The present invention relates in general to the field of water kiosks, and more specifically, to an emergency water filtration kiosk and method of delivering clean and safe water using the emergency water filtration kiosk. One aspect of the emergency water filtration kiosk and method of use may include a four-stage water filtration system to better purify, clean, and improve the taste of water. The emergency water filtration kiosk and method of use may further include a turn-key variable pump system that is configured to supply water to the emergency water filtration kiosk via three alternative power sources. The purpose of the invention is to provide a self-contained and rapidly deployable emergency response water filtration kiosk and method of use that delivers clean and safe drinking water to people in need after a natural disaster. An additional purpose of the invention is to provide an emergency water filtration kiosk and method of use that offers a wide variety of on-board integrated pumping solutions to supply water to the filtration kiosk under any power condition.

Provided herein are atmospheric moisture harvester systems, as well as methods using such systems, for capturing water from surrounding air. The systems and methods use adsorbents to adsorb water from the air. For example, the adsorbents may be metal-organic frameworks. The systems and methods desorb this water in the form of water vapor, and the water vapor is condensed into liquid water and collected. The liquid water is suitable for use as drinking water.

A method for storing solar energy and generating electric power comprising the steps of utilizing a solar powered water treatment device (2) to convert non-potable water (3) into distillate (4) and concentrate (5), storing the distillate and the concentrate in a distillate storage tank (104) and a concentrate storage tank (105) respectively and feeding the distillate from the distillate storage tank and the concentrate from the concentrate storage tank to a salient gradient power device (106) to generate electric power.

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.

A low to medium output solar fluid evaporation/distillation system is described that is practical to manufacture using current photovoltaic solar panels or enhanced photovoltaic panels designed exclusively for this application. The system works in conjunction with a water feed in system that provides a minimum quality of water or other fluid to the distillation chamber. The system utilizes a warming envelope and can have optimized dielectric mirrors designed to enhance the water purity and increase output.

The present disclosure relates to a method and device for obtaining distillate from non-potable water. The method comprises the steps of utilizing solar power from a solar power system to produce electricity and steam, utilizing the electricity and the steam in a water treatment device to convert the non-potable water into distillate and concentrate, transporting at least a part of the distillate to consumers for use. The method and device provide multiple effect distillation (MED) combined with vapour compression (VC) being able to work 24 hours a day only on solar energy.

Provided herein are atmospheric moisture harvester systems, as well as methods using such systems, for capturing water from surrounding air. The systems and methods use adsorbents to adsorb water from the air. For example, the adsorbents may be metal-organic frameworks. The systems and methods desorb this water in the form of water vapor, and the water vapor is condensed into liquid water and collected. The liquid water is suitable for use as drinking water.

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.

A hybrid system for freshwater production utilizing the latent heat of condensation of atmospheric air humidity as a source of thermal energy to evaporate freshwater in a brine or saline and delivered to the saline evaporating chamber by a heat pump. Distillates form on both sides of the heat transfer, and intensification of humidity condensation in the air leads to the intensification of saline evaporation contributing to the overall increased yield of freshwater. The process is optimized by integrated systems in which the waste heat of inside and outside sources and the heat sink effect of the saline feed amplify the COP and SEER indexes of the installation. The technological regimes in which the equipment is used are intensified and optimized, cutting the desalination costs to the ranges affordable to the general population residing in arid regions in need of such technology.

A potable water producing system for disposition at a salt water body and methods of producing potable water are provided. The system includes a wave energy conversion system (AWECS) and a portable filtration system. The AWECS forms a floating articulated barge having an onboard desalination system including reverse osmosis membranes. The filtration system is a sand filter residing on a damping plate submerged in the salt water body and filters the adjacent salt water for providing filtered salt water to the onboard desalination system. Wave action on the articulated barge provides energy to pump and pressurize the filtered salt water from the sand filter to the reverse osmosis membranes to produce potable water. The wave action on the articulated barge effects shaking of the reverse osmosis membranes, thereby rendering them self-cleaning. The potable water can be used for various applications, e.g., bottling, replenishing aquifers, ground and/or aquifer remediation, irrigation, etc.