The present invention relates to a high-efficiency air water system for a tropical climate, including a filtration system, in which an evaporator is provided in an internal accommodating space of a main body, and a condenser is installed in a perforated portion formed passing through a side wall of the main body, so that air cooled in the main body is used to dissipate heat generated in the condenser so as to improve dehumidification efficiency. The configuration of the high-efficiency air water system comprises: an air suctioning unit that suctions and supplies external air; a water generating unit that condenses moisture from the air supplied from the air suctioning unit to generate water; and a water purifying unit that filters and purifies the water generated by the water generating unit to a drinkable or usable state. The water generating unit is constituted by including a main body having an accommodating space provided therein, and an evaporator, a hopper, a water storing part, a condenser, and a compressor are installed in the main body.

The present invention relates to a high-efficiency air water system for a tropical climate, including a filtration system, in which an evaporator is provided in an internal accommodating space of a main body, and a condenser is installed in a perforated portion formed passing through a side wall of the main body, so that air cooled in the main body is used to dissipate heat generated in the condenser so as to improve dehumidification efficiency. The configuration of the high-efficiency air water system comprises: an air suctioning unit that suctions and supplies external air; a water generating unit that condenses moisture from the air supplied from the air suctioning unit to generate water; and a water purifying unit that filters and purifies the water generated by the water generating unit to a drinkable or usable state. The water generating unit is constituted by including a main body having an accommodating space provided therein, and an evaporator, a hopper, a water storing part, a condenser, and a compressor are installed in the main body.

A support system for rigid media of an evaporative cooler includes a water distribution pipe, a bottom support including at least one sidewall extending from a bottom surface of the bottom support, and a rigid media block having a bottom end at least partially supported by the bottom surface of the bottom support, the rigid media block including a slot formed across a top surface thereof and having the water distribution pipe running through the slot, the slot having a depth selected such that a gap is formed below the water distribution pipe when the water distribution pipe is disposed within the slot and the bottom end of the rigid media block is engaged with the bottom surface of the bottom support.

A process control apparatus includes a housing, a process control device disposed in the housing, and a temperature control device operably coupled to the housing for regulating a temperature of an atmosphere internal to the housing. The temperature control device includes a vortex tube and a flow control valve. The flow control valve is coupled to the vortex tube and includes a temperature sensing feature configured to sense a temperature of an atmosphere internal to the housing and configured to move a control element of the flow control valve based on the sensed temperature between a plurality of positions to selectively direct the flow of fluid from the first and second vortex outlets to the atmosphere internal to the housing.

A frame for an evaporative cooler includes a bottom channel including a bottom panel and two bottom-side panels, a top channel including a top panel and two top-side panels, and a pair of side channels disposed between, and engaged with, each of the bottom channel and the top channel. The side channels may include a vertical side panel, a flanged bottom, a flanged top, and a pair of flanged sides, where the flanged bottom is engaged with the bottom panel, the flanged top is engaged with the top panel, and each of the pair of flanged sides is engaged with a bottom-side panel of the bottom channel and a top-side panel of the top channel.

An air-cooled heat exchanger (6) arranged in a gas processing facility for performing a liquefaction process of natural gas is configured to supply cooling air to a tube (63) through which a fluid to be cooled is caused to flow, to thereby cool the fluid to be cooled, and a mist supply section (7) is configured to supply mist obtained by spraying demineralized water, to thereby cool the cooling air. Further, the mist supply section (7) is configured to spray the demineralized water from a lateral position on an upstream side of an intake.

An air-cooled heat exchanger (6) arranged in a gas processing facility for performing a liquefaction process of natural gas is configured to supply cooling air to a tube (63) through which a fluid to be cooled is caused to flow, to thereby cool the fluid to be cooled, and a mist supply section (7) is configured to supply mist obtained by spraying demineralized water, to thereby cool the cooling air. Further, the mist supply section (7) is configured to spray the demineralized water from a lateral position on an upstream side of an intake.

A cooling module is included in a supercritical fluid power generation system and is used in supercritical fluid supply method. The cooling module includes a cooling source flow unit in which a cooling source supplied from an outside flows, a cooler unit, and a buffer unit. The cooler unit enables a gas-phase working fluid introduced through a working fluid inlet port to undergo a phase change into a liquid-phase working fluid by performing heat exchange with the cooling source flowing in the cooling source flow unit. The buffer unit is provided under the cooler unit and receives and stores the liquid-phase working fluid cooled by the cooler unit. The stored liquid-phase working fluid is supplied to an outside fluid pump. Consequently, stable supply of the working fluid is achieved by the supercritical fluid power generation system.

A cooling module is included in a supercritical fluid power generation system and is used in supercritical fluid supply method. The cooling module includes a cooling source flow unit in which a cooling source supplied from an outside flows, a cooler unit, and a buffer unit. The cooler unit enables a gas-phase working fluid introduced through a working fluid inlet port to undergo a phase change into a liquid-phase working fluid by performing heat exchange with the cooling source flowing in the cooling source flow unit. The buffer unit is provided under the cooler unit and receives and stores the liquid-phase working fluid cooled by the cooler unit. The stored liquid-phase working fluid is supplied to an outside fluid pump. Consequently, stable supply of the working fluid is achieved by the supercritical fluid power generation system.

The present disclosure provides a drying chamber (condenser) including a container having a steam intake opening, the condenser liquefying steam taken from the steam intake opening into the container, and the drying chamber including a cooling pipe which is disposed in the container and through which coolant circulates.