A system for controlling the climate of a cab of an autonomously operable machine when operated unmanned, and related machine. The system includes at least one temperature sensor to generate a signal indicative of the temperature within the cab and a controller configured to receive the signal as well as determine if the machine is being operated unmanned. If the machine is being operated unmanned, the controller is further configured to generate machine control commands to turn on the cab cooling device or cab heating device and adjust a blower as needed to maintain the cab temperature above the minimum and/or below the maximum temperature thresholds.

A heating device for heating fluids, such as water or a liquid coolant, for application in electric or hybrid vehicles, where the absence of an internal combustion engine or its shorter time of use requires using heating devices for heating either the passenger compartment or other parts of the vehicle that require it. The heating device is provided with a configuration which limits the temperature to the temperature at which heat exchange occurs between the heat generation source and the liquid to be heated, such that the liquid does not generate precipitates, prolonging the service life of the device.

A method of controlling a vehicle climate system having a plurality of zones, wherein the plurality of zones includes a primary zone for a driver of the vehicle and one or more secondary zones for one or more passengers of the vehicle, the method including determining whether one or more of the plurality of zones is occupied by a person, receiving data indicative of a target temperature of each of the occupied zones, receiving data indicative of a target temperature in the primary zone, determining when one or more of the occupied zones becomes unoccupied, and adjusting the target temperature of one or more of the unoccupied zones to an adjusted target temperature. The adjusted target temperature is a function of the target temperature in the primary zone.

The present disclosure provides a multi-stage method to extend the range of a vehicle. The method includes taking progressive actions on a vehicle as the state of charge (SOC) drops below defined levels. The method may include monitoring the SOC of the vehicle in relation to a SOC threshold or monitoring the SOC of the vehicle in relation to the distance remaining to a predetermined destination.

A processor associated with a vehicle receives sensor data from a plurality of sensors associated with a vehicle, where each sensor generates data corresponding to a different parameter of a passenger in the vehicle. Based on the sensor data, one or more primitive emotional indications are generated. The processor applies a model to the one or more primitive emotional indications that when applied outputs a contextualized emotional indication associated with the passenger that includes an assessment of an emotional state of the passenger and a reason for the emotional state. A contextual response is selected based on the contextualized emotional indication, and the processor causes an output by the vehicle to enact the contextual response.

A method, system, and apparatus are provided for optimizing control of the rotational speed of a fan in a vehicle so as to reduce the aerodynamic drag of a vehicle in a given operating parameter, and accordingly, to improve fuel efficiency of operation of the vehicle. Certain exemplary embodiments include determining an optimized speed of rotation of a cooling fan of the vehicle for reducing overall fuel demand in given operating conditions, and controlling rotation speed of the fan at the optimized speed in order to minimize fueling demand of a prime mover of the vehicle.

The present embodiments relate to selection and execution of one or more output actions relating to a modification of at least one feature of a vehicle. A series of sensors on a vehicle can acquire data that can be used to identify vehicle environment characteristics indicative of a status of a vehicle environment and an emotional state of the user. The vehicle environment characteristics and the emotional state can be processed using a user model that corresponds to a user to generate one or more selected output actions. The output actions can be executed on the vehicle to increase user experience. The output actions can relate to any of entertainment features, safety features, and/or comfort features of the vehicle.

The present application provides a control method for a vehicle air conditioner, including: performing remote control in advance, wherein performing remote control in advance includes performing remote timing control in advance. Performing remote timing control in advance includes starting the air conditioner t0 minutes before the vehicle is started, so as to perform pre-cooling or pre-heating, wherein t0 is a constant. Compared with a vehicle air conditioner in the prior art, the vehicle air conditioner in the present application performs, by a configured step of performing remote control in advance, pre-cooling or pre-heating before the vehicle is started, so as to control an interior temperature of the vehicle in advance, such that when a user enters the vehicle, a comfortable ambient temperature is provided, thereby providing a comfortable ambient for a vehicle owner and a passenger.

The invention relates to a thermal management system for a motor vehicle passenger compartment, the system comprising a processing unit arranged to: determine two terms that make up a thermal comfort index (TCI) value related to the passenger in the passenger compartment, one of the terms being a stationary term (TCIs) which is representative of the heat exchanges needed to keep the passenger in a state of stabilized thermal comfort, in particular obtained using a thermo-physiological model, in particular using the data representing (MET) the metabolic activity of the passenger. the other term being a dynamic term (TCId) representing one or more local and transitory imbalances of the thermal comfort state of the passenger, which are the result of: either a recent thermal stress experienced by the passenger, or a thermal stimulus intended to achieve a pleasant temporary sensation of heat or cold.

Systems and methods for providing load shedding in a vehicle are provided. Particularly, the vehicle may be an electric vehicle and the loads that are shed may be HVAC or refrigeration loads. The load shedding methods and systems may include a predictive model of energy consumption, determining a predicted energy consumption and comparing it to a stored energy at the vehicle. If the predicted energy consumption exceeds the stored energy, load shedding operations may be performed at a transport climate control system, such as adjusting a set point, adjusting an operating mode of the transport climate control system, increasing a dead band of a compressor of the transport climate control system, utilizing free cooling such as ambient air to provide climate control in the vehicle, or increasing cooling provided by the transport climate control system to an energy storage of the vehicle.