Abstract: A method and apparatus for achieving high output efficiency from an electrolysis system (100) using a plurality of electrolysis cells all located within a single electrolysis tank (101) is provided. Each individual electrolysis cell includes a membrane (105A) and at least one pair of low voltage electrodes of different polarity (115A/116A). The electrolysis system also includes at least one pair of high voltage electrodes (119A/120A). In at least one embodiment, the low voltage electrodes within each electrolysis cell are comprised of at least one pair of low voltage electrodes of a first type (115A/116A) and at least one pair of low voltage electrodes of a second type (117A/118A). In at least one other embodiment, the low voltage electrodes within each electrolysis cell are comprised of at least one pair of low voltage electrodes (701A/702A). The voltage applied to the electrodes is pulsed.

Abstract: An electronic water treatment apparatus includes an electronic impulse generator and control box attached to a power source. An impulse chamber includes a cylindrical anode rod inside a tubular cathode and is connected to the impulse generator and control box with a low-voltage cable which is no more than about six feet long. The impulse generator and control box supply about 16 v DC power and 120-180 milliamps to the impulse chamber at between 2300 and 5200 Hertz. The discharge frequency within the impulse chamber automatically varies with the conductivity of the aqueous solution within the impulse chamber. The impulse generator and control box supply power with a waveform that includes about a two microsecond break between each positive and negative pulse to prevent corrosion of the electrodes and create the aragonite form of calcium carbonate instead of the calcite form.

Abstract: There is described a method for ensuring and monitoring electrolyzer safety and performances in a manufacturing process which uses at least one electrolyzing cell containing at least one cathode and at least one anode separated by a membrane, comprising the step of: determining a safe single voltage operation range depending of the current and corresponding to the normally working electrolyzing cell; determining a reference voltage deviation depending on the time derivation of the current; measuring the voltage over time at the terminals of the electrolyzing cell; determining the measured voltage deviation by calculating the time derivative of the measured voltage; comparing the measured voltage to the safe single voltage operation range and the measured voltage deviation to the reference voltage deviation over time; stopping the manufacturing process when the measured voltage is outside the safe single voltage operation range or the difference between the measured voltage deviation and the reference voltage

Abstract: There is disclosed a cleaning device for a heat exchanger which safely and effectively cleans the heat exchanger and which can sufficiently obtain a deodorizing effect and a sterilization effect. The cleaning device for the heat exchanger includes an electrolysis unit for treating dew condensation water of the heat exchanger by an electrochemical technique, a supply unit for supplying electrolytic water produced by the treatment performed by this electrolysis unit to an outer surface of the heat exchanger, and an control unit for controlling the electrolysis unit and the supply unit, and the control unit allows the electrolysis unit to electrolytically treat the dew condensation water of the heat exchanger and produce the electrolytic water, and allows the supply unit to supply the produced electrolytic water to the outer surface of the heat exchanger.

Abstract: A semiconductive counter electrode covers a highly electronically conductive electric current buss. The semiconductive counter electrode is impervious to ion flow. A substrate holder is operable to hold a substrate and to form a thin fluid gap between the semiconductive counter electrode and a substrate surface. A thin liquid electrolyte layer is located in the thin fluid gap. A power supply connected to the electric current buss and a peripheral edge of a conductive substrate surface is able to generate a potential difference between the electric current buss and the semiconductive counter electrode, on one side of the electrolyte layer, and the substrate on the other side. The semiconductive counter electrode provides a substantial resistance in the various current flow paths between the electric current buss and the semiconductive counter electrode, on one side, and the conductive substrate surface, on the other, thereby enhancing control of current distribution.

Abstract: An electroplating apparatus is provided that includes a plating tank for containing a plating electrolyte. A counter electrode, e.g., anode, is present in a first portion of the plating tank. A cathode system is present in a second portion of the plating tank. The cathode system includes a working electrode and a thief electrode. The thief electrode is present between the working electrode and the counter electrode. The thief electrode includes an exterior face that is in contact with the plating electrolyte that is offset from the plating surface of the working electrode. In one embodiment, the thief electrode overlaps a portion of the working electrode about the perimeter of the working electrode. In one embodiment, a method is provided of using the aforementioned electroplating apparatus that provides increased uniformity in the plating thickness.

