A temperature stimulation unit according to one or more embodiments may include a cover, a case including a top portion with an opening, and a control board. The case may include a bottom portion and a side portion having a through-hole. The bottom portion and the side portion may define a clearance at least with the control board.

A temperature stimulation unit according to one or more embodiments may include a cover, a case including a top portion with an opening, and a control board. The case may include a bottom portion and a side portion having a through-hole. The bottom portion and the side portion may define a clearance at least with the control board.

The chilling system provides cooling to components housed within a container by pumping propylene-glycol-water-mixture (PGWM) or equivalent through heat exchange assemblies and thermal transfer vessels. The thermal transfer vessels are filled with a paraffin-based phase change material (PCM) or equivalent solution for realizing phase change of the PCMs at selected melting points. The heat exchange assemblies are provided with thermal electric coolers for cooling the PGWM as it travels through the heat exchangers. The cooled PGWM is directed into and through a target cooling manifold of a target heat exchanger assembly to realize cooling the housed components. The system operates on direct current at under 500 watts of power and requires no Freon-type refrigerants or compressors. A microcontroller controls switches for realizing desired flow paths of the PGWM upon receiving phase change and temperature information from sensors.

The chilling system provides cooling to components housed within a container by pumping propylene-glycol-water-mixture (PGWM) or equivalent through heat exchange assemblies and thermal transfer vessels. The thermal transfer vessels are filled with a paraffin-based phase change material (PCM) or equivalent solution for realizing phase change of the PCMs at selected melting points. The heat exchange assemblies are provided with thermal electric coolers for cooling the PGWM as it travels through the heat exchangers. The cooled PGWM is directed into and through a target cooling manifold of a target heat exchanger assembly to realize cooling the housed components. The system operates on direct current at under 500 watts of power and requires no Freon-type refrigerants or compressors. A microcontroller controls switches for realizing desired flow paths of the PGWM upon receiving phase change and temperature information from sensors.

The present invention relates to a cooling arrangement, which comprises an insulation module (1) surrounding the insulated object (7) for its main part and formed by an internal layer (8), an external layer (3) and insulation material (9) located between them. The external layer of the insulation module is adapted to be surrounded by a protective enclosure (2) in a way that at least one air gap (4) is provided between the external layer and the protective enclosure. The insulation module has at least one exchange aperture (10) penetrating it at least in part with the first cooling element (12) adapted to it. The second cooling element (12) opposite to the first cooling element is, in turn, adapted to the external air gap (4) in a way that at least one thermoelectric generator (13) is arranged between them. The protective enclosure surrounding the insulation module is provided with a venting aperture (15) penetrating it, and a fan (5) utilizing the electric power produced by the thermoelectric generator (13) is adapted to it for increasing the efficiency of the airflow in the air gap.

The present invention relates to a cooling arrangement, which comprises an insulation module (1) surrounding the insulated object (7) for its main part and formed by an internal layer (8), an external layer (3) and insulation material (9) located between them. The external layer of the insulation module is adapted to be surrounded by a protective enclosure (2) in a way that at least one air gap (4) is provided between the external layer and the protective enclosure. The insulation module has at least one exchange aperture (10) penetrating it at least in part with the first cooling element (12) adapted to it. The second cooling element (12) opposite to the first cooling element is, in turn, adapted to the external air gap (4) in a way that at least one thermoelectric generator (13) is arranged between them. The protective enclosure surrounding the insulation module is provided with a venting aperture (15) penetrating it, and a fan (5) utilizing the electric power produced by the thermoelectric generator (13) is adapted to it for increasing the efficiency of the airflow in the air gap.

An actively heated or cooled mug has a body with a chamber that can receive and hold a beverage and a heating or cooling system disposed at least partially in a cavity below the chamber. The heating or cooling system has a heating or cooling element to actively heat or cool the chamber, power storage devices, and circuitry that controls the operation of the heating or cooling elements. A user interface is electrically connected to the circuitry and has one or more selection members actuatable a) to turn off the one or more heating or cooling element or b) to adjust a temperature setting to one of multiple temperature settings configured to control the one or more heating or cooling elements to heat or maintain the liquid at a user selected temperature.

An actively heated or cooled mug has a body with a chamber that can receive and hold a beverage and a heating or cooling system disposed at least partially in a cavity below the chamber. The heating or cooling system has a heating or cooling element to actively heat or cool the chamber, power storage devices, and circuitry that controls the operation of the heating or cooling elements. A user interface is electrically connected to the circuitry and has one or more selection members actuatable a) to turn off the one or more heating or cooling element or b) to adjust a temperature setting to one of multiple temperature settings configured to control the one or more heating or cooling elements to heat or maintain the liquid at a user selected temperature.

Proposed is a laser treatment device having a cooling system, the device including a laser module which irradiates a patient's skin with a laser, a sensing unit which detects a temperature of a surface of the patient's skin before, during, or after the skin is heated by the laser, a cooling module which includes an inlet which receives a refrigerant from a refrigerant storage unit, a nozzle which sprays the refrigerant on the skin, a conduit which connects the inlet with the nozzle, an flow rate control unit which controls a spray amount of the refrigerant by using a valve which is positioned on the conduit and connects or disconnects the inlet with or from the nozzle, and a refrigerant condition control unit which applies a thermal energy to the refrigerant by using a thermoelectric element located between the flow rate control unit and the nozzle.

A condenser and semiconductor processing machine, relating to the art of semiconductor equipment. The condenser 100 includes a sealed cavity; wherein, a gas passage is provided in the sealed cavity; cooling liquid is filled around the gas passage; a gas inlet, a gas outlet, and a liquid outlet are provided on the sealed cavity, the gas inlet is communicated with the inlet of the gas passage, the gas outlet is communicated with the outlet of the gas passage, and the liquid outlet is communicated with the gas passage; the gas passage is a Tesla valve structure passage.