An active temperature controlled container is configured to be portable so as to safely transport temperature sensitive and perishable goods (such as biological material): within a vessel that is thermally coupled to a thermoelectric assembly disposed within the container, where the thermal engine is powered by a power source, such as a battery. The thermoelectric assembly may include one or more resistors coupled to a resistor spacer block to act as a cool sink by actively and passively increasing the efficiency of the thermoelectric assembly.

An active temperature controlled container is configured to be portable so as to safely transport temperature sensitive and perishable goods (such as biological material): within a vessel that is thermally coupled to a thermoelectric assembly disposed within the container, where the thermal engine is powered by a power source, such as a battery. The thermoelectric assembly may include one or more resistors coupled to a resistor spacer block to act as a cool sink by actively and passively increasing the efficiency of the thermoelectric assembly.

An icemaker is mounted remotely from a freezer compartment. The icemaker includes an ice mold. A thermoelectric device is provided and includes a warm side and an opposite cold side. A flow pathway is connected in communication between the cold side of the thermoelectric device and the icemaker. In one aspect, a fan is operatively positioned to move air from the fresh food compartment across the warm side of the thermoelectric device and a pump moves fluid from the cold side of the thermoelectric device to the icemaker. Cold air, such as from a refrigerator compartment, may be used to dissipate heat from the warm side of the thermoelectric device for providing cold fluid to and for cooling the ice mold of the icemaker.

A piezoelectric cooling system and method for driving the cooling system are described. The piezoelectric cooling system includes a first piezoelectric cooling element and a second piezoelectric cooling element. The first piezoelectric cooling element is configured to direct a fluid toward a surface of a heat-generating structure. The second piezoelectric cooling element is configured to direct the fluid to an outlet area after heat has been transferred to the fluid by the heat-generating structure.

A piezoelectric cooling system and method for driving the cooling system are described. The piezoelectric cooling system includes a first piezoelectric cooling element and a second piezoelectric cooling element. The first piezoelectric cooling element is configured to direct a fluid toward a surface of a heat-generating structure. The second piezoelectric cooling element is configured to direct the fluid to an outlet area after heat has been transferred to the fluid by the heat-generating structure.

The present invention relates to a clothes-handing apparatus comprising: a cabinet having a holder opening provided at an upper panel; an air moving part provided inside the cabinet so as to generate an air flow; a holder which is withdrawable from the cabinet through the holder opening and on which clothes are hung; and holder air holes provided at the holder so as to supply air to the clothes hung on the holder.

The present invention relates to a clothes-handing apparatus comprising: a cabinet having a holder opening provided at an upper panel; an air moving part provided inside the cabinet so as to generate an air flow; a holder which is withdrawable from the cabinet through the holder opening and on which clothes are hung; and holder air holes provided at the holder so as to supply air to the clothes hung on the holder.

A cooling system for electrical and optical devices includes an electrocaloric cooler (EEC). A fluid circuit is in thermal communication with the EEC to dump heat from a working fluid of the fluid circuit into the EEC. The system can include a second EEC, a second fluid circuit in thermal communication with the second EEC to dump heat from a working fluid of the second fluid circuit into the EEC, and a second heat sink in thermal communication with the second fluid circuit to dump heat into the working fluid of the second fluid circuit. The second EEC, second fluid circuit, and second heat sink can be cascaded with the first EEC, first heat sink, and first fluid circuit wherein the second heat sink is in thermal communication with the first EEC to accept heat therefrom.

A portable, self-contained, temperature-controlled enclosure capable of maintaining a constant, user-specified temperature within the enclosure independent of the outside environment. The device is ideal for the transport of material that is highly temperature sensitive and requires a stable temperature environment. The portable enclosure includes capability of cellular and GPS location beacon identification, comprehensive internal status and operation monitoring, and wireless communication capability of the device status, temperature and humidity parameters, and location using BLUE TOOTH, WIFI and/or cellular technology. The system is powered by an onboard rechargeable battery, external DC power, or external AC power.

Cooling sub-assemblies with thermoelectric element(s), coupling clamps, hot side and cold side heat exchanger having a direct insertion or removal of cooling modules onto a fixed mounting frame arranged in rows and columns to produce desired and required cooling levels.