Abstract: A thermoelectric drinking apparatus has a feeding pipe, a cooling-gain circulating loop, a heating-gain circulating loop, an outlet pipe, and a thermoelectric heat pump. The thermoelectric heat pump has a cooling unit attached to the cold side of a thermoelectric chip, which has a cooling channel in its interior, and a heating unit attached to the hot side of the thermoelectric chip and provided with a heating channel in its interior. The feeding pipe conducts fluid into the cooling channel and the heating channel respectively. The cooling-gain and heating-gain circulating loop respectively cause fluids in the cooling channel and heating channel to create circular flows, such that the cold side and hot side of the thermoelectric chip respectively cool and heat the fluids via the cooling channel and heating channel. The outlet pipe discharges the cooled and/or heated fluids respectively from the cooling-gain circulating loop and heating-gain circulating loop.

Abstract: The invention is a split-thermo-electric structure for cooling, heating, or stabilizing the temperature of an object or for electric power generation. The structure of the invention is comprised of one or more legs comprised of two or more layers of thermo-electric material and a connection layer (26) between each pair of successive layers of thermo-electric material. A layer of thermo-electric material at one end of each of the legs is located at the heat absorption side of the structure and a layer of thermo-electric material at the other end of each of the legs is located at the heat dispersion side of the structure. The structure is characterized in that the layer of thermo-electric material located at the heat absorption side of the structure and the layer of thermo-electric material at the heat dispersion side of the structure are asymmetric, i.e.

Abstract: An exemplary system and method for storing and retrieving energy in a thermoelectric energy storage system is disclosed. The thermoelectric energy storage system includes a working fluid that is circulated through a first and second heat exchanger, and a thermal storage medium that is circulated through the first heat exchanger. The second heat exchanger is in connection with a first thermal bath during a charging cycle and with a second thermal bath during a discharging cycle. In this way roundtrip efficiency is improved through minimizing the temperature difference between the first thermal bath and the hot storage tank during charging, and maximizing the temperature difference between the second thermal bath and the hot storage tank during discharging.

Abstract: A space efficient system especially suited for use as an entirely self-contained stand-alone unit usable in any of multiple contexts where heating or cooling of a defined-volume or enclosure is required. Hot or cold sides of the thermoelectric assemblies face toward one another into a central airflow that enters and exits a housing through a top or bottom of the housing that faces into the enclosure, and the opposite sides of the thermoelectric modules face into channels on opposite sides of the central airflow. The channels can be connected to intake and exhaust air through a common end of the housing, or be separated to individually intake and exhaust air at opposing ends of the housing. Fastener-free mounting of components between insulation shells that cooperate with the thermoelectric assemblies to define the channel boundaries results in tool-free configurability of components for servicing, maintaining, reconfiguring, scaling or customizing of the system.

Abstract: A heat pump system including a heat pump having at least two Peltier elements arranged in series and connected to an energy supply, the heat pump system comprising an electrical dropping resistor arranged in series with the Peltier elements, wherein the Peltier elements and the dropping resistor are jointly supplied with energy by the energy supply. The heat pump system is preferably used in a household appliance, in particular a tumble drier.

Abstract: A temperature calibration device uses Peltier cells for heating and cooling. The Peltier cells are connected to a relay that connects the cells to each other in one configuration for heating and a different configuration for cooling. The Peltier cells also receive supply voltages having different magnitudes and polarities for heating and cooling. By changing the manner in which the Peltier cells are connected to each other and using different supply voltages for heating and cooling, the cells are able to operate closer to their specified maximum temperature differential without sacrificing the useful life of the cells.

Abstract: A fluid temperature control device, which is particularly suitably applied to the temperature control of a processing liquid in a semiconductor device manufacturing process, capable of performing quickly and precisely the temperature control of a temperature-controlled fluid, and the device can also be made as small as possible. This fluid temperature control device includes a body block having flow passage grooves formed therein; heat transfer plates which are disposed on surfaces of the body block to form flow passages where a temperature-controlled fluid flows; heaters which heat the temperature-controlled fluid flowing through the flow passages via at least one of the heat transfer plates; and thermoelectric modules which heat and cool the temperature-controlled fluid flowing through the flow passages via at least one of the heat transfer plates.

