 is a schematic configuration diagram of a vehicle equipped with an inertial traveling control device according to a first embodiment. It is a function block diagram of the engine stop control apparatus shown in FIG.1 and FIG.2. It is a flowchart explaining an example of a process of the inertial running control apparatus immediately after an ignition switch switches on. (A)-(e) is a time chart explaining the 1st example of a process of the inertial traveling control apparatus immediately after an ignition switch switches on. (A)-(e) is a time chart explaining the 2nd example of a process of the inertial running control apparatus immediately after an ignition switch switches on. It is a flowchart explaining an example of the process of the inertial traveling control apparatus in driving | running | working. It is a flowchart explaining an example of the determination process of inertial travel prohibition conditions. It is a flowchart explaining an example of the 1st inertia running end determination processing. (A)-(i) is a time chart explaining an example of a process of the inertial running control apparatus in driving | running | working. It is a schematic block diagram of the vehicle carrying the inertial traveling control apparatus which concerns on 2nd Embodiment. It is a function block diagram of the engine stop control apparatus shown in FIG. It is a flowchart explaining an example of operation | movement of the inertial traveling control apparatus which concerns on 2nd Embodiment.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
(Constitution)
The inertial traveling control device according to the first embodiment will be described below. Please refer to FIG. 1 and FIG. A torque converter 3 is provided on the output side of the engine 2 that is an internal combustion engine of the vehicle 1. A belt type continuously variable transmission 4 is connected to the output side of the torque converter 3. The rotational driving force output from the engine 2 is input to the continuously variable transmission 4 via the torque converter 3, and after being shifted by a desired gear ratio, the front wheels 6 a and 6 b that are driving wheels via the differential gear 5. Is transmitted to. The engine 2 includes a motor 7 that starts the engine and an alternator 8 that generates power.

The motor 7 may be, for example, a starter motor for starting the engine, or may be an SSG (Separated starter generator) motor provided separately from the starter motor. The motor 7 drives the motor 7 using the power supplied from the battery 9 based on the engine start command, and performs engine cranking. Further, when the fuel is injected and then the engine 2 can rotate independently, the starter motor is stopped. The alternator 8 generates power by being rotationally driven by the engine 2 and supplies the generated power to the battery 9 and the like.
The torque converter 3 performs torque amplification at a low vehicle speed. The torque converter 3 has a lock-up clutch 10. When the vehicle speed is equal to or higher than the predetermined speed V <b> 1, the torque converter 3 engages the lockup clutch 10 to restrict relative rotation between the output shaft of the engine 2 and the input shaft of the continuously variable transmission 4. The predetermined speed V1 may be about 14 km / h, for example.

The continuously variable transmission 4 includes a forward / reverse switching mechanism 11, a primary pulley 12 and a secondary pulley 13, and a belt 14 that is stretched over the primary pulley 12 and the secondary pulley 13. A desired gear ratio is achieved by changing the groove widths of the primary pulley 12 and the secondary pulley 13 by hydraulic control.
The forward / reverse switching mechanism 11 includes a forward clutch 16 and a reverse brake 17. The forward clutch 16 and the reverse brake 17 are friction engagement elements for transmitting the rotation transmitted from the secondary pulley 13 in the forward direction (forward direction) and the reverse direction (reverse direction), respectively.
An oil pump 15 driven by the engine 2 is provided in the continuously variable transmission 4. When the engine is operating, the converter pressure of the torque converter 3 and the clutch pressure of the lockup clutch 10 are supplied using the oil pump 15 as a hydraulic pressure source.

  Further, the oil pump 15 is used as a hydraulic pressure source to supply the pulley pressure of the continuously variable transmission 4 and the clutch engagement pressure of the forward clutch 16 and the reverse brake 17. Further, the continuously variable transmission 4 is provided with an electric oil pump 18 separately from the oil pump 15, and when the oil pressure cannot be supplied by the oil pump 15 due to the automatic engine stop, the electric oil pump 18 operates. Necessary hydraulic pressure can be supplied to each actuator. Therefore, even when the engine is stopped, the hydraulic oil leakage can be compensated and the clutch engagement pressure can be maintained.

The operating state of the engine 2 is controlled by the engine control unit 20. The engine control unit 20 receives an accelerator pedal operation amount signal from an accelerator pedal opening sensor 24 that detects an operation amount of the accelerator pedal 23 by the driver. The accelerator pedal 23 is an example of an operator that is operated by the driver to instruct the driving force of the vehicle 1.
In addition, the engine control unit 20 receives a brake signal from a brake switch 22 that outputs an ON signal when the driver operates the brake pedal 21. The brake pedal 21 is an example of an operator that is operated by the driver to instruct the braking force of the vehicle 1.

  A master cylinder 25 and a master back 27 are provided at the tip of the brake pedal 21. The master back 27 amplifies the brake operation force using the intake negative pressure of the engine 2. The engine control unit 20 receives a brake pedal operation amount signal from a master cylinder pressure sensor 26 that detects the master cylinder pressure of the master cylinder 25 that is generated based on the operation amount of the brake pedal 21. The engine control unit 20 receives a negative pressure signal from a negative pressure sensor 28 that detects the negative pressure in the master back 27.

Further, the engine control unit 20 receives wheel speed signals indicating wheel speeds detected by wheel speed sensors 29a to 29d provided on the front wheels 6a and 6b and the rear wheels 6c and 6d, respectively. In the following description, the front wheels 6a and 6b and the rear wheels 6c and 6d may be collectively referred to as “wheel 6”. The wheel speed sensors 29a to 29d may be collectively referred to as “wheel speed sensor 29”.
Further, the engine control unit 20 receives a transmission state signal from a transmission control unit 30 (to be described later) and signals such as engine water temperature, crank angle, and engine speed. The engine control unit 20 starts or automatically stops the engine 2 based on the various signals.

In place of the master cylinder pressure sensor 26, a brake pedal operation amount is detected by using a sensor for detecting a brake pedal stroke amount and a brake pedal depression force, a sensor for detecting a wheel cylinder pressure, and the like, and is input to the engine control unit 20. May be.
The transmission control unit 30 receives an engine state signal indicating the engine operating state from the engine control unit 20, and transmits a transmission state signal indicating the state of the continuously variable transmission 4 to the engine control unit 20. The transmission control unit 30 controls the gear ratio of the continuously variable transmission 4 based on these signals.

For example, when the D range is selected, the transmission control unit 30 engages the forward clutch 16 and determines the gear ratio from the gear ratio map based on the accelerator pedal opening and the vehicle speed, Control the pressure.
When the vehicle speed is less than the predetermined speed V1, the lockup clutch 10 is released, but when the vehicle speed is equal to or higher than the predetermined speed V1, the lockup clutch is engaged so that the engine 2 and the continuously variable transmission 4 are directly connected. Yes.

