Patent application number | Description | Published |
20080264780 | Water electrolysis system - In a water electrolysis system having an anode catalyst layer containing anode catalyst and a cathode catalyst layer containing cathode catalyst tightly attached, respectively, to each surface of a solid polymer electrolyte membrane comprising a cation exchange membrane, wherein at least one catalyst layer of said anode catalyst layer and cathode catalyst layer comprises a porous structure of anode catalyst or cathode catalyst dispersed in fluorine resin containing resin, featuring the surface of the anode catalyst layer or the cathode catalyst layer being hydrophobized and the water contact angle with the surface of the anode catalyst layer or the cathode catalyst layer of said porous structure being 90 degrees or more, whereby the transfer of gas to the counter electrode can be significantly suppressed, gas purity and current efficiency be improved, and safety operation of the electrolysis system be secured, without a major change in configuration of the water electrolysis system. | 10-30-2008 |
20090078582 | APPARATUS FOR ELECTROLYZING SULFURIC ACID, METHOD OF PERFORMING ELECTROLYSIS, AND APPARATUS FOR PROCESSING A SUBSTRATE - An apparatus for electrolyzing sulfuric acid, the apparatus comprising an electrolytic cell comprising a cathode chamber having a cathode and an anode chamber having an anode, the cathode chamber and the anode chamber being separated by a diaphragm, a sulfuric acid tank configured to store the sulfuric acid, a supply pipe connecting the sulfuric acid tank to an inlet port of the anode chamber, a connection pipe connecting an outlet port of the cathode chamber to the inlet port of the anode chamber, a first supply pump provided on the supply pipe and configured to supply the sulfuric acid from the sulfuric acid tank to the cathode chamber through the supply pipe, and a drain pipe connected to an outlet port of the anode chamber and configured to supply to a solution tank a solution containing an oxidizing agent generated by electrolysis in the anode chamber. | 03-26-2009 |
20090321252 | Sulfuric acid electrolytic cell and a sulfuric acid recycle type cleaning system applying the sulfuric acid electrolytic cell - In a sulfuric acid electrolytic cell to electrolyze sulfuric acid supplied to an anode compartment and a cathode compartment comprising a diaphragm, said anode compartment and said cathode compartment separated by said diaphragm, a cathode provided in said cathode compartment and a conductive diamond anode provided in said anode compartment, as said conductive diamond anode, a conductive diamond film is formed on the surface of said conductive substrate, the rear face of said conductive substrate is pasted, with conductive paste, on an current collector comprising a rigid body with size equal to, or larger than, said conductive substrate, an anode compartment frame constituting said anode compartment is contacted via gasket with the periphery on the side of the conductive diamond film of said diamond anode, said diaphragm is contacted with the front face of said anode compartment, further, with the front face of said diaphragm, the cathode compartment frame constituting said cathode compartment, a gasket, and said cathode are contacted in sequence, the rear face of said cathode is pasted with conductive paste to the current collector comprising a rigid body with size equal to, or larger than, said cathode and electric power is supplied from one current collector to the other current collector via said conductive paste. | 12-31-2009 |
20090321272 | Sulfuric acid electrolysis process - Sulfuric acid electrolysis process wherein;
| 12-31-2009 |
20090325390 | Cleaning method by electrolytic sulfuric acid and manufacturing method of semiconductor device - The cleaning method by electrolytic sulfuric acid and the manufacturing method of semiconductor device comprising:
| 12-31-2009 |
20100320082 | Conductive diamond electrode and ozone generator using the same - The present invention relates to a conductive diamond electrode, comprising a substrate having a plurality of convex and concave part disposed over the entire surface of the conductive diamond electrode, and a diamond film coated on the surface of said substrate, wherein the width of each convex part of said convex and concave part is in a range from 0.2 mm to 1 mm. The present invention can provide a conductive diamond electrode, applying a thin film of conductive diamond and a thick substrate, being less expensive than a self-supported type conductive diamond electrode and also having mechanical strength enough to be used in the zero-gap electrolysis, functioning stably for a long time with smooth water supply or gas liberation, and an ozone generator using the conductive diamond electrode. | 12-23-2010 |
20130313129 | METHOD FOR MEASURING TOTAL CONCENTRATION OF OXIDIZING AGENTS, CONCENTRATION METER FOR MEASURING TOTAL CONCENTRATION OF OXIDIZING AGENTS, AND SULFURIC ACID ELECTROLYSIS DEVICE EQUIPPED WITH SAME - Provided are: a method of measuring the total concentration of oxidizing agents, by which the total concentration can be determined in a single measurement with simple operations even in an evaluation solution containing multiple components such as persulfuric acid, perosulfate and hydrogen peroxide; a simple and inexpensive concentration meter for measuring the total concentration of oxidizing agents; and a sulfuric acid electrolysis device comprising the concentration meter. | 11-28-2013 |
20150290484 | METHOD AND APPARATUS OF DECOMPOSING FLUORINATED ORGANIC COMPOUND - A method of decomposing a fluorinated organic compound involves irradiating a target fluorinated organic compound with light in the presence of electrolyzed sulfuric acid. In detail, the inventive method involves adding electrolyzed sulfuric acid prepared by electrolysis of an aqueous sulfuric acid solution at an anode to a solution containing the target fluorinated organic compound and irradiating the solution with light to decompose the fluorinated organic compound into fluoride ions and carbon dioxide. The method can decompose fluorinated organic compounds at reduced decomposition energy, without high-temperature incineration that has been conventionally required. An apparatus for decomposing a fluorinated organic compound is also provided that is utilizable in practicing the method. | 10-15-2015 |