Abstract: An RE-containing alloy, which is represented by a compositional formula of RrTtAa (wherein R represents at least one rare earth element selected from among La, Ce, Pr, Nd, Sm, Eu, Tb, Dy, Ho, Tm, Yb, Gd, and Lu; T collectively represents transition metal elements containing at least Fe atoms, a portion of the Fe atoms being optionally substituted by at least one species selected from among Co, Ni, Mn, Pt, and Pd; A represents at least one element selected from among Al, As, Si, Ga, Ge, Mn, Sn, and Sb; and r, t, and a have the following relationships: 5.0 at. %?r?6.8 at. %, 73.8 at. %?t?88.7 at. %, and 4.6 at. %?a?19.4 at. %) and having an alloy microstructure containing an NaZn13-type crystal structure in an amount of at least 85 mass % and ?-Fe in an amount of 5-15 mass % inclusive.

Abstract: A system for controlling the temperature of a passenger cabin has a tube for receiving a heat transfer fluid from an engine and a number of heating coils being thermally connected to the tube. The system also has a number of thermo-electric heat pumps connected to the tube. The heat transfer fluid is modulated for controlling the temperature of the passenger cabin at a number of different points of the passenger cabin.

Abstract: A cooling system includes a container that is conductively coupled or convectively coupled to a thermoelectric device to selectively cool and/or heat the container. A climate controlled container system for a vehicle includes a container or cavity and a conduction element configured to cool the cavity. In some embodiments, the cooling system includes a housing, a housing inlet, a fluid passage and one or more thermoelectric devices and fluid transfer devices positioned within the housing.

Abstract: Provided are methods, devices and systems for controlled removal of thermal energy from a fluid within a thermally conducting metal conduit. The system allows for the in situ formation of a reversible plug that can stop the flow of fluid through the conduit, particularly without inducing thermally induced stress fractures or breaches in the conduit. The devices and systems include a thermal transfer device that can be adapted to be in thermal communication with a thermal conducting metal conduit containing a fluid, particularly a flowing fluid. The devices and systems allows for controlled re-heating of the conduit without inducing thermally induced stress fractures or breaches in the conduit to restore fluid flow through the conduit.

Abstract: A personal environment appliance is disclosed in which a person in a localized area can individually control the ambient conditions of the person's localized area. The control permits highly localized adjustment to suit individual preferences, thereby, reducing the impact of individual environmental preferences on the individuals. In addition to environment conditions, a variety of accessories may be provided such as beverage heaters and/or coolers.

Abstract: Example personal beverage warmers and coolers for vehicle seats are disclosed. A disclosed example apparatus to regulate the temperature of a beverage near a seat of a vehicle, the apparatus includes: a base including a thermally conductive material that conducts heat in a direction that is at least one of to or from a container seated thereon, a thermoelectric device thermally coupled with the base and to be energized to exchange heat with the base, and a heat exchanger thermally coupled with the thermoelectric device and a liquid medium to exchange heat therebetween.

Abstract: A method of forming a thermoelectric device may include providing a substrate having a surface, and thermally coupling a thermoelectric p-n couple to a first portion of the surface of a substrate. Moreover, the thermoelectric p-n couple may include a p-type thermoelectric element and an n-type thermoelectric element. In addition, a thermally conductive field layer may be formed on a second portion of the surface of the substrate adjacent the first portion of the surface of the substrate. Related structures are also discussed.

Abstract: A point-of-use food holding cabinet keeps food products cold using a conventional refrigeration device or a semiconductor solid state heat sink. In one embodiment, one compartment can be kept cold or refrigerated while an adjacent compartment can be kept warm or hot. Solid state heat pumps such as Peltier devices absorb heat on one side and emit heat on the other. By configuring the solid state heat sinks appropriately, one compartment or shelf of a holding cabinet can be refrigerated while an adjacent compartment can be kept warm.

Abstract: A device includes a first thermally conductive substrate having a first patterned electrode disposed thereon and a second thermally conductive substrate having a second patterned electrode disposed thereon, wherein the first and second thermally conductive substrates are arranged such that the first and second patterned electrodes are adjacent to one another. The device includes a plurality of nanowires disposed between the first and second patterned electrodes, wherein the plurality of nanowires is formed of a thermoelectric material. The device also includes a joining material disposed between the plurality of nanowires and at least one of the first and second patterned electrodes.

