JP5494857B2 - Vehicle control device - Google Patents

Description

  The present invention relates to a control device for a vehicle equipped with a manual transmission whose gear position is selected by a driver's operation. In particular, the present invention relates to a measure for obtaining a traveling state of a vehicle according to a driver's traveling orientation or the like.

  Conventionally, in a vehicle manual transmission as disclosed in Patent Document 1 and Patent Document 2, for example, a gear position is selected by operating a shift lever by a driver.

  For example, in a floor shift type manual transmission in which a shift lever is disposed on a floor in a passenger compartment, a left-right direction (vehicle width direction: hereinafter referred to as a select operation direction) and a front-rear direction (vehicle body front-rear direction: hereinafter, A shift lever is movably disposed in a shift gate formed with a gate groove extending in a direction (sometimes referred to as a shift operation direction). Then, after a select operation that operates the shift lever in the select operation direction along the gate groove, a desired gear position is established in the transmission mechanism of the manual transmission by performing a shift operation that operates in one direction of the shift operation direction. Let Then, in a state where this gear is established, the clutch device is engaged (clutch pedal depressing release operation), the clutch device is engaged, and the engine and the transmission mechanism are connected. The engine speed is changed at a gear ratio of the existing gear and the rotational driving force is output from the transmission mechanism to the drive wheels.

JP 2008-157184 A JP 2009-103268 A

  By the way, a vehicle equipped with the above-described manual transmission has a better fuel consumption rate than a vehicle equipped with an automatic transmission (for example, the fuel consumption rate is good as much as the loss of driving force due to the torque converter does not occur). Therefore, it is desired to improve the merchantability. As described above, in a manual transmission or the like in which the driver's shift lever operating force and clutch operating force are directly transmitted, vehicle control adapted to the driver's operation is performed, so that the driver and the vehicle There are situations where it is desirable to increase the sense of unity.

  In view of this point, the inventor of the present invention pays attention to the fact that it is possible to improve the merchantability of this type of vehicle if it is possible to realize the vehicle running state according to the driving orientation of the driver. Then, the technology for realizing it was discussed.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a vehicle control device that can obtain the traveling state of the vehicle according to the traveling orientation of the driver. .

-Principle of solving the problem-
The solution principle of the present invention taken to achieve the above object is to recognize the driver's state such as the driver's driving orientation from the information obtained by the driver's clutch operation that selects the gear position of the manual transmission. to make it in, and to perform the control of the vehicle in accordance with the travel-oriented, and the like.

-Solution-
Specifically, the present invention provides a manual transmission either of the plurality of shift speeds by shifting operation by the driver is a selectable及Beauty, the drive source and the manual transmission by a clutch operation of the driver A vehicle control device including a clutch device that performs connection and disconnection is assumed. To the control device of the vehicle, the driver of the clutches operation the driver of the traveling-oriented based on the operation information which changes according to, to determine the degree of fatigue of the proficiency level driver's operation of the driver, the Control means for performing control to change the control amount for the control target of the vehicle according to the determined driving orientation, driving skill level or fatigue level is provided. The control means determines the driver's travel orientation, the driver's driving skill or the driver's fatigue level based on the change speed of the clutch stroke position when the clutch is depressed , and the VDIM control intervention timing. Is changed according to the driving orientation of the driver, the driving skill of the driver or the fatigue level of the driver , and when the change speed of the clutch stroke position is higher than a predetermined value , When it is determined that the response performance of the vehicle control is required to be high and the intervention timing of the VDIM control is set late, while the change speed of the clutch stroke position is lower than a predetermined value , the vehicle with respect to the driving operation is set . it is determined that the response performance of the control is low is demanded, it is configured to set earlier intervention timing of VDIM control .

This particular matter, when the change speed of the clutch stroke position when the clutch depression is high, the driver can be determined that seeking a higher responsiveness of vehicle control against the driving operation. On the contrary, when the change speed of the clutch stroke position at the time of depressing the clutch is low, it can be determined that the driver is demanding that the response performance of the vehicle control with respect to the driving operation is low. And the control amount with respect to the control object of a vehicle is changed according to such a travel orientation determination result. That is, when the driver is demanding that the response performance of the vehicle control with respect to the driving operation is high, the intervention timing of the VDIM control is set late. Conversely, when the driver is demanding that the response performance of the vehicle control with respect to the driving operation is low, the intervention timing of the VDIM control is set earlier. By changing the control amount with respect to the control target of the vehicle as described above, it is possible to realize the traveling state of the vehicle in accordance with the driver's traveling orientation, and it is possible to improve the merchantability of this type of vehicle.

Further, instead of the above driving orientation, it is also possible to determine the driver's driving skill or the driver's fatigue level based on the change speed of the clutch stroke position during the clutch depression operation . For example, when the change speed of the clutch stroke position at the time of clutch depression operation is high, it can be determined that the driver's driving skill is high or the driver's fatigue level is low. On the contrary, for example, when the change speed of the clutch stroke position at the time of depressing the clutch is low, it can be determined that the driver's driving skill is low or the driver's fatigue level is high. In accordance with such a determination result, it is also possible to change the control amount for the control target of the vehicle in the same manner as described above. For example, when it is determined that the driver's driving skill level is high or the driver's fatigue level is low, the intervention timing of the VDIM control is set late. Conversely, when it is determined that the driver's driving skill is low or the driver's fatigue level is high, the intervention timing of the VDIM control is set earlier.

  In addition, it is possible to accurately determine the driving orientation of the driver using a detection signal of an existing sensor (such as a clutch stroke sensor).

  In the present invention, the driver's travel orientation and the like are recognized from information obtained by the driver's clutch operation, and the vehicle is controlled in accordance with the travel orientation and the like. For this reason, it is possible to realize the traveling state of the vehicle in accordance with the traveling orientation of the driver, and it is possible to improve the merchantability of the vehicle equipped with the manual transmission.

FIG. 1 is a diagram illustrating a schematic configuration of a power train mounted on a vehicle according to the embodiment. FIG. 2 is a diagram showing the configuration of the engine and its intake and exhaust system. FIG. 3 is a diagram illustrating a schematic configuration of the clutch device. FIG. 4 is a diagram showing an outline of the shift pattern of the 6-speed manual transmission. FIG. 5 is a diagram showing a schematic configuration of the air suspension system. FIG. 6 is a block diagram showing a configuration of a control system such as an engine ECU. FIG. 7 is a diagram illustrating three rotational speed change states in which the amount of change per unit time of the input shaft rotational speed is different from each other during a speed change operation. The upper part of FIG. 8 shows an example of changes in the input shaft rotational speed and the engine rotational speed during a shift operation, and the lower part of FIG. 8 shows an example of the change in clutch torque in this case. FIG. 9 is a diagram showing a throttle opening map for setting a change characteristic of the throttle opening according to the accelerator opening. FIG. 10 is a timing chart showing a change in the opening of the throttle valve when the tip-in characteristic adjustment operation is performed. FIG. 11 is a timing chart showing a change in the opening of the throttle valve when the tip-out characteristic adjusting operation is performed. FIG. 12 is a timing chart showing a change in engine torque when the fuel cut-on characteristic adjustment operation is performed. FIG. 13 is a timing chart showing changes in engine torque when the fuel cutoff characteristic adjusting operation is performed. FIG. 14 is a diagram showing a VDIM intervention timing map for setting the intervention timing of VDIM control according to the driving orientation. FIG. 15 is a flowchart showing the procedure of the control operation in the first embodiment. FIG. 16 is a flowchart showing the procedure of the control operation in the second embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the present embodiment, a case where the present invention is applied to an FR (front engine / rear drive) type vehicle will be described.

  FIG. 1 shows a schematic configuration of a power train mounted on a vehicle according to the present embodiment. In FIG. 1, 1 is an engine (drive source), MT is a manual transmission, 6 is a clutch device, and 9 is an engine ECU (Electronic Control Unit).

  In the power train shown in FIG. 1, the rotational driving force (torque) generated by the engine 1 is input to the manual transmission MT via the clutch device 6, and an appropriate gear ratio (driver shift) is input by the manual transmission MT. The gears are shifted by a gear ratio selected by lever operation and transmitted to the left and right rear wheels (drive wheels) T, T via the propeller shaft PS and the differential gear DF. The manual transmission MT mounted on the vehicle according to the present embodiment is a synchronous mesh type manual transmission with six forward speeds and one reverse speed.

  Hereinafter, the overall configuration of the engine 1, the clutch device 6, the control system, and the like will be described.

-Overall configuration of engine 1-
FIG. 2 is a diagram showing a schematic configuration of the engine 1 and its intake / exhaust system. In FIG. 2, only the configuration of one cylinder of the engine 1 is shown.

  The engine 1 in this embodiment is, for example, a four-cylinder gasoline engine, and includes a piston 12 that forms a combustion chamber 11 and a crankshaft 13 that is an output shaft. The piston 12 is connected to the crankshaft 13 via a connecting rod 14, and the reciprocating motion of the piston 12 is converted into rotation of the crankshaft 13 by the connecting rod 14.

  A signal rotor 15 having a plurality of protrusions (teeth) 16 on the outer peripheral surface is attached to the crankshaft 13. A crank position sensor (engine speed sensor) 81 is disposed near the side of the signal rotor 15. The crank position sensor 81 is, for example, an electromagnetic pickup, and generates a pulse-shaped signal (output pulse) corresponding to the protrusion 16 of the signal rotor 15 when the crankshaft 13 rotates.

  A water temperature sensor 82 that detects the engine water temperature (cooling water temperature) is disposed in the cylinder block 17 of the engine 1.

  A spark plug 2 is disposed in the combustion chamber 11 of the engine 1. The ignition timing of the spark plug 2 is adjusted by the igniter 21. The igniter 21 is controlled by the engine ECU 9.