  Please refer to FIG. The vehicle 1 is provided with a navigation device 40 and a sensor 41 for detecting whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient. The navigation device 40 is an information processing device that outputs travel route information for navigation cooperative control to the engine control unit 20. In the navigation cooperative control, the engine control unit 20 controls the vehicle speed of the vehicle according to the forward curve and the magnitude of the gradient based on the travel route information. In the navigation cooperative control, the navigation device 40 detects whether or not the road friction coefficient is equal to or less than a predetermined friction coefficient. For example, the navigation apparatus 40 may receive the weather information regarding the current weather state of the position of the vehicle 1 or the travel route scheduled to travel using the communication device 42. The navigation device 40 receives the weather information that informs the weather condition that causes the current or planned traveling road to be a low friction coefficient road having a predetermined friction coefficient or less, so that the road surface friction coefficient is less than the predetermined friction coefficient. Whether or not is detected indirectly. The communication device 42 may receive weather information by road-to-vehicle communication, vehicle-to-vehicle communication, or satellite communication, for example. The navigation device 40 inputs road surface information indicating whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient to the engine control unit 20. For example, the navigation device 40 inputs the received weather information to the engine control unit 20 as road surface information.

The sensor 41 detects whether the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient. For example, the sensor 41 may detect the weather condition of the current or planned traveling path of the vehicle 1. The sensor 41 indirectly detects whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient by detecting a weather condition that causes the current or planned traveling road to be a low friction coefficient road. For example, the sensor 41 may be an outside air temperature sensor that detects a low air temperature causing road surface freezing, a rain sensor that detects rain that reduces road surface friction, or a snowfall sensor that detects snowfall. There may be. The sensor 41 inputs road surface information indicating whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient to the engine control unit 20. For example, the sensor 41 inputs detected weather condition information to the engine control unit 20 as road surface information.
Further, the vehicle 1 includes a vehicle body control unit 43, an ignition switch 45 provided near the steering wheel 44, and a wiper switch 47 that switches the operation of the wiper 46.

When the vehicle body control unit 43 detects an engine start request by operating the ignition switch 45, the vehicle body control unit 43 outputs a start request signal for the engine 2 to the engine control unit 20. The vehicle body control unit 43 detects the operation of the wiper switch 47 and drives the wiper 46 in accordance with the detected operation.
In order to indirectly detect whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient, the wiper switch 47 may be used. When the wiper switch 47 is on, it may be detected that the current or planned traveling path is a low friction coefficient path due to rain or snow. The vehicle body control unit 43 inputs road surface information indicating whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient to the engine control unit 20. For example, the vehicle body control unit 43 outputs a wiper signal indicating the operating state of the wiper 46 to the engine control unit 20 as road surface information.
The engine control unit 20, the transmission control unit 30, the navigation device 40, and the vehicle body control unit 43 may be, for example, a computer including a CPU (Central Processing Unit) and CPU peripheral components such as a storage device. Each function of these computers described in this specification is implemented by each CPU executing a computer program stored in a storage device.

(Automatic engine stop processing)
Next, the automatic stop process of the engine 2 will be described. The automatic stop process is a process in which the engine control unit 20 automatically stops and restarts the engine 2 when a predetermined condition is satisfied. For this reason, the engine control unit 20, the transmission control unit 30, the navigation device 40, and the sensor 41 constitute an engine stop control device 31 that performs an automatic stop process of the engine 2.

Please refer to FIG. The engine stop control device 31 includes an inertia traveling control device 50 and an idle stop control device 51. The idle stop control device 51 performs so-called idle stop (also referred to as idle reduction) control that stops engine idling when a predetermined condition is satisfied when the vehicle 1 is stopped. Detailed description of the idle stop control is omitted.
The inertial traveling control device 50 stops the fuel supply to the engine 2 when the predetermined first inertial traveling condition is satisfied even if the vehicle speed is equal to or higher than the speed V2 higher than the predetermined speed V1. The front wheels 6a and 6b, which are drive wheels, are separated from each other, and the vehicle 1 is caused to travel in this state. In the present specification, traveling in a state where the vehicle speed is equal to or higher than the speed V2, fuel supply to the engine 2 is stopped, and the engine 2 and the driving wheel are separated is referred to as “first inertia traveling”. Further, the traveling in a state where the forward clutch 16 is engaged, that is, the engine 2 and the driving wheel are connected and fuel is supplied to the engine 2 may be referred to as “normal traveling”.

  The inertial travel control device 50 includes an inertial travel control unit 52. The inertia traveling control unit 52 includes a wheel speed signal from the wheel speed sensor 29, an accelerator pedal operation amount signal from the accelerator pedal opening sensor 24, a brake pedal operation amount signal from the master cylinder pressure sensor 26, and a negative pressure sensor 28. A negative pressure signal and a charge state signal of the battery 9 are received. The inertial traveling control unit 52 determines whether or not the first inertial traveling condition is satisfied based on the wheel speed signal, the accelerator pedal operation amount signal, and the charge state signal.

For example, the first inertia running condition is satisfied when all of the following two conditions are satisfied.
(1) The vehicle speed is not less than speed V2 and not more than speed V3. For example, the speed V2 may be about 30 km / h, and the speed V3 may be about 80 km / h.
(2) A predetermined time or more has elapsed since the accelerator operation amount became zero. For example, the predetermined time may be 2 seconds.
The inertial traveling control unit 52 permits the first inertial traveling and outputs an engine stop command to the engine 2 when the first inertial traveling condition is satisfied and the predetermined idle stop permission condition is satisfied. The idle stop permission condition may be, for example, that the engine is not warming up and the charging rate of the battery 9 is equal to or higher than a predetermined value.
The engine 2 that has received the engine stop command stops the fuel injection and stops the fuel supply to the engine 2. In addition, inertial traveling control unit 52 outputs an operation prohibition command for electric oil pump 18 to continuously variable transmission 4. Since the oil pump 15 is stopped by the stop of the engine 2 and the electric oil pump 18 is not operated, the forward clutch 16 of the forward / reverse switching mechanism 11 is released. Thereby, the engine 2 and the front wheels 6a and 6b are separated.

During the first inertia traveling, the inertia traveling control unit 52 determines whether or not a predetermined first end condition is satisfied based on the wheel speed signal, the accelerator pedal operation amount signal, and the charge state signal. When the first termination condition is satisfied, the inertial traveling control unit 52 prohibits the first inertial traveling and ends the first inertial traveling. For example, the first end condition is satisfied when any of the following three conditions is satisfied.
(1) The vehicle speed is less than the speed V2.
(2) The accelerator is stepped on.
(3) The idle stop permission condition is not satisfied.
When the first termination condition is satisfied, inertial traveling control unit 52 outputs a restart command to engine 2. The engine 2 that has received the restart command restarts fuel injection, drives the motor 7, and performs engine cranking. When the engine 2 starts rotating, the forward clutch 16 of the forward / reverse switching mechanism 11 is engaged.