Abstract: Heat exchangers of a refrigerant circuit are constructed of a first adsorption heat exchanger and a second adsorption heat exchanger, both of which have an adsorbent supported thereon, and are constructed so as to be switched into an evaporator and a condenser. An air passage is constructed so as to be switched into states in which air flowing from the outside of a room to the inside of the room and air flowing from the inside of the room to the outside of the room flow through either of the first adsorption heat exchanger and the second adsorption heat exchanger. A dehumidifying operation mode and a humidifying operation mode can be performed by switching the flow of refrigerant and the flow of air at specified intervals, a cooling operation mode and a heating operation mode can be performed without switching the flow of refrigerant and the flow of air, and an ventilating operation mode can be performed by flowing air through the air passage in a state where the refrigerant circuit is stopped.

Abstract: A thermoelectric structure for cooling an integrated circuit (IC) chip comprises a first type superlattice layer formed on top of the IC chip connected to a first voltage, and a second type superlattice layer formed on the bottom of the IC chip connected to a second voltage, the second voltage being different from the first voltage, wherein an power supply current flows through the first and second type superlattice layer for cooling the IC chip.

Abstract: A component has an outer wall defining an interior chamber to be cooled. Electronic equipment is mounted within the outer wall in the chamber. A thermoelectric cooler has a cool node positioned to be within the chamber, and a hot node positioned outwardly of the outer wall. A fuel cell provides electricity to the thermoelectric cooler. The fuel cell is mounted outwardly of the outer wall.

Abstract: An object of the present invention is to perform temperature setting of a heating plate so that a wafer is uniformly heated in an actual heat processing time. The temperature of a wafer is measured during a heat processing period from immediately after a temperature measuring wafer is mounted on the heating plate to the time when the actual heat processing time elapses. Whether the uniformity in temperature within the wafer is allowable or not is determined from the temperature of the wafer in the heat processing period, and if the determination result is negative, a correction value for a temperature setting parameter of the heating plate is calculated using a correction value calculation model from the measurement result, and the temperature setting parameter is changed.

Abstract: Systems and methods for controlling the temperature of an electrical device is described. The system includes a heat sink system in conjunction with a thermoelectric assembly. The systems and methods are particularly suitable in NEMA-4 electrical enclosures used in electrical submersible pump applications.

Abstract: A system for using a thermal cycle for heating or cooling. The system comprises a thermoelectric module flowing a gas; and an internal heat exchanger flowing the gas and exchanging heat between the gas and another fluid; the gas flow from at least one of the thermoelectric module and the internal heat exchanger flowing for heating or cooling. The system may be for using a closed cycle to remove a liquid from at least one object comprising moisture, the system comprising an enclosure containing the at least one object and arranged to receive a hot and dry gas for flow over the at least one object and thereby to produce a flow of moist gas at an intermediate temperature. The internal heat exchanger is arranged to exchange heat between the flow of the moist gas at the intermediate temperature and a flow of cold dry gas, thereby producing cooled moist gas and pre-warmed dry gas.

Abstract: A flexible thermoelectric device and a manufacturing method thereof are provided. Flexible substrates are formed by using LIGA process, micro-electro-mechanical process or electroforming technique. The flexible substrates are used to produce thermoelectric device. The structure and the material property of the substrates offer flexible property and tensile property to the thermoelectric device. Thermal transfer enhancement structures such as thermal via or metal diffusion layer are formed on the flexible substrates to overcome the low thermal transfer property of the flexible substrates.

Abstract: The air conditioning device for electronic components features three channels (6, 7, 8) for two flowing fluids that are in heat exchange with one another. In the first operating mode these two fluids are guided by means of switchable flaps into two selected channels (7, 8) where they are in heat exchange with one another at a partition (12) that is equipped with heat exchange elements (12, 13). In a second operating mode the flaps are switched in such a manner that the two fluids are in heat exchange with one another at a Peltier element (9) that is equipped on both sides with heat exchange elements (9, 11). In a third operating mode the Peltier element is switched as a heating element. In the first operating mode on the other hand the Peltier element is deactivated and consumes no electric energy.

