The invention relates to 100% renewably-powered desalination/water purification stations for universal applications, the station is disruptive, scalable, amphibious and deportable to seawater, brackish or spill oil sites for simple wave-powered and autonomous operations, the station has a mooring assembly with pumping-purification-delivery subsystems powered by wave and solar energies, the pumping subsystems has the simplest, most efficient wave push/pull pump mechanisms powered by amplified wave centrifugal forces , the mechanical purifications has turbine filters, reverse-osmosis filters, forward-osmosis filters and relief valves to backwash buildups without releasing brine, release water through collecting spill oil, the solar thermal purifications are provided with distilling processes under vaccine conditions, the delivery subsystems with wave turbines and solar panels for generating electricity, propellering and transferring the stations for delivering fresh waters to destinations under GPS guide with the lowest LCOW.

The invention relates to 100% renewably-powered desalination/water purification stations for universal applications, the station is disruptive, scalable, amphibious and deportable to seawater, brackish or spill oil sites for simple wave-powered and autonomous operations, the station has a mooring assembly with pumping-purification-delivery subsystems powered by wave and solar energies, the pumping subsystems has the simplest, most efficient wave push/pull pump mechanisms powered by amplified wave centrifugal forces , the mechanical purifications has turbine filters, reverse-osmosis filters, forward-osmosis filters and relief valves to backwash buildups without releasing brine, release water through collecting spill oil, the solar thermal purifications are provided with distilling processes under vaccine conditions, the delivery subsystems with wave turbines and solar panels for generating electricity, propellering and transferring the stations for delivering fresh waters to destinations under GPS guide with the lowest LCOW.

Certain embodiments may provide a method for controlling a desalination system. The method may include performing a desalination procedure with salt-water in a desalination compartment of the desalination system. The method may also include extracting brine and freshwater from the desalination procedure. The method may further include directing the brine to a brine treatment compartment of the desalination system, and the freshwater to a firewater container. In addition, the method may include performing a brine treatment procedure in the brine treatment compartment. Further, the method may include collecting concentrated brine from the brine treatment compartment.

Certain embodiments may provide a method for controlling a desalination system. The method may include performing a desalination procedure with salt-water in a desalination compartment of the desalination system. The method may also include extracting brine and freshwater from the desalination procedure. The method may further include directing the brine to a brine treatment compartment of the desalination system, and the freshwater to a firewater container. In addition, the method may include performing a brine treatment procedure in the brine treatment compartment. Further, the method may include collecting concentrated brine from the brine treatment compartment.

An evaporation unit for evaporating liquid from a solution, comprising: a plurality of evaporation elements extending radially outwardly from a common central axis, the evaporation elements being configured for rotation about the central axis; and a liquid discharge system for distributing the liquid onto the evaporation elements to promote evaporation.

Disclosed are a desalination device and processes of desalination using the device. The device is directly ocean-situated and fully nature-powered with on intake, no brine production, and no electricity consumption. The device contains a heating unit, configured to receive a dry air stream and heat the dry air stream with one or more renewable energy sources to produce a heated air stream; a humidifier, configured to receive the heated air stream, evaporate at least portion of water present in the humidifier and humidify the heated air stream to produce a wet air stream, a cooling unit, configured to receive the wet stream and cool the wet air stream resulting in condensation of at least a portion of the moisture to produce fresh water and a dehumidified air stream; and a fresh water collection tank, configured to collect at least a portion of the fresh water.

An electric water desalination assembly for desalinating water without burning fossil fuels includes an evaporator and a renewable electrical power generation system. The renewable electrical power generation system is electrically coupled to the evaporator for providing power to the evaporator. The evaporator is fluidly coupled to a source of salt water for boiling the salt water into desalinated steam. Additionally, the evaporator is fluidly coupled to the water desalination system for processing the desalinated steam into freshwater. Additionally, the water desalinating system is fluidly coupled to a freshwater distribution system. In this way the freshwater distribution system receives freshwater from the water desalination system.

An electric water desalination assembly for desalinating water without burning fossil fuels includes an evaporator and a renewable electrical power generation system. The renewable electrical power generation system is electrically coupled to the evaporator for providing power to the evaporator. The evaporator is fluidly coupled to a source of salt water for boiling the salt water into desalinated steam. Additionally, the evaporator is fluidly coupled to the water desalination system for processing the desalinated steam into freshwater. Additionally, the water desalinating system is fluidly coupled to a freshwater distribution system. In this way the freshwater distribution system receives freshwater from the water desalination system.

Proposed is a complex system of offshore wind power generation, seawater desalination, and water electrolysis. The system may include a wind power generator which generates electric power in such a manner that blades are rotated by wind power. The wind power generator may include a cooler for preventing a overheating phenomenon caused by electric power generation. The system may also include a seawater desalination apparatus which desalinates seawater by using hot water discharged after heat exchange through the cooler. The system may further include a water electrolysis apparatus which receives fresh water produced by the desalination apparatus and a heat source discharged therefrom to use the fresh water and heat source for producing hydrogen. A part of a heat source discharged from the water electrolysis apparatus after the production of hydrogen may be heat-exchanged with the cooler, and heat-exchanged with the heat source discharged from the desalination apparatus.

Disclosed are a desalination device and processes of desalination using the device. The device is directly ocean-situated and fully nature-powered with on intake, no brine production, and no electricity consumption. The device contains a heating unit, configured to receive a dry air stream and heat the dry air stream with one or more renewable energy sources to produce a heated air stream; a humidifier, configured to receive the heated air stream, evaporate at least portion of water present in the humidifier and humidify the heated air stream to produce a wet air stream, a cooling unit, configured to receive the wet stream and cool the wet air stream resulting in condensation of at least a portion of the moisture to produce fresh water and a dehumidified air stream; and a fresh water collection tank, configured to collect at least a portion of the fresh water.