  An intake passage 3 and an exhaust passage 4 are connected to the combustion chamber 11 of the engine 1. An intake valve 31 is provided between the intake passage 3 and the combustion chamber 11. By opening and closing the intake valve 31, the intake passage 3 and the combustion chamber 11 are communicated or blocked. An exhaust valve 41 is provided between the exhaust passage 4 and the combustion chamber 11. By opening and closing the exhaust valve 41, the exhaust passage 4 and the combustion chamber 11 are communicated or blocked. The opening / closing drive of the intake valve 31 and the exhaust valve 41 is performed by each rotation of the intake camshaft (not shown) and the exhaust camshaft 41a to which the rotation of the crankshaft 13 is transmitted.

  An air cleaner 32, a hot-wire air flow meter 83, an intake air temperature sensor 84 (built in the air flow meter 83), and an electronically controlled throttle valve 33 that adjusts the intake air amount of the engine 1 are disposed in the intake passage 3. ing. The throttle valve 33 is driven by a throttle motor 34. The opening degree of the throttle valve 33 is detected by a throttle opening degree sensor 85.

  A fuel injection injector 35 is disposed in the intake passage 3. Fuel of a predetermined pressure is supplied from the fuel tank to the injector 35 by a fuel pump, and the fuel is injected into the intake passage 3. This injected fuel is mixed with intake air to form an air-fuel mixture and introduced into the combustion chamber 11 of the engine 1. The air-fuel mixture (fuel + air) introduced into the combustion chamber 11 passes through the compression stroke of the engine 1 and is then ignited and burned by the spark plug 2. The combustion of the air-fuel mixture in the combustion chamber 11 causes the piston 12 to reciprocate and the crankshaft 13 to rotate.

Two three-way catalysts 42 and 43 are disposed in the exhaust passage 4 of the engine 1. These three-way catalysts 42 and 43 have an O ₂ storage function (oxygen storage function) for storing (storing) oxygen, and it is assumed that the air-fuel ratio has deviated from the stoichiometric air-fuel ratio to some extent by this oxygen storage function. In addition, HC, CO and NOx can be purified.

An air-fuel ratio sensor (A / F sensor) 86 is provided upstream of the upstream side three-way catalyst 42 in the exhaust passage 4, and an oxygen sensor (O ₂ sensor) 87 is provided upstream of the downstream side three-way catalyst 43. Each is arranged.

-Clutch device 6
FIG. 3 shows a schematic configuration of the clutch device 6. As shown in FIG. 3, the clutch device 6 includes a clutch mechanism 60, a clutch pedal 70, a clutch master cylinder 71, and a clutch release cylinder 61.

  The clutch mechanism 60 is provided so as to be interposed between the crankshaft 13 and the input shaft (input shaft) IS of the manual transmission MT (see FIG. 1), and is driven from the crankshaft 13 to the input shaft IS. Transmits or cuts off the force, or changes the transmission state of the driving force. Here, the clutch mechanism 60 is configured as a dry single-plate friction clutch. Note that other configurations may be adopted as the configuration of the clutch mechanism portion 60.

  Specifically, a flywheel 62 and a clutch cover 63 are attached to a crankshaft 13 that is an input shaft of the clutch mechanism 60 so as to be integrally rotatable. On the other hand, a clutch disk 64 is splined to an input shaft IS that is an output shaft of the clutch mechanism 60. Therefore, the clutch disk 64 can slide along the axial direction (left and right direction in FIG. 3) while rotating integrally with the input shaft IS. A pressure plate 65 is disposed between the clutch disk 64 and the clutch cover 63. The pressure plate 65 is in contact with the outer end of the diaphragm spring 66 and is urged toward the flywheel 62 by the diaphragm spring 66.

  A release bearing 67 is slidably mounted on the input shaft IS along the axial direction. In the vicinity of the release bearing 67, a release fork 68 is rotatably supported by a shaft 68a, and one end (the lower end in FIG. 3) is in contact with the release bearing 67. Then, one end portion (the right end portion in FIG. 3) of the rod 61a of the clutch release cylinder 61 is connected to the other end portion (the upper end portion in FIG. 3) of the release fork 68. Then, when the release fork 68 is operated, the clutch mechanism 60 is engaged and disengaged.

  The clutch pedal 70 is configured by integrally forming a pedal portion 72 a as a stepping portion at a lower end portion of a pedal lever 72. A position near the upper end of the pedal lever 72 is rotatably supported about a horizontal axis by a clutch pedal bracket (not shown) attached to a dash panel that partitions the vehicle compartment and the engine compartment. The pedal lever 72 is applied with a biasing force in a turning direction toward the near side (driver side) by a pedal return spring (not shown). When the driver depresses the pedal portion 72a against the urging force of the pedal return spring, the release operation of the clutch mechanism portion 60 is performed. Further, the release operation of the clutch mechanism 60 is performed when the driver releases the stepping operation of the pedal portion 72a (these release and connection operations will be described later).

  The clutch master cylinder 71 has a structure in which a piston 74 and the like are incorporated in a cylinder body 73. The piston 74 is connected to one end portion of the rod 75 (left end portion in FIG. 3), and the other end portion (right end portion in FIG. 3) of the rod 75 is connected to the intermediate portion of the pedal lever 72. Yes. A reserve tank 76 for supplying a clutch fluid (oil) that is a working fluid into the cylinder body 73 is provided on the upper portion of the cylinder body 73.

  The clutch master cylinder 71 is adapted to generate hydraulic pressure when the piston 74 moves in the cylinder body 73 by receiving an operation force generated by the driver depressing the clutch pedal 70. At this time, the driver's stepping operation force is transmitted from the intermediate portion of the pedal lever 72 to the rod 75, and hydraulic pressure is generated in the cylinder body 73. The hydraulic pressure generated in the clutch master cylinder 71 is changed according to the stroke position of the piston 74 in the cylinder body 73.

  The hydraulic pressure generated by the clutch master cylinder 71 is transmitted to the clutch release cylinder 61 by the oil in the hydraulic pipe 77.

  As with the clutch master cylinder 71, the clutch release cylinder 61 has a configuration in which a piston 61c and the like are incorporated in a cylinder body 61b. The other end portion (the left end portion in FIG. 3) of the rod 61a is connected to the piston 61c. The stroke position of the piston 61c is changed according to the hydraulic pressure received by the piston 61c.

  In the clutch device 6, the release fork 68 is operated in accordance with the hydraulic pressure in the clutch release cylinder 61, so that the clutch mechanism 60 is engaged and released. In this case, the clutch engagement force (clutch transmission capacity) of the clutch mechanism unit 60 is changed in accordance with the depression amount of the clutch pedal 70.

  Specifically, when the depression amount of the clutch pedal 70 is increased, oil is supplied from the clutch master cylinder 71 to the clutch release cylinder 61, and the hydraulic pressure in the clutch release cylinder 61 is increased, the piston 61c and the rod 61a are 3, the release fork 68 connected to the rod 61 a is rotated and the release bearing 67 is pushed toward the flywheel 62. Further, the movement of the release bearing 67 in the same direction causes the inner end portion of the diaphragm spring 66 to elastically deform in the same direction. Accordingly, the urging force of the diaphragm spring 66 on the pressure plate 65 is weakened. For this reason, it will be in the half clutch state to which the pressure plate 65, the clutch disc 64, and the flywheel 62 are joined, sliding. When the urging force is further weakened, the pressure plate 65, the clutch disc 64, and the flywheel 62 are separated, and the clutch mechanism 60 is released. As a result, power transmission from the engine 1 to the manual transmission MT is interrupted. In this case, when the depression amount of the clutch pedal 70 exceeds a predetermined amount, the clutch mechanism 60 is completely disengaged (the clutch transmission capacity is 0%).

  On the other hand, when the depression amount of the clutch pedal 70 is reduced, the oil is returned from the clutch release cylinder 61 to the clutch master cylinder 71, and the hydraulic pressure in the clutch release cylinder 61 is lowered, the piston 61c and the rod 61a are moved to the left in FIG. Moved in the direction. Thereby, the release fork 68 is rotated, and the release bearing 67 is moved to the side away from the flywheel 62. Along with this, the urging force to the pressure plate 65 by the outer end portion of the diaphragm spring 66 increases. At this time, a frictional force, that is, a clutch engagement force is generated between the pressure plate 65 and the clutch disk 64 and between the clutch disk 64 and the flywheel 62. When the clutch engagement force increases, the clutch mechanism 60 is engaged, and the pressure plate 65, the clutch disk 64, and the flywheel 62 rotate together. Thereby, the engine 1 and the manual transmission MT are directly connected. In this case, when the operation amount of the clutch pedal 70 is less than a predetermined amount, the clutch mechanism 60 is completely engaged (the clutch transmission capacity is 100%).

  Further, the clutch device 6 is provided with a clutch stroke sensor 8B that transmits an output signal corresponding to the operation amount (depression amount) of the clutch pedal 70. The clutch stroke sensor 8B detects the amount of operation of the clutch pedal 70 by the driver by detecting the position of the rod 61a of the clutch release cylinder 61, for example. Then, the detection signal of the clutch stroke sensor 8B is output to the engine ECU 9, whereby the engaged state of the clutch mechanism unit 60 can be recognized, whereby the current clutch torque capacity (the clutch mechanism unit 60 can be transmitted). The maximum torque value). The position where the clutch stroke sensor 8B is disposed is not limited to the vicinity of the rod 61a of the clutch release cylinder 61, and the amount of movement of the clutch pedal 70 is detected by being disposed near the clutch pedal 70. Alternatively, it may be arranged in the vicinity of the release bearing 67 to detect the amount of movement of the release bearing 67.

  Further, an input rotation speed sensor 8A is disposed in the vicinity of the input shaft IS. The input rotational speed sensor 8A detects the rotational speed (input shaft rotational speed, input shaft rotational speed) of the input shaft IS and outputs a rotational speed signal to the engine ECU 9 (see FIG. 1).

-Shift pattern-
Next, the shift pattern (shift gate shape) of the shift gate that is arranged on the floor in the passenger compartment and guides the movement of the shift lever will be described.

  FIG. 4 schematically shows a shift pattern of the 6-speed manual transmission MT in the present embodiment. The shift lever L indicated by a two-dot chain line in the figure is configured to be able to perform a selection operation in the direction indicated by an arrow X in FIG. 4 and a shift operation in a direction indicated by an arrow Y orthogonal to the selection operation direction.

