An apparatus for removing contaminants from fluid is disclosed. The apparatus includes a rotating electrode assembly including an inner shaft rotatably mounted within the housing and a first rotatable planar electrode extending radially outward from the inner shaft. The apparatus also includes a first planar stationary electrode having a first opening, the first opening shaped to permit the inner shaft to pass through the first opening, the first planar stationary electrode extending parallel to the first rotatable planar electrode, wherein the first planar stationary electrode and the first rotatable planar electrode are configured to be coupled to an external source. In addition, the apparatus includes a motor assembly including a motor and a first outer shaft coupled to the inner shaft. The rotating electrode assembly is configured to be removed from the housing when the inner shaft is decoupled from the first outer shaft.

An apparatus for electrochemical activation may include an intake for an aqueous salt solution, a flow conduit structured to direct the aqueous salt solution through the apparatus comprising at least two electrodes spaced apart from each other within the flow conduit; a control module electrically coupled to the at least two electrodes, wherein the control module controls application of electricity to the at least two electrodes; and a sensor structured to measure a parameter of the aqueous salt solution and provide feedback to the control module to control an aspect of operation of the apparatus.

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.

A sprayer apparatus includes a spray nozzle in fluid communication with a reservoir for an aqueous salt solution; at least two electrodes spaced apart from each other integrated into the reservoir; a controller structured to apply electricity to the at least two electrodes, wherein the controller controls an application of electricity to cause a first one of the at least two electrodes to be positively charged and a second one of the at least two electrodes to be negatively charged; and wherein the sprayer apparatus is configured to produce air bubbles during application of electricity, wherein the air bubbles cause agitation and mixing of the aqueous salt solution.

An apparatus includes a reservoir for an aqueous salt solution, at least two electrodes spaced apart from each other integrated into the reservoir, a control module electrically coupled to the at least two electrodes, wherein the control module controls application of electricity to cause a first one of the at least two electrodes to be positively charged and a second one of the at least two electrodes to be negatively charged, and an impeller disposed in the reservoir for mixing the aqueous salt solution in the reservoir.

Disclosed are a water treatment apparatus including an anode, a cathode disposed to face the anode at a distance therefrom, and at least one electrochemical unit disposed at a distance from the anode and the cathode, respectively, wherein the electrochemical unit includes a layer having bipolarity when a voltage is applied between the anode and the cathode, and a water treatment method using the same.

In an electrochemical treatment of a liquid in a precipitation reactor, the liquid is brought into contact with an electrically conductive electrode and an electrically conductive counter-electrode. The electrically conductive electrode comprises a flexible area electrode essentially having a two-dimensional extension. An electric voltage is applied between the electrode and the counter-electrode. The flexible area electrode is repeatedly deformed perpendicularly to its two-dimensional extension to inhibit the accumulation of substances precipitated from the liquid on the electrode and to remove substances precipitated from the liquid and accumulated on the electrode from the electrode.

A water treatment apparatus using a lamella structure according to an embodiment of the present invention includes a first treatment tank which includes a plurality of inclined plates and is configured to pass water subject to treatment between the inclined plates adjacent to each other and a second treatment tank which is installed at a rear end of the first treatment tank to accommodate the water subject to treatment and into which bubbles are supplied, wherein the plurality of inclined plates include positive electrode plates and negative electrode plates that are alternately arranged, and the water subject to treatment passes between the positive electrode plate and the negative electrode plate.

A liquid treatment apparatus constituted of: a vessel arranged to contain liquid; at least one first electrode in contact with the liquid; at least one second electrode in contact with the liquid; an electrical pulse generator, a first polarity output of the electrical pulse generator coupled to each of the first electrodes and a second polarity output of the electrical pulse generator coupled to each of the second electrodes, the first polarity opposing the second polarity; at least one third electrode disposed in the liquid in the vessel, and a mechanical force generator arranged to provide a predetermined mechanical force along a predetermined path within the liquid, a portion of the mechanical force applied to the least one third electrode so as to chaotically interrupt a conducting pathway formed by the at least one third electrode between a pair of the first and second electrodes.

An electrochemical oxidation reactor includes rotatable electrodes inside a reactor vessel. The electrodes are mounted to support plates, which in turn are mounted on shafts. The plates are attached to each other in a spaced relationship so that a gap is formed therebetween. The plates are each electrically insulated from each other. The electrodes are mounted to the inside surfaces of these plates, inside the gap. The gap is sized to receive liquid to be treated so that liquid located within the gap will react with the electrodes. An electrical charge is applied to each shaft so that a dielectric is formed across the gap within the fluid located in the gap. According to a first embodiment, an electrochemical reactor includes containing two spaced electrode support plates. According to another embodiment, an electrochemical reactor includes several spaced electrode support plates.