Abstract: There is described a method and a system for evaluating damage of a plurality of cells in an electrolyser. The method comprises acquiring a voltage for each one of the cells; comparing the voltage to at least two threshold voltage levels; classifying the cells as one of: severely damaged cells, non-severely damaged cells and undamaged cells, based on the comparison of the voltage with the at least two threshold voltage levels; and deactivating the cells classified as severely damaged cells from the electrolyser.

Abstract: An apparatus and method for simultaneously electroplating at least two parts in a series electrical configuration in an electroplating system using a shared electrolyte with excellent consistency in thickness profiles, coating weights and coating microstructure. Parts in high volume and at low capital and operating cost are produced as coatings or in free-standing form.

Abstract: A method and a device for electrochemically machining workpiece having blade end plates at the longitudinal both ends of a blade-shaped portion having aerofoil shape in cross section by extending and retracting divided electrodes. A part of the blade-shaped portion and one blade end plate continued therewith are electrochemically machined by advancing the main electrode in an acute angle direction relative to the longitudinal direction of the blade-shaped portion. At the same time or subsequently, the remaining part of the blade-shaped portion and the other blade end plate continued therewith are electrochemically machined by slidably advancing an auxiliary electrode along the slope of the main electrode forming an acute angle relative to the blade-shaped-portion-machining-surface. Thus, the number of the parts of an electrode unit can be reduced and the structure thereof can be simplified.

Abstract: An anodizing method for growing an anodized layer on a surface of aluminum in electrolyte is disclosed. The method comprises applying a DC/AC-combined pulse wave between an anode and a cathode. The DC/AC-combined pulse wave is provided by combining a DC pulse wave with an AC wave, and has a peak voltage at a start point of each pulse. The grown anodized layer may be equal to or less than 300 ?m in thickness, and the diameter of a cell in the anodized layer may range between 50 nm and 100 nm. The power supply used for anodizing may comprise a rectifying modulator unit, an AC modulating unit, a pulse wave synthesizing unit, and a control unit.

Abstract: In an electrolytic apparatus for removing contaminants from water, a set (110) of spaced apart conductive electrodes (40) in a reaction chamber (54, 112, 114), is arranged in oppositely charged groups of first and second interleaved electrodes with flow paths between them. Non-conductive turbulence inducers (158, 168) on the faces of electrodes (40) are applied to water in the flow paths. One variety is modular elements (1 58) with stepped increases in width to present a narrow leading edge in the direction of flow. Another variety is a continuous set of wave guides (168) bordering the flow path. Electrodes (40) are selectively powered in patterns creating turbulence, with effective patterns including a first and last electrode powering pattern and a mini-cell electrode powering pattern.

Abstract: Electrodeposition painting systems may include an electrodeposition bath containing an electrodeposition paint solution, wherein the electrodeposition paint solution is in contact with an electrodeposition bath anode that charges the paint such that it electrocoats parts submerged therein to form electrocoated parts, a rinse tank that rinses the electrocoated parts, wherein a rinse tank reservoir of the rinse tank is capable of fluid communication with the electrodeposition bath, a filter that filters the electrodeposition paint solution to separate filtered water from the paint, and an ionizer assembly including one or more electrodes in contact with the filtered water and a power supply connected to the one or more electrodes, wherein the power supply causes a plurality of electrode ions from the one or more electrodes to enter the filtered water to produce filtered water including electrode ions such that the filtered water including electrode ions flows into and sterilizes the electrodeposition paint solu

Abstract: In various embodiments, the present invention provides an electrolytic cell contact bar having a first pole and a pair of second poles. The second poles are opposite in charge to the first pole and each of the pair of second poles are adjacent to and parallel to the first pole. In various embodiments, the contact bar may include an electrode holder capable of holding at least one electrode.

Abstract: An electrochemical process and device for the controlled and uniform heating of electrically-conductive fluids, the process or device having at least one reactor and at least one power source with at least one electrode and at least one additional conductive material for direct heating of the fluid and for producing electrochemical changes of the fluid to result in at least one property change of the fluid and at least one product.

