The present invention relates to a method for obtaining electrolysed water comprising the following steps: —Providing running or spring water, optionally comprising sodium chloride (NaCl) at a concentration of 0.5 to 2 g/L —Electrolysing this water by means of an electrolysis module comprising at least one boron-doped diamond electrode attached to a silicon substrate in which the concentration of boron is between 200 ppm (3×10.sup.19 B atoms/cm.sup.3) and 1500 ppm (2×10.sup.20 B atoms/cm.sup.3), the electric current density during the electrolysis process being between 15 and 500 mAh/L water, more preferably between 40 and 250 mAh/L water, and more preferably still between 50 and 200 mAh/L, and the electrolysis period being less than or equal to 60 minutes. The invention also concerns a water obtained according to this method for treating skin disorders and a composition containing such a water and a device for treating skin disorders comprising a vessel containing a water obtained according to the inventive method.

The systems and methods for wastewater treatment comprise a porous substrate with photocatalytic material(s), and optionally electrocatalytic material(s), for generation of hydroxyl radicals that decompose contaminants in wastewater. The systems and methods intentionally facilitate the photocatalytic and/or electrocatalytic generation of oxygen bubbles, which facilitate an increase in concentration of hydroxyl radicals and shrink the liquid layer of wastewater at photocatalytic and/or electrocatalytic surfaces where hydroxyl radicals are generated in order to decrease quenching of hydroxyl radicals and simultaneously increase utilization or efficiency of the hydroxyl radicals for decomposition of contaminants. In embodiments, the systems and methods prolong hydroxyl radical lifetime and enhance water treatment performance for residential, commercial, municipal, medical, and/or industrial applications. In embodiments, oxygen bubbles generated on surfaces are compressed into pores or microchannels where they store generated hydroxyl radicals to prolong their lifetime in the gas phase and exchange hydroxyl radicals with the adjacent liquid layer.

In accordance with the principals of the present invention, an electrolytic generator and method of electrolytic generation are provided. An electrolytic stack includes of a first electrode, a second electrode, and a polymer-electrolyte membrane placed between the first and second electrodes. A first fluid passage provides fluid passage over the first electrode while a second fluid passage provides fluid passage over the second electrode. A third fluid passage provides fluid connection between the first fluid passage and the second fluid passage such that the fluid flows from the first fluid passage to the second fluid passage via the third fluid passage. An electronic current is provided between the first electrode and the second electrode when a voltage bias is applied to the electrodes.

Electro oxidation membrane evaporator 1 comprises sweep air handler 60; fluid tank 20 defining a fluid container; fluid contactor/separator 30; oxidation cell 40; and scrubber 80. Electro oxidation membrane evaporator 1 may allow higher percent water recovery from wastewater prior to delivering brine to a brine water recovery system and can allow O.sub.2 from air such as cabin air to continuously diffuse into the wastewater as O.sub.2 is consumed to generate oxidants, helping to eliminate the low oxidant environment at the end of the cycle that causes pH to remain high, and low pH prevents precipitates from forming for longer so more water can be evaporated from the wastewater.

An apparatus for the treatment of acid mine drainage and selective recovery of at least one of metals, critical elements, sulphuric acid and water is disclosed. The apparatus includes at least one electrochemical reactor, at least one catholyte reservoir and at least one anolyte reservoir for containing the acid mine drainage and a buffer, respectively. The reservoirs are in fluid communication with the at least one electrochemical reactor. The apparatus also includes at least one sensor for monitoring a pH of a contents of the reactor; and a power source for supplying an electrical current to the at least one electrochemical reactor. The electrical current is supplied until a predetermined pH is reached for the selective recovery of the at least one of metals, critical elements, sulphuric acid and water. A process for the treatment of acid mine drainage is also disclosed.

An electrochemical cell for treating a fluid, the electrochemical cell comprising: at least two opposing electrodes defining a flow path for the fluid between the electrodes, where at least one of the electrodes is formed of electrically conductive diamond material; drive circuitry configured to apply a potential across the electrodes such that a current flows between the electrodes when the fluid is flowed through the flow path between the electrodes; and a housing in which the electrodes are disposed, the housing comprising pressure seals configured to containing the fluid within the fluid path and a support structure for supporting the electrodes, wherein the support structure and the pressure seals are configured such that the electrochemical cell has an operating pressure in a range 2 to 10 bar within which the electrodes are supported without fracturing and within which the fluid is contained within the flow path, wherein the electrodes are spaced apart by a distance in a range 0.5 mm to 4 mm, and wherein the drive circuitry is configured to apply a potential across the electrodes giving a current density ≥15,000 Amp/m.sup.2 over an electrode area of at least 20 cm.sup.2 for an operating voltage of no more than 20 V.

An illustrative expendable or reconstructable ozone generator cartridge for an aqueous ozone delivery device, for example, for antimicrobial sanitizing and/or medical treatment, includes a housing for a water treatment manifold providing parallel and operably fixed water pathways through ozone generating cells coupled to the manifold, and optionally a data logging and authentication feature.

The invention relates to a easily adaptable or DIY installation water cleaning device on any existing spa or pool, said cleaning device including an electrolysis module equipped with a particular boron-doped diamond electrode on silicum substrate. The inventions also relates to a method to clean water on spa or pools using a water cleaning device comprising said particular boron-doped diamond electrode present on the elecrolysis module. The invention also relates to electrolyzed bathing water for use in the treatment of inflammatory diseases of the skin and for use for use in the treatment of wound healing of the skin.

A trace metal analysis detector and method of operating the same to detect metals in various fluid samples using boron doped diamond working electrodes.

An apparatus has a hub including a water inlet for receiving source water, a water outlet for discharging ozonated water, and an interface between the water inlet and the water outlet. The apparatus also has a cartridge including an electrolytic cell for ozonating the source water. The electrolytic cell has a cathode, an anode comprising diamond, and a membrane between the cathode and the anode. The electrolytic cell is configured to flow source water through both the cathode and the anode. The cartridge further includes at least one cartridge port for removably coupling with the interface on the hub. The at least one cartridge port and the interface are configured to flow source water from the hub into the electrolytic cell and to flow ozonated water from the electrolytic cell into the hub.