The invention concerns an electrolytic reactor, in particular for separating phosphate from phosphate-containing liquids and recovering phosphate salts, comprising a housing, an inlet and an outlet for the liquid and two electrodes of different polarity, which enclose a reactor chamber between them, whereby at least one of the two electrodes is a sacrificial electrode and consists of a magnesium-containing material, whereby the sacrificial electrode is constructed of trapezoid bars which have a first and a second upper surface, whereby the first upper surface is smaller than the second upper surface, and whereby four lateral surfaces connect the first upper surface with the second upper surface.

A dewatering apparatus for cellulosic materials includes a chamber for an aqueous solution of a cellulosic material, an inner electrode in the chamber, an outer electrode in the chamber about the inner electrode, and a power supply connected to the inner electrode and the outer electrode applying a voltage potential across the electrodes to remove water associated with the aqueous solution and to dewater the cellulosic materials.

An electrolysis system for water cleaning employs close anode and cathode plate spacing while providing cleaning of the plates. In one embodiment a moving anode allows access to the plates for cleaning.

A liquid treatment apparatus including: a tubular treatment tank whose end along a central axis is closed and sectional shape orthogonal to the central axis is a circular shape; a first electrode disposed on one end of the central axis of the treatment tank and having a bar shape; a second electrode disposed on the other end thereof; a power supply applying voltage between the first electrode and the second electrode; a rotation mechanism rotating the first electrode about a central axis of the first electrode; and an air introduction portion introducing the liquid to the one end of the central axis of the treatment tank from a tangential direction of the circular sectional shape of the treatment tank, and causing liquid to swirl about the central axis of the treatment tank therein to generate a gas phase in a swirling flow of the liquid.

In alternative aspects, the invention provides electrocoagulation processes and apparatus in which the anode oscillates in the electrochemical cell. In some embodiments, this facilitates control of the mixing conditions at the electrode surface independently from the flow through the cell. A constant DC current may be applied in the electrocoagulation, so that as the anode moves closer to a cathode, the cell voltage will oscillate. This may for example be carried out to provide a comparable degree of electrocoagulation with a net reduction in the energy consumption compared to a non-oscillating cell.

A waste water treatment apparatus utilizing electrochemical technology. Electrochemical waste water treatment is based on the application of an electric field between an anode and a cathode to the waste water. The apparatus for waste water treatment comprise a channel extending through a housing between an inlet and an outlet and a water treatment zone between the inlet and outlet. The apparatus further comprise first and second spaced apart electrodes having working ends for treating waste water in the treatment zone, and an electrode feed arrangement for feeding the first and second electrodes towards the channel to control the spacing between the working ends of the first and second electrodes.

A three-dimensional photo/electrodialysis unit includes four compartments. A first compartment holds a three-dimensional electrode and a group of one or more electrochemically active redox species. A first electroactive cation selective membrane couples the first compartment to a second compartment that provides a first feedstock. An electroactive anion selective membrane couples the second compartment to a third compartment that provides a second feedstock. And a second electroactive cation selective membrane couples the third compartment to a fourth compartment

The invention relates to a device for building a closed current circuit A, in which electric charge carriers move at least through a metal conductor, a flowable medium and a resonantly mechanically vibrating metal conductor C, which is mechanically connected to elements which generate mechanical vibrations. The device is characterized in that the current circuit B generating the previously mentioned resonant mechanical vibrations is decoupled from the previously mentioned current circuit A and from the components transmitting mechanical vibrations between the elements generating vibrations and the resonantly mechanically vibrating metal conductor C, which is in contact with the flowable medium, by means of electrically non-conductive coupling elements on two sides of the vibration-generating elements.

A capacitive adsorption module assembly is proposed. The capacitive adsorption module assembly includes a plurality of capacitive adsorption modules, each having a disk-shaped spacer configured to form a flow path through which feed flows, a cation exchange membrane attached to any one of an upper surface and a lower surface of the spacer, a first electrode attached to the cation exchange membrane, an anion exchange membrane attached to the other of the upper surface and the lower surface of the spacer, and a second electrode attached to the anion exchange membrane, wherein the capacitive adsorption modules are vertically stacked such that adjacent capacitive adsorption modules share or contact the first electrode or the second electrode, and at least one first terminal and second terminal passing through the stacked modules being provided.

A method and system for removing at least dissolved hydrogen sulphide or another targeted constituent from a feedstock is provided wherein the targeted constituent has a gas: liquid equilibrium. In some embodiments, the method includes the steps of: contacting the feedstock in at least one stripping vessel with a stripping gas to produce a gas stream containing at least hydrogen sulphide gas; conveying the gas stream from the at least one stripping vessel to an oxidation reactor; contacting the gas stream with an oxidizing agent in the oxidation reactor so as to oxidize the at least hydrogen sulphide gas to produce sulphuric acid; and conveying the produced sulphuric acid from the oxidation reactor to the at least one stripping vessel so as to reduce a pH value of the feedstock within the stripping vessel.