Abstract: Methods and systems for generating biocidal solution having a predetermined level of available free chlorine and pH, including an electrolytic cell that generates the biocidal solution by an electrolytic reaction, the electrolytic cell including an input pipe for receiving an input brine solution, an anode chamber including an anode and a cathode chamber including a cathode separated by a separator, electrical connections for application of voltage to the anode and cathode; temperature sensing means for detecting a temperature of a solution of the electrolytic cell and outputting a signal indicative of the detected temperature; and process control means for adjusting the voltage applied to the electrolytic cell by the process control means thereby maintaining the level of available free chlorine and pH at the predetermined level in response to the signal output from the temperature sensing means.

Abstract: A hydrogen generation and storage system provides energy storage and energy production through use of hydrogen. The system may comprise a hydrogen generation subsystem and a storage subsystem. Typically, the system will be powered by a renewable or environmentally friendly electrical source, such as wind, solar, geothermal, hydroelectric, or wave energy. The stored hydrogen may automatically be used to supplement electrical output, such as to meet demand for electricity.

Abstract: An electrochemical gas generator is provided with an electrolysis cell (1) with a housing, which is closed by a gas-permeable membrane (2) for the escape of the test or calibrating gas. A cathode (5) is provided formed of a noble metal, a mixture of noble metals or a material containing carbon. The cathode is in direct contact with an electrolyte (7) disposed in the housing. An anode (4) is provided formed of a noble metal, a mixture of noble metals or a material containing carbon. The anode is in direct contact with an electrolyte (7). The electrolyte (7) contains a carboxylic acid salt. A control unit (6) is provided that acts as a current source and which is connected to the electrodes (4, 5).

Abstract: The present invention relates to the technical filed of electrochemical elimination or reduction of microbial impurities of liquids. The liquids treated may inter alia include wastewater, industrial process water and water intended for human consumption.

Abstract: In various embodiments, the present invention provides an electrolytic cell contact bar having a first pole and a pair of second poles. The second poles are opposite in charge to the first pole and each of the pair of second poles are adjacent to and parallel to the first pole. In various embodiments, the contact bar may include an electrode holder capable of holding at least one electrode.

Abstract: By providing two or more consumable electrodes within a single reactor vessel, an alloy having a high degree of chemical ordering may be deposited in situ in that the current flows of the individual consumable electrodes are controlled to obtain a substantially layered deposition of the two or more metals. Hence, especially in copper-based metallization layers, the advantage of enhanced resistance against electromigration offered by alloys may be achieved without unduly reducing the overall conductivity.

Abstract: A novel system and method for generating hydrogen by electrolysis of water from a green power source. Electricity generated by solar panel or wind mill is measured and connected with plurality of electrolysis stacks. The number of operating electrolysis stacks are constantly controlled by a controlling mechanism that calculates an optimal operating number of electrolysis stacks using the measured electricity parameter and the operating parameter of an electrolysis unit.

Abstract: System (10) for electrocoagulatively removing contaminants from contaminated water (13), electrocoagulation reactor unit (16), and sedimentation column (302). Electrocoagulation reactor unit (16) includes reactor housing assembly (102) having: lower pair of integrally configured, and complementary upper pair of removably and replaceably configured, electrode positioning, spacing, holding elements, and, two wall electrode or electrode wall electrocoagulatively unreactive zones, each having an interior face of a side wall configured flush against and directly contacting adjacent, nearest neighboring, electrode face, for preventing water flowing and making contact therebetween. Sedimentation column (302) includes first sediments-water separator assembly having a water/sediments distributor assembly, and second sediments water separator assembly having downward flow multi-conduit assembly.

Abstract: A novel electromechanical, chemical, thermal apparatus having the combined properties of a voltage intensifier, a diode and a capacitor for the molecular breakdown of water into its oxygen and hydrogen components. The instant invention uses only water (tap water, distilled water, purified water, etc.) without the need of adding any electrolyte. The system comprises a unique molecular reactor core having conductive inner and outer windings and a molecular reactor control assembly having water level controls via a float switch mechanism and temperature control process serving as the basis for the unique operation of the system. The instant invention provides a novel combination of the molecular reactor core and molecular reactor control assembly, in conjunction with a means for replenishing the water therein, all powered and controlled by simple control circuitry, and having usage implications for various functions, including but not limited to the generation of hydrogen gas.