  Further, when the vehicle 1 is decelerating and it is determined through the deceleration fuel cut control that the vehicle 1 is likely to stop and shift to the idling stop control, the fuel supply to the engine 2 is stopped. At this time, the vehicle 1 is coasting without the driver operating the accelerator pedal 23. When it is determined that there is a high possibility of shifting to the idling stop control, the traveling in a state where the fuel supply to the engine 2 is stopped is referred to as “second inertia traveling”. The second inertia traveling is sometimes referred to as coast stop traveling, and the control for stopping the fuel supply to the engine 2 during the coast stop traveling is sometimes referred to as coast stop control.

  During the deceleration fuel cut control, the fuel injection is stopped, but the engine speed is maintained via the lock-up clutch by the coast torque transmitted from the front wheels 6a and 6b as drive wheels. However, since the lock-up clutch 10 is released when the speed is reduced to the predetermined speed V1, the engine 2 stops unless fuel is injected. Therefore, conventionally, deceleration fuel cut control is stopped at the timing when the lockup clutch 10 is released, fuel injection is restarted, and engine self-sustaining rotation is maintained. After that, after the vehicle 1 has completely stopped, the engine idling is stopped. However, fuel consumption can be improved if the fuel at the time of restarting fuel injection can be further suppressed in the process of restarting fuel injection once and restarting the engine from the running state where fuel injection is stopped in this way. It becomes. Therefore, when the predetermined second inertia running condition is established, the engine 2 is kept stopped without restarting the fuel injection, and after the vehicle 1 is stopped, the routine directly shifts to the normal idling stop control.

The inertia traveling control unit 52 determines whether or not the second inertia traveling condition is satisfied based on the accelerator pedal operation amount signal, the brake pedal operation amount signal, and the charge state signal. For example, the second inertia running condition is satisfied when all of the following two conditions are satisfied.
(1) The brake pedal operation amount is a predetermined value or more.
(2) The accelerator pedal operation amount is zero.
When the second inertia traveling condition is satisfied and the idle stop permission condition is satisfied, inertial traveling control unit 52 outputs an engine stop command to engine 2. When the engine 2 is automatically stopped, the continuously variable transmission 4 operates the electric oil pump 18 and maintains the forward clutch 16 of the forward / reverse switching mechanism 11 engaged. Thereby, the connection between the engine 2 and the front wheels 6a and 6b is maintained. Since the second inertia traveling starts after the deceleration fuel cut control, the vehicle speed during the second inertia traveling is slower than the predetermined speed V1.

During the second inertia traveling, the inertia traveling control unit 52 determines whether or not a predetermined second end condition is satisfied based on the negative pressure signal and the charge state signal. When the second end condition is satisfied, the inertial traveling control unit 52 prohibits the second inertial traveling and ends the second inertial traveling.
End. For example, the second end condition is satisfied when either of the following two conditions is satisfied.
(1) The negative pressure in the master back 27 is less than a predetermined value.
(2) The idle stop permission condition is not satisfied.
When the second end condition is satisfied, inertial traveling control unit 52 outputs a restart command to engine 2.
As described above, the inertial traveling control device 50 can improve the fuel efficiency of the vehicle 1 by increasing the engine stop chance by the first inertial traveling and the second inertial traveling.

(Inertia prohibition process)
However, coasting on a low friction coefficient road is not preferable. For example, when the first end condition is satisfied during the first inertia traveling on the low friction coefficient road, the released forward clutch 16 is re-engaged. If the forward clutch 16 is re-engaged while traveling on a low friction coefficient road, tire locking and slipping are likely to occur and the vehicle behavior may become unstable. Further, for example, if the second end condition is satisfied during the second inertia traveling on the low friction coefficient road, and driving of the driving wheels by the engine 2 is resumed, tire slip is likely to occur and the vehicle behavior may become unstable. .
Therefore, the inertial traveling control device 50 detects that the traveling path is a low friction coefficient road before the vehicle 1 enters the low friction coefficient road, and prohibits the start of the first inertial traveling and the second inertial traveling.

The inertia travel control device 50 includes a road surface state detection unit 53, an inertia travel prohibition unit 54, and an inertia travel maintenance unit 55. The road surface state detection unit 53 detects whether or not the friction coefficient of the road surface of the current or planned traveling road of the vehicle 1 is equal to or less than a predetermined friction coefficient. For example, the road surface state detection unit 53 detects whether or not the current weather state is a weather state that causes the current or planned traveling road of the vehicle 1 to be a low friction coefficient road, thereby detecting the road surface friction. It may be indirectly detected whether the coefficient is equal to or less than a predetermined friction coefficient. That is, the road surface state detection unit 53 may function as a weather state detection unit that detects the weather state of the current or planned traveling road of the vehicle 1.
Further, the road surface state detection unit 53 may indirectly detect whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient by detecting whether or not the wiper switch 47 is on. The function of the road surface state detection unit 53 may be implemented by any one of the sensor 41, the navigation device 40, and the wiper switch 47, for example.
Further, the road surface state detection unit 53 causes the current weather state to cause the current or planned traveling road of the vehicle 1 to be a low friction coefficient road depending on whether or not the wiper switch 47 is on. It may be detected whether or not.

  The inertia travel prohibition unit 54 determines whether or not a predetermined inertia travel prohibition condition is satisfied based on the determination result of the road surface state detection unit 53. For example, the inertial travel prohibition unit 54 determines that the inertial travel prohibition condition is satisfied when the road surface state detection unit 53 determines that the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient. For example, the inertial travel prohibition unit 54 determines that the inertial travel prohibition condition is satisfied when the road surface state detection unit 53 detects a weather condition that causes the travel path of the vehicle 1 to be a low friction coefficient road. The weather condition that causes the low friction coefficient road may be, for example, a low temperature that causes road surface freezing. For example, the weather condition that causes the low friction coefficient road may be an outside air temperature that is equal to or lower than a predetermined temperature Tt. For example, the weather condition that causes the low friction coefficient road may be rain or snow that reduces road friction. For example, the inertial travel prohibition unit 54 may determine that the inertial travel prohibition condition is satisfied when the wiper switch 47 is on.

