Methods and systems are provided for improving the operating range of an electric vehicle having an engine wherein waste heat generated during motor operation is transferred to pre-heat the engine. Engine starting is predicted based on the electrical torque demand of the vehicle relative to the actual and predicted electrical energy consumption of the electric vehicle. Prior to starting the engine to charge a battery of the motor, various engine components are pre-heated in an order that improves vehicle range while also optimizing fuel economy.

A transport vehicle for containers, in particular a floor-bound and driverless heavy-load transport vehicle for ISO containers, has a platform for receiving at least one container to be transported, with the platform being delimited by guide elements for guiding a container when being deposited on the platform, and includes a drive unit and a battery module for supplying electric energy to the drive unit. The battery module has a support frame and a battery, with there being at least one air conditioner device arranged in the support frame together with the battery.

A battery system for an electric vehicle includes a first battery module with a first heater and a second battery module with a second heater. The battery system also includes a control system configured to selectively activate the first or the second heater to dissipate energy from the first or the second battery module.

A vehicle floor structure is provided including: a vehicle interior opening formation section provided inside a vehicle cabin, and demarcating a vehicle interior opening that opens into the vehicle cabin; a vehicle exterior opening formation section provided further toward a vehicle lower side than a floor inside the vehicle cabin, and demarcating a vehicle exterior opening that opens toward a vehicle exterior; a storage section provided at the vehicle lower side of the floor, and demarcating a storage space that connects the vehicle interior opening and the vehicle exterior opening together; and a pull-out receptacle disposed inside the storage section at a position corresponding to the vehicle interior opening, and capable of moving from inside the storage section to the vehicle exterior through the vehicle exterior opening.

A vehicle management method is provided for managing an electric vehicle by using a management server based on vehicle-specific ID information that defines a condition of use transmitted from an onboard controller. The vehicle management method includes acquiring vehicle ID information from the electric vehicle by using the management server; determining the vehicle ID information to be valid if the vehicle ID information acquired falls within a use period set in advance and determining the vehicle ID information to be invalid if the vehicle ID information acquired falls outside a use period set in advance; and applying a prescribed limitation to charging of a battery of the electric vehicle having the vehicle ID information upon determining that the vehicle ID information is invalid.

A vehicle having: a power storage system; a main thermoregulation circuit that is configured to distribute a thermoregulation liquid within the power storage system; a thermoregulation system that is arranged in a front position, and is configured to cause the thermoregulation liquid to circulate in the main thermoregulation circuit; at least one component that is arranged in a rear position behind; and a secondary thermoregulation circuit that is arranged in a rear position and is coupled to the component. The main thermoregulation circuit has: a drawing point that goes through the rear wall of the power storage system and supplies the thermoregulation liquid to the secondary thermoregulation circuit; and a return point that goes through the rear wall of the power storage system and receives the thermoregulation liquid from the secondary thermoregulation circuit.

A system includes heat generating components in a vehicle and a coolant flow path connected to the heat generating components. The system includes a coolant pump that circulates coolant through the coolant flow path and a reversing mechanism that reverses a direction of circulation of coolant.

A system and method for controlling heating of at least one of an engine and a battery in a hybrid vehicle includes at least one heater and at least one system controller. The system controller receives a command signal and generates a heater control signal based on the command signal. The heater is in the hybrid vehicle and is electrically coupled to an electrical port integrated in the hybrid vehicle. The electrical port receives electric power from a power source external to the hybrid vehicle. In addition, the system includes a heater switch. The heater switch receives the heater control signal to control an amount of energy transferred from the electrical port to the heater and the heater selectively heats at least one of the engine and the battery in the hybrid vehicle.

A method of operating an electric vehicle having a battery system with a first battery module and a second battery module includes sending a triggering signal. And, in response to the triggering signal, selectively dissipating energy from the first battery module without dissipating energy from the second battery module.

Disclosed are joint active thermal management (ATM) systems for electric-drive vehicles, control logic for operating such ATM systems, and electric-drive vehicles equipped with a joint ATM system for heating/cooling the powertrain's drive unit (DU) section, power electronics (PE) section, and rechargeable energy storage system (RESS) section. A disclosed active thermal management system includes a first coolant loop with fluid conduits fluidly connecting a first electronic heat exchanger and a first pump with the DU and PE sections. The ATM system also includes a second coolant loop with fluid conduits fluidly connecting a second electronic heat exchanger and a second pump with the RESS section. A coolant-to-coolant heat exchanger, which is fluidly connected to the first and second coolant loops, is operable to selectively transfer heat between the coolant fluid circulating in the first set of fluid conduits and the coolant fluid circulating in the second set of fluid conduits.