The present application comprises symbiotic reverse osmosis train system for maximizing desalinated water recovery, meanwhile yielding high salinity brine suitable for osmotic power generation or commercial salt production; trains comprise series of number of cells operating in interrelated sequential pattern within a salinity field. Each cell forms a closed hydraulic brine loop having pumping means, power recovery means and shared semipermeable membranes between adjacent cells, defining the boundaries of flow path within a given cell, using applicant's technology for semipermeable Flat Sheet Membranes [FSM] or Hollow Fiber Membranes [HFM] intended for new and novel development in Hypersalinity processes and applications in desalination and osmotic power generation of brackish, seawater and brines of 15% salinity or more. Charging each cell in the train of plurality of cells with a formulated brine having a specified ionizable inorganic salt concentration and type, without permitting mixing of the given brines among the adjacent cells in the plurality of cells, allowing the train of multiple cells to achieve water recovery exceeding 85% with concentrated rejected brine of 28-30% salt content that is recoverable by evaporation/crystallization for commercial use. Highlighting, the first of its kind, a large scale Seashore Tower of flat Sheet membrane [FSM] for Induced Osmotic Desalination Plant of a capacity 28-56 million cubic meter per year (15 billion gallons per year) at a recovery rate of 85%, and rejected brine salinity of 28-30%, either used for sodium chloride salt recovery of 1-2 million metric tons per year, or to generate Induced Osmotic Power of 25-50 MW.

A process for solution mining of minerals is disclosed. The process comprises injecting an unsaturated stream (150) at an injection pressure into a mineral formation (130) to dissolve the mineral and extracting a high concentration stream (110) containing said dissolved mineral. The process comprising converting latent osmotic energy present in said high concentration stream into an increase in the total pressure of said stream by passage through an osmotic power unit (200) and generating electricity and reducing to the injection pressure the total pressure of a reduced concentration output stream (150) by passage through a power generating device (250) and using the reduced concentration output stream (150) at the injection pressure as the unsaturated stream (150). A process for storing a fuel in an underground formation is also disclosed.

The present invention concerns a device for producing electrical energy comprising two cells intended to contain two solutions of different concentrations of at least one solute and separated by at least one separation membrane in which channels are arranged, each of the cells being provided with an electrode intended to be in contact with the solution that said cell will contain, characterized in that the walls of the channels consist of a material chosen from boron nitride, carbon doped with boron, boron nitride doped with carbon, or any other mixture of the elements boron, carbon and nitrogen, and a method for producing electrical energy that implements such a device.

An electroosmotic actuator configured to generate a haptic response is described. The electroosmotic actuator includes a flexible structure with a non-zero thickness less than 2 millimeters (mm) configured to be worn on a portion of a user's body. The flexible structure includes a flexible printed circuit board having a plurality of electrodes, a fluid-filled reservoir, individually-controlled pouches in fluid communication with the fluid-filled reservoir, a respective individually-controlled pouch associated with two electrodes of the plurality of electrodes. Furthermore, fluid from the fluid-filled reservoir moves into the respective individually-controlled pouch of the individually-controlled pouches when a non-zero voltage (V) less than 700 V is provided to the two electrodes by a power source coupled to the flexible printed circuit board, thereby causing haptic feedback to be provided to the portion of the user's body on which the flexible structure is worn.

A method of operating a dual reverse osmosis/pressure retarded osmosis plant, including when electricity costs less than a first predetermined price, moderate salinity water is pumped into the first portion of a pressure vessel having first and second portions separated by a water permeable/salt impermeable osmotic membrane to yield desalinated permeate in the second portion and brine in the first portion. Further, when electricity costs greater than the first predetermined price, low salinity water is pumped into the second portion and brine is pumped into the first portion to yield pressurized moderate salinity water in the second portion which is run through an energy recovery device to generate electricity. The salinity of the low salinity water is lower than the salinity of the moderate salinity water, and the salinity of the moderate salinity water is lower than the salinity of the brine.

A power generation process is disclosed, the process comprises dissolving a solute (10) into an unsaturated stream (140) to produce a high concentration stream (130) and converting latent mixing energy present in a high concentration input stream (130) into power by passage through a power unit (20) in which the concentration of the high concentration input stream (130) is reduced. The process comprises using a reduced concentration output stream (140) derived from the high concentration input stream (130) following passage through the power unit (20) as the unsaturated stream (140). A first fraction of the high concentration stream (130) is passed to the power unit (20) for use as the high concentration input stream (130) and a second fraction of the high concentration stream (130) is output from the process.

A system for generating electricity from a high density liquid and a low density liquid is provided. The system includes a first liquid chamber, a first drive chamber, at least one permeable wall and at least one pressure retaining osmosis membrane, a first ejector, and a first liquid channel; and a second liquid chamber, a second drive chamber, at least one permeable wall and at least one pressure retaining osmosis membrane, a second ejector, and at least two electrodes.

A method of desalinating water, including the steps of when electricity costs between a first predetermined price and a second predetermined price, fill water is pumped into a reverse osmosis desalination unit to yield desalinated permeate and saltwater having a first salinity, when electricity costs less than the first predetermined price, fill water is pumped into a reverse osmosis desalination unit to yield desalinated permeate and saltwater having a second salinity, and when electricity costs greater than the second predetermined price, pure water is flowed into a reverse osmosis unit to yield pressurized saltwater which is run through a turbine to generate electricity. The first salinity is lower than the second salinity.

A nano check valve osmosis and energy collection method and device are provided, which includes principles and methods of osmosis and energy collection technology proposed based on principles of nano check valves and osmotic effects. By providing two semipermeable membranes and filling a solution, cooperating with a concentration control module, solution concentrations at interfaces of the semipermeable membranes are regulated. This ensures that concentrations near the two semipermeable membranes are different, allowing for regulation of osmotic pressure and creation of a check valve effect. It automatically rectifies disordered, high-speed thermal motion of solvent molecules into an orderly unidirectional flow, forming potential energy of the liquid level or kinetic energy of liquid flow for energy storage or power generation. The device can extract molecular thermal kinetic energy from the environment to generate electricity, without consuming energy resources or increasing the Earth's temperature rise.

A method of desalinating water, including the steps of when electricity costs between a first predetermined price and a second predetermined price, fill water is pumped into a reverse osmosis desalination unit to yield desalinated permeate and saltwater having a first salinity, when electricity costs less than the first predetermined price, fill water is pumped into a reverse osmosis desalination unit to yield desalinated permeate and saltwater having a second salinity, and when electricity costs greater than the second predetermined price, pure water is flowed into a reverse osmosis unit to yield pressurized saltwater which is run through a turbine to generate electricity. The first salinity is lower than the second salinity.