  In the select operation direction, the 1st-2nd speed select position P1, the 3rd-4th speed select position P2, the 5th-6th speed select position P3 and the reverse select position P4 are arranged in a line.

  The shift lever L can be moved to the first speed position 1st or the second speed position 2nd by the shift operation (operation in the arrow Y direction) at the first speed-2 speed select position P1. When the shift lever L is operated to the first speed position 1st, the first synchromesh mechanism provided in the transmission mechanism of the manual transmission MT is operated to the first speed establishment side to establish the first speed stage. When the shift lever L is operated to the 2nd speed position 2nd, the first synchromesh mechanism is operated to the 2nd speed establishment side to establish the 2nd speed stage.

  Similarly, the shift lever L can be moved to the 3rd speed position 3rd or the 4th speed position 4th by a shift operation at the 3rd speed-4th gear select position P2. When the shift lever L is operated to the 3rd speed position 3rd, the second synchromesh mechanism provided in the transmission mechanism of the manual transmission MT operates to the 3rd speed establishment side to establish the 3rd speed stage. When the shift lever L is operated to the 4th speed position 4th, the second synchromesh mechanism operates to the 4th speed establishment side, and the 4th speed stage is established.

  Further, the shift lever L can be moved to the fifth speed position 5th or the sixth speed position 6th by a shift operation at the fifth speed-6th speed select position P3. When the shift lever L is operated to the fifth speed position 5th, the third synchromesh mechanism provided in the transmission mechanism of the manual transmission MT operates on the fifth speed establishment side to establish the fifth speed stage. Further, when the shift lever L is operated to the sixth speed position 6th, the third synchromesh mechanism is operated to the sixth speed establishment side, and the sixth speed stage is established.

  Furthermore, the shift lever L can be moved to the reverse position REV by a shift operation at the reverse select position P4. When the reverse position REV is operated, all the synchromesh mechanisms are in a neutral state, and the reverse idler gear provided in the transmission mechanism of the manual transmission MT is operated to establish a reverse gear.

  Further, as a sensor for detecting the operation position of the shift lever L, a select operation direction position sensor 8C (FIG. 1 and FIG. 1) for detecting the operation position of the shift lever L in the select operation direction (direction indicated by an arrow X in FIG. 4). 6) and a shift operation direction position sensor 8D (see FIGS. 1 and 6) for detecting the operation position of the shift lever L in the shift operation direction (the direction indicated by the arrow Y in FIG. 4). It has been.

  For example, when the shift lever L is selected at the neutral position, the selection operation direction position sensor 8C has the operation position of the 1st speed-2nd speed selection position P1, the 3rd speed-4th speed selection position P2, and the 5th speed. It is possible to detect which of the sixth speed select position P3 and the reverse select position P4. Further, in the shift operation direction position sensor 8D, the operation position of the shift lever L is at the vehicle front side position (a position corresponding to the first speed position 1st, the third speed position 3rd, the fifth speed position 5th, the reverse position REV), It is in a vehicle rear side position (a position corresponding to the 2nd speed position 2nd, 4th speed position 4th, 6th speed position 6th) or neutral position (the 1st speed-2nd speed selection position P1, the 3rd speed-4th speed selection position P2). , 5th-6th gear select position P3 and reverse select position P4).

  Specifically, when the shift lever L is operated, the operation position is the rotation position of the shift select shaft for transmitting the operation force to the synchromesh mechanism of the transmission mechanism (not shown) (for example, the select operation direction of the shift lever L). ) And a slide movement position (for example, a slide movement position according to the position of the shift lever L in the shift operation direction) are determined. Each of the sensors 8C and 8D is constituted by a rotary encoder or a potentiometer that detects the rotation position and slide movement position of the shift select shaft. Thereby, the current position of the shift lever L can be recognized by the shift lever position signal from the sensors 8C and 8D.

  Further, the shift lever L is provided with a shift load sensor 8E (see FIGS. 1 and 6) that detects a shift load corresponding to the driver's operating force with respect to the shift lever L. As the shift load sensor 8E, for example, a strain gauge attached to the shift lever L is employed, and the shift load is detected by utilizing the fact that the amount of strain generated in the shift lever L increases as the shift load increases. Yes. This shift load is generally detected as a larger value as the operation speed of the shift lever L is higher.

(Air suspension system)
The vehicle according to the present embodiment includes an air suspension system as a suspension device. This air suspension system has suspension characteristics (damping characteristics) by configuring the suspension with air springs to supply and exhausting the air springs according to the movement state of the vehicle in order to ensure the ride comfort and handling stability of the vehicle. Is variably controlled. By variably controlling the suspension characteristics, it is possible to realize smoothing of the behavior of the vehicle with respect to the roll motion and pitch motion of the vehicle body.

  An outline of the air suspension system will be described below. FIG. 5 shows an outline of the air suspension system 100 in the present embodiment. As shown in FIG. 5, an air suspension system 100 includes an air pump 101, a conduit 103 having one end connected to the air pump 101 and the other end connected to an air chamber 113 of an air spring 102 of each wheel, and the conduit 103 An air dryer 104 provided in the main body, and a normally closed electromagnetic on-off valve 105 provided in a branch pipe portion of each pipe 103 to each wheel. The conduit 103 between the air dryer 104 and the electromagnetic on-off valve 105 is branched into two conduit portions 103A and 103B. One conduit portion 103A is provided with an electromagnetic switching valve 106, and the other conduit portion 103B is provided with the other conduit portion 103B. A check valve 107 that allows only air flow from the air dryer 104 toward the air spring 102 is provided.

  The electromagnetic switching valve 106 switches between a throttle position where the flow of the conduit portion 103A is restricted by the orifice and a communication position where air is allowed to freely flow through the conduit portion 103A, and is normally set to the throttle position. ing. One end of an air discharge conduit 108 is connected to the conduit 103 between the air pump 101 and the air dryer 104, and the other end of the air discharge conduit 108 is open to the atmosphere. The air discharge conduit 108 is provided with a normally closed electromagnetic on-off valve 109.

  The air spring 102 has a chamber member 111 supported by the piston rod 110a or the vehicle body of the shock absorber 110, and a rolling diaphragm 112 installed between the chamber member 111 and the cylinder 110b of the shock absorber 110. Thus, an air chamber 113 is formed.

  The air pump 101, the electromagnetic on-off valve 105, the electromagnetic switching valve 106, and the electromagnetic on-off valve 109 are controlled by an air suspension ECU (not shown), thereby controlling the supply and discharge of air to and from the air chamber 113, so that the suspension damping force is increased. It has come to be adjusted. By adjusting the damping force, it is possible to absorb a shock from the road surface and improve comfortable riding comfort, steering stability, and turning characteristics. For example, when obtaining a driving state that emphasizes steering stability, adjust the damping force to be high, while adjusting the driving force to emphasize a comfortable ride, adjust the damping force to be low. become.

  In place of the air suspension system 100 described above, the upper and lower oil chambers in the cylinder are filled with a magnetorheological fluid, and the MLV coil provided in the communication path between the oil chambers is energized to change the viscosity of the magnetorheological fluid. It is also possible to employ a damping force variable damper system that variably controls the damping force.

-Control system-
Various controls such as the operating state of the engine 1 described above are controlled by the engine ECU 9. As shown in FIG. 6, the engine ECU 9 includes a CPU (Central Processing Unit) 91, a ROM (Read Only Memory) 92, a RAM (Random Access Memory) 93, a backup RAM 94, and the like.

  The ROM 92 stores various control programs, maps that are referred to when the various control programs are executed, and the like. The CPU 91 executes arithmetic processing based on various control programs and maps stored in the ROM 92. The RAM 93 is a memory that temporarily stores calculation results in the CPU 91, data input from each sensor, and the like. The backup RAM 94 is a non-volatile memory that stores data to be saved when the engine 1 is stopped.

  The ROM 92, CPU 91, RAM 93, and backup RAM 94 are connected to each other via a bus 97, and are connected to an external input circuit 95 and an external output circuit 96.

  The external input circuit 95 is operated by the driver in addition to the crank position sensor 81, the water temperature sensor 82, the air flow meter 83, the intake air temperature sensor 84, the throttle opening sensor 85, the air-fuel ratio sensor 86, and the oxygen sensor 87. An accelerator opening sensor 88 that detects the opening of the accelerator pedal, a cam angle sensor 89 that detects the rotational position of the camshaft, the input rotational speed sensor 8A, a clutch stroke sensor 8B, a select operation direction position sensor 8C, and a shift operation direction. A position sensor 8D, a shift load sensor 8E, and the like are connected.

  On the other hand, a throttle motor 34 for driving the throttle valve 33, the injector 35, the igniter 21 and the like are connected to the external output circuit 96.

  The engine ECU 9 executes various controls of the engine 1 based on the detection signals of the various sensors. For example, known ignition timing control of the spark plug 2, fuel injection control of the injector 35 (air-fuel ratio feedback control based on the outputs of the air-fuel ratio sensor 86 and the oxygen sensor 87), drive control of the throttle motor 34, and the like are executed. .

  Further, the air suspension system 100 is connected to the external output circuit 96, and various sensor signals and control signals are transmitted to the air suspension system 100.

  The engine ECU 9 transmits / receives various sensor signals and control signals to / from a VDIM (Vehicle Dynamics Integrated Management) ECU 200, which will be described later. For example, the engine ECU 9 receives control signals from the VDIMECU 200 to control the engine 1 (throttle motor). 34, control of the spark plug 2 and the like).

(VDIM system)
The VDIMECU 200 sets a dynamic required engine torque or the like required for the engine 1 in order to stabilize the behavior of the vehicle. The dynamic required engine torque means the required engine torque in a transient state in which the output torque of the engine 1 changes.