When the inertia travel prohibition condition is satisfied, the inertia travel prohibition unit 54 prohibits the start of the first inertia travel and the second inertia travel. When prohibiting the start of the first inertia traveling and the second inertia traveling, the inertia traveling prohibiting unit 54 outputs, for example, an inertia traveling prohibiting signal to the inertia traveling control unit 52. When permitting the start of the first inertia traveling and the second inertia traveling, for example, the output of the inertia traveling prohibition signal is stopped.
When the inertial travel control unit 52 receives the inertial travel prohibition signal, the inertial travel control unit 52 does not start the first inertial travel even if the first inertial travel condition is satisfied. In addition, when the inertial travel control signal is received, the inertial travel control unit 52 does not start the second inertial travel even if the second inertial travel condition is satisfied. When reception of the inertial travel prohibition signal is stopped and the first inertial travel condition is satisfied, inertial travel control unit 52 starts the first inertial travel. When reception of the inertial travel prohibition signal stops and the second inertial travel condition is satisfied, inertial travel control unit 52 starts the second inertial travel.

The inertia traveling maintenance unit 55 determines whether or not the traveling road where the vehicle 1 is currently located is a low friction coefficient road. That is, the inertia traveling maintenance unit 55 determines whether or not the vehicle 1 is traveling on a low friction coefficient road.
For example, the inertia traveling maintenance unit 55 receives the wheel speed signals of the plurality of wheels 6 from the wheel speed sensor 29. The inertia traveling maintenance unit 55 may determine that the traveling path is a low friction coefficient path based on the wheel speed difference between the plurality of wheels 6. For example, the inertia traveling maintenance unit 55 may determine that the traveling path is a low friction coefficient path when the wheel speed difference between the plurality of wheels 6 exceeds a predetermined speed difference Tw. In addition, the inertia traveling maintenance unit 55 may determine that the traveling road is a low friction coefficient road based on road surface information received from any of the navigation device 40, the sensor 41, and the vehicle body control unit 43, for example.

When the inertial traveling maintenance unit 55 detects that the traveling path is a low friction coefficient road during the first inertia traveling, that is, when it is determined that the vehicle has entered the low friction coefficient road during the first inertia traveling, the vehicle 1 The first inertia traveling is permitted until it is determined that the current traveling road is not a low friction coefficient road. When permitting the first inertia traveling, the inertia traveling maintaining unit 55 outputs an inertia traveling maintaining signal to the inertia traveling control unit 52 to continue the first inertia traveling.
When the inertial traveling control unit 52 receives the inertial traveling maintenance signal, the inertial traveling control unit 52 does not terminate the first inertial traveling even if the first termination condition is satisfied. When reception of the inertial running maintenance signal is stopped and the first termination condition is satisfied, the inertial traveling control unit 52 ends the first inertial traveling. In this way, the inertial running maintenance unit 55 continues the first inertial traveling until the vehicle 1 in the first inertial traveling enters the low friction coefficient road until it advances from the low friction coefficient road.

In addition, when the inertial traveling maintenance unit 55 detects that the traveling path is a low friction coefficient road during the second inertial traveling, that is, when it is determined that the vehicle has entered the low friction coefficient path during the second inertial traveling, The second inertia traveling is permitted until it is determined that the traveling road where 1 is currently located is not a low friction coefficient road. When permitting the second inertia traveling, the inertia traveling maintaining unit 55 outputs an inertia traveling maintaining signal to the inertia traveling control unit 52 to continue the second inertia traveling.
When the inertial running control unit 52 receives the inertial running maintenance signal, the inertial running control unit 52 does not end the second inertial running even if the second end condition is satisfied. When reception of the inertial traveling maintenance signal is stopped and the second end condition is satisfied, the inertial traveling control unit 52 ends the second inertial traveling. In this manner, the inertial running maintenance unit 55 continues the second inertial traveling until the vehicle 1 in the second inertial traveling enters the low friction coefficient road until the vehicle 1 advances from the low friction coefficient road.

For example, the inertia running maintenance unit 55 detects the occurrence of slip when the wheel speed difference between the plurality of wheels 6 exceeds a predetermined speed difference Tw. When the occurrence of slip is detected, inertial running maintenance unit 55 sets a value “1” indicating that slip is occurring in slip occurrence flag Fs.
In addition, the inertia traveling maintenance unit 55 detects the end of slip when the wheel speed difference between the plurality of wheels 6 is equal to or less than a predetermined speed difference Tw. When the end of slip is detected, inertial running maintenance unit 55 sets a value “0” indicating that slip is not occurring in slip occurrence flag Fs. The inertia traveling maintenance unit 55 outputs an inertia traveling maintenance signal when the value of the slip occurrence flag Fs is “1”. The inertia running maintenance unit 55 stops outputting the inertia running maintenance signal when the value of the slip occurrence flag Fs is “0”.

As described above, the inertial travel prohibition unit 54 starts the first inertial travel and the second inertial travel depending on whether the road surface state detection unit 53 detects that the road surface friction coefficient is equal to or less than the predetermined friction coefficient. The first inertia traveling and the second inertia traveling are prohibited before. Therefore, the start of the first inertia traveling and the second inertia traveling before entering the low friction coefficient road can be prevented. As a result, it is possible to prevent the vehicle behavior from becoming unstable due to the end of the first inertia traveling or the second inertia traveling during traveling on the low friction coefficient road. For example, the inertial travel prohibition unit 54 may prohibit the start of the first inertial travel and the second inertial travel based on the detection result of the road surface state detection unit 53 immediately after the ignition switch 45 is turned on. Immediately after the ignition switch 45 is turned on, by prohibiting the start of the first inertia travel and the second inertia travel, the first inertia travel and the second inertia travel before the start of the first inertia travel and the second inertia travel. Can be banned. For example, the inertial traveling prohibition unit 54 may prohibit the start of the first inertial traveling and the second inertial traveling based on the detection result of the road surface state detection unit 53 during traveling.
Further, the inertial running maintenance unit 55 performs the first inertial traveling or the second inertial traveling until the vehicle 1 in the first inertial traveling or the second inertial traveling enters the low friction coefficient road until the vehicle 1 enters the low friction coefficient road. To continue. As a result, it is possible to prevent the vehicle behavior from becoming unstable due to the end of the first inertia traveling or the second inertia traveling during traveling on the low friction coefficient road.

(Operation)
Next, an example of processing of the inertial traveling control device 50 immediately after the ignition switch 45 is turned on will be described. Please refer to FIG. In the example of processing described below in the present specification, whether the road surface condition detection unit 53 is a weather condition that causes the current weather condition to cause the current or planned traveling path of the vehicle 1 to be a low friction coefficient road. A case will be described in which it is indirectly detected whether or not the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient.
When the ignition switch 45 is turned on in step S10, the sensor 41 reads the outside air temperature in step S11. In step S12, the navigation device 40 starts navigation cooperative control and receives current weather information.
In step S13, the engine control unit 20 starts the engine 2. In step S14, the inertia traveling prohibition unit 54 determines whether or not the outside air temperature detected by the sensor 41 is equal to or lower than a predetermined temperature Tt. If the outside air temperature is equal to or lower than the predetermined temperature Tt (step S14: Y), the process proceeds to step S16. If the outside air temperature is not equal to or lower than the predetermined temperature Tt (step S14: N), the process proceeds to step S15.