Abstract: Disclosed is a cooling apparatus including: a heat receiving plate to which a plurality of heating elements are attached; a radiator plate to which a plurality of Peltier devices are attached; a thermal transport heat pipe that couples the heat receiving plate with the radiator plate; and a heat dissipating device being provided on an exothermic side of the Peltier devices; wherein the plurality of heating elements are arranged along a longitudinal direction of the thermal transport heat pipe, and the plurality of Peltier devices are arranged along the longitudinal direction of the thermal transport heat pipe, whereby, when using a plurality of Peltier devices, reducing power consumption thereof by equalizing each operation of the respective Peltier devices.

Abstract: A heat exchange system selectably controls the temperature of a fluid being delivered to a patient's body by a pump device. The heat exchange system includes a thermal element and a heat exchanger that is removably coupled under pressure to the thermal element. The heat exchanger includes a first half made from thermally conductive material that correspondingly mates with the thermal element, a second half made from thermally conductive material opposite the first half, and an internal heat exchange zone existing between the first half and the second half, wherein fluid flows therethrough. The thermal element of the heat exchange system may controllably and safely warm and/or cool the fluid prior to delivery.

Abstract: An improved efficiency thermoelectric system is disclosed wherein convection is actively facilitated through a thermoelectric array. Thermoelectrics are commonly used for cooling and heating applications. Thermal power is convected through a thermoelectric array toward at least one side of the thermoelectric array, which leads to increased efficiency. Several different configurations are disclosed to provide convective thermal power transport, using a convective medium. In addition, a control system is disclosed which responds to one or more inputs to make adjustments to the thermoelectric system.

Abstract: A cooling system cools an electrically rechargeable portable device accommodated in a docking station. The cooling system includes a docking station having a non-forced air active cooling unit and a housing. The cooling unit maintains a first heatsink surface at a temperature below an ambient temperature and a second heatsink surface at a temperature exceeding said first heatsink surface temperature. The housing accommodates an electrically re-chargeable portable device. The housing re-charges said portable device and seats said portable device in a position providing thermal contact between said docking station first heatsink surface and a heat spreader of said portable device while re-charging of said portable device.

Abstract: A voltage regulator is configured to receive an input voltage from a power supply, measure a temperature associated with a heat transfer medium, produce an output voltage to drive a thermo-electric cooler, and vary the output voltage in accordance with changes in the measured temperature. Varying the output voltage results in: 1) extracting of heat from the heat transfer medium when the measured temperature is above a threshold value, or 2) supplying of heat to the heat transfer medium when the measured temperature is below a threshold value. The voltage regulator can cap upper and lower bounds of the output voltage to prevent the thermo-electric cooler from reaching its saturation point. The voltage regulator can be configured to produce an output voltage having reduced voltage ripple.

Abstract: A climate control device includes a first and a second thermal module. The first module is configured to provide climate conditioned air to a first portion of a seat. The second module is configured to provide climate conditioned air to a second portion of the seat. A control system is provided for controlling the climate control device. The control system includes an input device for providing a set point for the system. A first control unit of the control system is provided for the first thermal module and a second control unit is provided for the second thermal module.

Abstract: A food or beverage serving apparatus is associated with a heat source or sink and one or more heat transfer devices. The food or beverage serving apparatus includes a serving surface for supporting a food or beverage. Each of the one or more heat transfer devices has a first portion in thermal communication with the serving surface and a second portion in thermal communication with the heat source or sink. The one or more heat transfer devices communicate heat between the first portion and the second portion via phase change of an internal working fluid.

Abstract: A thermoelectric heating/cooling structure may include a heat exchanger and a heat spreader spaced apart from the heat exchanger. In addition, a plurality of spaced apart thermoelectric components may be thermally coupled in parallel between the heat exchanger and the heat spreader. More particularly, each of the thermoelectric components may include a first header adjacent the heat exchanger, a second header adjacent the heat spreader, and a plurality of thermoelectric elements thermally coupled in parallel between the first and second headers. The first headers of the thermoelectric components may be spaced apart adjacent the heat exchanger, and the second headers of the thermoelectric components may be spaced apart adjacent the heat spreader.

