A powertrain system for a vehicle is described, and includes an internal combustion engine that is selectively coupled to a driveline. The engine is configured to operate in a coasting mode, wherein the coasting mode includes operating the powertrain system with the engine in an OFF state and decoupled from the driveline. Devices are configured to monitor an output torque request, vehicle speed, and vehicle operating conditions. An executable instruction set monitors the vehicle speed and the output torque request. The engine is controlled to operate in the coasting mode when the output torque request is within the predetermined torque region and the vehicle speed is greater than a minimum speed threshold. The engine is controlled to discontinue operating in the coasting mode in response to the output torque request being outside the torque region of the vehicle speed being less than a minimum speed threshold.

A method for operating a drive device for a motor vehicle. The drive device has an internal combustion engine, an output shaft, and a clutch connected between the internal combustion engine and the output shaft. In a coasting operating mode, an idling speed control of the internal combustion engine to an idling speed is carried out and the clutch is opened, and, in an overrun operating mode, the clutch is closed. When shifting from the coasting operating mode to the overrun operating mode, while, at the same time, carrying out the idling speed control of the internal combustion engine to the idling speed, the clutch is closed, so that an entrainment of the internal combustion engine occurs.

A method of and an apparatus for controlling MHSG of a mild hybrid electric vehicle may include: detecting data for controlling the MHSG; determining whether an entry condition of coasting is satisfied based on the data; releasing a shift clutch of a transmission when the entry condition of coasting is satisfied; determining whether a release condition of coasting is satisfied in a state in which the mild hybrid electric vehicle is coasting; determining a target speed of an engine when the release condition of coasting is satisfied; and controlling the MHSG such that a speed of the engine increases to the target speed.

A sailing stop control method for a vehicle including a transmission and a friction engaging element in series between an engine and drive wheels includes performing a sailing stop control to coast by shutting off power transmission by the friction engaging element, stopping the engine based on satisfaction of a sailing enter condition, restarting the engine upon satisfaction of a sailing exit condition during coasting by the sailing stop control, executing a shift control to set a target speed ratio of the transmission to a highest speed ratio smaller than a coasting speed ratio in normal time and satisfying engine exhaust performance after the restart of the engine if the sailing exit condition is a brake pedal depressing operation, and re-engaging the friction engaging element, if input and output revolution speeds of the friction engaging element are determined to be a synchronous revolution speed after end of the shift control.

The present invention relates to a vehicle (1) having a torque generating machine (4); and one or more driven wheel (W.sub.D). A driveline (6) is provided for transmitting torque from the torque generating machine (4) to said one or more driven wheel. The driveline (6) includes a torque transmitting means (8). A first decoupling mechanism (11) is operable to decouple the torque transmitting means (8) from the torque generating machine (4). The first decoupling mechanism (11) is closed to couple the torque transmitting means (8) to the torque generating machine (4) and is opened to decouple the torque transmitting means (8) from the torque generating machine (4). A second decoupling mechanism (12) is operable to decouple the torque transmitting means (8) from the one or more driven wheel. The second decoupling mechanism (12) is closed to couple the torque transmitting means (8) to the one or more driven wheel and is opened to decouple the torque transmitting means (8) from the one or more driven wheel. A controller (2) is provided having at least one electronic processor for controlling operation of the first and second decoupling mechanisms (11, 12). The at least one electronic processor (P) is configured to close the second decoupling mechanism (12) to couple the torque transmitting means (8) to the one or more driven wheel, determine a target operating speed of the torque generating machine (4), control an operating speed of the torque generating machine (4) in dependence on the determined target operating speed and close the first decoupling mechanism (11) when the operating speed of the torque generating machine (4) at least substantially matches the determined target operating speed. The present invention also relates to a corresponding method of controlling first and second decoupling mechanisms (11, 12) to control the transmittal of torque from a torque generating machine (4) to one or more driven wheel of a vehicle (1).

Provided is a novel control apparatus for a vehicle which allows the number of stops and restarts to be reduced while performing engine stop and coasting control. The configuration is such that, when there is a high probability of restarting an engine under circumstances where engine stop and coasting control is performed, the engine is maintained in idling operation while only the clutch is disengaged. For example, if it is determined that there is a high probability of restarting due to a change in the acceleration of a host vehicle or a preceding vehicle, the clutch is disengaged and the vehicle is coasted. Since the engine is maintained in an idle state, there is no need for restarting, and the number of restarts can be minimized.

A control method for a mild type hybrid electric vehicle is provided. The method determining whether a coasting condition is satisfied and initiating coasting when the coasting condition is satisfied. A reacceleration intention is then detected and a torque of a mild hybrid starter & generator (MHSG) is increased in response thereto. A revolutions per minute (RPM) of the MHSG is compared with a RPM of an engine an engagement of the MHSG with the engine is attempted when the RPM of the MHSG corresponds to the RPM of the engine. The RPM of the MHSG is then synchronized with the RPM of the engine. When the MHSG is successfully engaged with the engine, the torque of the MHSG is increased to inject a fuel to the engine.

Provided herein is a method of disconnecting and connecting elements of a tandem axle system (100) drivingly connected to an engine (206) and transmission (204) of a vehicle, the method including the steps of: providing a tandem axle system (100) having: an inter-axle differential and clutch assembly (102) in driving engagement with the engine, wherein the inter-axle differential and clutch assembly includes an inter-axle differential (108) and an inter-axle differential lock (110); a forward axle assembly (104) including a differential assembly (116), a disconnect assembly (114) and two axle half shafts (104a, 104b); and a rear axle assembly (106) including a differential assembly (120), a disconnect assembly (122) and two axle half shafts (106a, 106b); providing a control system (300) in communication with the inter-axle differential lock, the disconnect assemblies and the engine; detecting (402) a disconnect opportunity; commanding (404) the engine torque set to zero; disconnecting (406) the axle half shafts of the forward and rear axle assemblies; engaging (408) the inter-axle differential lock; and allowing (410) the engine to idle.

A method (300) and control arrangement (210) for controlling a vehicle (100) to freewheel with engine off. The vehicle (100) has an engine (260) for propelling the vehicle (100) and a hydraulic power steering system (400). The hydraulic power steering system (400) comprises a primary power steering pump (270a) arranged to be driven by the engine (260) and a secondary power steering pump (270b). The method (300) includes: determining (301) when to start freewheeling the vehicle (100) with its engine off; and prior to starting the freewheeling of the vehicle (100) with engine off, determining (302) to start the secondary power steering pump (270b).

A method for inertia drive control is provided. The method includes performing advanced inertia drive control by an inertia drive controller. The controller detects a speed reduction event during road driving of a vehicle, lane division together with road type division for a road, and performs inertia drive control guide and the inertia drive control based on drive conditions of lane change and lane maintenance.