According to an embodiment of the disclosure, a desalination system includes a latent heat exchanger, a hydroclone, a compressor, and a quiescent vertical column. The latent heat exchanger is configured to receive saltwater. The latent heat exchanger includes tubes with an interior that are configured to circulate supersaturated brine with suspended salts. The hydroclone is configured to receive a flow from the latent heat exchanger. And, the hydrocodone has a flow that is substantially steam exiting the top and a flow that is substantially liquid exiting the bottom. The compressor that receives at least a portion of the flow that is substantially steam exiting the top of the hydroclone. An output of the compressor recirculating at least a portion of the flow back to the latent heat exchanger.

The present disclosure relates to a seawater desalination system which improves energy efficiency by applying a heated cooling water discharged from a nuclear power plant and high-temperature steam generated in a nuclear reactor to seawater desalination. A seawater desalination system related to an exemplary embodiment of the present disclosure includes: a steam supply pipe 40 which supplies heat exchange steam that is a part of the steam discharged from a turbine 20; a seawater supply pipe 36 which diverges from a discharge pipe 34; and a heat exchanger 50 which is connected to the steam supply pipe 40 so as to be supplied with the heat exchange steam, and connected to the seawater supply pipe 36 so as to be supplied with first seawater that is a part of the seawater discharged from a condenser 30, in which the heat exchanger 50 increases a water temperature of the first seawater by using heat included in the heat exchange steam, and the first seawater with the increased water temperature is supplied to the fresh water-generating unit 2 through a connection pipe 4, such that desalination of the first seawater is performed.

One exemplary embodiment can be a process for cooling a vent stream from a receiver. Generally, the process may include providing a refrigerant including at least one compound contained in the receiver so the refrigerant leaking into the receiver can be compatible with the process.

The present invention is related to a solar driven irrigation apparatus for converting contaminated water contained in a contaminated water body into distilled water and using said distilled water for irrigating the vegetation grown on the said irrigation apparatus, the solar driven irrigation apparatus comprising a cover in the form of a geometrical projection comprising a wall, an opening, a semi-permeable mesh, a soil layer and a chamber. The present invention also related to a process for irrigating natural vegetation using the solar driven irrigation apparatus.

An optimized system creates potable water from water vapor in the atmosphere, or purifies salt water or contaminated water. The system employs a condenser having multiple metal condensation surfaces. These condensation surfaces are cooled by coolant passing through conduits attached to the condensation surfaces. The coolant is cooled by a cooling unit. Power is supplied to the cooling unit by solar photovoltaic panels, or wind turbines, or the electric grid. The system can be mobile or fixed and can produce potable water at remote locations. The system may employ an evaporator which evaporates non-potable water into an air stream. The evaporator includes a solar or gas heater which increases the temperature of the air. Metals may be extracted from the salt water. If sewage is used, solid organic waste may be processed into combustible gas which is burned by an engine running a generator to power that system.

An evaporation-condensation system and methods of manufacturing and using the same are disclosed. The system may include a condensation surface having one or more wipers and a gas diffusion apparatus. The one or more wipers may be configured to move over the condensation surface to displace one or more of fouling material and condensed material that may be present on the condensation surface. The gas diffusion apparatus may include one or more anti-gas blades positioned substantially parallel to the condensation surface and one or more gas storage areas. The gas diffusion apparatus may be configured to guide an amount of vapor molecules towards the condensation surface and promote condensation of the vapor molecules by rotating the one or more anti-gas blades around a central axis and displacing an amount of non-condensable gas into the one or more gas storage areas.

One exemplary embodiment can be a process for cooling a vent stream from a receiver. Generally, the process may include providing a refrigerant including at least one compound contained in the receiver so the refrigerant leaking into the receiver can be compatible with the process.