A refrigerant system includes a first, substantially outdoor, two phase heat transfer fluid vapor compression circulation loop including a compressor, a heat exchanger condenser, an expansion device, and the heat absorption side of a heat exchanger evaporator condenser, connected by conduit in a closed loop and having disposed therein a first heat transfer fluid having a critical temperature of greater than or equal to 31.2 C. The system also includes a second, at least partially indoor, two phase heat transfer fluid circulation loop that transfers heat to the first loop through the heat exchanger evaporator condenser. The second loop includes the heat rejection side of the heat exchanger evaporator condenser, a liquid pump, and a heat exchanger evaporator, connected by conduit in a closed loop and having disposed therein a second heat transfer fluid that has an ASHRAE Class A toxicity rating and an ASHRAE Class 1 or 2L flammability rating.

A light cooling and heating machine, for which electrons or other charged particles serves as a refrigerant, comprising a light source and a sealed container. When cooling, the interior of the sealed container is filled with an electron gas, the light source produces an incident light, under the irradiation of the incident light, the radial attractive force among vibrating electrons reduces the average kinetic energy of the electrons for thermal motion, thus reducing the temperature of the electron gas and implementing cooling. When heating, the interior of the sealed container is filled with oxygen ions and helium ions, tinder the irradiation of the incident light, the radial repulsive force among the vibrating oxygen ions and vibrating helium ions increases the average kinetic energy of the electrons for thermal motion, thus increasing the temperature and implementing heating.

A heat exchanger system includes a heat exchanger device, which has elastocaloric elements made of elastocaloric material and is designed to move the elastocaloric elements, as a result of which said elements are deformed, so that an elastocaloric effect is achieved. The heat exchanger system further includes a vibrating unit, which generates mechanical vibrations, and a vibration transfer device arranged between the vibrating unit and the heat exchanger device, and which transfers the vibrations from the vibrating unit into the elastocaloric elements so that the elastocaloric elements move.

A heat exchanger system includes a heat exchanger device, which has elastocaloric elements made of elastocaloric material and is designed to move the elastocaloric elements, as a result of which said elements are deformed, so that an elastocaloric effect is achieved. The heat exchanger system further includes a vibrating unit, which generates mechanical vibrations, and a vibration transfer device arranged between the vibrating unit and the heat exchanger device, and which transfers the vibrations from the vibrating unit into the elastocaloric elements so that the elastocaloric elements move.

The present invention refers to a hybrid thermal apparatus comprising at least one heat exchanger and at least one heat source and/or heat sink. The thermal apparatus according to the invention is formed as a combination of a first thermal apparatus (1, 15) based on a vapour-compression principle and comprising a first medium for heat transfer, and of a second thermal apparatus (2, 16) based on an elastocaloric principle and comprising a second medium for heat transfer. Said thermal apparatuses (1, 15; 2, 16) have at least one deformable heat exchanger (3, 21) of elastocaloric material in common.

The present invention refers to a hybrid thermal apparatus comprising at least one heat exchanger and at least one heat source and/or heat sink. The thermal apparatus according to the invention is formed as a combination of a first thermal apparatus (1, 15) based on a vapour-compression principle and comprising a first medium for heat transfer, and of a second thermal apparatus (2, 16) based on an elastocaloric principle and comprising a second medium for heat transfer. Said thermal apparatuses (1, 15; 2, 16) have at least one deformable heat exchanger (3, 21) of elastocaloric material in common.

An immersion tank includes a tank main body configured to store a coolant, at least one first air bag that is provided in the tank main body, that is coupled to a bottom portion of the tank main body, that is able to be inflated toward an upper portion of the tank main body, and that is able to be deflated, from an inflated state thereof, toward the bottom portion, and a guide member that is provided outside the at least one first air bag in the tank main body and that is configured to guide the at least one first air bag during the inflation and the deflation of the at least one first air bag.

Embodiments described herein relate to a system with an electroactive substrate, a plurality of nanoparticles, and a control unit. The plurality of nanoparticles deposited in communication with the electroactive substrate. The control unit is configured to manipulate a shape of the electroactive substrate between an unactuated mode and an actuated mode to change an absorption band or an emission band of the plurality of nanoparticles. When the electroactive substrate shape is manipulated, the absorption band or the emission band of the plurality of nanoparticles is changed to tune the system for a radiative cooling based on a current dominating wavelength.

An air conditioning apparatus includes a first pump and a first intermediate heat exchanger connected in series, and a second pump and a second heat intermediate exchanger connected in series. A flow path switching mechanism including at least four pairs of first and second valves. The first valves select an outflow port of one of the first and second pumps, and the second valves select an inflow port of the other of the first and second pumps. A third intermediate heat exchanger operates as an auxiliary heat exchanger, and is detachably connected to one pair of first and second valves. A pipe is detachably connected to and communicating the inflow port and the outflow port of a second pair of the pairs of the first and second valves. At least one indoor heat exchanger is connected to a third pair of the first and second valves.

An air conditioning apparatus includes a first pump and a first intermediate heat exchanger connected in series, and a second pump and a second heat intermediate exchanger connected in series. A flow path switching mechanism including at least four pairs of first and second valves. The first valves select an outflow port of one of the first and second pumps, and the second valves select an inflow port of the other of the first and second pumps. A third intermediate heat exchanger operates as an auxiliary heat exchanger, and is detachably connected to one pair of first and second valves. A pipe is detachably connected to and communicating the inflow port and the outflow port of a second pair of the pairs of the first and second valves. At least one indoor heat exchanger is connected to a third pair of the first and second valves.