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.

A method of controlling an air conditioning system for a vehicle enables a user to recognize whether economical heating is available, while a vehicle travels. The method includes: (A) when starting of the vehicle is in an on state, confirming a heating condition and a waste heat source state while the vehicle travels, and predicting power consumption of an electric heater; and (B) comparing a power consumption reference value of the electric heater with a power consumption prediction value of the electric heater, displaying that economical heating is available or unavailable on the display unit, determining whether to turn off the starting of the vehicle, and terminating a control.

A method of controlling an air conditioning system for a vehicle is provided. The method includes setting a scheduled heating and performing charging of the battery and the scheduled heating. A desire target temperature (DTT) of a user is then received and a discharge temperature of air supplied into the vehicle is compared with the DTT to adjust revolutions per minute (RPM) of a compressor. When the RPM of the compressor is adjusted the RPM of the compressor is determined based on whether the discharge temperature is the same as the DTT, and whether to operate the electric heater is determined.

A method of controlling an air conditioning system for a vehicle enables a user to recognize whether economical heating is available, while a vehicle travels. The method includes: (A) when starting of the vehicle is in an on state, confirming a heating condition and a waste heat source state while the vehicle travels, and predicting power consumption of an electric heater; and (B) comparing a power consumption reference value of the electric heater with a power consumption prediction value of the electric heater, displaying that economical heating is available or unavailable on the display unit, determining whether to turn off the starting of the vehicle, and terminating a control.

A method for displaying the status of a heating or air conditioning device of a vehicle wherein a graphical object that depicts the vehicle is displayed by a display device of the vehicle, the status of the heating or air conditioning device is detected, and different statuses of the heating or air conditioning device are displayed by the display device by different depictions of vehicle surfaces. Also disclosed is a heating or air conditioning device for performing the method.

This vehicle air-conditioning system is provided with a preliminary operation control means which activates preliminary operation equipment in response to a planned-boarding signal. The preliminary operation control means provides preparatory control which precedes basic control. An air-flow switching control means drives a blower motor for just a prescribed short time period, and stops the blower motor. An air-outlet switching control means sets an air outlet in a position other than a face blowing position, and stands by. A compressor control means drives a compressor for just a prescribed short time period, and stops the compressor. An electric-heater control means allows the passage of current to an electric heater for 10 minutes, and subsequently stops the passage of current to the electric heater.

An auxiliary heating system for motor vehicles driven by electric motors and a method for realizing an auxiliary heating function in a motor vehicle having an electric drivetrain.

A heater system for preheating a vehicle and method of operating the same, wherein the method of operation is dependent upon the temperature of the coolant fluid in the vehicle coolant system.

An auxiliary heating system for a vehicle interacts with an ignition controller having a Run state in which an engine of the vehicle is running and an Off state in which the engine is not running. An auxiliary heater has a Parking mode for heating a passenger cabin of the vehicle when the ignition controller is in the Off state. An auxiliary heater controller has a user-configurable setting for selectably entering the Parking mode when the ignition controller enters the Off state. A manual interface is responsive to a user to provide user commands to the auxiliary heater controller including setting commands during the Run state for determining the user-configurable setting and a cancel command during the Off state for terminating the Parking mode.

A vehicular heat management system including a heater for carrying out heating of a heat medium and stop the heating, and a heat exchanger configured to carry out heat exchange between lubricant oil for lubricating a speed change apparatus and the heat medium. A heat medium circulator is provided that is configured to switch the heat medium circulation state between a first circulation state where the heat medium circulates through the heater and the heat exchanger, and a second circulation state where the heat medium circulates through the heater and a heater core. An electronic control unit is also provided.