  A VDIM system including the VDIMECU 200 and actuators (throttle motor 34, spark plug 2, etc.) controlled by a control signal from the VDIMECU 200 includes a VSC (Vehicle Stability Control), a TRC (Traction Control), and an ABS (ABS). It is a system that integrates Anti Lock Break System (EPS), EPS (Electric Power Steering), etc., and calculates the difference between the driving image of the driver by the amount of operation of the accelerator, steering, and brake, and the vehicle behavior by various sensor information, The vehicle driving force, brake hydraulic pressure, etc. are controlled to reduce the difference.

  The VSC automatically sets optimum values such as brake hydraulic pressure of each wheel and dynamic required engine torque of the vehicle when a sensor (a lateral acceleration sensor 202 described later) detects a state where the front and rear wheels are likely to skid. This is a control to set and ensure the stability of the vehicle.

  When the sensor (wheel speed sensor 204, which will be described later) senses the idling of the driving wheel when starting and accelerating on a slippery road surface, the above TRC optimizes the brake hydraulic pressure of each wheel and the dynamic required engine torque of the vehicle. This is a control that automatically sets a value and ensures an optimum driving force.

  The ABS is a control system that automatically sets the optimum value of the brake hydraulic pressure and prevents the wheels from being locked.

  The EPS is a control system that assists steering of a steering wheel by the force of an electric motor.

  Since each system is already known, a detailed description thereof is omitted here.

  The VDIMECU 200 includes a longitudinal acceleration sensor 201 for detecting the longitudinal acceleration of the vehicle, a lateral acceleration sensor 202 for detecting the lateral acceleration of the vehicle, a yaw rate sensor 203 for detecting the yaw rate, as sensors for detecting the behavior of the vehicle. A wheel speed sensor 204 or the like for detecting the rotation speed of the wheel is connected. The vehicle behavior is detected by detection signals from these sensors 201 to 204, and the control of the VSC, TRC, ABS, and EPS is executed so that the behavior is stabilized.

-Driving-oriented reflection control-
Next, operations characteristic of this embodiment will be described. As the "determination based on the operation information which changes according to the driver's clutches Operations" in the present invention, include "travel-oriented driver proficiency of the driver operation, the determination of the degree of fatigue of the driver." It is done. Hereinafter, a case where the driving orientation of the driver is determined will be described as a representative.

  The engine ECU 9 determines the driving orientation of the driver and performs various controls of the engine 1 and the like according to the determination result. Hereinafter, various kinds of control of the engine 1 and the like according to the determination result of the driver's travel orientation will be referred to as “travel orientation reflection control” (control executed by the control means in the present invention). Hereinafter, the travel-oriented reflection control will be specifically described.

  This travel orientation reflection control is an operation for determining the travel orientation of the driver based on a change in information (information such as operation speed) resulting from a shift operation (operation of the clutch pedal 70 and operation of the shift lever L) by the driver. (Hereinafter referred to as “travel-oriented determination operation”) and an operation for controlling the vehicle in accordance with the travel-oriented determination result of the travel-oriented determination operation (hereinafter referred to as “travel-oriented reflection operation”). Each will be described in detail below.

(Driving-oriented judgment operation)
The driver's operations at the time of shifting the manual transmission MT include a manual operation (shift operation) of the shift lever L and a depression operation and a release operation (clutch operation) of the clutch pedal 70. Therefore, as the travel orientation determination operation, “shift lever operation determination operation” for determining travel orientation by manual operation of the shift lever L and “clutch pedal operation determination for determining travel orientation by operation of the clutch pedal 70”. There is "operation".

<Shift lever operation determination operation>
As described above, the shift lever operation determination operation determines the travel orientation by manual operation of the shift lever L. Specifically, the driving orientation is determined using at least one of the following information (operation information that changes according to the speed change operation).

(S-1) Amount of change per unit time of the rotation speed of the input shaft IS (S-2) A rotation speed of the input shaft IS (S-3) A movement amount of the shift lever L per unit time (S-4) Shift speed selected by operation of shift lever L (S-5) Shift speed of shift speed by operation of shift lever L (S-6) Shift load magnitude Each of these will be described in detail below.

(S-1) The amount of change per unit time of the rotational speed of the input shaft IS The amount of change per unit time of the rotational speed of the input shaft IS is such that the shift stage of the transmission mechanism is switched by manual operation of the shift lever L. In this case, the rotational speed of the input shaft IS (Ni: the rotational speed of the input shaft IS at the stage before the clutch device 6 is engaged) is obtained by a time differential value (dNi / dt). Specifically, it is obtained by time-differentiating the rotational speed of the input shaft IS detected by the input rotational speed sensor 8A. That is, when the manual operation speed of the shift lever L by the driver is high, the shift stage is switched within a relatively short time, so that the amount of change per unit time of the rotational speed of the input shaft IS becomes large. Conversely, when the manual operation speed of the shift lever L by the driver is low, a relatively long time is required until the gear position is switched, and therefore the amount of change per unit time of the rotational speed of the input shaft IS is small. . That is, the manual operation speed of the shift lever L can be determined by calculating the amount of change per unit time of the rotational speed of the input shaft IS.

  When the amount of change per unit time of the rotational speed of the input shaft IS is larger than a predetermined value (the manual operation speed of the shift lever L is high), the driving orientation of the driver is the vehicle control for the driving operation. It can be determined that high response performance is required. The predetermined value is appropriately set by experiment or the like. “High response performance of vehicle control with respect to driving operation” means that so-called sports mode driving is required such that the acceleration characteristic of the vehicle with respect to the depression operation of the accelerator pedal is high (accelerated quickly). Means that. Hereinafter, this travel orientation is referred to as “sport mode travel orientation”.

  On the other hand, when the amount of change per unit time in the rotational speed of the input shaft IS is smaller than a predetermined value (the manual operation speed of the shift lever L is low), the driving orientation of the driver is the vehicle control for the driving operation. It can be determined that low response performance is required. The predetermined value is also set as appropriate through experiments and the like. This “low response performance of vehicle control with respect to driving operation” means, for example, driving in a so-called comfort mode such that the acceleration characteristic of the vehicle with respect to the depression operation of the accelerator pedal is low (slowly accelerating). This means that driving with an emphasis on ride comfort is required. Hereinafter, this travel orientation is referred to as “comfort mode travel orientation”.

  In this way, the driving orientation of the driver can be determined based on the amount of change per unit time of the rotational speed of the input shaft IS.

Various periods can be set as the calculation period of the change amount per unit time of the rotational speed of the input shaft IS. For example, (a) an average change amount of the rotational speed of the input shaft IS during a period from the start of the shift to the completion of the shift, and (b) a change amount of the rotational speed of the input shaft IS immediately before the completion of the shift. Explain each,
(A) The average amount of change in the rotational speed of the input shaft IS during the period from the start of shifting to the completion of shifting has a correlation with the time required from the start of shifting to the completion of shifting. That is, when the average change amount of the rotation speed of the input shaft IS during this period is large, the manual operation speed and the shift load of the shift lever L are high, and it can be determined that the driving orientation of the driver is sports mode driving orientation. . On the contrary, when the average change amount of the rotation speed of the input shaft IS during this period is small, the manual operation speed and the shift load of the shift lever L are low, and it is determined that the driving direction of the driver is the comfort mode driving direction. it can.

  (B) The amount of change in the rotational speed of the input shaft IS immediately before the completion of the shift has a correlation with the shift operation speed and the shift load from the neutral position toward the target shift stage. For example, when upshifting from the first speed to the second speed, the shift lever L is operated from the first speed-2 speed select position P1 (see FIG. 4) toward the second speed position 2nd. This corresponds to the operation speed and shift load of the shift lever L. When the amount of change in the rotation speed of the input shaft IS immediately before the completion of the shift is large, the manual operation speed and the shift load of the shift lever L immediately before the completion of the shift are high, and the driving direction of the driver is the sports mode driving direction. It can be judged. Conversely, when the amount of change in the rotational speed of the input shaft IS just before the completion of the shift is small, the manual operation speed and shift load of the shift lever L immediately before the completion of the shift are low. Judgment can be determined.

  The amount of change in the rotational speed of the input shaft IS immediately before the completion of the above-described (b) shift will be specifically described with reference to FIG. FIG. 7 shows the change in the rotational speed of the input shaft IS when upshifting from the first speed to the second speed, and the shift lever even if the speed change operation period (time required for speed change) is the same. An example of three shift operations with different operation states of L (partially different shift operation speeds (shift loads)) is shown.

  A change A in the rotational speed of the input shaft IS indicated by a solid line in FIG. 7 is a change in the rotational speed of the input shaft IS when a general driver performs a normal shift operation.

  On the other hand, the change B in the rotational speed of the input shaft IS indicated by the alternate long and short dash line in FIG. 7 operates the shift lever L from the first speed-second speed select position P1 (see FIG. 4) toward the second speed position 2nd. The amount of change in the rotational speed of the input shaft IS (the amount of decrease in the rotational speed) at the beginning of the operation is large, and the amount of change in the rotational speed of the input shaft IS just before the completion of this operation is small.

  On the other hand, a change C in the rotational speed of the input shaft IS indicated by a two-dot chain line in FIG. 7 operates the shift lever L from the first-speed / second-speed select position P1 (see FIG. 4) toward the second-speed position 2nd. The amount of change in the rotational speed of the input shaft IS at the beginning of the operation (the amount of decrease in the rotational speed) is small, and the amount of change in the rotational speed of the input shaft IS immediately before the completion of this operation is large.

  Thus, even if the speed change operation period (time required for speed change) is the same, whether the driving orientation of the driver is the sports mode driving orientation or not by analyzing the rotation speed change waveform of the input shaft IS (waveform analysis). It is possible to determine whether the mode driving orientation is intended. For example, in the case of a change in the rotational speed of the input shaft IS indicated by the solid line A, it is determined that the driving mode is oriented to the comfort mode, and in the case of a change in the rotational speed of the input shaft IS indicated by the one-dot chain line B or the two-dot chain line C It is determined that the vehicle is traveling-oriented.

  Further, (a) the average change amount of the rotational speed of the input shaft IS during the period from the start of the shift to the completion of the shift, and (b) the two change amounts of the change amount of the rotational speed of the input shaft IS immediately before the completion of the shift. You may make it determine driving | running | working orientation.

