A vehicle battery management apparatus and a method thereof are provided. The vehicle battery management apparatus includes a battery that supplies power to a vehicle, a cooling device that cools the battery and a controller that monitors a state of the battery during parking and controls the cooling device to cool the battery with a cooling level corresponding to the state of the battery.

Systems and methods are provided for vehicle processing component cooling. A vehicle may include a compartment, a computing system including one or more processing components located within the compartment, and a cooling system configured to cool the one or more processing components. The cooling system may include a heat exchanger defining a plurality of flow channels. Each flow channel may be defined by an outlet and may be configured to provide cooling fluid. Operation of the processing components may heat the surrounding cabin air within the compartment through an air cooling operation. The cabin air from within the compartment may be directed through the heat exchanger to cool the cooling fluid. The compartment may be a trunk of the vehicle, and the heat exchanger may be located within the trunk and near the processing components.

A vehicle heat transfer system includes a flow through heat exchanger, a surface heat exchanger, at least a first vehicle component, and a controller that is operable to selectively transfer heat to or from the first vehicle component with either or both of the flow through heat exchanger and the surface heat exchanger based on one or more operating conditions. In a further aspect, a vehicle heat transfer system includes, a vehicle component positioned on a vehicle that is heated or cooled by a fluid, and a surface heat exchanger positioned on the vehicle, the surface heat exchanger having an inlet that receives the fluid used to heat or cool the vehicle component, an outlet that returns the fluid to heat or cool the vehicle component, and a closed fluid path extending between the inlet and the outlet.

A vehicle heat pump system is provided. The system includes a battery coolant line connected to a battery module and into which a coolant flows. A cooling device includes a radiator and a first water pump connected to a coolant line, to circulate a coolant in the coolant line to cool electrical equipment, and to be selectively connected to the battery coolant line via a first valve. A chiller is disposed in the battery coolant line, to be connected to a refrigerant line of an air conditioner via a connecting line, and to adjust a temperature of a coolant or a refrigerant by selectively exchanging heat between the coolant and refrigerant flowing into the chiller. An integrated control valve is connected to the refrigerant line and the connecting line to adjust a refrigerant flow direction and to selectively expand a refrigerant passing through the inside of the integrated control valve.

An in-vehicle-cabin storage device includes an exhaust device having a duct, and the duct provides communication between the inside of a storage part and the outside of a vehicle cabin. When the atmospheric pressure inside the storage part is higher than the atmospheric pressure outside the vehicle cabin, the exhaust device secures ventilation from the inside of the storage part to the outside of the vehicle cabin.

A system for cooling a mobile device within a vehicle is provided. The system includes mounting structure within the vehicle cabin, which can be a portion of the center console. The HVAC system of the vehicle provides forced air to the mobile device when the mobile device is mounted to the mounting structure. The system may include a supplemental passageway in which forced air will be provided toward a supplemental air outlet disposed adjacent the mounting structure. The mounting structure may include a movable flap that is biased to a closed position that blocks the flow of air out of the supplemental air outlet, and that moves to open the supplemental air outlet in response to mounting the mobile device. The mounting structure may include nubs on a base surface to space the device away from the base surface and allow air to flow around the mobile device.

An in-vehicle computer includes a computer casing, an electronic component, a fan, and an air duct. The electronic component and the fan are disposed inside the computer casing. An air inlet of the air duct is located outside the computer casing, and an air outlet thereof is toward or connected to the fan. The fan can generate an airflow for dissipating heat from the electronic component. Therein, the computer casing, the fan, and the air duct therefore form a heat dissipating system. A vehicle includes a vehicle cage and the in-vehicle computer. The in-vehicle computer is disposed inside the vehicle cage. The air inlet of the air duct communicates with the interior space of the vehicle cage, so that when the air conditioner of the vehicle is turned on, the fan can draw the cold air from the cockpit space for enhancing the heat dissipation efficiency.

A display device for a vehicle includes: an irradiation unit configured to irradiate a display light for an occupant of the vehicle to display an image; and a storage unit housing the irradiation unit so as to expose a display screen to which the display light is irradiated. The storage unit has an air intake port to take in air and an air discharge port to discharge the air. The display device includes a confluence portion configured to merge a first exhaust air discharged from the air discharge port and a second exhaust air discharged from an air conditioner for a cabin of the vehicle through an air outlet arranged in the cabin. The confluence portion is defined such that a first flow direction of the first exhaust air and a second flow direction of the second exhaust air coincide with each other.

A vehicle is disclosed. The vehicle includes a passenger cabin; a steering wheel having a hub and a rim; and a ventilation system having a first air outlet for discharging a first jet of air, and a second air outlet for discharging a second jet of air. The first jet of air projects through a gap between the hub and the rim, and the second jet of air intersects and deflects the first jet of air.

An integrated thermal management system for mobility vehicles, may include a hybrid compressor including a mechanical compression unit driven using the driving force of an engine, and an electric compression unit driven using the driving force of a motor and configured such that an air blower is connected to the electric compression unit, a refrigerant circulation line fluidically-connected to the hybrid compressor, a condenser and an expansion valve such that a refrigerant circulates thereto, and an indoor air conditioning unit configured to cool or heat air introduced through the air blower and then to discharge the air to the inside of a mobility vehicle and including a cooling core connected to a point of the refrigerant circulation line downstream of the expansion valve of the refrigerant circulation line and a heating core fluidically-connected to an exhaust gas discharge line connected to the engine.