Abstract: High concentrations of hypochlorous acid can be produced from, most typically, brine using an system of simple design with minimum residual salt production, reduced power consumption, and at high operating efficiencies. This is accomplished by separating the system into two operations, each of which is preferably optimized. This process employs at least two electrochemical cells, the first of which has no separator between the anode and cathode and generates a high-strength hypochlorite solution. The hypochlorite is then diluted to a desired chlorine concentration and/or pH and fed into the anode compartment of a second electrochemical cell wherein the electrodes are separated by a barrier, such as, for example, a membrane or diaphragm. The separated cell produces a solution containing predominantly hypochlorous acid.

Abstract: A process for the production of sodium hydroxide, hydrogen gas and chlorine gas which comprises (1) forming an aqueous solution of sodium chloride, (2) placing the sodium chloride solution in a cell having two compartments separated by a separator, (3) subjecting the cell to a direct electrical current of about 3-24 volts and 0.1-500 K amperes; thereby generating hydrogen gas, chlorine gas and an aqueous sodium hydroxide solution and wherein the electrical current is generated by a solar panel.

Abstract: An electrochemical gas generator is provided including an electrolysis cell (1) with a gas-impermeable housing, which is closed by a gas-permeable membrane (2) for the discharge of the test gas or calibrating gas CO. A chemically inert cathode (5) formed of a noble metal, a mixture of noble metals or a material containing carbon, is in direct contact with an electrolyte (7). An anode (4) formed of a noble metal, a mixture of noble metals or a material containing carbon, is in direct contact with a mesoxalic acid salt, the mesoxalic acid salt being in direct contact with the electrolyte (7). A control unit (6) is provided that also acts as a power source and is connected to the electrodes (4, 5).

Abstract: A cooling tower water management system is disclosed. A water treatment module is positioned in a water circulation line in a cooling tower. The water treatment module comprises a treatment cell having a cathodic tube and an anodic rod within the tube. A controller and power supply create a pulsed electrical potential across water in the treatment cell from the cathode to the anode to perform electrolysis on the water. Suspended and dissolved solids in the water are built up on a surface within the treatment cell. The controller can initiate a regeneration cycle to remove the built up solids from the surface. The regeneration comprises switching the electrical contact from the anode to a portion of the cathodic tube.

Abstract: There is disclosed a treatment process of wastes containing organic molecules with electron-withdrawing groups on conjugated unsaturated bonds, for instance belonging to aromatic rings. The process comprises an electrochemical reduction step and a simultaneous or subsequent oxidation step, optionally also of electrochemical nature.

Abstract: The present invention relates generally to the processing of fluids and/or their carriers. Carriers may comprise pipes, tubes and the like or reservoirs for the distribution and/or storage of fluids. In one form, the present invention relates to a method and apparatus that is suitable for use in the treatment of various fluids, such as water, by introducing at least one chemically active metal into the water and its carriers for disinfection of the water in a controlled manner. The invention also relates to a biasing means for displacement of an electrode arrangement to allow for the introduction of ions into a fluid at a controlled or easily monitored rate that is commensurate with the amount of fluid flow.

Abstract: The Product Gas Generator works in conjunction with a Combustion Management System to supply a product gas, comprising a dynamic mixture of nascent hydrogen (H) and oxygen (O), to the internal combustion engine to propagate the formation of hydroxide radicals (OH) and thereby to improve the level of completion of the hydrocarbon combustion reaction. The Combustion Management System provides product gas volumetric requirement information; and takes into account the engine style, primary torque requests, and hydrocarbon fuel consumption information to develop an operating system specific application that produces consistent measurable results.

Abstract: The present invention generally relates to apparatus and methods for plating conductive materials on a substrate. One embodiment of the present invention provides an apparatus for plating a conductive material on a substrate. The apparatus comprises a fluid basin configured to retain an electrolyte, a contact ring configured to support the substrate and contact the substrate electrically, and an anode assembly disposed in the fluid basin, wherein the anode assembly comprises a plurality of anode elements arranged in rows.

