A cooling assembly includes an instrument panel. A passenger compartment for a vehicle can also utilize the cooling assembly. The instrument panel includes a first surface and a second surface opposing the first surface. The cooling assembly also includes a thermoelectric apparatus coupled to one of the first and second surfaces. The thermoelectric apparatus includes a first conductive plate and a second conductive plate spaced apart from each other. The first and second conductive plates are configured to be at different temperatures from each other during operation of the thermoelectric apparatus. The cooling assembly further includes a film secured to one of the first and second surfaces of the instrument panel and thermally connected to one of the first and second conductive plates of the thermoelectric apparatus such that operation of the thermoelectric apparatus causes the film to decrease in temperature by an amount sufficient for cooling the instrument panel.

Methods and systems for providing multi-zone climate control for a vehicle. One system includes a power source, a plurality of switches, a first zone heating/cooling device, a second zone heating/cooling device, and an electronic controller. The electronic controller is configured to operate the plurality of switches to supply current bi-directionally through the first zone heating/cooling device, bi-directionally through the second zone heating/cooling device, or bi-directionally through a series connection of the first zone heating/cooling device and the second zone heating/cooling device.

Embodiments related to moisture abatement during a heating operation of a climate control system are disclosed. In some embodiments, the climate control system includes a thermoelectric device (TED) or other thermal condition device having a hot side and a cold side. In certain embodiments, the thermal conditioning device is operated (e.g., by a processor or a condensate switch) to inhibit or prevent the occurrence of condensation, and/or to abate condensation that has already occurred, on the cold side of the thermal conditioning device during the heating operation.

The seat air conditioner configured to supply conditioning air to a seat in a vehicle cabin includes a refrigeration cycle, an air blower, and a conditioning air supply unit. The refrigeration cycle includes a compressor that compresses and discharges a refrigerant, a heat emitting portion that emits heat of the refrigerant discharged from the compressor to generate a warm air, a decompressor that decompresses the refrigerant flowing out of the heat emitting portion, and a heat absorbing portion that evaporates the refrigerant decompressed by the decompressor to generate a cold air. The air blower blows air to exchange heat with the refrigerant. The conditioning air supply unit supplies each of the warm air generated by the heat emitting portion and the cold air generated by the heat absorbing portion as the conditioning air to the seat.

A vehicle air conditioner, including a first duct having a first ventilation opening that is disposed on first side in a width direction of a seat provided in a vehicle, a second duct having a second ventilation opening that is disposed on second side in the width direction of the seat, the second side being opposite side of the first side, and a third duct having a third ventilation opening that is disposed in front of the seat.

A thermal conditioning system for conditioning a seat surface of a vehicle or other surface. The system includes a thermoelectric Peltier device with a main side and a waste side. A flap adjusts a proportion of an airflow between a main side airflow path and a waste side airflow path based on whether the surface is occupied, the power provided the thermoelectric Peltier device, the flow rates along the airflow paths, the power provided to a blower, and/or other factors.

A thermoelectric system and method provides distributed localized heating, cooling, or both heating and cooling. The thermoelectric system includes a plurality of thermoelectric assemblies. Each thermoelectric assembly comprises a plurality of thermoelectric elements, and each thermoelectric assembly is in thermal communication with a first working fluid and in thermal communication with a region corresponding to the thermoelectric assembly. Each thermoelectric assembly is selectively operable either to heat the region corresponding to the thermoelectric assembly by transferring heat from the first working fluid to the region corresponding to the thermoelectric assembly or to cool the region corresponding to the thermoelectric assembly by transferring heat from the region corresponding to the thermoelectric assembly to the first working fluid. Each thermoelectric assembly is operable independently from operation of other thermoelectric assemblies of the plurality of thermoelectric assemblies.

A climate control device (15) for influencing at least one climatic parameter of a handle (5) of a steering device (2), has an air moving device (21) for providing a stream of air, a handle distributor (26) for distributing a stream of air within at least a part of the handle, an air guidance device (22) for guiding air between the air moving device and the distributor. The air moving device (21) can be or is mounted to an area remaining static in relation to an adjustment movement of the steering device (2). The handle distributor (26) can be or is mounted to an area moving in relation to the static area when the steering device (2) is subject to an adjustment movement. The climate control device (15) is provided with a connecting device (30) allowing the air moving device (21) and the handle distributor (26) to move in relation to each other.

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.

Vehicle air comfort systems and methods. The systems and methods may comprise: (1) a plurality of flow tunnels for passage of a heat-transfer fluid; (2) a thermoelectric cooler in thermal communication with the flow tunnels for thermally conditioning the heat-transfer fluid in the flow tunnels; (3) an air inlet for receiving unconditioned air; (4) a thermal exchange assembly for facilitating thermal exchange between the thermally conditioned heat-transfer fluid and the unconditioned air to result in conditioning of the air; and (5) an air outlet for outputting the conditioned air into the vehicle.