Abstract: Systems and methods for controlling the temperature of an electrical device is described. The system includes a heat sink system in conjunction with a thermoelectric assembly. The systems and methods are particularly suitable in NEMA-4 electrical enclosures used in electrical submersible pump applications.

Abstract: Apparatus, systems, and methods provide for the cooling of a system on an aircraft or other platform. According to embodiments described herein, a first coolant is routed through a heat-producing system to absorb heat and maintain the system at a desired temperature. The first coolant is routed through a thermoelectric chiller for cooling before returning to absorb further heat from the system. Thermoelectric cooler modules within the chiller transfer heat from cold plates containing the first coolant to hot plates containing a second coolant. The second coolant absorbs the transferred heat and is routed to a radiator, where the heat is discharged into an ambient air stream. The second coolant is routed back to the hot plates to absorb further heat.

Abstract: A sample block for use in the polymerase chain reaction, DNA sequencing, and other procedures that involve the performance of simultaneous reactions in multiple samples with temperature control by heating or cooling elements contacting the bottom surface of the block is improved by the inclusion of hollows in the block that are positioned to decrease the mass of the block in the immediate vicinity of the wells.

Abstract: A thermoelectric module having an excellent durability is provide. The thermoelectric module comprises: a first support substrate having a first inner surface, a first outer surface and a plurality of first connecting electrodes formed on the first inner surface; a second support substrate having a second inner surface opposed to the first inner surface, a second outer surface and a plurality of second connecting electrodes formed on the second inner surface; a plurality of P-type thermoelectric elements and a plurality of N-type thermoelectric elements provided between the first inner surface and the second inner surface; a temperature-detecting element provided on the first inner surface.

Abstract: An air conditioner for a vehicle includes first and second heating heat exchangers disposed to heat air by using a cooling fluid for cooling an engine as a heat source, a heater disposed to heat the cooling fluid flowing to the second heating heat exchanger, and a controller that outputs an operation request signal to the engine when a temperature of the cooling fluid is lower than a predetermined temperature. The first and second heating heat exchangers are arranged in parallel with respect to a flow direction of the cooling fluid. In the air conditioner, the controller controls a flow amount of the cooling fluid flowing into the second heating heat exchanger to be, smaller than a flow amount of the cooling fluid flowing into the first heating heat exchanger when the heater heats the cooling fluid flowing to the second heating heat exchanger.

Abstract: A thermoelectric system includes a first plurality of thermoelectric elements and a second plurality of thermoelectric elements. The thermoelectric system further includes a plurality of heat transfer devices. Each heat transfer device has a first side in thermal communication with two or more thermoelectric elements of the first plurality of thermoelectric elements and a second side in thermal communication with one or more thermoelectric elements of the second plurality of thermoelectric elements, so as to form a stack of thermoelectric elements and heat transfer devices. The two or more thermoelectric elements of the first plurality of thermoelectric elements are in parallel electrical communication with one another, and the two or more thermoelectric elements of the first plurality of thermoelectric elements are in series electrical communication with the one or more thermoelectric elements of the second plurality of thermoelectric elements.

Abstract: A thermoelectric system includes a first thermoelectric element including a first plurality of segments in electrical communication with one another. The thermoelectric system further includes a second thermoelectric element including a second plurality of segments in electrical communication with one another. The thermoelectric system further includes a heat transfer device including at least a first portion and a second portion. The first portion is sandwiched between the first thermoelectric element and the second thermoelectric element. The second portion projects away from the first portion and configured to be in thermal communication with a working medium.

Abstract: Embodiments herein relate to footwear, such as a boots and shoes, and in particular to footwear having a removable element, such as a liner, that includes temperature control elements for controllably regulating and/or altering the temperature of the footwear and thus the wearer's foot. Various embodiments also include an electrical contact in the foot bed adapted to couple to the temperature control element in the liner, and a power source, controller, and actuator coupled to the footwear upper.

Abstract: A cooling system is disclosed including a first heat exchanger, a second heat exchanger, a means for regulating a flow of a fluid, and a thermoelectric device for cooling a fluid, wherein a difference in temperature between a hot side and a cold side of the thermoelectric device is minimized and an efficiency of the thermoelectric device is maximized.

Abstract: A thermoelectric heat pump (10) is provided including a thermoelectric array (30) having alternating P-type and N-type semiconductors (33, 34) and one or more water transport membranes (20).