Abstract: The system of the invention is a very efficient means for the on-demand production of hydrogen for aid, power, and electricity, operated by a control system with a modular, smart, and high-power efficiency arrangement using nanotechnology. A vast number of selections are provided for the user to obtain power production when needed or furthermore with variable delivery. Respecting cleanliness, environmental, and air pollution reduction constraints, the system is devised for use in the areas of housing, transportation, or more generally, any industry producing electricity or heat particularly by hydrocarbon means, or furthermore any environment requiring power for stationary or mobile operation.

Abstract: The present invention relates to an electrical device for impeding corrosion of a metal body. The electrical device includes a driver circuit including at least one inductive component. The driver circuit is suitable for driving one or more pads coupled to the metal body so that corrosion of the metal body is impeded. A control circuit is provided for controlling the operation of the driver circuit. A feedback circuit provides feedback from the driver circuit to the control circuit. The driver circuit can operate as a resonant circuit, owing to the at least one inductive component, and ballast energy applied to the pads.

Abstract: Contemplated electrochemical devices and methods include an electrolyte flow path in which substantially all of the electrolyte has laminar flow. A segmented electrode contacts the electrolyte, and each of the segments in the segmented electrode is preferably coupled to a control device to provide control over the flow of current to and/or from the electrolyte. Thus, it should be appreciated that the redox state of the electrolyte can be changed in a single-pass through the flow path, which effectively eliminates problems associated with mass transport phenomena and reduced current efficiency.

Abstract: An anode and cathode for an electrolytic cell are configured as a low inductance transmission line to enable control of an interphase at an electrode surface. The anode and cathode are coupled to a switched current source by a low inductance path that include a parallel plate transmission line, a coaxial transmission line, or both. The switched current source provides switching between current sources at three or more voltages to provide fast charging and discharging of the double-layer capacitance associated with the electrode surface.

Abstract: An apparatus and method are provided. The apparatus includes first and second liquid lines, a container and a dispenser. The first liquid line is configured to receive a liquid. The container is coupled to the first liquid line and is configured to retain media of at least one liquid-activating material. The media of the at least one liquid-activating material is configured to modify an oxidation reduction potential of the received liquid to provide a treated liquid. The second liquid line is coupled to the container and is configured to receive the treated liquid from the container. The dispenser is operably coupled to the second liquid line at a location downstream from the container and is configured to dispense the treated liquid.

Abstract: An apparatus for direct analysis of the redox products, or intermediates, of an electrochemical reaction by coupling an electrochemical cell to desorption electrospray ionization mass spectrometry.

Abstract: A system including nanostructure arrays for converting carbon dioxide to an organic compound, e.g., methanol, which does so, for example, without any external electric energy. In one embodiment, the system for converting carbon dioxide to an organic compound includes an array of nanotubes, which include nanoparticles of an electron mediator, e.g. palladium, dispersed on a surface of the nanotubes, and an electrically conductive fluid. The array of nanotubes is at least partially immersed in the electrically conductive fluid. The system further includes a light source that irradiates the array of nanotubes, a source of carbon dioxide, and an inlet for delivering the carbon dioxide to the electrically conductive fluid whereat at least a portion of the carbon dioxide is converted to a different organic compound, such as methanol, via contact with an irradiated array of nanotubes. In one example, the array is an ordered array of titania nanotubes.

Abstract: System for producing electric energy and hydrogen based on renewable energy sources, such as wind energy from one or several wind turbines, and incorporating means for producing hydrogen. The system comprises a hybrid electrolyzer device, which comprises a combination of at least two different electrolysis technologies and at least one control device, which manages the hydrogen production between the two electrolyzers of the different electrolysis technologies; being at least one electrolyzer of a rapid dynamics electrolysis technology type and, at least the second one of a substantially slower dynamics electrolysis technology type.

Abstract: A hydrogen gas generating system comprising at least one electrolytic cell having nested annular electrodes, a water distribution system arranged to contain and deliver an aqueous electrolytic solution to the electrolytic cell, and a gas collection network having at least one module for drying the hydrogen gas stream. The system delivers the hydrogen gas into the aft intake of an internal combustion engine to supplement the fuel. A supplemental electrical signal is supplied to the engine oxygen sensor to prevent the engine computer from compensating for the drop in oxygen content.

