Provided is a thermal control system of an electric vehicle including a powertrain thermal architecture, a cabin heating layout, a battery thermal architecture, and a cabin cooling layout. Also provided is a method of operation of a thermal control system for an electric vehicle. Also provided is a method of operation of a heating, ventilation, and air conditioning (HVAC) system for an electric vehicle having an electric motor and an inverter.

Provided is a thermal control system of an electric vehicle including a powertrain thermal architecture, a cabin heating layout, a battery thermal architecture, and a cabin cooling layout. Also provided is a method of operation of a thermal control system for an electric vehicle. Also provided is a method of operation of a heating, ventilation, and air conditioning (HVAC) system for an electric vehicle having an electric motor and an inverter.

A utility vehicle is provided, comprising a plurality of ground engaging members. A frame is supported by the plurality of ground engaging members, and the frame comprises a first frame portion extending generally rearwardly and upwardly from a front portion of the frame, a second frame portion extending generally rearwardly and downwardly from the first frame portion, and a third frame portion extending rearwardly from the second frame portion. An electric powertrain is supported by the frame, and the electric powertrain comprises a first motor longitudinally aligned with at least a portion of the first frame portion and a second motor longitudinally aligned with at least a portion of the third frame portion. The electric powertrain also includes a battery operably coupled to each of the first motor and the second motor, and the battery is longitudinally aligned with at least a portion of the second frame portion.

A utility vehicle is provided, comprising a plurality of ground engaging members. A frame is supported by the plurality of ground engaging members, and the frame comprises a first frame portion extending generally rearwardly and upwardly from a front portion of the frame, a second frame portion extending generally rearwardly and downwardly from the first frame portion, and a third frame portion extending rearwardly from the second frame portion. An electric powertrain is supported by the frame, and the electric powertrain comprises a first motor longitudinally aligned with at least a portion of the first frame portion and a second motor longitudinally aligned with at least a portion of the third frame portion. The electric powertrain also includes a battery operably coupled to each of the first motor and the second motor, and the battery is longitudinally aligned with at least a portion of the second frame portion.

In an aspect of the present disclosure is a system for in-flight re-routing of an electric aircraft including a battery pack configured to provide electrical power to the electric aircraft; a sensor configured to detect at least a temperature metric of the battery pack and generate a temperature datum based on the at least a temperature metric; a controller communicatively connected to the sensor, the controller configured to: receive the temperature datum from the sensor; and re-route the electric aircraft based on the temperature datum.

In an aspect of the present disclosure is a system for in-flight re-routing of an electric aircraft including a battery pack configured to provide electrical power to the electric aircraft; a sensor configured to detect at least a temperature metric of the battery pack and generate a temperature datum based on the at least a temperature metric; a controller communicatively connected to the sensor, the controller configured to: receive the temperature datum from the sensor; and re-route the electric aircraft based on the temperature datum.

The present subject matter relates generally to a driver assistance system and method for a vehicle. The driver assistance system includes a vehicle having a plurality of sensors, a telematics unit to communicate vehicle level data to the surroundings of the vehicle, a display device to display the vehicle level data, a server, and a smart device. The smart device communicates with the server on a first network and with the display device on a second network. The vehicle, the server, and the smart device communicates through each other via communication network. The invention is based on smart device interface with different communication devices to provide the user with real time vehicle, environmental data, and user related data.

The present subject matter relates generally to a driver assistance system and method for a vehicle. The driver assistance system includes a vehicle having a plurality of sensors, a telematics unit to communicate vehicle level data to the surroundings of the vehicle, a display device to display the vehicle level data, a server, and a smart device. The smart device communicates with the server on a first network and with the display device on a second network. The vehicle, the server, and the smart device communicates through each other via communication network. The invention is based on smart device interface with different communication devices to provide the user with real time vehicle, environmental data, and user related data.

A method for controlling power transfer from a grid to a rechargeable energy storage system, RESS, and/or an auxiliary load of the vehicle, via at least one intermediate power transfer component. The method comprises providing predicted operational information of the vehicle, the predicted operational information comprising a connected time period in which the vehicle is connected to the grid, providing component data comprising power transfer characteristic of the intermediate power transfer component, the component data including at least the critical temperature limit of the intermediate power transfer component, transferring power from the grid to the RESS and/or from the grid to the auxiliary load of the vehicle according to a power transfer model, such that the temperature of the intermediate power transfer component is kept at least below the critical temperature limit.

A mobile charging station for a high voltage electric vehicle including a mobile vehicle for transporting charging apparatus. The charging apparatus includes an electric energy source for providing electricity, a circuit for converting the energy source electricity to a specific voltage range required by the electric vehicle to be charged and at least one connector engageable with a charging connector on the electric vehicle to be charged. The mobile charging station may be driven to the location of the electric vehicle. A vehicle charge may be initiated by a communication sent from a cellular device or a mobile communication device. The mobile charging station may include a remote command center capable of receiving communication from a consumer and remotely initiating a service call to the consumer or an automatic battery health and safety check system to ensure the battery is not leaking, or over heated to prevent vehicle fire.