(S-2) Rotation speed of input shaft IS If the vehicle speed is the same, the lower the gear position (the higher the gear ratio), the more the rotation speed of the input shaft IS (the input shaft IS detected by the input rotation speed sensor 8A). The number of revolutions) increases. As described above, when the gear speed is low even if the vehicle speed is the same, it is estimated that the driver is driving in a travel-oriented manner that requires rapid acceleration of the vehicle. On the other hand, if the gear speed is high even if the vehicle speed is the same, it is estimated that the driver is driving in a travel-oriented manner that requires slow acceleration of the vehicle. For this reason, when the rotation speed of the input shaft IS is higher than a predetermined value (when the low gear is selected and traveling; the rotation speed of the input shaft IS is higher than the predetermined value with respect to the vehicle speed). The driving orientation of the driver can be determined to be sports mode driving orientation. On the contrary, when the rotational speed of the input shaft IS is lower than a predetermined value (when the high gear is selected and traveling; the rotational speed of the input shaft IS is lower than the predetermined value with respect to the vehicle speed). It can be determined that the driving orientation of the driver is the comfort mode driving orientation. These predetermined values are appropriately set by experiments or the like.

  In this way, the driving orientation of the driver can be determined based on the rotational speed of the input shaft IS.

(S-3) The amount of operation movement per unit time of the shift lever L The amount of operation movement per unit time of the shift lever L is the shift lever when the gear position of the transmission mechanism is switched by manual operation of the shift lever L. It is obtained from the time differential value (dsfts / dt) of the movement amount (sfts) of L. Specifically, the amount of movement of the shift lever L detected by the select operation direction position sensor 8C and the shift operation direction position sensor 8D is obtained by time differentiation. When the operation movement amount per unit time of the shift lever L is larger than a predetermined value, it can be determined that the driving orientation of the driver is sports mode driving orientation. On the contrary, when the operation movement amount per unit time of the shift lever L is smaller than a predetermined value, it can be determined that the driver's travel orientation is the comfort mode travel orientation. These predetermined values are appropriately set by experiments or the like.

  In this way, the driving orientation of the driver can be determined based on the amount of operation movement per unit time of the shift lever L.

  When determining the travel orientation of the driver based on the operation movement amount per unit time of the shift lever L, various periods can be set as the calculation period of the operation movement amount per unit time. For example, (a) the average operation moving speed of the shift lever L during the period from the start of shifting to the completion of shifting, (b) the amount of operating movement per unit time of the shift lever L at the beginning of shifting, (c) the shift during shifting The amount of operation movement per unit time of the lever L, (d) the amount of operation movement per unit time of the shift lever L immediately before completion of the shift, and the like.

(S-4) Shift stage selected by operation of shift lever L Even when the vehicle speed is the same, if the shift stage is low (if the shift stage selected by operation of shift lever L is low; relative to the vehicle speed In the case of a predetermined low speed stage), it is presumed that the driver is driving in a driving direction that requires rapid acceleration of the vehicle. Conversely, when the gear stage is high (when the gear stage selected by operating the shift lever L is high; when the vehicle speed is a predetermined high speed stage), the driver makes a slow acceleration of the vehicle. It is presumed that the driver is driving as required. When the vehicle is traveling with a predetermined low gear position selected, it can be determined that the driver's travel orientation is sport mode travel orientation. Conversely, when the vehicle is traveling with a predetermined high gear selected, it can be determined that the driver's travel orientation is comfort mode travel orientation.

  For example, a vehicle speed suitable for each shift stage is set in advance for each shift stage. Specifically, the first speed is less than 20 km / h, the second speed is 25 to 35 km / h, the third speed is 30 to 50 km / h, and the fourth speed is 45 to 45 km / h. 70 km / h, 65 to 90 km / h are assigned to the fifth speed stage, and 100 km / h or more are assigned to the sixth speed stage. When the actual vehicle speed is higher than these assigned vehicle speeds (when the vehicle speed is higher than the vehicle speed assigned to the current gear), the driver's driving intention is the sports mode driving intention. Is determined. In other words, when the currently selected gear position is a gear position lower than the gear position appropriate for the vehicle speed, it is determined that the driver's travel orientation is the sport mode travel orientation. On the other hand, when the actual vehicle speed is lower than the assigned vehicle speed (lower than the vehicle speed assigned to the current gear position), the driver's driving intention is the comfort mode driving intention. Judge that there is. In other words, when the currently selected shift stage is a shift stage higher than the shift stage appropriate for the vehicle speed, it is determined that the driver's travel orientation is the comfort mode travel orientation.

  In this way, the driving orientation of the driver can be determined based on the gear selected by operating the shift lever L.

(S-5) Shifting speed of the shift stage by operating the shift lever L When the operating speed of the shift lever L is high, the shifting speed of the shift stage (the time required for shifting the shift stage) is short. When the operation speed of the shift lever L is low, the shift time for the shift stage becomes longer. That is, when the shift stage switching time by the operation of the shift lever L is shorter than the predetermined time, it can be determined that the driving orientation of the driver is the sports mode driving orientation. On the contrary, when the shift speed of the shift stage by the operation of the shift lever L is longer than the predetermined time, it can be determined that the driver's travel orientation is the comfort mode travel orientation.

  More specifically, the shift operation direction position sensor 8D detects when the shift lever L is started and when the operation is completed, and calculates the period to thereby change the gear position by operating the shift lever L. The switching time is calculated. In addition, the predetermined time is appropriately set by experiment or the like.

  In this way, the driver's travel orientation can be determined based on the shift speed switching time by the operation of the shift lever L.

(S-6) The magnitude of the shift load When the operation speed of the shift lever L is high, the shift load becomes large. Conversely, when the operation speed of the shift lever L is low, the shift load becomes small. That is, when the shift load is larger than the predetermined value, it can be determined that the driving orientation of the driver is the sports mode driving orientation. On the contrary, when the shift load is smaller than the predetermined value, it can be determined that the driver's travel orientation is the comfort mode travel orientation. These predetermined values are appropriately set by experiments or the like.

  Specifically, the shift load is detected by the shift load sensor 8E.

  In this way, the driving orientation of the driver can be determined based on the magnitude of the shift load.

  In addition, you may make it determine a driving | running | working orientation of a driver | operator combining combining among the shift lever operation determination operation | movement of (S-1)-(S-6) mentioned above.

  For example, (S-1) combining the amount of change per unit time of the rotational speed of the input shaft IS with (S-4) the shift speed selected by operating the shift lever L can be mentioned. The operation for determining the driving orientation of the driver in this case will be described below.

  When the driver operates the shift lever L, it is easier to apply operating force when operating the shift lever L toward the rear (vehicle rear) than when operating the shift lever L toward the front (vehicle front). It is. That is, it is easier to apply the operation force to the pulling operation than to push the shift lever L, and the operation speed of the shift lever L is easily increased by the pulling operation. That is, the amount of change per unit time of the rotation speed of the input shaft IS tends to increase. In other words, even if the driver has the same travel orientation, there is a difference between the travel orientation determination on the pull operation side and the travel orientation determination on the push operation side.

  Taking this into account, the gear selected by the operation of the shift lever L (the gear selected when the gear shift is completed) is the push operation side, that is, the first gear, third gear, fifth gear, reverse In the case of any of the stages, the amount of change is corrected so that the amount of change is slightly larger than the amount of change per unit time of the actual rotational speed of the input shaft IS. As a result, the driver's driving orientation can be accurately determined by handling the amount of change in the same manner as when the pulling operation side, that is, any one of the second speed stage, the fourth speed stage, and the sixth speed stage is selected. To do.

  In addition, about the combination in the case of determining a driving | running | working orientation of a driver | operator combining several among the shift operation determination operation | movement of said (S-1)-(S-6), (S-1) and (S-) mentioned above. The combination is not limited to 4), and other combinations may be used, and the driving orientation of the driver may be determined by combining three or more.

  Further, execution conditions for such a shift lever operation determination operation include “the vehicle is in a warm-up completion state” and “the clutch device 6 is being operated”. The reason is that when the vehicle is not in the warm-up completed state, the viscosity of the lubricating oil inside the speed change mechanism is high, and the viscosity acts greatly as a resistance of the shift lever operation, and the driver's driving orientation is detected with high accuracy. For this reason, it is difficult for the vehicle to be warmed up. In addition, it is difficult to detect the driver's driving orientation with high accuracy even when the shifting operation is performed without operating the clutch device 6, so that the operation of the clutch device 6 is performed. This is an execution condition for the orientation determination operation.

<Clutch pedal operation determination operation>
Next, the clutch pedal operation determination operation (operation for determining the travel orientation by operating the clutch pedal 70) will be described. In this clutch pedal operation determination operation, the travel orientation is determined using at least one of the following information (operation information that changes according to the clutch operation).

(C-1) Clutch torque (= clutch stroke position at half clutch)
(C-2) Speed of change of clutch stroke position (C-3) Time to reach a predetermined clutch stroke Each of these will be specifically described below.

(C-1) Clutch torque (= clutch stroke position at half clutch)
Generally, the clutch torque (Tc) is obtained as the sum (Tc = Te + Iedωe / dt) of the engine torque (Te) and the inertia torque (Iedωe / dt). The inertia torque is a torque transmitted along with the reduction of the engine speed when the clutch device 6 is engaged. That is, when the engine torque is the same, the clutch torque increases as the inertia torque increases. For example, when the amount of depression of the accelerator pedal at the time of engagement of the clutch device 6 is large and the depression release speed of the clutch pedal 70 is high, the inertia torque per unit time increases, and as a result, the clutch torque also increases. Become. Such a situation is a case where the driver has an intention to connect the clutch device 6 early (in a short time). Therefore, when the clutch torque is higher than a predetermined value (when the clutch torque is larger than the predetermined value with respect to the engine torque), it can be determined that the driver's driving intention is the sports mode driving intention. On the other hand, when the clutch torque is lower than a predetermined value (when the clutch torque is smaller than the predetermined value with respect to the engine torque), it can be determined that the driving direction of the driver is the comfort mode driving direction. These predetermined values are appropriately set by experiments or the like.