In step S15, the inertial travel prohibition unit 54 determines whether or not the weather information received by the navigation device 40 is weather information notifying bad weather such as rainfall or snowfall. If the weather information notifies bad weather (step S15: Y), the process proceeds to step S16. If the weather information does not indicate bad weather (step S15: N), the coasting prohibition unit 54 ends the process without outputting the coasting prohibition signal. As a result, the first inertia traveling and the second inertia traveling are permitted.
In step S16, the inertial travel prohibition signal is output to the inertial travel control unit 52 to prohibit the first inertial travel and the second inertial travel. Thereafter, the process ends.

With reference to FIG. 5A to FIG. 5E, a first example of the process of the inertial traveling control apparatus 50 immediately after the ignition switch 45 is turned on will be described. As shown in FIG. 5A, the sensor 41 reads the outside air temperature immediately after the ignition switch 45 is turned on at time t1.
As shown in FIG. 5C, the outside air temperature is equal to or lower than a predetermined temperature Tt. For this reason, as shown in (d) of Drawing 5, coasting prohibition part 54 judges that outside temperature is low temperature at time t2.

  Thereafter, when the engine control unit 20 starts the engine 2, as shown in FIG. 5B, the rotational speed of the engine 2 increases at time t3. The inertia travel prohibition unit 54 determines that the inertia travel prohibition condition is satisfied at time t4 because the outside air temperature is low, and prohibits the first inertia travel and the second inertia travel. For this reason, the fuel supply to the engine 2 does not stop, and the rotation speed of the engine 2 is maintained.

  Next, a first example of processing of the inertial traveling control device 50 immediately after the ignition switch 45 is turned on will be described with reference to FIGS. 6A to 6E. As shown in FIG. 6A, the ignition switch 45 is turned on at time t1. At time t2 immediately after that, the navigation device 40 starts navigation cooperative control as shown in FIG. 6C, and receives weather information. Then, as shown in FIG. 6D, at time t3, the inertial travel prohibition unit 54 determines that the current position of the vehicle 1 or the weather condition of the travel route planned to travel is bad weather based on the received weather information. .

  Thereafter, as shown in FIG. 6B, the engine 2 is started at time t4, whereby the rotational speed of the engine 2 increases. The inertial travel prohibition unit 54 determines that the inertial travel prohibition condition is satisfied at time t5 because the weather condition of the current position of the vehicle 1 or the travel route planned to travel is bad weather, and prohibits the first inertial travel and the second inertial travel. To do. For this reason, the fuel supply to the engine 2 does not stop, and the rotation speed of the engine 2 is maintained.

Next, an example of processing of the inertial traveling control device 50 while the vehicle 1 is traveling will be described. Please refer to FIG. In step S20, the inertia traveling prohibition unit 54 determines whether or not the inertia traveling prohibition condition is satisfied.
With reference to FIG. 8, an example of the determination process of the inertia running prohibition condition will be described. In step S40, the inertia traveling prohibition unit 54 determines whether or not the outside air temperature detected by the sensor 41 is equal to or lower than the predetermined temperature Tt. If the outside air temperature is equal to or lower than the predetermined temperature Tt (step S40: Y), the process proceeds to step S43. If the outside air temperature is not equal to or lower than the predetermined temperature Tt (step S40: N), the process proceeds to step S41.

In step S41, the inertial travel prohibition unit 54 determines whether or not the weather information received by the navigation device 40 is weather information notifying bad weather. If the weather information notifies bad weather (step S41: Y), the process proceeds to step S43. If the weather information does not indicate bad weather (step S41: N), the process proceeds to step S42.
In step S42, the inertia traveling prohibition unit 54 determines whether or not the wiper 46 is operating. If the wiper 46 is operating (step S42: Y), the process proceeds to step S43. If the wiper 46 is not activated (step S42: N), the process proceeds to step S44.

In step S43, the inertial travel prohibition unit 54 determines that the inertial travel prohibition condition is satisfied. Thereafter, the processing returns to the flowchart shown in FIG. In step S44, it is determined that the inertia traveling prohibition condition is not satisfied. Thereafter, the processing returns to the flowchart shown in FIG.
Referring to FIG. 7, when the inertia traveling prohibition condition is satisfied (step S20: Y), the process returns to step S20. If the inertia travel prohibition condition is not satisfied (step S20: N), the process proceeds to step S21.
In step S21, inertial traveling control unit 52 determines whether an idle stop permission condition is satisfied. If the idle stop permission condition is satisfied (step S21: Y), the process proceeds to step S22. If the idle stop permission condition is not satisfied (step S21: N), the process returns to step S20.

In step S22, the inertial traveling control unit 52 determines whether or not the first inertial traveling condition is satisfied. If the first inertia running condition is satisfied (step S22: Y), the process proceeds to step S23. If the first inertia running condition is not satisfied (step S22: N), the process proceeds to step S27. In step S <b> 23, the inertia traveling control unit 52 outputs an engine stop command to the engine 2. As a result, the fuel supply to the engine 2 is stopped and the first inertia traveling is started.
In step S24, the inertial traveling control unit 52 and the inertial traveling maintaining unit 55 perform a first inertial traveling end determination process for determining whether or not to end the first inertial traveling.

An example of the first inertial traveling end determination process will be described with reference to FIG. In step S50, the inertia traveling maintenance unit 55 determines whether or not the value of the slip generation flag Fs is “1”, that is, whether or not slip is occurring. If the value of the slip occurrence flag Fs is not “1” (step S50: N), the process proceeds to step S51. If the value of the slip occurrence flag Fs is “1” (step S50: Y), the process proceeds to step S54.
In step S51, the inertia traveling maintenance unit 55 determines whether or not the wheel speed difference between the plurality of wheels 6 exceeds a predetermined speed difference Tw, that is, whether or not a slip has occurred.

If a slip has occurred (step S51: Y), the process proceeds to step S52. If no slip has occurred (step S51: N), the process proceeds to step S56. In this case, the value of the slip generation flag Fs is “0”, which indicates that the slip is not being generated, so the output of the inertia traveling maintenance signal is stopped.
In step S52, the inertia traveling maintenance unit 55 sets the value of the slip occurrence flag Fs to “1”. Thereby, the inertia running maintenance part 55 outputs an inertia running maintenance signal. For this reason, the inertial traveling control unit 52 determines in step S53 that the first inertial traveling is not terminated.

