Class / Patent application number | Description | Number of patent applications / Date published |
204550000 | Ionophoresis | 8 |
20090145761 | OXYGEN SEPARATION ELEMENT AND METHOD - An electrically driven oxygen separation element and method in which an oxygen containing feed stream is passed through a passageway of a composite structure having a current collector defining the passageway, a cathode electrode to ionize the oxygen, an electrolyte to transport oxygen ions to an anode to recombine into elemental oxygen. An elongated element, preferably formed of an irregular mesh of wire having loops in contact with the current collector can be provided to disrupt the flow directly adjacent the current collector and to help distribute the electrical current along the length of the current collector. | 06-11-2009 |
20100126866 | METHODS OF DETERMINING POLYDISPERSITY AND/OR MOLECULAR WEIGHT DISTRIBUTION OF A POLYETHYLENE GLYCOL SAMPLE - Disclosed herein are methods of determining polydispersity (PDI) and molecular mass distribution (MMD) of reactive PEG samples using mass spectrometry. More specifically, a mass spectrometry method called GEMMA is used to determine PDI and MMD of PEG samples which provides more accurate measurements for high molecular weight PEG samples than prior known MALDI-TOF analysis. | 05-27-2010 |
20100175997 | Method of purifying water and apparatus therefor - A method of purifying cooling water which requires the lowest maintenance and management cost without the need for a cumbersome cleaning operation for removing scale in an electrolytic purifying vessel by taking out the electrodes from the electrolytic purifying vessel, and an apparatus therefor are provided. In the method of purifying circulating cooling water by applying a DC voltage across opposing electrodes while flowing water to be treated therebetween, so that ions in the water are electrolytically precipitated on the surfaces of electrodes on the negative pole side, thereby purifying the water to be treated, the electrodes comprise titanium and have an oxide film preformed by heating having a thickness of 5 nm to 130 nm thereon, and electric current is flown between the electrodes in an amount large enough to apply a voltage capable of dielectrically breaking down the oxide film on the surfaces of electrodes on the positive pole side. | 07-15-2010 |
20110100822 | Device and method for quantitatively determining an analyte, a method for determining an effective size of a molecule, a method for attaching molecules to a substrate, and a device for detecting molecules - A device for quantitatively determining an analyte is provided to conspicuously improve the performance of the quantitative determination. This device is equipped with a flow channel, an analyte detecting unit for capturing and detecting the analyte, and a quantitative measurement unit for quantitatively determining the analyte, wherein a signal generated when the analyte detecting unit has detected the analyte is divided into a plurality of parts in the direction of the flow in the flow channel at the quantitative measurement unit for processing. Also provided are technologies including one for controlling the density of molecules attached to the surface of a solid. In these technologies, when molecules are attached to a substrate, the density of attached molecules is controlled, by having an electrolyte also present in a solution containing the molecules to adjust the screening effect by the electrolyte, and by taking into consideration the effective size of a molecule. | 05-05-2011 |
20130105321 | Controller and Method of Operation of a Capacitive Deionization System | 05-02-2013 |
20150083596 | Device and method for killing bacteria and viruses in blood - A device, system and method for killing viruses and bacteria in blood. An iontophoretic cartridge destroys blood borne viruses and bacteria using ionized silver nanoparticles. Blood from the arm of the patient is routed to a holding bladder. From the bladder, the blood is pumped to the iontophoretic cartridge. In the cartridge, the blood is split into four tubes containing silver nanowires that treat the blood and destroy the viruses as they flow through the cartridge. The blood is then rerouted to the patient's arm. | 03-26-2015 |
20160039688 | WATER RECLAMATION SYSTEM AND DEIONIZATION TREATMENT DEVICE, AND WATER RECLAMATION METHOD - An object of the invention is to reliably prevent the precipitation of scale during a reclamation step in a deionization treatment. A water reclamation system and a deionization treatment device of the present invention each comprises a deionization section, a supply section which supplies a scale inhibitor to a water to be treated, and a control section. The control section acquires a supply start time and a supply stop time for at least one of the scale inhibitor and a low ion concentration water based on the concentration of a scale component in the deionization section, and causes the supply section to supply at least one of the scale inhibitor and the low ion concentration water in the interval between the supply start time and the supply stop time. | 02-11-2016 |
20160138132 | A SYSTEM AND METHOD FOR SEPARATION AND PURIFICATION OF DISSOLVED RARE EARTH/PRECIOUS METALS ELEMENTS/COMPOUNDS - A method for purification and separation of mixed elements, comprising at least a first free flow electrophoresis separation chamber, wherein a solution of the mixed elements is passed through the first separation chamber, an electric field submitted perpendicular to the solution flow and separating mobile ions of the solution based on electrophoretic mobility. A continuous method comprises selecting a complexing ligand, and controlling the temperature and pH of the solution. Also, a system or method for separating components of a multi-component concentrate comprising directing solution to at least a first and second channel each receiving part of the solution; each channel comprising a concentration section comprising a first transverse electric field across the channel, a fractionation section comprising a second electric field in a direction opposite the first electric field thereby distributing ions of the solution across the channel, and a flow splitter at an output of the fractionation section that divides the flow of each channel into subflows concentrated in heavier elements and concentrated in lighter elements. | 05-19-2016 |