An assembly includes an appliance configured for use within a recreational vehicle, an electrical sensor configured to produce a slide out detection signal in response to electrical activation of a slide out control circuit of the recreational vehicle, and an automated shutoff controller in electrical communication with the electrical sensor and the appliance, the automated shutoff controller being configured to shut off at least one component of the appliance in response to receipt of the slide out detection signal from the electrical sensor.

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.

A controller controls an air-conditioning device so that air of the air-conditioning device is supplied to a cabin based on a warm-up state of air of the air-conditioning device. When remote air conditioning is performed, the controller controls the air-conditioning device so that air of the air-conditioning device is supplied to the cabin even in a state where the warm-up state is lower than in a case where air of the air-conditioning device is supplied to the cabin of the vehicle in the operation air conditioning. In a manner described above, a vehicle capable of suppressing power loss and lengthening of charging time in heating during the remote air conditioning and the preliminary air conditioning is provided.

A heat generating system for a motor vehicle includes a carbon nanotube heating element and a controller. The controller is configured to activate the carbon nanotube heating element in response to a wireless activation signal received from a remote communication device. A related method of heating a passenger compartment of a motor vehicle is also disclosed.

An auxiliary heater with a casing enclosing internal components which components include a heat exchanger separate from and outside the coolant tank and wherein two coolant loops each have their own coolant pumps and wherein a potable water loop exchanges heat with coolant within the heat exchanger. A control circuit provides enhanced coolant flow through the heat exchanger when the call for hot water is significant without significantly reducing the temperature of the hot water being used. A level switch within the coolant tank prevents coolant pumps from running without pump coolant and a filling and air purging operation improves the initial filling operation of the auxiliary heater with coolant and also prevents the coolant pump from running dry. A user switch may dedicate the hot coolant from the coolant tank to either the production of hot potable water or it may share both hot water and space heating.

A method is provided for operating a fuel-operated vehicle heater (10) during a start phase of combustion operation. The heater includes a combustion air feed device (26) feeding air and a fuel feed device (22) feeding fuel (B) to a burner area (12) with a combustion chamber (16). An electrically energizable ignition element (32) ignites a fuel/air mixture formed. The method includes energizing the ignition element (32) in a preheating phase prior to the fuel feed, at a time of entry into an ignition phase, detecting electrical resistance of the ignition element (32) and determining a desired resistance based on the electrical resistance of the ignition element (32) detected and operating the ignition element (32) in a resistance-regulating operating mode during the ignition phase such that an actual resistance of the ignition element (32) is in the range of the determined desired resistance of the ignition element (32).

A vehicular heat management system includes a refrigerant circulation line configured to generate hot energy or cold energy depending on a flow direction of a refrigerant, a heater core side coolant circulation line configured to transfer refrigerant heat generated in the refrigerant circulation line to a heater core to heat a passenger compartment, and a battery side coolant circulation line configured to receive coolant heat of the heater core side coolant circulation line via a coolant and then circulate the coolant through a battery to preheat the battery.