In step S54, the inertia traveling maintenance unit 55 determines whether or not the wheel speed difference between the plurality of wheels 6 is equal to or less than a predetermined speed difference Tw, that is, whether or not the slip has ended. If the slip has ended (step S54: Y), the process proceeds to step S55. If the slip has not ended (step S54: N), the process proceeds to step S53. In this case, the value of the slip occurrence flag Fs is “1”, and the inertia running maintenance unit 55 outputs an inertia running maintenance signal.
In step S55, the inertia traveling maintenance unit 55 sets the value of the slip occurrence flag Fs to “0”. For this reason, the output of the inertia running maintenance signal is stopped.
In step S56, the inertial traveling control unit 52 determines whether or not the first end condition is satisfied. If the first end condition is satisfied (step S56: Y), the process proceeds to step S57. When the first termination condition is not satisfied (step S56: N), the process proceeds to step S53, and the inertial traveling control unit 52 determines that the first inertial traveling is not terminated.
In step S57, the inertial traveling control unit 52 determines to end the first inertial traveling.

Please refer to FIG. If it is determined that the first inertia traveling is to be ended (step S25: Y), the process proceeds to step S26. If it is determined that the first inertial running is not finished (step S25: N), the process returns to step S24.
In step S <b> 26, the inertia traveling control unit 52 restarts the engine 2 by outputting a restart command to the engine 2. As a result, the first inertia traveling is finished. Thereafter, the process ends.
In step S27, the inertial traveling control unit 52 determines whether or not the second inertial traveling condition is satisfied. If the second inertia running condition is satisfied (step S27: Y), the process proceeds to step S28. If the second inertia running condition is not satisfied (step S27: N), the process returns to step S20. In step S <b> 28, inertial traveling control unit 52 outputs an engine stop command to engine 2. As a result, the fuel supply to the engine 2 is stopped and the second inertia traveling is started.

In step S29, the inertial traveling control unit 52 determines whether or not the brake pedal 21 is depressed by the driver. When the brake pedal 21 is depressed (step S29: Y), the process ends without ending the second inertia traveling. If the brake pedal 21 is not depressed (step S29: N), the process proceeds to step S30.
In step S30, the inertial travel control unit 52 and the inertial travel maintenance unit 55 perform a second inertial travel end determination process for determining whether or not to end the second inertial travel. The second inertial travel end determination process is the same as the first inertial travel end determination process shown in FIG. 9 except that it is determined in step S56 in FIG. 9 that the second end condition is satisfied instead of the first end condition. .

Please refer to FIG. If it is determined that the second inertia traveling is to be ended (step S31: Y), the process proceeds to step S26. When it is determined that the first inertia traveling is not finished (step S31: N), the process returns to step S29.
In step S <b> 26, the inertia traveling control unit 52 restarts the engine 2 by outputting a restart command to the engine 2. As a result, the second inertia traveling is finished. Thereafter, the process ends.

Next, an example of processing of the inertial traveling control device during traveling will be described with reference to FIGS. 10 (a) to 10 (i).
As shown in FIGS. 10A and 10B, the vehicle speed is equal to or higher than the speed V2 at time t1, and the accelerator operation amount is zero. Further, as shown in FIG. 10 (d), the idle stop permission condition is satisfied. Therefore, the first inertia traveling condition is satisfied at time t2 when a predetermined time has elapsed from time t1, and inertial traveling is permitted as shown in FIG. As a result, the first inertia traveling starts as shown in FIG. 10 (f), the engine speed decreases as shown in FIG. 10 (g), and then the engine 2 stops.

When the wheel speed difference between the plurality of wheels 6 exceeds the speed difference Tw at time t3 as shown in (h) of FIG. 10, the inertia traveling maintenance unit 55 at time t4 as shown in (i) of FIG. 10. Determines that the road is a low friction coefficient road. If it is determined that the travel road is a low friction coefficient road, the inertia travel maintenance unit 55 outputs an inertia travel maintenance signal to the inertia travel control unit 52.
As a result, as shown in FIG. 10A, after the vehicle speed becomes less than V2 at time t5 and the first end condition is satisfied, the state where the inertial running is permitted as shown in FIG. continue. As a result, the first inertia running continues as shown in FIG.

Thereafter, when the wheel speed difference between the plurality of wheels 6 becomes equal to or smaller than the speed difference Tw at time t6 as shown in FIG. 10 (h), the inertial running maintenance unit 55 at time t7 as shown in FIG. 10 (i). Determines that the traveling road is not a low friction coefficient road. As a result, the inertia running maintenance unit 55 stops outputting the inertia running maintenance signal.
At this time, the vehicle speed is less than V2 as shown in FIG. 10 (a) and the first termination condition is satisfied, so that the first inertia traveling is prohibited at time t8 as shown in FIG. 10 (e). Is done. As a result, the running state of the vehicle 1 returns from the inertia running to the normal running as shown in FIG. For this reason, the engine 2 starts and the rotation speed of the engine 2 increases. Further, since the forward clutch 16 is connected and the driving force of the engine 2 is transmitted to the front wheels 6a and 6b, the vehicle speed increases.

(Effect of 1st Embodiment)
(1) The inertial traveling control device 50 according to the first embodiment determines whether or not it has been detected that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient, and determines that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient. When detected, the start of the first inertia traveling and the second inertia traveling is prohibited. For this reason, the first inertia traveling and the second inertia traveling can be prohibited in advance before the vehicle 1 travels on the low friction coefficient road. Therefore, it is possible to prevent the vehicle 1 that is traveling on the low friction coefficient road from being switched from inertia traveling to normal traveling.
(2) The inertia traveling maintenance unit 55 determines whether or not the traveling road is a low friction coefficient road, and when the vehicle 1 during the first inertia traveling or the second inertia traveling enters the low friction coefficient road. The first inertia traveling or the second inertia traveling is continued until the vehicle advances from the low friction coefficient road. For this reason, even if the vehicle 1 during the first inertia traveling or the second inertia traveling enters the low friction coefficient road, it is possible to prevent the vehicle 1 traveling on the low friction coefficient road from switching from the inertia traveling to the normal traveling. .
(3) The inertia traveling maintenance unit 55 determines whether or not the traveling path is a low friction coefficient path based on the wheel speed difference between the plurality of different wheels 6 of the vehicle 1. Therefore, it can be determined whether or not the vehicle 1 traveling in the first inertia traveling or the second inertia traveling has entered the low friction coefficient road.
(4) By detecting the weather condition while the vehicle 1 is traveling, it is detected in advance that the friction coefficient of the road surface becomes a predetermined friction coefficient before the vehicle 1 enters the low friction coefficient road. Second inertia traveling can be prohibited. Therefore, it is possible to prevent the vehicle 1 that is traveling on the low friction coefficient road from being switched from inertia traveling to normal traveling.

