An air conditioning system for an interior of a vehicle, which has at least one cooling unit as at least one component. The at least one cooling unit has thermally conductive composite yarn and carrier material, which has phase change material. The carrier material is woven into the composite yarn. The phase change material is designed to absorb heat from the interior above its melting point.

A device for temperature control for a motor vehicle, includes a diffractive optical element disposed on a surface of the motor vehicle, and a radiator. The diffractive optical element couples in incident radiation and conducts the coupled-in incident radiation away from an area of the motor vehicle to be cooled. The radiator includes an absorber to absorb the coupled-in incident radiation which is conducted to the absorber from the diffractive optical element. The radiator releases energy based on the coupled-in incident radiation absorbed by the absorber.

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 air conditioner energy-saving inflatable device is adapted to be disposed in a vehicle body. The air conditioner energy-saving inflatable device includes an air pump, an air bag, a circuit board and a sensor. The air bag is connected to the air pump and adapted to be disposed beside an area in the vehicle body. The circuit board is electrically connected to the air pump and includes a controller. When an air-conditioning system of the vehicle body is activated, the sensor is adapted to sense whether the area is vacant. When the sensor senses that the area is vacant, the controller instructs the air pump to inflate the air bag, so that the air bag fills at least a portion of the area. When the air-conditioning system of the vehicle body stops running, the air bag is deflated. A vehicle is also provided.

Multiple vehicle heating systems are disclosed providing a multilayered heating fabric to provide thermal radiation to vehicle occupants. In one embodiment, a heating system comprises a plurality of electrical bus bars and a heating fabric. The plurality of electrical bus bars connect to a battery within a vehicle to receive electrical power. The heating fabric comprises a conductive layer, and a non-conductive layer. The conductive layer comprises a plurality of non-uniform conductive fibers disbursed within a binder. The non-uniform conductive fibers are in electrical communication with at least two of the plurality of electrical bus bars. The non-uniform conductive fibers are adapted to convert electrical power to thermal radiation. The non-conductive layer insulates the conductive layer from the vehicle.

Inserts for the air-conditioning of a vehicle and methods for forming same are provided. In an exemplary embodiment, the insert includes a spacer material part. The spacer material part includes an open region extending from a top side to an opposite underside, the open region forming an air-guiding structure. The spacer material part is covered by at least one cover layer on at least one of the top side and the underside. The open areas of the air-guiding structure include a plurality of ducts connected to one another to form a net-like duct structure. The duct structure forms flow regions or flow zones. A cover layer has at least one perforation in the region of connection or intersection points of the ducts.

Vehicles and methods for cooling a cabin using a cold roof of the vehicle are provided. The vehicle includes a roof, a cabin, and an insulation layer disposed between the roof and the cabin. The vehicle also includes a passage that fluidly couples the roof with the cabin. The passage is switchable between an open mode and a closed mode. The passage is switched between the open mode and the closed mode depending on a relationship between a roof temperature, a cabin temperature, and/or a threshold temperature. The passage may be formed through the insulation layer or extend outside of the insulation layer fluidly coupling the roof with the cabin.

The objective of the present invention is to decrease air temperature reduction along an indoor-side surface of a vehicle opening part caused by heat transfer from outside air. A heating device for a vehicle is provided with a heat generating part (2) which is installed on a vehicle component provided along an edge of a vehicle opening part, and which increases, via heat generation, the temperature of low temperature air along an indoor-side surface of the vehicle opening part caused by heat transfer from outside air. The heat generating part (2) may be disposed along an opening part installed with a vehicle window (52), and the heat generating part (2) may include an electric heater that uses electric power as a heat source.

A power consumption device, a method for manufacturing a power consumption device and an apparatus for manufacturing a power consumption device, belonging to the technical field of batteries. The power consumption device includes a passenger compartment and a box, the box being configured for accommodating a battery cell, the box including a thermal management component. Where the thermal management component is configured to accommodate fluid to adjust a temperature for the battery cell and the passenger compartment. The power consumption device, the method for manufacturing a power consumption device and the apparatus for manufacturing a power consumption device are capable of realizing reasonable use of energy, thereby reducing waste of energy.