A method of controlling a temperature altering element within a seating assembly of a vehicle comprising: presenting a vehicle including a seating assembly including a temperature altering element, a controller in communication with the temperature altering element, the controller including a Pre-established Predictive Activation Model setting forth rules governing the activation of the temperature altering element as a function of data relating to Certain Identifiable Conditions, and a user interface configured to allow the temperature altering element to be manually activated or deactivated; occupying the seating assembly with a first occupant; collecting data relating to the Certain Identifiable Conditions while the first occupant is occupying the seating assembly; determining, by comparing the collected data to the rules of the Pre-established Predictive Activation Model, whether the collected data satisfies the rules of the Pre-established Predictive Activation Model so as to activate the temperature altering element; and activating the temperature altering element.

Systems are disclosed for providing a work vehicle with a mounted auxiliary power source. The control system of the auxiliary power source may be connected to a communication network of the work vehicle to receive data from various systems of the work vehicle and control and power various systems of the work vehicle.

A vehicle and a network system are provided to operate the air conditioning apparatus of the vehicle when a passenger within the vehicle is left unattended. The vehicle transmits a signal via a vehicle network to rescue the rear passenger, thereby ensuring passenger safety. The vehicle includes an output device and a communicator configured to communicate with a user terminal, an air conditioner, a sensor. The sensor obtains a movement of the passenger and a controller outputs an identification image through the output device when a movement signal of the passenger exceeds a reference signal after the vehicle doors are closed.

A method for operating a temperature control fan integrated in an air guiding system, the method includes steps of: determining a current volume flow generated by a flow generator of the temperature-control fan within a detection region, and then adjusting at least one operating parameter of the temperature-control fan according to the determined current volume flow within the detection region.

A method of providing thermal conditioning for a vehicle occupant according to an example of the present disclosure includes determining a respective target temperature for each of a plurality of discrete OPZs. Each OPZ is associated with a different occupant body area. The determining is based on a difference between a first OTS indicative of a target heat flux for the occupant and a second OTS indicative of an estimated heat flux experienced by the occupant, wherein the respective target temperatures differ between the OPZs. The method includes providing thermal conditioning in each OPZ based on the target temperature for the OPZ, which includes utilizing at least one thermal effector in the OPZ. The method also includes receiving a temperature offset value for a particular one of the OPZs from the occupant, and adjusting the target temperature for the particular one of the OPZs based on the temperature offset value.

Systems and methods are disclosed for supporting and executing automated control of climate comfort settings based on user classification within a group identity database. Methods of generating and employing the group identity database are also disclosed.

A ratio between a flow rate of a refrigerant flowing in an air conditioning heat exchanger of an air conditioner of which a blowout port mode is a face mode and a flow rate of a refrigerant flowing in a battery cooling heat exchanger is determined based on a battery temperature. As a result, depending on the battery temperature, air conditioning can be prioritized over battery cooling, and comfort of an occupant can be ensured. On the other hand, the flow rate of the refrigerant flowing in the battery cooling heat exchanger is larger than the flow rate of the refrigerant flowing in the air conditioning heat exchanger of the air conditioner of which the blowout port mode is a mode other than the face mode. As a result, the battery cooling can be prioritized and deterioration of a battery can be suppressed.

A system for determining an identification of an occupant within a vehicle can include a processor, a communications interface, and a memory. The memory can store an information reception module, an identification prediction module, and an actuation module. The information reception module can cause the processor to receive, via the communications interface, from at least one sensor, and at a time when a source of a propulsion force for the vehicle is in an off state, at least one signal having information about at least one detectable characteristic associated with the occupant within the vehicle. The identification prediction module can cause the processor to produce, based on the information, a prediction of the identification of the occupant. The actuation module can cause the processor to cause, in response to a production of the prediction, a setting of a component of the vehicle to have a specific value.

An air conditioning unit for a recreational vehicle including a first heater and a second heater, and configured to initiate a heating operation including analyzing an interior temperature and an exterior temperature, determine an operating mode of the air conditioning unit, and controlling the first heater and the second heater according to the determined operation mode.

Please substitute the new Abstract submitted herewith for the original Abstract: An air-conditioning system for an electrically driveable motor vehicle includes a coolant-conducting HVA circuit to which a traction battery and an evaporator for cooling the traction battery are connected, a coolant-conducting heating circuit for controlling the temperature of an interior compartment of the motor vehicle, to which heating circuit a condenser for releasing thermal power is connected, a coolant-conducting refrigeration circuit, to which the evaporator, the condenser and a compressor are connected, a heat exchanger, which is connected to the HVA circuit and which is controllably connectable to the heating circuit and which is configured for coolant-based transfer of thermal power from the heating circuit into the HVA circuit, and a control device.