An apparatus for water purification includes a membrane distillation (MD) cell; an air conditioner; a photovoltaic solar collector (PVSC) cell including a transparent photovoltaic cell configured to generate electricity, an absorber plate configured to absorb solar radiation, and a flow tube configured to receive the fluid; a first heat exchanger; a second heat exchanger; and a fluid source storing a fluid configured to circulate through the apparatus, wherein the fluid circulating in the apparatus carries heat generated by a condenser of the air conditioner to the PVSC cell where the fluid interacts with the PVSC cell to increase a temperature of the fluid to become a heated fluid; and the heated fluid circulates to the hot channel where the heated fluid drives the distillation of water in the MD cell.

A thermally reflective membrane apparatus comprises a housing structure, and a thermally reflective membrane contained within the housing structure. The thermally reflective membrane comprises a semipermeable structure, and a porous, thermally reflective structure physically contacting the semipermeable structure. The porous, thermally reflective structure comprises discrete thermally reflective particles, and a binder material coupling the discrete thermally reflective particles to one another and the semipermeable structure. A fluid treatment system and method of treating a fluid are also described.

A fluid power circuit with a switch-mode power transformer used to transfer power while keeping the pressure of power source and reverse osmosis processes relatively decoupled. The switch-mode power transformer uses the inertia of a hydraulic motor driven electric generator and switching of a hydraulic motor inlet between high and low-pressure ends to decrease the pressure at which power is being transmitted to a reverse osmosis process.

The present disclosure to an apparatus for membrane distillation using a solar absorber and a heat pump, in which in the implementation of a membrane distillation process for producing treated water using a temperature difference between raw water and a coolant, raw water is heated using the solar absorber with improved heat collection efficiency, and through this, the treated water production efficiency of the membrane distillation process is improved.

A solar distillation device includes a feed water chamber having an open interior feed water compartment and a feed water inlet to the feed water compartment. A distillate chamber has a top and sides and an open interior distillate compartment, and a distillate water outlet in liquid communication with the distillate compartment. The top, the rear wall, and the sides of the distillate chamber includes a solar radiation transmissive portion. A distillation membrane separates the feed water compartment from the distillate compartment, and has a feed water facing surface and a distillate facing surface. The membrane can include a porous hydrophobic material, and the distillate surface of the distillation membrane can be black. The transmissive portion allows solar radiation to pass through the top, the rear wall, and the sides of the distillate chamber and strike the distillation membrane.

The present invention discloses a pressure converter system for sustainably forcing saline water through a semi-permeable membrane, comprising a hydraulic oil pump, a hydraulic oil cylinder comprising pressurized oil generated from the hydraulic oil pump, a sustainable energy source for powering the hydraulic oil pump, a saline water cylinder containing saline water, wherein the hydraulic oil cylinder and the saline water cylinder are connected using a piston and an electrical circuit for determining a direction of movement of the piston. This system may be developed to a stand-alone desalination facility comprising a ducted windmill that can harvest energy from a wide range of wind speeds, especially very low wind speeds. Because of the above, the present invention successfully converts mechanical energy to high pressure that is required to produce fresh water from saline water.

In some embodiments, the present disclosure pertains to systems and methods for distilling a fluid by exposing the fluid to a porous membrane that includes a surface capable of generating heat. In some embodiments, the heat generated at the surface propagates the distilling of the fluid by converting the fluid to a vapor that flows through the porous membrane and condenses to a distillate. In some embodiments, the surface capable of generating heat is associated with a photo-thermal composition that generates the heat at the surface by converting light energy from a light source to thermal energy. In some embodiments, the photo-thermal composition includes, without limitation, noble metals, semiconducting materials, dielectric materials, carbon-based materials, composite materials, nanocomposite materials, nanoparticles, hydrophilic materials, polymers, fibers, meshes, fiber meshes, hydrogels, hydrogel meshes, nanomaterials, and combinations thereof. Further embodiments pertain to methods of making the porous membranes of the present disclosure.

An ocean wave actuated gravitational desalination apparatus and system for generating potable water comprised of, a box platform with a piston pump at sea level, an inverted prism shaped subterranean water tank below sea level, and a desalination processing structure above sea level. When the ocean waves pass over the top of the box platform, the piston pump is raised to open a set of valves to let the sea water into a cylindrical chamber. When the piston goes down, the valves close and a second set of valves open to release the water into the subterranean tank to be further released into containers on a carousal structure that move on rails by gravity. The water in the containers is emptied into holding and pre-filtration tanks and forced through filters into a pipe by the actions of a hydraulic oil pump and the filtered water released for storage and use.

Techniques for solar thermal water purification by recycling photovoltaic reflection losses are provided. In one aspect, a solar thermal water purification system includes: a water purification component for desalinating salt water, the water purification component having multiple stages through which the salt water passes, and condensers in each of the stages; and a photovoltaic component configured to heat the salt water prior to the salt water entering a first stage of the water purification component, wherein desalinated water evaporates and condenses in each of the stages to be collected as pure water. A system using reverse osmosis and a heat-driven water pump is also provided. Methods for water purification are also provided.

Methods and systems for desalinating feedwater are disclosed. The system includes at least one feedwater source, a reverse osmosis module, an input feedwater stream fed to the reverse osmosis module, and a control module. The feedwater stream comprises water from at least one feedwater source, e.g., from two or more feedwater sources of different salinities. The control module analyzes the level of energy available to the system, and increases the salinity of the input feedwater stream proportional to an increase in available energy. Feedwater stream salinity can be adjusted to reach water demand targets and fully utilize variable power inputs from renewable sources.