A system and method for controlling air conditioning and ISG systems for a vehicle are provided. The system includes a heater controller that detects a defrost mode selection signal or an A/C blower operation signal and transmits the signal to a cluster controller. The cluster controller then transmits the defrost mode selection signal or the A/C blower operation signal to an engine ECU. The engine ECU determines ISG entry prevention or ISG release after ISG entry in response to receiving the defrost mode selection signal or the A/C blower operation signal from the cluster controller.

Examples of the present disclosure relate to systems and methods for providing cooling and/or heating in a vehicle. For example, the systems and methods may cool and/or heat a vehicle cabin while the vehicle’s engine is not idling or otherwise in operation, without consuming excessive power stored by a vehicle battery. In example implementations, thermoelectric cooling cells may be used.

A windshield defogging system and method are provided. The system includes a heated windshield with an electrical heating element, an air circulation system with a blower to provide a stream of air over a surface of the windshield and a controller configured to select a duty cycle for the heating element based upon air circulation system operating parameters and environmental conditions such as ambient temperature.

A method for operating a fuel-operated vehicle heater, wherein after receipt of a switch-off signal by a control unit of the fuel-operated vehicle heater, a shutdown phase is initiated, during which remaining fuel present in the fuel-operated vehicle heater is combusted, and wherein a restart phase is initiated by the control unit after receipt of a switch-on signal during the shutdown phase, without the shutdown phase being terminated after complete combustion of the remaining fuel.

A vehicle heating device includes a heat storage material, a heat recovery unit, a footrest, and a heat controller. The vehicle heating device heats an occupant with heat stored in the heat storage material. The heat recovery unit recovers thermal energy from at least one of a heat source generated by a vehicle or a natural heat source from outside of the vehicle. The heat storage material stores the recovered thermal energy. The footrest is provided at a front portion of a vehicle seat disposed in a vehicle cabin, and has the heat storage material packed inside a heat insulating material. The heat controller heats the footrest by radiating the heat stored in the heat storage material at a predetermined timing with respect to the occupant to be on the vehicle.

The air-conditioning control device is configured to control an air conditioner for a vehicle having a radiant heater and to output a cancel signal that allows an engine, which has been stopped in response to an idling stop control, to restart. The radiant heater is configured to generate radiant heat to heat an occupant in a compartment of the vehicle. The air conditioner is configured to heat an interior of the compartment using engine cooling water. The air-conditioning control device stops the engine in response to the idling stop control. The air-conditioning control device outputs a cancel signal allowing the engine to restart following the engine having been stopped such that an idling stop time is longer when the radiant heater is operated than when the radiant heater is not operated.

A vehicle climate control system includes a heat exchanger to heat ambient air using engine waste heat, and a plurality of positive temperature coefficient (PTC) heating elements to heat air passed through the heat exchanger. The vehicle also includes a controller programmed to, while the vehicle is driven without engine propulsion, issue a command to sequentially de-energize the PTC heating elements before an upcoming engine activation. The sequential de-energization of the PTC heating elements is performed according to a schedule that is based upon a power surge dissipation time.

A heater unit emits radiation heat caused by heat generated with a heat generation unit when energized. The heater device includes a contact detection unit having a contact detection region overlying the heater unit to detect a contact by an object on the contact detection region. The heater device includes a determination unit to determine, when a contact by the object on the contact detection region is detected by the contact detection unit, whether the contact is for a predetermined switching operation. A control unit stops energization of the heat generation unit when the determination unit determines that the contact is not for the predetermined switching operation. The control unit switches between a start and a stop of energization of the heat generation unit when the determination unit determines that the contact is for the switching operation.

A method and device for mitigating environmental-control load for a hybrid vehicle are disclosed. In operation, a determination is made as to whether a hybrid vehicle is at a high-power operational mode. When the hybrid vehicle is at a high-power operational mode, a determination of an estimated time-of-travel to a low-power operational mode is made based on vehicle trajectory plan data. Heat-load buffer data is generated based on the estimated time to prolong a passenger comfort setting during the low-power operational mode.

A method for heating the passenger compartment of an electric vehicle, including the following steps: pre-heating at least one part of the passenger compartment by at least one electric heater when the vehicle is connected to an external energy source, and heating the at least one part of the passenger compartment by a combustion heater when the vehicle is in use. Also provided is a system implementing such a method and an electric vehicle, in particular of the electric bus type, utilizing such a method or such a system.