Abstract: A nanopump for pumping small volumes of electrolyte solution under the control of a voltage source is described. The device includes a chamber and a nanopore membrane which partitions the chamber into upstream and downstream regions. When a voltage potential is applied across the membrane, electroosmotic flow through the membrane channels produces a precise-volume flow between the two chamber regions. A method for precise-volume pumping employing the nanopump and a nanopump device for determining the lengths of nucleic acid fragments in an electrolyte solution of different-length fragments are also described.

Abstract: A metal and oxygen material such as a transparent electrically conductive oxide material is electro deposited onto a substrate in a solution deposition process. Process parameters are controlled so as to result in the deposition of a high quality layer of material which is suitable for use in a back reflector structure of a high efficiency photovoltaic device. The deposition may be carried out in conjunction with a masking member which operates to restrict the deposition of the metal and oxygen material to specific portions of the substrate. In particular instances the deposition may be implemented in a continuous, roll-to-roll process. Further disclosed are semiconductor devices and components of semiconductor devices made by the present process, as well as apparatus for carrying out the process.

Abstract: A method of rear surface treatment is carried out by: preparing a semiconductor device in which an integrated circuit having a plurality of electrodes is provided on the front surface of a semiconductor substrate; electrically connecting the plurality of electrodes to an anode; and electropolishing the rear surface of the semiconductor substrate by performing anodic oxidation with an electrolytic solution placed in contact with the rear surface of the semiconductor substrate.

Abstract: A method of rear surface treatment is carried out by: preparing a semiconductor or device in which an integrated circuit having a plurality of electrodes is provided on the front surface of a semiconductor substrate; electrically con netting the plurality of electrodes to an anode; and electropolishing the rear surface of the semiconductor substrate by performing anodic oxidation with an electrolytic solution placed in contact with the rear surface of the semiconductor substrate.

Abstract: Electrocatalytic generation of halogenated biocides are disclosed by electrolyzing low salinity water with an applied current. The direction of the applied current is reversed periodically, for a shorter duration, and at a lower current density. Mixed types of electrodes are utilized without a significant reduction in reliability and performance.

Abstract: An Electro-Osmotic Pulse (EOP) system is used to dewater structure, both natural and manmade. Preferably, the system employs durable, dimensionally stable anodes affixed to structure in a configuration designed to maximize electrical contact with the structure and minimize electrode gas generation. The anodes and cathodes are attached to a DC power supply that provides a voltage potential between them. DC power is cycled until the structure has been sufficiently treated. Select embodiments employ perforated metal pipes as cathodes for the purpose of transport and drainage of fluids. In select embodiments of the present invention, the cathodes are connected to variable resistors designed to reduce opportunity for corrosion of buried metal objects in the vicinity of the EOP system. Select embodiments employ a pre-specified pulse train of DC voltage pulses to migrate water from under a crawl space while moving available cations in the soil. Select embodiments also protect large structures such as concrete dams.

Abstract: The invention relates to an electrochemical device which simultaneously carries out the production of an oxidising solution at controlled composition containing hypochlorous acid and the sprinkling thereof in a continuous process, useful for biocide treatments in agricultural fields. The device can be installed on motor vehicles or mobile means in general.

Abstract: A hydrogen supplementation fuel apparatus and method having a power source, a hydrogen generator and an accumulator for supplementing hydrogen gas to improve the fuel efficiency of internal combustion engines. The hydrogen generator uses electrodes that are helically wound about a separator to increase the hydrogen generation output.

Abstract: An electromachining system is described. The electromachining system includes a computer numerical controller (CNC) device and an electromachining controller device coupled to the CNC device and a power supply. The electromachining system also includes an electromachining tool coupled to the CNC device and the power supply. The electromachining controller device is configured to control operation of the electromachining tool and the CNC device is configured to position the electromachining tool relative to a workpiece.

Abstract: An apparatus and method are provided, in which and electroporation electrode is configured for example to apply an alternating electric field through liquid dispensed from the apparatus to a surface or volume being treated and thereby cause electroporation of microorganisms in contact with the liquid. The liquid may be suspended from the surface by charged nanobubbles and/or another mechanism to enhance application of the electric field to the microorganisms.