  This clutch torque will be described with reference to FIG. The upper part of FIG. 8 shows an example of changes in the input shaft speed and the engine speed during the shifting operation from the first speed to the second speed, and the lower part of FIG. 8 shows the change in clutch torque in this case. An example is shown. The operation of the shift lever L is started from the first speed position 1st (see FIG. 4) toward the first speed-2 speed select position P1 at the timing t1 in the figure, and at the timing t2, the shift lever L is moved to the second speed position 2nd. It is being operated. In this way, the clutch device 6 is engaged with the input shaft rotational speed reaching the second gear synchronous speed, and the clutch device 6 is fully engaged at the timing t3, and the engine rotational speed is also the second. The high speed synchronous rotation speed has been reached.

  As a change in the clutch torque in this case, the inertia torque rises from the timing t2 when the engagement operation (clutch pedal depressing release operation) of the clutch device 6 is started, and the total value of the engine torque becomes the clutch torque. Become. The inertia torque increases as the maximum value of the clutch torque increases (see the one-dot chain line in the lower part of FIG. 8), and it is determined that the driving direction of the driver is the sports mode driving direction. Become.

  Note that this clutch torque matches the clutch torque capacity when the clutch device 6 is in the half-clutch state (a state where slippage occurs between the flywheel 62 and the clutch disc 64). That is, when there is a difference between the engine speed calculated based on the output signal from the crank position sensor 81 and the input shaft IS speed detected by the input speed sensor 8A. The clutch torque at that moment is obtained from the clutch stroke position detected by the clutch stroke sensor 8B (there is a correlation with the clutch torque capacity).

  In this way, the driving orientation of the driver can be determined based on the clutch torque.

  Various periods can be set as the clutch torque calculation period. For example, (a) the maximum or average value of the clutch torque at the beginning of clutch engagement start (for example, the period ta in the lower stage of FIG. 8), (b) in the middle period of clutch engagement (for example, the period tb in the lower stage of FIG. 8) The maximum value or average value of the clutch torque, (c) the maximum value or average value of the clutch torque immediately before the completion of clutch engagement (for example, the period tc in the lower stage of FIG. 8), and the like. In any of these periods, the greater the clutch torque (maximum value or average value), the more the driver's travel orientation is determined to be the sport mode travel orientation.

  In addition, the driver's travel orientation is determined from a plurality of pieces of information: (a) clutch torque at the beginning of clutch engagement, (b) clutch torque in the middle of clutch engagement, and (c) clutch torque immediately before completion of clutch engagement. May be determined.

(C-2) Changing speed of clutch stroke position The changing speed of the clutch stroke position is obtained from the time differential value (dclts / dt) of the operation movement amount (clts) of the clutch pedal 70. Specifically, it is obtained by time differentiation of the amount of movement of the clutch stroke detected by the clutch stroke sensor 8B. When the change speed of the clutch stroke position is higher than a predetermined value, it can be determined that the driving orientation of the driver is sports mode driving orientation. On the contrary, when the change speed of the clutch stroke position is lower than the predetermined value, it can be determined that the driving direction of the driver is the comfort mode driving direction. These predetermined values are appropriately set by experiments or the like.

  In this way, the driving orientation of the driver can be determined based on the changing speed of the clutch stroke position.

  Even when the driver's travel orientation is determined based on the change speed of the clutch stroke position, as in the case where the driver's travel orientation is determined based on the clutch torque described above, the calculation period of the change speed of the clutch stroke position is as follows: Various periods can be set. For example, (a) a change speed at the initial stage of clutch engagement, (b) a change speed in the middle of clutch engagement, (c) a change speed immediately before completion of clutch engagement, and the like.

  The changing speed of the clutch stroke position is not limited to the changing speed when the clutch device 6 is engaged (when the clutch pedal 70 is released), but when the clutch device 6 is released (when the clutch pedal 70 is pressed). Change rate). That is, the driving orientation of the driver may be determined based on the depressing operation speed of the clutch pedal 70.

(C-3) Time until the predetermined clutch stroke is reached When the operation speed of the clutch pedal 70 is high, the time required for the engagement of the clutch device 6 is short, and conversely, when the operation speed of the clutch pedal 70 is low. The time required for the engagement of the clutch device 6 becomes longer. That is, when the time until the predetermined clutch stroke is reached (for example, the time from disengagement to engagement of the clutch device 6) is shorter than a predetermined value, the driving orientation of the driver is the sports mode driving orientation. I can judge. On the other hand, when the time until the predetermined clutch stroke is reached is longer than the predetermined value, it can be determined that the driver's travel orientation is the comfort mode travel orientation. These predetermined values are appropriately set by experiments or the like.

  Specifically, the clutch stroke sensor 8B calculates a period from the start of operation of the clutch pedal to the completion of operation (clutch engagement).

  In this way, the driving orientation of the driver can be determined based on the time until the predetermined clutch stroke is reached.

  The time until the predetermined clutch stroke is reached is not limited to the time when the clutch device 6 is engaged (when the clutch pedal 70 is released), but the time when the clutch device 6 is released (when the clutch pedal 70 is depressed). Time of operation).

  Further, as the travel orientation determination operation, a plurality of the shift lever operation determination operations (S-1) to (S-6) and the clutch pedal operation determination operations (C-1) to (C-3) described above are combined. It may be.

  Further, the execution conditions of such a clutch pedal operation determination operation are “the vehicle is in a warm-up completed state”, “any gear stage is established in the transmission mechanism when the clutch device 6 is operated” Is mentioned. The reason for this is that when the vehicle is not in a warm-up completed state, the viscosity of the oil in the clutch master cylinder 71 and the clutch release cylinder 61 is high, and the viscosity acts greatly as a resistance for clutch pedal operation, so Is difficult to detect with high accuracy, and the vehicle is in a warm-up completion state is set as an execution condition of the travel orientation determination operation. Further, since it is difficult to determine the driver's travel orientation even if the clutch operation is performed in a state where the gear stage is not established, any one of the gear stages is established in the transmission mechanism when the clutch device 6 is operated. Is the execution condition of the travel orientation determination operation.

In addition, regardless of the shift lever operation determination operation and the clutch pedal operation determination operation described above, regardless of whether the travel orientation is determined, the condition for maintaining the travel orientation determination result may be any of the following.
(1) Until the next shift operation is executed (2) Until the vehicle stops (3) Until the ignition OFF operation is performed That is, until one of these operations is performed, the determination result of the driving orientation of the driver The information is stored in the RAM 93, and the travel-oriented determination result information is read from the RAM 93 as needed (when the driver's travel-oriented determination operation is started).

(Driving-oriented reflection operation)
Next, a description will be given of a travel orientation reflecting operation for controlling the vehicle that reflects the travel orientation of the driver determined by the travel orientation determining operation (shift lever operation determining operation or clutch pedal operation determining operation) described above.

  Specifically, at least one of the following operations (operation for changing the control amount for the control target of the vehicle) is executed as the travel-oriented reflection operation.

(A-1) Throttle opening characteristic adjustment operation (A-2) Tip-in and tip-out characteristic adjustment operation (A-3) Fuel cut-on and fuel cut-off characteristic adjustment operation (A-4) VDIM intervention timing adjustment operation ( A-5) Air Suspension Characteristic Adjustment Operation Each of these will be specifically described below.

(A-1) Throttle opening characteristic adjusting operation The throttle opening characteristic adjusting operation is an operation for adjusting the opening characteristic of the throttle valve 33 with respect to the depression amount of the accelerator pedal, reflecting the driver's travel orientation.

  Specifically, when the driver's driving orientation is sport mode driving orientation, the opening degree of the throttle valve 33 is set to be large with respect to the depression amount of the accelerator pedal (the smoothing rate with respect to the opening degree control of the throttle valve 33). Conversely, when the driver's driving orientation is the comfort mode driving orientation, the opening of the throttle valve 33 with respect to the depression amount of the accelerator pedal is set to be small (the opening control of the throttle valve 33). Set the annealing rate to a large value).

  FIG. 9 is a throttle opening degree map for determining the opening degree of the throttle valve 33 when the throttle opening characteristic adjusting operation is performed. The solid line in the figure indicates the normal throttle opening characteristic when the driver's travel orientation is neither the sport mode travel orientation nor the comfort mode travel orientation. When it is determined that the driver's driving orientation is the sports mode driving orientation, the characteristic is changed to a curve indicated by a broken line in the figure, and the opening of the throttle valve 33 with respect to the depression amount of the accelerator pedal is increased. Try to set. On the other hand, if it is determined that the driver's driving orientation is the comfort mode driving orientation, the characteristic is changed to the curve indicated by the alternate long and short dash line in the figure, and the opening of the throttle valve 33 with respect to the depression amount of the accelerator pedal is reduced. Set to. As a result, the acceleration performance of the vehicle when traveling in the sport mode is enhanced, and a comfortable riding comfort when traveling in the comfort mode can be realized.

(A-2) Tip-in / Chip-out characteristic adjustment operation Tip-in / Chip-out characteristic adjustment operation reflects the driver's driving orientation and when the chip-in occurs (when the accelerator pedal depression amount increases rapidly) This is an operation for adjusting the opening characteristic of the throttle valve 33 and the opening characteristic of the throttle valve 33 at the time of tip-out (when the amount of depression of the accelerator pedal is rapidly reduced).

  First, the chip-in characteristic adjustment operation will be described. When the driving orientation of the driver is sports mode driving orientation, the amount of change per unit time (the amount of change in the opening direction) of the opening degree of the throttle valve 33 at the time of tip-in is set to a large value (at the time of tip-in) The smoothing rate for the opening degree control of the throttle valve 33 is set small). On the other hand, when the driver's driving orientation is the comfort mode driving orientation, the amount of change per unit time (the amount of change in the opening direction) of the opening of the throttle valve 33 at the time of tip-in is set to be small (chip). The smoothing rate for the opening control of the throttle valve 33 at the time of in is set large).

