A control device for a vehicle includes: a coasting control unit configured to, during normal traveling at a low speed within a predetermined range, cause a vehicle to travel through inertia by blocking power transmission between an engine and driving wheels by disengaging a power transmitting/blocking device that includes a first engaging portion connected to the engine and a second engaging portion connected to the driving wheels, and by stopping the engine; and a return control unit configured not to full-engage the power transmitting/blocking device while the engine is cranking by a motor in a case of returning from coasting traveling to normal traveling and to full-engage the power transmitting/blocking device after the motor stops.

A vehicle control device turns off a clutch to put a vehicle into an inertia operation state in response to a predetermined executing condition being met, and turns on the clutch to terminate the inertia operation state in response to a predetermined terminating condition being met during the inertia operation. The vehicle control device includes a deceleration degree calculating device, a determination device, and an operation control device. The deceleration degree calculating device calculates an actual deceleration degree. The determination device determines whether the actual deceleration degree is greater than a threshold value defined on the basis of a deceleration degree of the vehicle in an accelerator-off and clutch-on state. The operation control device terminates or maintains the inertia operation depending on a condition of the actual deceleration degree.

A vehicle control device includes control means for executing coasting control, in which a friction engaging element is disengaged and a rotation speed of a rotary shaft of a drive source is set at zero, when a shift range corresponds to a travel range and a coasting condition is established, and the control means executes the coasting control when the shift range is modified to a neutral range.

A controller including an electronic control unit, the electronic control unit executes slip control of a clutch when a specified termination condition is established during execution of coasting control and an acceleration request is made through an operation of an accelerating operation member even when engagement of the clutch is prohibited. Thus, power from an engine can be transmitted to drive wheels while a load imposed on the engine is suppressed.

A vehicle control system configured to carry out an energy saving control is provided. The vehicle control system is applied to a vehicle having an engine, a torque converter, a transmission and a clutch device selectively connecting a turbine runner to the transmission. The vehicle control system executes the energy saving control by controlling both an operating condition of the engine and an engagement condition of the clutch device or only the engagement condition of the clutch device. The vehicle control system comprises a clutch control means configured to increase the torque transmitting capacity of the clutch device using an increasing amount of a speed of the turbine runner as a target value, when bringing the clutch device into engagement being in disengagement during execution of the energy saving control.

The disclosure relates to a method for operating a motor vehicle that includes a drive unit, an output unit, and a clutch arranged between the drive unit and the output unit and configured to transmit a torque. A detection unit detects an operating state of the drive unit. When the operating state of the drive unit is in an overrun mode, a control unit controls a clutch slip, which results in adjustment of the torque that can be transmitted as a function of a speed of the motor vehicle. The disclosure further relates to a device for operating a motor vehicle, and to a motor vehicle that includes such a device.

The present disclosure relates to a clutch control apparatus, and more particularly, to a clutch control apparatus that achieves miniaturization of machinery and reduces an operational error by using a non-contact type displacement detection system using a position detecting sensor for a clutch clearance, and regulates the operation of an actuator using a plurality of solenoid valves, as a result, allowing accurate position control of a pneumatic cylinder which operates the clutch, thereby improving fuel efficiency and achieving fuel reduction as well as reducing emissions of carbon dioxide.

A running control system for vehicles is provided to reduce engagement shocks of a clutch and to raise the torque of drive wheels quickly upon satisfaction of a condition of engagement of the clutch. In a vehicle to which the running control system is applied, power transmission between an engine and the drive wheels is selectively enabled by the clutch. The running control system is configured to raise a speed of the engine from an idling speed if the clutch is expected to be engaged during coasting where the clutch is in disengagement to interrupt a torque transmission between the engine and the drive wheels.

A method for operating a transmission device for a motor vehicle, wherein the transmission device has an automatic clutch and a manual transmission. During one operation of the transmission device, the clutch is closed before a driving gear is engaged at the manual transmission if, when the clutch is at least partially open, actuation of the manual transmission is identified.

The invention relates to a method for operating a functional element (1) which can be driven by a main drive (2) via a slip clutch (3) and/or by an auxiliary drive (4) which is coupled to the clutch (3), comprising the following method steps: determining the efficiency curve (.sub.K) of the clutch (3); determining the efficiency curve (.sub.HA) of the auxiliary drive (4); superimposing the efficiency curves (.sub.K, .sub.HA); deriving an operating zone diagram (7) from the physical limits (n.sub.E, n.sub.Kmax, n.sub.HAmax, n.sub.I, G.sub.IK) of the clutch (3) and the auxiliary drive (4); and optimizing the interplay of clutch (3) and auxiliary drive (4) determined by the superimposition of the efficiency curves (.sub.K, .sub.HA) with respect to an optimized overall efficiency curve (.sub.opt) of the auxiliary drive (4) and the clutch (3) and/or a minimized heat generation of the clutch (3).