An electrified vehicle includes a passenger cabin, an electrically powered heating device configured to heat airflow for conditioning the passenger cabin, and a controller configured to selectively command actuation of the electrically powered heating device based on a target discharge air temperature, an actual discharge air temperature, and an amount of power available.

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.

An air conditioner for a vehicle includes a cooling water circuit and a heater. The cooling water circuit allows a cooling water to circulate between an engine and a heater core in a heating operation. The engine is a power source of the vehicle. The heater core is configured to heat air using a heat of the cooling water. The heater is located downstream of the engine and upstream of the heater core in the cooling water circuit and is configured to heat the cooling water.

An air-conditioner for a vehicle includes: a first circuit in which a cooling medium circulates; a heater heating the cooling medium; a first pump disposed in the first circuit; a second circuit cooling a heat emitting portion; a second pump disposed in the second circuit; an adjustment portion controlling a circulation amount of the cooling medium flowing in the first circuit and a circulation amount of the cooling medium flowing in the second circuit; and a control portion. The vehicle includes a regenerative device, and a storage device is charged with electric energy recovered by the regenerative device. When the regenerative device is recovering the electric energy and when it is determined that power in the storage device needs to be consumed, the control portion drives the heater to heat the cooling medium such that the power in the storage device is converted into heat energy.

The invention relates to a high-voltage vehicle heater (10), comprising a control device (12), comprising an electrical heating element (14) which is intended for heating a heating medium (16), and comprising a first data interface (18) by means of which a heating request signal can be received, said heating request signal representing an external heating request, wherein the control device (12) determines a first data set which represents at least one first electrical power with which the electrical heating element is to be operated in order to meet the external heating request, wherein the control device (12) determines, on the basis of a parameter data set, a second data set which represents at least one second electrical power which can be supplied to the electrical heating element (14) in addition to the first electrical power, without there being a risk of the vehicle heater (10) being damaged.

A heating, ventilation and air conditioning (HVAC) system for an electric vehicle, may include a heating line on which an electric heater and a heating pump are provided; a first heating line connected to the heating line through a main valve, provided with a heater core for indoor heating, and having cooling water flow therethrough to form a first heating channel along with the heating line; a second heating line having one end portion connected to one end portion of the heating line through the main valve and the other end portion connected to the other end portion of the heating line, and having the cooling water flow therethrough to form a second heating channel along with the heating line; and a controller configured for controlling an opening degree of the main valve to control the flow of cooling water of the first heating channel or the second heating channel.

An electrified vehicle includes a passenger cabin, an electrically powered heating device configured to heat airflow for conditioning the passenger cabin, and a controller configured to selectively command actuation of the electrically powered heating device based on a target discharge air temperature, an actual discharge air temperature, and an amount of power available.

A method of efficiently heating a passenger cabin of a vehicle includes heating a first fluid using a fluid heater. The first fluid flows through a thermal storage element to transfer thermal energy to the thermal storage element. The heating of the first fluid and the thermal storage element occurs during a recharging of a rechargeable power source used to power the vehicle. During operation of the vehicle and following discontinuation of the recharging of the rechargeable power source, the thermal energy stored to the thermal storage element is transferred to air to be distributed to the passenger cabin of the vehicle by flowing the first fluid through a first heat exchanger in thermal communication with the air to be distributed to the passenger cabin of the vehicle, thereby extending a range of the vehicle.

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 method of efficiently heating a passenger cabin of a vehicle includes heating a first fluid using a fluid heater. The first fluid flows through a thermal storage element to transfer thermal energy to the thermal storage element. The heating of the first fluid and the thermal storage element occurs during a recharging of a rechargeable power source used to power the vehicle. During operation of the vehicle and following discontinuation of the recharging of the rechargeable power source, the thermal energy stored to the thermal storage element is transferred to air to be distributed to the passenger cabin of the vehicle by flowing the first fluid through a first heat exchanger in thermal communication with the air to be distributed to the passenger cabin of the vehicle, thereby extending a range of the vehicle.