Methods and systems are provided for reducing emissions and improving fuel economy for vehicles participating in car-sharing models. In one example, a method comprises while a vehicle is stationary with an engine deactivated, actively raising a temperature of an exhaust catalyst positioned in an exhaust system of the engine to maintain the temperature of the exhaust catalyst above a threshold temperature until a subsequent request for engine torque to propel the vehicle is requested. In this way, cold-starts of engines for vehicles participating in car-sharing models may occur less frequently, and accordingly release of undesired emissions to the environment may be reduced.

A controller for a hybrid vehicle restarts an engine in a start mode selected from multiple start modes. The multiple start modes include a first start mode of starting combustion in the engine when a clutch starts transmitting torque and a second start mode of starting combustion in the engine after the clutch starts transmitting torque. The controller is configured to, in a case in which the engine is restarted in the second start mode, measure a cranking start time from when engagement of the clutch is commanded to when transmission of the torque through the clutch is started, and only when measurement of the cranking start time has been completed after the vehicle is activated, restart the engine in the first start mode.

Methods, apparatus and systems for reducing engine idling of fuel-driven equipment, for example found on a wellsite and/or including hydraulic pumping systems are provided. In particular, systems and methods are provided for controlling the starting and shutdown of equipment powered by a fuel-driven engine, the system comprising of an energy accumulator comprising or consisting of one or more supercapacitors. The transmission, transmission fluid, or other components can be warmed to prolong time between engine restarts.

An apparatus includes a route circuit and a stop-start circuit. The route circuit is structured to estimate a number of charging locations for an energy storage system of a vehicle for a planned route. The stop-start circuit is structured to determine a stop-start strategy for an engine of the vehicle based on the estimated number of charging locations and expected charges to be received by the energy storage system. The stop-start strategy defines a frequency and duration of using the engine in an on-mode during operation of the vehicle along the planned route. The stop-start circuit is further structured to determine that the energy storage system fails to receive an expected charge at one of the charging locations, and update the stop-start strategy to compensate for failing to receive the expected charge by increasing use of the engine in the on-mode during operation of the vehicle along the planned route.

A flexible intelligent electrical switching device with multi-function capability, and methods of use are presented herein which provide an autonomous, reconfigurable switching device. The present disclosure is specifically designed to reduce space, cost of manufacture, efficiency, installation reduction time and ease of implementation.

A method of controlling a mild hybrid electric vehicle may include determining whether a Smart Cruise Control (SCC) mode is set according to a signal input through a driver interface; determining whether an Start Stop Control (SSC) entrance condition is satisfied when the SCC mode is set; when the SSC entrance condition is determined by the control unit, to be satisfied to enter an SSC mode, interrupting a supply of fuel to an engine and turning off the engine; monitoring a distance in which the control unit determines whether a distance to a front vehicle is increased or decreased based on a front distance signal transmitted from a detecting unit electrically-connected to the control unit; and increasing or decreasing a vehicle speed by controlling the engine, a Mild Hybrid Starter Generator (MHSG), or an Electronic Stability Control (ESC) based on the monitoring of the distance.

A method for operating a hybrid motor vehicle. In one example, the vehicle comprises an internal combustion engine (10) and at least one electric motor (20). As long as at least one parameter of an exhaust gas aftertreatment system (12) of the internal combustion engine (10) lies outside a given range, the starting of the internal combustion engine (10) is delayed and the internal combustion engine (10) is dragged by the electric motor (20). At the same time at least one measure is carried out which changes the parameter.

Methods and systems for operating an engine with an electrically heated catalyst and an electrically driven compressor are described. In one example, the electrically driven compressor and the electrically heated catalyst are activated before an engine start so that vehicle emissions may be reduced more efficiently at engine starting and thereafter.

A method actuates a starter of an internal combustion engine by way of a starter relay. The starter relay is configured to supply the starter optionally with current via an on-board electrical system. The method has the following steps: determining an error status of the internal combustion engine; commencing repeated actuations of the starter relay; determining a current status of the internal combustion engine, wherein the current status of the internal combustion engine displays at least one error status or at least one operating status; and, if the current status displays at least one operating status, ending the repeated actuation of the starter relay, otherwise once again determining the current status. A system for actuating a starter of an internal combustion engine includes a control device, a power source, a starter relay, connected to the control device and configured to supply the starter of the internal combustion engine optionally with current from the power source via an on-board electrical system, wherein the control device is configured to carry out the method.

A control device comprising an electric power supply control part controlling a supply of electric power to a rotary electrical machine so as to use the output electric power of a second battery to make up for insufficient output electric power of a first battery when driving a vehicle by just drive power of the rotary electrical machine and a startup preparation starting part starting a supply of electric power to the catalyst device to start preparation for startup of the internal combustion engine if driving a vehicle by just drive power of the rotary electrical machine and the state of charge of the second battery becomes less than the state of charge for preparation for startup. The startup preparation starting part is configured to increase the state of charge for preparation for startup when the maximum output electric power of the first battery calculated based on the state of the first battery is small compared to if it is large.