Treatment of wastewater containing heavy metal ions, and providing an efficient bio-electrochemical copper ion removal system. Based on the technology of microbial fuel cell and membrane bioreactor, using sacrificial aluminum anode and externally supplied power from microbial fuel cell, aluminum micro-electrolysis is realized. Aluminum hydrate ion, produced by micro-electrolysis of aluminum under the action of water molecules, is naturally efficient flocculating agent. The flocculating agent of this system is self-generated without any external reagent addition. The process of flocculation is mild, and the flocculation removal efficiency of copper ion is high. Under the filtration and screening effect of bifunctional conductive membrane, the copper ion in the cathode chamber can be completely removed. The concentration of the copper ion in the effluent of the system can fully meet the national first-level discharge standard, and the effluent can be recycled and reused.

A method for treating waste water from various sources, removing solids and pollutants and then either evaporating or recycling the treated water. Waste water is received at the treatment site where the solids are removed before entering the system for treatment. The treatment consists of injecting the pressurized waste water into the exhaust stream of a turbine which is at least 900 degrees Fahrenheit, capturing it in pipes to keep it at above 600 degrees Fahrenheit for at sufficient time, temperature and turbulence to dispose of any volatile organic compounds. The system continues to either immediate atmospheric venting of the remaining treated water or in collecting ponds or tanks for evaporation. If the water is to be recovered it is cooled, condensed and sparged to release exhaust gases and the exhausted and condensed water is recovered.

A Biorefinery System (BIOSYS) that effectively treats all human activity-derived waste (black water, grey water, and food waste streams) using biological systems and that produces as process by-products: recovered potable water, liberated free oxygen, edible protein cake (with and without lipids), soil amendments, and machinery lube oils. Additionally, the system captures and chemically binds carbon dioxide into microbial cells and associated by-products, thus producing recovered usable returned cabin air.

A liquid distiller device. The device includes a dome impermeable to steam, configured to host the liquid to be distilled in an inferior part of its volume; a heat pump arranged in the interior of the dome and provided with a condenser which releases heat and an evaporator which absorbs heat, respectively conforming a hot part and a cold part of the heat pump; a radiator connected to the hot part of the heat pump, suitable for evaporating the liquid to be distilled; a condenser deposit connected to the cold part of the heat pump and suitable for condensing the evaporated liquid and collecting the distillate and; a collector tube, connected to the condenser deposit for the exit of the distillate.

A desalination and energy storage system comprises at least one water reservoir, at least one negative-ion redox electrode, at least one positive-ion redox electrode, a cation-exchange membrane disposed between the at least one negative-ion redox electrode and the water reservoir, and an anion-exchange membrane disposed between the at least one positive-ion redox electrode and the water reservoir. The at least one water reservoir comprises an input and an output, wherein water in the at least one water reservoir is reduced below a threshold concentration during a desalination operation mode. The at least one negative-ion electrode comprises a first solution and is configured to accept, and have, a reversible redox reaction with at least one negative ion in the water, and the at least one positive-ion electrode comprises a second solution and is configured to accept, and have, a reversible redox reaction with at least one positive ion in the water.

The present invention relates to the fields of energy technology and seawater desalination, and more specifically, relates to a seawater desalination device of industrial exhaust heat-driven ejector refrigeration and an application method thereof The seawater desalination device comprises a seawater collecting pool, a low-pressure seawater storage tank, an ejector refrigeration system and a fresh water storage tank which are successively connected; the ejector refrigeration system comprising a nozzle for spraying low-pressure vapor, a mixing chamber, a diffuser, a first heat-exchanger, a condenser, a condensate pump and a generator; bottom of the low-pressure seawater storage tank being connected with a second heat-exchanger; the mixing chamber being connected with the nozzle, the diffuser and the low-pressure seawater storage tank, respectively; and the diffuser, the first heat-exchanger, the condenser and the fresh water storage tank being successively connected. The present invention provides a seawater desalination device of industrial exhaust heat-driven ejector refrigeration, which achieves efficient recovery and utilization of industrial exhaust heat, and the fresh water and cooling load can be provided for users, thus effectively utilizing the industrial exhaust heat, reducing the environmental pollution and cost, and enhancing the energy efficiency.

An Energy Storage Barge provides supplemental energy for a power system when renewable energy sources fail to provide enough hour at peak times. In an embodiment, the Energy Storage Barge is further provided a freeze chamber for pure water and mineral collection. In another embodiment, the Energy Storage barge produces super-chilled air to conduct freeze processing or maintain temperature of a cold storage facility.

The present invention includes a method including providing an anode and a cathode; providing a desalination device operably coupled to establish an electrical potential between the anode and the cathode when the desalination device is operating; providing water containing dissolved solids; thereby establishing the electrical potential; reducing a salinity of the water by supplying the water to the desalination device; and generating electrical power by reducing the salinity of the water.

An energy recovery device is provided in a seawater desalination system for desalinating seawater by removing salinity from the seawater. A pressure exchange chamber for pressurizing seawater by a pressure of concentrated seawater discharged from a reverse-osmosis membrane-separation apparatus includes a first supply and discharge port connected to a switching valve for performing supply and discharge of liquid, a second supply and discharge port connected to a directional control valve for performing supply and discharge of liquid, a flow resistor provided at the first supply and discharge port side in the chamber and configured to regulate the flow, and a flow resistor provided at the second supply and discharge port side in the chamber and configured to regulate the flow, and a flowmeter provided between the two flow resistors and configured to measure a flow rate of the liquid in the chamber.

Method of desalination and wastewater treatment in a microbial desalination cell reactor is provided, the microbial desalination cell reactor has three compartments, an anodic compartment, a cathodic compartment and a saline compartment, the method is carried out by (a) adding electrically conductive particles or electrically conductive material in the anodic compartment and cathodic compartment, (b) adding bacteria species of the genus Geobacter in the anodic compartment and several solutions in the compartments (c) replacing the solutions in the cathodic compartment and in the saline compartment and (d) oxidizing organic matter present in wastewater by bacteria from the genus Geobacter in the anodic compartment and desalinating the solution in the saline compartment and (e)after 20 to 30 operation cycles, replacing the solution in the saline compartment by a solution of hypochlorite salt