  FIG. 10 is a timing chart showing changes in the opening degree of the throttle valve 33 when this tip-in characteristic adjustment operation is performed. The solid line in the figure shows the change in the throttle opening during normal tip-in when the driver's travel orientation is neither sport mode travel comfort nor comfort mode travel orientation. When it is determined that the driver's travel orientation is the sport mode travel orientation, the amount of change per unit time of the opening degree of the throttle valve 33 at the time of tip-in as shown by a broken line in the figure. Set to a larger value. On the other hand, when it is determined that the driving orientation of the driver is the comfort mode driving orientation, the change per unit time of the opening degree of the throttle valve 33 at the time of tip-in as shown by a dashed line in the figure. Set the amount smaller. Thereby, the responsiveness of the vehicle at the time of tip-in in the case of sport mode driving orientation is enhanced, and a comfortable ride at the time of tip-in in the case of comfort mode driving orientation can be realized.

  Next, the chip-out characteristic adjustment operation will be described. When the driver's driving orientation is sport mode driving orientation, the amount of change per unit time (the amount of change in the closing direction) of the opening degree of the throttle valve 33 at the time of tip-out is set to be large (at the time of tip-out) The smoothing rate for the opening degree control of the throttle valve 33 is set small). Conversely, when the driver's driving orientation is the comfort mode driving orientation, the amount of change per unit time of the opening of the throttle valve 33 at the time of tip-out (the amount of change in the closing direction) is set to be small (chip). The smoothing rate for the opening control of the throttle valve 33 at the time of out is set large).

  FIG. 11 is a timing chart showing changes in the opening degree of the throttle valve 33 when the tip-out characteristic adjustment operation is performed. The solid line in the figure shows the change in the throttle opening at the normal tip-out when the driver's travel orientation is neither the sport mode travel orientation nor the comfort mode travel orientation. When it is determined that the driver's travel orientation is the sport mode travel orientation, the amount of change per unit time of the opening degree of the throttle valve 33 at the time of tip-out as indicated by a broken line in the figure. Set to a larger value. On the other hand, when it is determined that the driving orientation of the driver is the comfort mode driving orientation, a change per unit time of the opening degree of the throttle valve 33 at the time of tip-out as shown by a dashed line in the figure. Set the amount smaller. Thereby, the responsiveness of the vehicle at the time of tip-out in the case of sport mode traveling orientation is enhanced, and a comfortable riding comfort at the time of tip-out in the case of comfort mode traveling orientation can be realized.

(A-3) Fuel cut-on and fuel cut-off characteristics adjustment operation The fuel cut-on and fuel cut-off characteristic adjustment operations are performed by the driver during the fuel cut operation that is executed when the accelerator pedal is fully closed. Reflecting and adjusting the engine torque characteristics at the time of fuel cut-on (when stopping fuel injection from the injector 35) and the engine torque characteristics at the time of fuel cut-off (when restarting fuel injection from the injector 35) It is.

  First, the fuel cut-on characteristic adjustment operation will be described. When the driver's driving orientation is sport mode driving orientation, the engine torque characteristics at the time of fuel cut-on are that the fuel is cut quickly (fuel injection is stopped) by rapidly reducing the torque (engine torque control). Set the annealing rate to a small value). Conversely, when the driver's driving orientation is comfort mode driving orientation, the engine torque characteristics during fuel cut-on are that the torque decrease is moderated and the fuel cut is delayed (the smoothing rate for engine torque control is Set larger).

  FIG. 12 is a timing chart showing changes in engine torque when the fuel cut-on characteristic adjustment operation is performed. The solid line in the figure shows the engine torque characteristic at the time of normal fuel cut-on when the driver's driving intention is neither the sport mode driving intention nor the comfort mode driving intention. If it is determined that the driver's driving orientation is sport mode driving orientation, as shown by a broken line in the figure, the amount of change per unit time of the engine torque at the time of fuel cut-on is set larger. . On the other hand, if it is determined that the driver's driving orientation is comfort mode driving orientation, as shown by the dashed line in the figure, the amount of change per unit time of engine torque at fuel cut-on is set to be small To do.

  More specifically, after the fuel cut condition (F / C condition) is satisfied, the engine torque is lowered by gradually retarding the ignition timing of the spark plug 2, and the engine torque reaches a predetermined value. Stop fuel injection at this point. In this case, if it is determined that the driving orientation of the driver is the sports mode driving orientation, the ignition delay amount per unit time is set large, the engine torque is reduced early, and the fuel injection is also accelerated. To stop. On the other hand, if it is determined that the driver's driving orientation is the comfort mode driving orientation, the ignition delay amount per unit time is set to a small value, and the decrease in engine torque is delayed to delay the stop of fuel injection. I will let you.

  Thereby, the responsiveness of the vehicle at the time of fuel cut-on when it is oriented to sport mode travel is enhanced, and a comfortable ride at the time of fuel cut-on when it is oriented to comfort mode travel can be realized.

  Next, the fuel cutoff characteristic adjustment operation will be described. When the driver's travel orientation is sport mode travel orientation, the torque is rapidly increased as the engine torque characteristic at the time of fuel cutoff. Conversely, when the driver's driving orientation is the comfort mode driving orientation, the increase in torque is moderated as the engine torque characteristic at the time of fuel cut-off.

  FIG. 13 is a timing chart showing changes in engine torque when the fuel cutoff characteristic adjusting operation is performed. The solid line in the figure shows the engine torque characteristic at the time of normal fuel cut-off when the driver's driving orientation is neither the sport mode driving orientation nor the comfort mode driving orientation. If it is determined that the driver's driving orientation is sport mode driving orientation, as shown by the broken line in the figure, the amount of change per unit time of the engine torque at the time of fuel cutoff is set to be large. . On the other hand, if the driver's driving orientation is determined to be comfort mode driving orientation, as shown by the alternate long and short dash line in the figure, the change amount per unit time of the engine torque at the time of fuel cutoff is set to be small To do.

  More specifically, after the fuel cut cancellation condition (F / C cancellation condition) is established, the fuel injection is resumed and the ignition timing of the spark plug 2 is gradually advanced to increase the engine torque. The target engine torque corresponding to the amount of depression of the accelerator pedal is obtained. In this case, when it is determined that the driving orientation of the driver is the sports mode driving orientation, the ignition advance amount per unit time is set large, and the engine torque is increased early. On the other hand, if it is determined that the driving orientation of the driver is the comfort mode driving orientation, the ignition advance amount per unit time is set small to delay the increase in engine torque.

  Thereby, the responsiveness of the vehicle at the time of fuel cut-off when it is oriented to sport mode driving is enhanced, and a comfortable ride at the time of fuel cut-off when it is oriented to comfort mode driving can be realized.

(A-4) VDIM Intervention Timing Adjustment Operation The VDIM intervention timing adjustment operation is an operation for adjusting the above-described VDIM control intervention timing, reflecting the driver's travel orientation.

  Specifically, when the driving orientation of the driver is the sports mode driving orientation, the intervention timing of the VDIM control is set late, and conversely, when the driving orientation of the driver is the comfort mode driving orientation, The intervention timing of VDIM control is set early.

  FIG. 14 is a diagram showing a VDIM intervention timing map for setting the intervention timing of VDIM control according to the driving orientation. According to this map, when the driving orientation of the driver is the sports mode driving orientation, the higher the orientation is, the slower the intervention timing of the VDIM control is set. Conversely, when the driver's travel orientation is the comfort mode travel orientation, the higher the orientation is, the earlier the intervention timing of VDIM control is set. Thus, in the case of sports mode driving orientation, the vehicle control corresponding to the driver's operation (accelerator pedal or steering operation) is continuously performed for a relatively long time, whereas the comfort mode driving orientation is intended. In this case, vehicle control that can obtain traveling stability at an early stage is executed.

(A-5) Air Suspension Characteristic Adjustment Operation The air suspension characteristic adjustment operation is an operation for adjusting the damping characteristic in the air suspension system 100 described above, reflecting the driver's travel orientation.

  Specifically, when the driving orientation of the driver is a sports mode driving orientation, the damping force in the air suspension system 100 is set high so that a driving state in which steering stability is emphasized is obtained. On the other hand, when the driving orientation of the driver is the comfort mode driving orientation, the damping force in the air suspension system 100 is set to be low so that a driving state in which a comfortable riding comfort is emphasized is obtained.

-Procedure for driving-oriented reflection control-
Next, a control procedure for actually executing the travel-oriented reflection control described above will be described. Here, the case where the driving orientation of the driver is determined by the shift lever operation determination operation and the vehicle driving state is controlled as the first embodiment, and the driving orientation of the driver is determined by the clutch pedal operation determination operation. A case where the running state is controlled will be described as a second embodiment.

(First embodiment)
The first embodiment employs a determination operation based on the amount of change (dNi / dt) per unit time of the rotational speed of the input shaft IS as the shift lever operation determination operation, and a throttle opening characteristic adjustment operation as a travel-oriented reflection operation A case where the VDIM intervention timing adjustment operation is employed will be described.

  FIG. 15 is a flowchart showing the procedure of the control operation in the first embodiment. This flowchart is executed every several milliseconds after the ignition switch is turned on.

  First, in step ST1, it is determined whether or not a speed change operation has been started. Specifically, it is determined whether or not the operation of the clutch device 6 is performed and the operation of the shift lever L is started. Whether or not the clutch device 6 has been operated is determined based on an output signal from the clutch stroke sensor 8B. Whether or not the operation of the shift lever L has been started is determined based on the output signal from the shift operation direction position sensor 8D. Alternatively, the shift start may be determined only by either the clutch operation or the shift lever operation.

  If the speed change operation has not been started and NO is determined in step ST1, the routine returns without executing the travel orientation reflecting operation.

  On the other hand, when the speed change operation is started and YES is determined in step ST1, the process proceeds to step ST2, and it is determined whether or not the vehicle has been warmed up. The reason for making this determination is as described above. If the vehicle has not been warmed up and the determination in step ST2 is NO, the routine returns without executing the travel orientation reflecting operation.