Abstract: The present invention relates to a cooling and heating cabinet device of a rear seat side for a vehicle using a thermoelectric module that is mounted between rear seats of a vehicle, having cooling and heating functions and further having an arm-resting function irrespective of its activation as the cooling and heating device, and that makes the exhaust fan activated by the control of the controller of the air conditioning system, thereby achieving the air-refreshing function as well as the cooling or heating mode function of the cooling and heating cabinet.

Abstract: An air conditioner includes a heat storage unit having a heat storage medium, a first heat exchanger for heat exchange with air in a compartment, a second heat exchanger for heat exchange with outside air, and a peltier unit having a first and second heat exchange surfaces opposite to each other. The first heat exchange surface is thermally conductive to the heat storage unit, and the second heat exchange surface is thermally conductive to the first and second heat exchangers. In heat storage mode electric current flows through the peltier unit in one direction to provide heat transfer between the second heat exchanger and the heat storage unit. In air conditioning mode electric current flows through the peltier unit in the other direction to provide heat transfer between the first heat exchanger and the heat storage unit.

Abstract: A refrigeration unit (40) having a defroster (30) has a refrigeration compartment (44), an evaporator coil (26) having an amount of crystallized water being aggregated thereon from air and a thermo-electric module (32, 46, 48, 50) having a semiconductor material. The thermo-electric module (32, 46, 48, 50) provides heating from a first location of the thermoelectric module (32, 46, 48, 50) and cooling from a second location of the thermo-electric module (32, 46, 48, 50) based on a Peltier effect when a current from a power supply is traversed through the thermo-electric module (32, 46, 48, 50). The heating from a first location heats the evaporator coil (26) to defrost the aggregated amount of crystallized water thereon. The cooling from the second location is communicated to the refrigeration compartment (44).

Abstract: A thermal-protection apparatus disposed in a vehicle cabin or storage compartment includes a housing enveloping a chamber in which a thermally-sensitive consumer electronic device is received, a thermoelectric module mounted in a wall of the housing, and a remote electronic controller and power source coupled to the housing via an electrical cable for activating the thermoelectric module, and optionally the consumer electronic device, in a manner to prevent the temperature in the chamber from exceeding a prescribed maximum operating temperature of the consumer electronic device or falling below a prescribed minimum operating temperature of the consumer electronic device.

Abstract: A heating and cooling system to maintain an area at a desired temperature including a thermoelectric device (102), a vapor compression system (106), and a control system (104) operably connected to the thermoelectric device (102) and the vapor compression system (106).

Abstract: A temperature-controlled portable container for carrying an injector is provided. The temperature-controlled portable container includes an outer container and an inner container disposed within the outer container. The injector is stored within the inner container, and the inner container is constructed of a thermally conductive material. The temperature-controlled portable container also includes a temperature control device, which maintains an inner container temperature above a first predetermined temperature and below a second predetermined temperature, where the second predetermined temperature is higher than the first predetermined temperature. The temperature-controlled portable container also includes a processor subsystem and a portable power source. The portable power source is coupled to the temperature control device and the processor subsystem, and provides power to the temperature control device and the processor subsystem.

Abstract: Some embodiments provide a system for optimizing electrical power management in a vehicle. The system includes a HVAC device and a thermal storage device, both configured to provide heating and cooling to an occupant compartment of the vehicle. The system further includes a controller connected to an electrical storage device and an electrical generating device. The controller receives electrical power generated by the electrical generating device and directs the electrical power to satisfy the vehicle's power requirements and/or stores the electrical power in at least one of the electrical storage device and the thermal storage device. Furthermore, the controller directs at least one of the HVAC device and the thermal storage device to provide heating and cooling to the occupant compartment of the vehicle, depending on the available storage of the thermal storage unit or occupant compartment demands.

Abstract: This is an enhanced thermoelectric cooler with superconductive heat-dissipative coolers for use in air-conditioner. This invention is comprised of a thermoelectric cooling chip sandwiched between two superconductive unidirectional heat-dissipative cooling devices. Each device consists of special superconductive pipes, heat-dissipative plates, and a fan. The cooling devices are to dissipate heat quickly from the thermoelectric cooling chip and to maintain constant hot to cold air flow.