An adiabatic cooling system includes a condenser coil and at least one mist chamber positioned around the condenser coil such that at least a portion of intake air for the adiabatic cooling system passes through the mist chamber prior to contacting the condenser coil. The at least one mist chamber includes a first cooling pad with a first intake-side face and a first output-side face and a second cooling pad with a first intake-side face and a first output-side face. The second-intake side face of the second cooling pad faces the first output-side face of the first cooling pad and is separated from the first-output side face of the first cooling pad by a gap. The gap includes a mist of water.

A spray structure for temperature regulation includes a spray system and a heat exchange cycling system. The heat exchange cycling system includes a thermal chip for providing a temperature regulation water which is received in the spray system to exchange energies. After the temperature regulation water is flowed through the thermal chip to exchange energies, the temperature regulation water is atomized by the spray system to regulate an inner temperature inside a space.

A spray structure for temperature regulation includes a spray system and a heat exchange cycling system. The heat exchange cycling system includes a thermal chip for providing a temperature regulation water which is received in the spray system to exchange energies. After the temperature regulation water is flowed through the thermal chip to exchange energies, the temperature regulation water is atomized by the spray system to regulate an inner temperature inside a space.

A device for cooling a substance stored within the device is provided. The device has a body with an internal compartment. The compartment can be sealed closed and can be accessed for adding a substance to be cooled to the compartment or removing the substance from the compartment. The body of the device has an internal cavity that surrounds the exterior of the compartment holding the substance to be cooled. Fluidized coolant is injected into the cavity through an injection port to cool the substance for use.

A spray structure for temperature regulation comprises a spray system and a heat exchange cycling system. The heat exchange cycling system includes a thermal chip for providing a temperature regulation water which is received in the spray system to exchange energies. After the temperature regulation water is flowed through the thermal chip to exchange energies, the temperature regulation water is atomized by the spray system to regulate an inner temperature inside a space.

A dry air-water heat exchanger, wherein a cooling fan, a main tube row, at least an air pre-cooling water tube row, a water evaporator and a catchment chamber are set in a housing, wherein the air pre-cooling water tube row is provided to pre-cool for the entering air, and the water evaporator is provided to evaporate water for heat exchanging after air pre-cooling to thereby lower the temperature of the entering air, and the circulating refrigerant (or the circulating water) inside the main the row is heat exchanged by the main tube row, to thereby perform the high-efficiency cooling process with minimum energy and water consumption, to thereby cool and lower the temperature of the circulating refrigerant (or circulating water), to improve the cooling efficiency of the circulating refrigerant (or circulating water), and achieve the purpose of reducing bacterial growth and scale formation.

A dry air-water heat exchanger, wherein a cooling fan, a main tube row, at least an air pre-cooling water tube row, a water evaporator and a catchment chamber are set in a housing, wherein the air pre-cooling water tube row is provided to pre-cool for the entering air, and the water evaporator is provided to evaporate water for heat exchanging after air pre-cooling to thereby lower the temperature of the entering air, and the circulating refrigerant (or the circulating water) inside the main the row is heat exchanged by the main tube row, to thereby perform the high-efficiency cooling process with minimum energy and water consumption, to thereby cool and lower the temperature of the circulating refrigerant (or circulating water), to improve the cooling efficiency of the circulating refrigerant (or circulating water), and achieve the purpose of reducing bacterial growth and scale formation.

An elevated platform cooling assembly includes a portable assembly frame; a mast carried by the assembly frame, the mast selectively positional between a folded, collapsed transport configuration and an erected, extended functional and operational configuration; a fan carried by the mast; a fan motor drivingly engaging the fan; a working fluid pump and supply mechanism disposed in fluid communication with the fan motor; and 4 prime mover drivingly engaging the working fluid pump and supply mechanism. A method of cooling an elevated platform is also disclosed.

A jet flow evaporative cooling system that cools a heat generation unit with a jet flow of liquid includes a heat transfer portion integrally formed with a cooling portion configured to receive the jet flow of liquid and an arrangement portion on which the heat generation unit is arranged, an opening portion configured to jet a liquid supplied from a supply portion to the cooling portion, a drain portion configured to drain the liquid, and a chamber configured to accommodate the opening portion, the drain portion, and the cooling portion and configured to not accommodate the arrangement portion therein, wherein the chamber is maintained under a reduced pressure environment, wherein the opening portion is configured to jet the liquid to the cooling portion, wherein at least a part of the cooling portion is inclined, and wherein the liquid is drained from the drain portion via the cooling portion.

A jet flow evaporative cooling system that cools a heat generation unit with a jet flow of liquid includes a heat transfer portion integrally formed with a cooling portion configured to receive the jet flow of liquid and an arrangement portion on which the heat generation unit is arranged, an opening portion configured to jet a liquid supplied from a supply portion to the cooling portion, a drain portion configured to drain the liquid, and a chamber configured to accommodate the opening portion, the drain portion, and the cooling portion and configured to not accommodate the arrangement portion therein, wherein the chamber is maintained under a reduced pressure environment, wherein the opening portion is configured to jet the liquid to the cooling portion, wherein at least a part of the cooling portion is inclined, and wherein the liquid is drained from the drain portion via the cooling portion.