  On the other hand, if the vehicle has been warmed up and the determination in step ST2 is YES, the process proceeds to step ST3, where the absolute value of the change amount (dNi / dt) per unit time of the rotational speed of the input shaft IS is calculated. It is determined whether or not it is less than a predetermined threshold value α1. That is, it is determined whether or not the manual operation speed of the shift lever L is relatively low. The absolute value is used here in order to enable determination whether the speed change operation is an upshift operation or a downshift operation.

  If the absolute value of the amount of change (dNi / dt) in the rotational speed of the input shaft IS per unit time is less than the predetermined threshold value α1, and YES is determined in step ST3, the process proceeds to step ST4 and the driver's travel It is determined that the orientation is the comfort mode travel orientation, the information is stored in the RAM 93, and the process proceeds to step ST5.

In step ST5, the throttle opening characteristic is set to the comfort mode. That is, the opening degree of the throttle valve 33 with respect to the depression amount of the accelerator pedal is set to be small (see the characteristic indicated by the one-dot chain line in FIG. 9). Also, the VDIM intervention timing is set to the comfort mode. That is, the intervention timing of VDIM control is set early .

  On the other hand, when the absolute value of the change amount (dNi / dt) per unit time of the rotational speed of the input shaft IS is equal to or greater than the predetermined threshold value α1 and NO is determined in step ST3, the process proceeds to step ST6. It is determined whether or not the absolute value of the change amount (dNi / dt) per unit time of the rotational speed of the shaft IS exceeds a predetermined threshold value α2. That is, it is determined whether or not the manual operation speed of the shift lever L is relatively high. This threshold value α2 is larger than the threshold value α1 by a predetermined amount. The reason why the absolute value is used here is to enable determination whether the speed change operation is an upshift operation or a downshift operation.

  If the absolute value of the amount of change (dNi / dt) per unit time of the rotational speed of the input shaft IS exceeds the predetermined threshold value α2, if YES is determined in step ST6, the process proceeds to step ST7, where the driver's It is determined that the travel orientation is the sport mode travel orientation, the information is stored in the RAM 93, and the process proceeds to step ST8.

In step ST8, the throttle opening characteristic is set to the sport mode. That is, the opening degree of the throttle valve 33 with respect to the depression amount of the accelerator pedal is set to be large (see the characteristic indicated by the broken line in FIG. 9). Also, the VDIM intervention timing is set to the sport mode. That is, the intervention timing of VDIM control is set late .

  On the other hand, when the absolute value of the change amount (dNi / dt) per unit time of the rotational speed of the input shaft IS is equal to or less than the predetermined threshold value α2 and NO is determined in step ST6, the driving orientation of the driver is It is determined that neither the sport mode driving orientation nor the comfort mode driving orientation is desired, and the process returns as it is.

  The above operation is executed every time a speed change operation is started, and the throttle opening characteristic and the VDIM control intervention timing are set in accordance with the driver's travel orientation.

(Second Embodiment)
The second embodiment employs a determination operation based on the clutch torque and the clutch operation speed (clutch stroke position changing speed) as the clutch pedal operation determination operation, and the throttle opening characteristic adjustment operation and the VDIM intervention timing as the travel orientation reflecting operation. A case where the adjustment operation is employed will be described.

  FIG. 16 is a flowchart showing the procedure of the control operation in the second embodiment. In this flowchart, the same step numbers are assigned to the same operations as those in the flowchart (FIG. 15) shown in the first embodiment. The flowchart in this embodiment is also executed every several milliseconds after the ignition switch is turned on.

  First, when both the determination operation in step ST1 (determination operation for determining whether or not the shifting operation has been started) and the determination operation in step ST2 (determination operation for determining whether or not the vehicle has been warmed up) are both determined YES Then, the process proceeds to step ST10, in which it is determined whether or not any gear stage is currently established in the transmission mechanism. If the shift stage is not established and NO is determined in step ST10, the process returns without executing the travel orientation reflecting operation.

  On the other hand, if the gear position is established and the determination in step ST10 is YES, the process proceeds to step ST3 ′, and whether the clutch torque is less than a predetermined threshold β1 and the clutch operation speed is less than a predetermined threshold γ1. Determine whether or not. That is, it is determined whether or not the operation speed of the clutch pedal 70 is relatively low.

  If the clutch torque is less than the predetermined threshold value β1 and the clutch operating speed is less than the predetermined threshold value γ1, and YES is determined in step ST3 ′, the process proceeds to step ST4, and the driving orientation of the driver is the comfort mode driving. The information is determined to be intentional, the information is stored in the RAM 93, and the process proceeds to step ST5. The operation in step ST5 is the same as that in the first embodiment described above.

  On the other hand, if NO is determined in step ST3 ′, the process proceeds to step ST6 ′ to determine whether or not the clutch torque exceeds a predetermined threshold β2 and the clutch operation speed exceeds a predetermined threshold γ2. . That is, it is determined whether or not the operation speed of the clutch pedal 70 is relatively high. The threshold value β2 is larger than the threshold value β1 by a predetermined amount, and the threshold value γ2 is larger than the threshold value γ1 by a predetermined amount.

  If the clutch torque exceeds the predetermined threshold β2 and the clutch operation speed exceeds the predetermined threshold γ2, and YES is determined in step ST6 ′, the process proceeds to step ST7, and the driving orientation of the driver is determined to be the sports mode. It is determined that the vehicle is traveling-oriented, the information is stored in the RAM 93, and the process proceeds to step ST8. The operation in step ST8 is the same as that in the first embodiment described above.

  On the other hand, if NO is determined in step ST6 ', it is determined that the driver's travel orientation is neither the sport mode travel orientation nor the comfort mode travel orientation, and the routine returns.

  The above operation is executed every time a speed change operation is started, and the throttle opening characteristic and the VDIM control intervention timing are set in accordance with the driver's travel orientation.

  As described above, in the present embodiment, it is determined whether the driving direction of the driver is the sports mode driving direction or the comfort mode driving direction based on information obtained from the driver's speed change operation or clutch operation. (See the shift lever operation determination operations (S-1) to (S-6) and the clutch pedal operation determination operations (C-1) to (C-3)), and control of the vehicle according to the determination result. The state is changed (see the travel-oriented reflection operation (A-1) to (A-5)). Thereby, the traveling state of the vehicle according to the driving orientation of the driver can be realized, and the merchantability of the vehicle equipped with the manual transmission MT can be improved.

-Other embodiments-
In the embodiment described above, the case where the driving orientation of the driver is determined by the shift lever operation determination operation or the clutch pedal operation determination operation has been described. However, such a shift lever operation determination operation and the clutch pedal operation determination operation are not performed. It can also be used as an index for determining the driving skill of a person. That is, the driving skill of the driver is determined by the shift lever operation determination operation or the clutch pedal operation determination operation, and the control operation (driving skill reflection operation) similar to the above-described driving orientation reflection operation is performed according to the determination result. It is also possible to do so.

  Furthermore, the shift lever operation determination operation and the clutch pedal operation determination operation can be used as an index for determining the degree of fatigue of the driver. That is, the driver's fatigue level is determined by the shift lever operation determination operation and the clutch pedal operation determination operation, and the control operation (fatigue level reflection operation) similar to the above-described travel orientation reflection operation is performed according to the determination result. It is also possible to do. Moreover, you may make it perform alerting | reporting which encourages a driver | operator as this fatigue degree reflecting operation.

In the above embodiment, the select operation direction position sensors 8C and shifting direction position sensor 8D is provided as a means for detecting an operation position of the shift lever L. Not limited to being this, it may be arranged a shift position sensor for each gear position.

  Further, in the above-described embodiment, the case where the present invention is applied to a vehicle mounted on an FR type vehicle and equipped with a synchronous mesh type manual transmission with six forward speeds and one reverse speed is described. The present invention is not limited to this, and can also be applied to a manual transmission mounted on other types of vehicles such as FF (front engine / front drive) vehicles. Further, the present invention can be applied to a transmission having a different number of stages from the above (for example, a forward fifth speed stage).

  In the above embodiment, the case where the present invention is applied to a vehicle equipped with the gasoline engine 1 as a drive source has been described. The present invention is not limited to this, and can also be applied to a vehicle equipped with a diesel engine or a hybrid vehicle equipped with an engine (internal combustion engine) and an electric motor (for example, a traveling motor or a motor generator).

  The present invention can be applied to a control device that is mounted on a vehicle equipped with a manual transmission and controls the vehicle according to the operation speed of the clutch pedal and the operation speed of the shift lever.

1 Engine 34 Throttle motor 6 Clutch device 81 Crank position sensor 88 Accelerator opening sensor 8A Input rotation speed sensor 8B Clutch stroke sensor 8C Select operation direction position sensor 8D Shift operation direction position sensor 8E Shift load sensor 9 Engine ECU
100 Air suspension system 200 VDIMECU
MT manual transmission IS input shaft (input shaft of manual transmission)
L Shift lever

Claims (1)

Manual transmission either of the plurality of shift speeds by shifting operation is made selectable by the driver,及Beauty, a clutch device for performing engagement and disengagement between the drive source and the manual transmission by a clutch operation of the driver In a vehicle control device comprising:
The driver of the clutches operation the driver of the traveling-oriented based on the operation information which changes according to, to determine the degree of fatigue of the proficiency level driver's operation of the driver, the determination to the travel-oriented, the operation Control means for performing control to change the control amount for the control target of the vehicle according to the skill level or the fatigue level,
The control means determines the driver's driving orientation, the driver's driving skill or the driver's fatigue level based on the change speed of the clutch stroke position at the time of clutch depression , and determines the intervention timing of the VDIM control, It is changed according to the driving orientation of the driver, the driving skill of the driver or the fatigue level of the driver , and when the change speed of the clutch stroke position is higher than a predetermined value , the vehicle control for the driving operation is performed . the response performance is judged to be high it is sought while setting slow intervention timing of VDIM control, when the change speed of the clutch stroke position is lower than a predetermined value, the vehicle control for the driving operation it is determined that the response performance is low is demanded, this being configured to set earlier intervention timing of VDIM control Control apparatus for a vehicle according to claim.

Images