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 device and a method for defogging and/or defrosting a glazing unit of a motor vehicle with a partially or totally electric propulsion system is disclosed. The device comprises means (1) for cooling a coolant fluid, using at least one electric current source, and a thermal battery (2), the device being configured to allow, in certain phases, the cooling of the coolant fluid by the cooling means (1) and the storage of cold from the coolant fluid in the battery (2), and, in other phases, the release of cold from the battery (2) into the coolant fluid.

A thermoelectric arrangement for use in a cooling system (4, 6) of a motor vehicle has a thermocouple (8) with a first, heat-outputting thermal element (10), a second, heat-absorbing thermal element (12) and a conductor element (14) through which current flows. At least two cooling circuits (16, 18, 20) are provided. The first thermal element (10) is arranged in at least one cooling circuit (16, 18, 20), and the second thermal element (12) is arranged in at least one heating circuit (48). The first thermal element (10) is arranged in a first connecting line (22) that is connected fluidically to the respective cooling circuits (16, 18, 20) via valve arrangements (24, 26; 28, 30; 32, 34) on the input and output sides of the first thermal element (10). A cooling system having such a thermoelectric arrangement also is described.

A solid-state cooling apparatus for a galley installed in an aircraft that includes at least one storage enclosure for containing chilled beverage and/or foods for storage and a solid-state air-to-air thermoelectric device having a hot side and a cold side mounted in the galley and having at least one fan for circulating chilled air in proximity to the storage enclosure. A waste heat capture device is provided and includes a hot air outlet for discharging waste heat from the hot side of the cooling thermoelectric devices into the aircraft exterior to the galley.

An air-heating blower device for a passenger compartment of a motor vehicle comprising a body with at least one inlet opening at least one outlet opening an electrically driven axial fan rotatably mounted around its axis within the body. The fan is associated to an electric motor (M) with toroidal geometry, having an annular rotor which is rotatable within an annular stator and defining a central opening inside thereof, said fan (F) having one or more blades (B) which are carried by the rotor and each blade extending into said central opening towards a free end of the blade which terminates at a distance from the central axis of the fan, and in that the annular body of the rotor and/or the annular body of the stator define a guide tube for the airflow activated by the fan (F) over the resistive electric heater (H).

A vehicle comprising, a passenger cabin, a door to the passenger cabin, and an air conditioning system is disclosed. The air conditioning system comprise a Peltier device, a blower for directing an airflow over a first side of the Peltier device and ducting for ducting air to the blower, the ducting comprising an inlet located on an underside of the door.

A vehicle comprising a passenger cabin and an air conditioning system is disclosed. The air conditioning system comprises a Peltier device, a first blower for directing a first airflow over a first side of the Peltier device, and a second blower for directing a second airflow over a second side of the Peltier device. The second blower draws the second airflow from inside the passenger cabin, and the second airflow is discharged to outside the passenger cabin.

A refrigeration device and a vehicle are provided, and relate to the technical field of vehicles. The refrigeration device is disposed in a trunk of the vehicle, and the refrigeration device includes: a semiconductor refrigeration sheet, having a cold end and a hot end which are disposed oppositely, wherein the hot end of the semiconductor refrigeration sheet is attached to an inner wall of the trunk, and the cold end of the semiconductor refrigeration sheet is disposed toward an inner space of the trunk.

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.

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.