A cooling system includes a plurality of sensor sub-units arranged in a grid having first sides configured to be thermally connected to a heat source and opposing second sides. The heat source including a plurality of sub-regions that correspond with the first sides of each of the plurality of sensor sub-units. The plurality of sensor sub-units are configured to sample temperatures of the sub-regions of the heat source. The cooling system also includes a plurality of solid-state cooling sub-units configured to dissipate heat, a plurality of heat exchanger channels and a controller configured to determine the one or more sub-regions of the heat source to cool. Each heat exchanger channel is configured to dissipate heat. At least one surface of at least one of the heat exchanger channels includes a coating configured to boost conversion of heat energy being dissipated into infrared radiation.

A temperature control device has a temperature acquisition unit that acquires information indicating a temperature around a user and a control unit that controls a Peltier element worn by the user to cool or warm the user based on the temperature. The control unit causes the Peltier element to warm the user when the temperature is higher than or equal to a first threshold and causes the Peltier element to cool the user when the temperature is lower than a second threshold.

A heat dissipation module and a heat dissipation method thereof are provided. A cold side of a thermoelectric cooler is disposed on a heat conducting member. A processing circuit controls a voltage control circuit to provide an output voltage to the thermoelectric cooler according to a temperature sensing signal generated by a temperature sensor sensing a temperature of the heat conducting member, so as to adjust a temperature of the cold side of the thermoelectric cooler to dissipate heat for a heat source.

The invention relates to a temperature-control device for the temperature control of an energy source, wherein the temperature-control device comprises a temperature-control unit, which has at least one Peltier element which is arranged between an accommodation area for the energy source and a fluid area in a thermally effective manner. Furthermore, the temperature-control device comprises a control unit for supplying voltage to the Peltier element, wherein the control unit is designed to supply a voltage to the Peltier element, which causes the Peltier element to transfer heat from the hotter part of the accommodation area or fluid area to the colder part of the accommodation area or fluid area.

An apparatus for preventing deformation of a communication card includes a card holder configured to install a communication card; a temperature control component that is located on one side of the card holder and connected to a power supply configured to perform cooling or heating; a temperature sensor configured to collect temperature of the card holder; and the power supply configured to generate a supply current according to the temperature collected by the temperature sensor to supply power to the temperature control component, so that the temperature control component performs cooling or heating to maintain the temperature of the card holder within a preset temperature range, and the communication card is not deformed when the communication card is in the card holder and within the preset temperature range.

Disclosed is container for modifying temperature of an object on receiving commands from a computing device. The container includes a hollow outer vessel, a hollow inner vessel, a hollow cylindrical bracket, a first temperature sensor, a peltier element, a heat sink, a second temperature sensor, a battery, a printed circuit board, a memory unit, a microprocessor, a bi-directional communication unit, and a bottom cover. The hollow cylindrical bracket is having a first indent, a second indent, a sidewall, and a closed bottom end. The hollow bracket sidewalls move between the second outer surface and the first inner surface. The first temperature sensor measures temperature of the second outer surface of the inner vessel. The memory unit stores pre-defined reference temperature. The microprocessor processes signals received from the first temperature sensor and the second temperature sensor. The microprocessor regulates current and voltage for the peltier element depending upon the processed signals and the stored pre-defined reference temperature. The bi-directional communication unit communicates signals between the microprocessor and the computing device. The computing device sends command to the controller to regulate the temperature of the inner vessel. The bottom cover covers the battery and the printed circuit board. Further, the bottom cover attaches to the hollow bracket.

A heating device includes a heating element, a temperature sensor, a first heat pump element, a first heating block, a second heating block and a controller. The heating element is to receive an energy of the controller and convert the energy into a first thermal energy provided to the first heating block. A sensing result is generated by the temperature sensor according to the first thermal energy. The first heat pump element is to receive the energy of the controller for generating a temperature difference. The first thermal energy is conducted to the first heat pump element for forming a second thermal energy. The second heating block is to receive the second thermal energy. The controller correspondingly outputs the energy to the heating element and the first heat pump element according to the sensing result, and thereby controls the first thermal energy and the temperature difference.

The present invention provides a refrigerator capable of supplying hot and cold drinking water to a user. The refrigerator includes a cold water tank and a hot water tank and a Peltier effect thermoelectric element disposed between the tanks. When a unidirectional current is supplied to the thermoelectric element, its heat absorption portion can absorb heat from the cold water tank and cool down the water stored therein; and its heat generation portion can release to the hot water tank and heat up the water stored therein. The cold water tank can further be cooled by the cold air in the refrigerator; while the hot water tank can further be heated by the heat in the machine room.

A portable cooler container is provided. The temperature control system cools a chamber of the container to transport temperature sensitive contents via the container. An electronic display screen on one of the lid and the container body selectively displays an electronic shipping label for the portable cooler container.

The present work depicts a thermal device for solid and liquid products consisting of a container with an external surface with one or more thermoelectric plates (20) or micro heat exchangers interconnected with a micro-compressor heat sink (30); this container (10) is placed on an eccentric axle (40) connected to a rotary electric motor or moving device (50) which increases the heat transfer coefficient by internal convection of the container (10) where the element to be cooled or heated is stored.