A climate control system and method controls climate at selected regions. The thermoelectric system includes a plurality of thermoelectric assemblies. The system can include a fluid conduit configured to allow a liquid to flow in the at least one fluid conduit. The system can further include a plurality of thermoelectric assemblies. At least two thermoelectric assemblies of the plurality of thermoelectric assemblies are in thermal communication with the liquid to provide climate control to a region.

A flexible Peltier device in which emitting heat conversion properties between Peltier elements and an object transferring heat may be improved and a flexible heat-emitting sheet having the Peltier elements bonded thereto may be bent without worrying the separation there between. A flexible Peltier device includes a single or plural Peltier element which is disposed on one surface side of a heat-emitting sheet having flexibility made from heat-conductive rubber containing a heat conductive filler and each semiconductor element which has a heating side and a cooling side and composes the Peltier element at least one of the heating side and the cooling side is bonded integrally to the heat-emitting sheet by a direct covalent bond and/or by an indirect covalent bond through a molecular adhesive at active groups existing on each other surfaces.

A temperature control system for a vehicle seat includes a finish trim layer, a thermally conductive panel in thermal contact with the finish trim layer, a thermal device generating a temperature gradient, and a heat transfer structure connecting the panel and the thermal device. The panel and the heat transfer structure are adapted to together thermally conduct the quantity of heat between the finish trim layer and the thermal device.

A vehicular air conditioner includes a first outlet that blows a conditioned air frontward to flow past a neck part of an occupant on a seat, and a second outlet that is provided below the first outlet and blows the conditioned air upward to flow past an armpit part of the occupant. The second outlet blows the conditioned air to merge with the conditioned air blown from the first outlet. The second outlet blows the conditioned air with an airflow volume larger than an airflow volume of the conditioned air from the first outlet such that the conditioned air blown from the second outlet guides the conditioned air blown from the first outlet to flow along a face of the occupant.

An energy-efficient thermal management system for an electric or hybrid vehicle is provided. The system has a first coolant circuit for controlling the temperature of electric components of an electric powertrain, an air-conditioning unit being provided for air-conditioning an interior. A second coolant circuit air-conditions the interior and is operable independently of the first coolant circuit. Each coolant circuit comprises a pump and a respective ambient heat exchanger. In order to control the temperature of the interior, a temperature control device which can be designed as a Peltier module is integrated into the second coolant circuit, said temperature control device operating in the manner of a heat pump for heating purposes. The two coolant circuits can be coupled to each other in order to exchange heat. An additional temperature control device can be integrated in order to air-condition an interior component in a decentralized manner, in particular a seat.

Systems and methods for providing heating and cooling to a cabin of an autonomous or semiautonomous electric vehicle. A system includes one or more autonomous or semiautonomous electric vehicle components generating thermal energy as a byproduct of operation, a radiator fluidly coupled to the one or more vehicle components and positioned downstream from the one or more vehicle components such that the radiator receives at least a portion of the thermal energy, a thermoelectric cooler thermally coupled to and located downstream from the radiator, and one or more bypass valves that control fluid flow from the radiator such that fluid flows directly to a cabin of the vehicle or flows through the thermoelectric cooler before flowing into the cabin.

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.

A dehumidifier for a vehicle includes a heat exchanger provided in a flow path of air and configured to have a heat transfer material flowing therein so as to cool or heat the air. A first thermoelectric element is provided at an air inlet side of the heat exchanger and is configured to cool introduced air. A first thermal conductor is configured to connect a heat-generating surface of the first thermoelectric element to the heat exchanger and radiate heat generated from the first thermoelectric element through the heat exchanger.

Disclosed are a cooling device and a vehicle including the same. The cooling device according to one aspect of the present disclosure includes a housing part having a first hole formed at one side thereof and a second hole formed at the other side thereof, a heat exchange part accommodated in an internal space of the housing part and having one side communicating with the first hole and the other side communicating with the second hole, a thermoelectric element part provided above the heat exchange part, and a radiational cooling part provided above the thermoelectric element part and at least partially exposed to the outside.

A seat thermal conditioning device includes a seat portion having a vent configured to provide conditioned air to a seat occupant neck area. A thermoelectric module is arranged in the seat portion. The thermoelectric module is configured to both heat and cool an air supply to provide the conditioned air.