A water treatment system is provided that provides desalination of water for aquifer recharge, agricultural, mining or industrial use. The water treatment system comprises: an input, for receiving contaminated water to be treated; an output, for providing treated water, wherein a level contamination of a contaminant i s lower in the treated water than in the contaminated water; and a hydrophilic membrane between the input and the output. The hydrophilic membrane configured to allow water to pass from the input to the output, and to at least partly impede the passage of the contaminant from the input to the output. In use, a low pressure is applied to the output to cause the water to flow across the membrane.

A filtration system suitable for recovering base stock from used lubricating oil and other applications pass feedstock over nano-filtration membranes assembled as a stack of membranes all experiencing parallel flow. On exiting a first stack of membranes the feedstock passes through an opening in a pressure-sustaining separator plate to flow in the reverse direction past a second stack of membranes and subsequently establish a serpentine flow of feedstock through multiple stacks of membranes. The stacks of membranes all share a common pressure containment vessel. Pressure boosters installed in the flow-through openings of separator plates separating consecutive stacks can serve to restore lost pressure of the feedstock and maintain effective permeation of permeate through the membranes. A pressure control valve at the outlet to the permeate-receiving cavities of a stack can be used to adjust the trans-membrane pressure.

Extraction Apparatus (2) for extraction of a biomass comprises an extraction vessel (4) for containing a biomass. Electrical heating tape (6) is provided around the vessel (4) for maintaining the temperature of the wall of vessel (4). Upstream of vessel (4) is a solvent recycling vessel (8) which is fitted with a cooling coil (10) which communicates with an external refrigeration unit (12). Operation of unit (12) is arranged to cool (and thereby liquefy) solvent in the vessel (8). A solvent pump (22) is arranged to pump liquid between vessel (8) and vessel (4) via an electrically powered heat exchanger (24). The heat exchanger (24) is arranged to increase the temperature of solvent flowing through it very rapidly which allows the temperature of solvent introduced into extraction vessel (4) to be very rapidly changed in a step-wise manner.

A device controls temperature of soft water and/or permeate for dialysis applications based on the principle of reverse osmosis. The device, which can be used in a dialysis system, includes a buffer tank for heat which is coupled in terms of heat flow to a heat source and/or heat sink and receives or contains a fluid heat transfer medium. A soft water heat exchanger is connected on the primary side to the buffer tank by a pump circuit for the heat transfer medium, which is connected on the secondary side to the soft water supply line. A permeate heat exchanger is connected on the primary side to the buffer tank by a pump circuit for the heat transfer medium, which is connected on the secondary side to the permeate extraction line.

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.

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.

A method including increasing modifying a volume of seawater that holds an amount of dissolved inorganic carbon; acidifying the amount of seawater; and collecting an amount of carbon dioxide from the acidified seawater. A system including an electrodialysis unit including an acidified solution compartment, a basified solution compartment, a membrane and an acidified solution output compartment; a vessel coupled to an inlet of the acidified solution compartment and operable to contain a modified volume of seawater therein; and a desorption unit coupled to the acidified compartment output, the desorption unit operable to receive carbon dioxide gas from a solution from the acidified output compartment.

A method including increasing modifying a volume of seawater that holds an amount of dissolved inorganic carbon; acidifying the amount of seawater; and collecting an amount of carbon dioxide from the acidified seawater. A system including an electrodialysis unit including an acidified solution compartment, a basified solution compartment, a membrane and an acidified solution output compartment; a vessel coupled to an inlet of the acidified solution compartment and operable to contain a modified volume of seawater therein; and a desorption unit coupled to the acidified compartment output, the desorption unit operable to receive carbon dioxide gas from a solution from the acidified output compartment.

Disclosed is a refrigeration system including a heat transfer fluid circulation loop configured to allow a refrigerant to circulate therethrough. A purge gas outlet is in operable communication with the heat transfer fluid circulation loop. The system also includes at least one gas permeable membrane having a first side in operable communication with the purge gas outlet and a second side. The membrane includes a porous inorganic material with pores of a size to allow passage of contaminants through the membrane and restrict passage of the refrigerant through the membrane. The system also includes a permeate outlet in operable communication with a second side of the membrane.

A reverse osmosis (RO) system is described that is connected to a dialysis machine and is capable of using heated purified water to clean and disinfect an external connection section or portion disposed between the RO systems and the dialysis unit (or any other external heat tolerant device) without forming a closed loop system between both systems before and during a heat forward process. This can be accomplished without the need for direct/indirect or wired/wireless communication with the dialysis unit or the need to introduce a chemical cleaner or process that would require further rinsing after chemical disinfection.