(5) When the outside air temperature detected by the road surface state detection unit 53 is equal to or lower than a predetermined temperature, it is determined that the friction coefficient of the road surface is equal to or lower than the predetermined friction coefficient. For this reason, the start of the first inertia traveling and the second inertia traveling can be prohibited in the case of a low temperature where the road surface may freeze and become a low friction coefficient road. As a result, the first inertia traveling and the second inertia traveling can be prohibited in advance before the vehicle 1 travels on the low friction coefficient road.
(6) When at least one of rain and snow is detected by the road surface state detection unit 53, it is determined that the friction coefficient of the road surface is a predetermined friction coefficient or less. For this reason, when the friction coefficient of a running path falls by rainfall and snowfall, the start of the 1st inertia running and the 2nd inertia running can be prohibited. As a result, the first inertia traveling and the second inertia traveling can be prohibited in advance before the vehicle 1 travels on the low friction coefficient road.
(7) When the wiper 46 of the vehicle 1 is used, it is determined that the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient. Thereby, without providing the dedicated sensor 41 and the navigation device 40, it is possible to detect a decrease in the friction coefficient of the road surface and prohibit the start of the first inertia traveling and the second inertia traveling.

(Modification)
The inertial traveling control device 50 of the first embodiment can also be applied to a vehicle that employs an automatic transmission of a type other than the continuously variable transmission 4. For example, the inertial traveling control device 50 can be applied to a vehicle that employs a parallel shaft gear type automatic transmission. In addition, the inertial traveling control device 50 can be applied to a vehicle including only an internal combustion engine as a drive source or a hybrid vehicle.
At the time of the first inertia traveling, the inertial traveling control device 50 may output a clutch release signal that the forward clutch 16 actively releases to the continuously variable transmission 4 instead of the operation prohibition command of the electric oil pump 18.
In addition, after the ignition switch 45 is turned on, the inertial travel prohibition unit 54 may determine that the inertial travel prohibition condition is satisfied before starting the engine and prohibit the start of the first inertial travel and the second inertial travel. . By prohibiting the start of the first inertia travel and the second inertia travel before starting the engine, the first inertia travel and the second inertia travel can be more reliably prohibited before the vehicle 1 travels on the low friction coefficient road. Can do.

(Second Embodiment)
Next, the inertial traveling control device 50 according to the second embodiment will be described. In addition to the configuration and function of the inertial travel control device 50 according to the first embodiment, the inertial travel control device 50 according to the second embodiment starts the first inertial travel and the second inertial travel based on conditions other than weather conditions. Is prohibited. For example, the first inertia traveling or the second inertia traveling on a curved road may make the vehicle behavior unstable. For this reason, for example, the inertial traveling control device 50 prohibits the start of the first inertial traveling and the second inertial traveling when the traveling path of the vehicle 1 is a continuous curved road. Further, for example, when the steering angle of the vehicle 1 exceeds a predetermined value, the start of the first inertia traveling and the second inertia traveling is prohibited.
Further, for example, when the turning behavior control function for automatically controlling the horizontal behavior of the vehicle 1 is operating, there is a possibility that the vehicle is traveling on a low friction coefficient road. Two-wheeled running may make vehicle behavior unstable. For this reason, the inertial traveling control device 50 prohibits the start of the first inertial traveling and the second inertial traveling when the turning behavior control function is operating. The turning behavior control function may be, for example, vehicle dynamics control (VDC).

(Constitution)
Please refer to FIG. The same reference numerals are used for the same components as in the first embodiment. Moreover, since it demonstrates centering around the structure relevant to 2nd Embodiment, description is abbreviate | omitted about a part of the same component as the component of 1st Embodiment.
The vehicle 1 includes a brake control unit 70 that controls braking force, brake actuators 71a to 71d provided on the front wheels 6a and 6b and the rear wheels 6c and 6d, respectively, and a steering angle sensor that detects the steering angle θ of the steering wheel 44. 72. The vehicle 1 also includes a yaw rate sensor 73 and an acceleration sensor 74. The brake actuators 71a to 71d may be collectively referred to as “brake actuator 71”.

The brake control unit 70 calculates the target side slip amount based on the steering angle θ detected by the steering angle sensor 72 and the operation amount of the brake pedal 21 detected by the master cylinder pressure sensor 26. The brake control unit 70 detects the actual amount of skid of the vehicle 1 based on the yaw rate detected by the yaw rate sensor 73, the acceleration detected by the acceleration sensor 74, and the wheel speed detected by the wheel speed sensor 29. When the difference between the target skid amount and the actual skid amount exceeds the threshold, the brake control unit 70 activates the turning behavior control function, and controls the behavior of the vehicle 1 in the horizontal plane by controlling the brake actuator 71 of the wheel 6 and engine output control. To improve vehicle stability. The brake control unit 70 outputs an operation signal indicating whether or not the turning behavior control function is operating to the engine control unit 20.
In addition, a steering angle signal indicating the steering angle θ of the steering wheel 44 detected by the steering angle sensor 72 is input to the engine control unit 20.

  Please refer to FIG. The same reference numerals are used for the same components as in the first embodiment. Moreover, since it demonstrates centering around the structure relevant to 2nd Embodiment, description is abbreviate | omitted about a part of the same component as the component of 1st Embodiment. The inertial traveling control device 50 includes a continuous curve detection unit 80. The continuous curve detection unit 80 detects a continuous curve existing on the travel route of the vehicle 1 or the planned travel route based on the travel route information given from the navigation device 40 in the navigation cooperative control. When the continuous curve is detected, the continuous curve detection unit 80 outputs a continuous curve detection signal to the inertia running prohibition unit 54.

  When the inertial running control unit 52 receives the continuous curve detection signal during normal running, the inertial running control unit 52 prohibits the start of the first inertial running and the second inertial running by outputting an inertial running inhibition signal to the inertial running control unit 52. Alternatively, the inertial travel control unit 52 outputs an inertial travel prohibition signal to the inertial travel control unit 52 when the steering angle θ indicated by the steering angle signal received from the steering angle sensor 72 during normal traveling is equal to or greater than a predetermined value Tθ. To do. Alternatively, the inertial traveling control unit 52 determines whether or not the turning behavior control function is operating based on the operation signal received from the brake control unit 70. When the turning behavior control function is operating during normal travel, the inertial travel control unit 52 outputs an inertial travel prohibition signal to the inertial travel control unit 52.

(Operation)
Next, the operation of the inertial traveling control device 50 according to the second embodiment during normal traveling will be described. Please refer to FIG. In step S60, the continuous curve detection unit 80 determines whether or not there is a continuous curve on the travel path of the vehicle 1 or the planned travel path. If there is a continuous curve (step S60: Y), the process proceeds to step S63. If there is no continuous curve (step S60: N), the process proceeds to step S61.
In step S61, the inertial traveling control unit 52 determines whether or not the steering angle θ is equal to or greater than a predetermined value Tθ. If the steering angle θ is equal to or greater than the predetermined value Tθ (step S61: Y), the process proceeds to step S63. When the steering angle θ is less than the predetermined value Tθ (step S61: N), the process proceeds to step S62.

