A vehicle occupant air curtain system includes a seat that has a seat cushion and a seat back. The seat back has a region that is configured to be arranged above an occupant shoulder. An air vent is supported on the seat back and is arranged in the region. The air vent is configured to be directed adjacent to a seated occupant's head and neck.

Disclosed is a vehicle air-conditioning device using semiconductor as a cooling core, including a thermoelectric cooling chip, a cooling circulator, a heat dissipation device, and a power-supplying and temperature-controlling device. The thermoelectric cooling chip has an electricity receiving end electrically connected to the power-supplying and temperature-controlling device to receive electricity therefrom to be energized as to have an end thereof forming a cold generating surface adjacent to the cooling circulator and an end opposite to the cold generating surface forming a heat generating surface adjacent to the heat dissipation device. The cooling circulator includes a tube-winding circulation box including temperature-reduction conducting fins distributed on a surface, a temperature-receiving water tank, a temperature-receiving conducting plate, a fan, and an assistive temperature transferring device including an electric water pump. The tube-winding circulation box is connected through piping to the temperature-receiving water tank that is stacked with the temperature-receiving conducting plate.

The invention relates to a surface temperature-controlling device, in particular for use in vehicles, comprising a first air-distributing layer which has multiple air inlets extending through the first air-distributing layer and multiple air outlets extending through the first air-distributing layer, and a second air-distributing layer which fluidically connects air inlets and air outlets of the first air-distributing layer, wherein the air inlets are designed to introduce pre-heated or pre-cooled air into the second air-distributing layer, and the air outlets are designed to discharge air out of the second air-distributing layer.

A system configured to generate electricity based upon a temperature difference between a vehicle occupant and a portion of a vehicle interior is described herein. The system includes a thermoelectric device containing nano-scale metal fibers or carbon nanotubes incorporated into an interior surface of the vehicle. The thermoelectric device has a first side in contact with the vehicle occupant and a second side opposite the first side in contact with the portion of the vehicle interior. The thermoelectric device is configured to supply electrical power to an electrical system of the vehicle.

There is provided a passenger compartment structure that can save power while ensuring thermal comfort of an occupant. The passenger compartment structure allows control of thermal comfort of the occupant in a posture seated on a seat. The passenger compartment structure includes a layered structure constituting at least part of an interior member disposed at a position where the interior member is able to face a lower leg of the occupant. The layered structure disposed in each of a front middle portion, a front lower portion, a frontal lower portion, and a right surface front upper portion having a high geometric factor for the lower leg includes a surface layer, a structural parent layer, and a temperature control mechanism layer interposed between the surface layer and the structural parent layer.

An arrangement for a vehicle roof, having a first pane element configured to realize an outer pane for the vehicle roof, a second pane element that is configured to realize an inner pane for the vehicle roof, the second pane element (2) being coupled to the first pane element, a cooling device, which may have a semiconductor layer having Peltier elements, and strip conductors connected to the semiconductor layer, and wherein the cooling device being designed to cool a vehicle interior, and being coupled to the second pane element, such that the cooling device is arranged between the first and the second pane element.

A vehicle interior panel includes a thermoelectric air conditioner capable of providing conditioned air locally within a passenger cabin of the vehicle. Air is drawn from the passenger cabin through an intake port in the panel, conditioned locally along a back side of the panel by a thermoelectric device, and discharged back into the cabin through a discharge port in the panel. Additional air flows along a waste side of the thermoelectric device and can be discharged outside the passenger cabin. The panel can be an interior door panel from which the waste side air is discharged within a B-pillar of the vehicle body.

A thermal comfort device comprises a pair of selectively contractable piezo-electric diaphragms and a body sandwiched between the pair of diaphragms, the body defines a cavity and an opening, wherein, the piezo-electric diaphragms are adapted to be selectively contracted to flex outward, drawing air into the cavity, and to flex inward, forcing air out of the cavity, each of the piezo-electric diaphragms adapted to be selectively controlled by varying the voltage and the frequency, wherein the velocity of the air being forced outward from the cavity is selectively variable, and a thermo-electric device adapted to thermally condition air forced outward from the cavity by one of heating and cooling the air forced outward from the cavity, wherein the thermo-electric device is positioned at one of within the cavity and outside the cavity aligned with the opening.

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.

A thermal regulation system for an electric drive vehicle has two loop circuits provided with respective pumps, for circulating heat transfer fluid, and with respective heat exchangers for cooling the heat transfer fluid. A battery pack and an electric/electronic drive unit are arranged in parallel with each other in the first and second loop circuit respectively, so that they are cooled by the heat transfer fluid at flow rates which are different from each other, when the two circuits form a single cooling circuit. At least one Peltier cell is arranged along the first loop circuit to heat the heat transfer fluid circulating towards the battery pack.