In step S62, the inertial traveling control unit 52 determines whether or not the turning behavior control function is operating. If the turning behavior control function is operating (step S62: Y), the process proceeds to step S63. If the turning behavior control function is not activated (step S62: N), the process ends without prohibiting the start of the first inertia traveling and the second inertia traveling.
In step S63, the inertial travel control unit 52 outputs the inertial travel prohibition signal to the inertial travel control unit 52, thereby prohibiting the start of the first inertial travel and the second inertial travel. Thereafter, the process ends.

(Effect of 2nd Embodiment)
(1) The continuous curve detection unit 80 determines whether or not the traveling path of the vehicle 1 is a continuous curved road. When the traveling path is a continuous curved road, the inertial traveling control unit 52 performs the first inertial traveling. The start of traveling and second inertia traveling is prohibited. As a result, it is possible to prevent the vehicle behavior from becoming unstable due to the first inertia traveling or the second inertia traveling on the continuous curved road.
(2) The inertial traveling control unit 52 determines whether or not the steering angle θ of the vehicle 1 is a predetermined value Tθ. When the steering angle θ is equal to or larger than the predetermined value Tθ, the first inertial traveling and the second inertial traveling are performed. Prohibit starting. As a result, the vehicle behavior can be prevented from becoming unstable due to the first inertia traveling or the second inertia traveling on the curved road.

(3) The inertial running control unit 52 determines whether or not the turning behavior control function is activated, and prohibits the start of the first inertial running and the second inertial running when the turning behavior control function is activated. To do. As a result, the start of the first inertia traveling and the second inertia traveling can be prohibited when it is determined that the traveling road is a low friction coefficient road because the turning behavior control function is activated. Thereby, it is possible to prevent the vehicle behavior from becoming unstable due to the first inertia traveling or the second inertia traveling on the low friction coefficient road.
Although the present invention has been described with reference to a limited number of embodiments, the scope of rights is not limited thereto, and modifications of each embodiment based on the above disclosure are obvious to those skilled in the art.

  DESCRIPTION OF SYMBOLS 1 ... Vehicle, 2 ... Engine, 3 ... Torque converter, 4 ... Stepless transmission, 5 ... Differential gear, 6a-6b ... Front wheel, 6c-6d ... Rear wheel, 7 ... Motor, 8 ... Alternator, 9 ... Battery, DESCRIPTION OF SYMBOLS 10 ... Lock-up clutch, 11 ... Forward / reverse switching mechanism, 12 ... Primary pulley, 13 ... Secondary pulley, 14 ... Belt, 15 ... Oil pump, 16 ... Forward clutch, 17 ... Reverse brake, 18 ... Electric oil pump, DESCRIPTION OF SYMBOLS 20 ... Engine control unit, 21 ... Brake pedal, 22 ... Brake switch, 23 ... Accelerator pedal, 24 ... Accelerator pedal opening sensor, 25 ... Master cylinder, 26 ... Master cylinder pressure sensor 26, 27 ... Master back, 28 ... Negative Pressure sensor, 29a-29d ... wheel speed sensor, 30 ... transmission control unit, DESCRIPTION OF SYMBOLS 1 ... Engine stop control apparatus, 40 ... Navigation apparatus, 41 ... Sensor, 42 ... Communication apparatus, 43 ... Vehicle body control unit, 44 ... Steering wheel, 45 ... Ignition switch, 46 ... Wiper, 47 ... Wiper switch, 50 ... Inertia running Control device 51 ... Idle stop control device 52 ... Inertia travel control unit 53 ... Road surface condition detection unit 54 ... Inertia travel prohibition unit 55 ... Inertia travel maintenance unit 70 ... Brake control unit 71a-71d ... Brake actuator , 72 ... rudder angle sensor, 73 ... yaw rate sensor, 74 ... acceleration sensor, 80 ... continuous curve detector

Claims (10)

A process for determining whether or not it is detected that the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient;
A process for prohibiting the start of inertial running in which the fuel supply to the engine of the vehicle is stopped when it is detected that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient;
A process for determining whether or not the road is a low friction coefficient road;
When the vehicle in inertia traveling that stops traveling with the fuel supplied to the engine enters the low friction coefficient road, it is determined whether or not the vehicle has advanced from the low friction coefficient road. Processing to continue coasting until it is determined that it has advanced,
The inertial running control method characterized by causing a computer to execute. 2. The inertial traveling control method according to claim 1 , wherein it is determined whether or not the travel path is a low friction coefficient path based on wheel speed differences between a plurality of different wheels of the vehicle.   The coasting according to claim 1, wherein a weather condition is detected while the vehicle is traveling, and it is determined whether or not a friction coefficient of the road surface is equal to or less than the predetermined friction coefficient according to the weather condition. Control method. Detecting the outside temperature as the weather condition,
When the outside air temperature is equal to or lower than a predetermined temperature, it is determined that the friction coefficient of the road surface is equal to or lower than the predetermined friction coefficient.
The inertial traveling control method according to claim 3 . The coasting control method according to claim 3 , wherein the road surface friction coefficient is determined to be less than or equal to the predetermined friction coefficient when at least one of rain and snow is detected as the weather condition. The inertial traveling control method according to claim 3 , wherein when the wiper of the vehicle is used, it is determined that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient. Furthermore, determine whether the road is a continuous curve road,
The inertial traveling control method according to any one of claims 1 to 6 , wherein when the traveling path is a continuous curved road, start of inertial traveling is prohibited. Furthermore, it is determined whether the steering angle of the vehicle is a predetermined value or more,
The inertial travel control method according to any one of claims 1 to 7 , wherein start of inertial travel is prohibited when the steering angle is equal to or greater than the predetermined value. Further, it is determined whether or not the turning behavior control function for automatically controlling the horizontal behavior of the vehicle is activated,
The inertial traveling control method according to any one of claims 1 to 8 , wherein start of inertial traveling is prohibited when the turning behavior control function is activated. A sensor or information processing device for detecting that the friction coefficient of the road surface is equal to or less than a predetermined friction coefficient;
A controller that prohibits the start of inertial running in which the fuel supply to the engine of the vehicle is stopped when it is detected that the friction coefficient of the road surface is equal to or less than the predetermined friction coefficient;
Equipped with a,
The controller determines whether or not the travel path is a low friction coefficient path, and when the vehicle in inertia traveling traveling with the fuel supply to the engine stopped enters the low friction coefficient path, It determines whether to advance from a low friction coefficient road, the coasting control device characterized that you continue coasting until it is determined that advanced from the low friction coefficient road.

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