Sulfur Dioxide Patents (Class 436/122)
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Patent number: 10908142Abstract: A stream including oxygen is provided to a rock sample from a subterranean zone. The rock sample is subjected to a first heating process to thermally oxidize at least a portion of the contaminant present in the rock sample. A first level of total organic content (TOC) of the rock sample is determined based on the first heating process. The rock sample is subjected to a second heating process to thermally oxidize at least a portion of the organic material present in the rock sample. A second level of TOC of the rock sample is determined based on the second heating process.Type: GrantFiled: January 30, 2019Date of Patent: February 2, 2021Assignee: Saudi Arabian Oil CompanyInventor: Sebastian Robert Glynn Henderson
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Patent number: 9086382Abstract: The invention concerns methods for measuring sulfur content in a fiber or polymer resin sample comprising: a) contacting the sample with a solution comprising sodium hydroxide to convert sulfur to sodium sulfate, b) combusting the sample of step a) in a furnace to remove essentially all organic materials to produce a residue; c) dissolving the residue in concentrated nitric acid; and d) determining the sulfur content of the sample using ICP Emission Spectrometry.Type: GrantFiled: January 11, 2012Date of Patent: July 21, 2015Assignee: E I DUPONT DE NEMOURS AND COMPANYInventor: Jonathan Samuel Tschritter
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Patent number: 8796035Abstract: The invention relates to a method and to a device for sulfur characterization and quantification in a sample of sedimentary rocks or of petroleum products wherein the following stages are carried out: heating said sample in a pyrolysis oven (1) in a non-oxidizing atmosphere, oxidizing part of the pyrolysis effluents and continuously measuring the amount of SO2 generated by said part after oxidation, then transferring the pyrolysis residue of said sample into an oxidation oven (1?) and continuously measuring the amount of SO2 contained in the effluents resulting from said oxidation heating.Type: GrantFiled: October 27, 2009Date of Patent: August 5, 2014Assignees: IFP Energies Nouvelles, Vinci TechnologiesInventors: Jean Espitalie, Roland Antonas, Violaine Lamoureux-Var, Gérémie Letort, Daniel Pillot, Valérie Beaumont, Frank Haeseler
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Publication number: 20140193922Abstract: A method for combustion analysing a sample in a combustion analyzer (120,160,180) is provided, where the sample comprises a proportion of sulphur. The sample is supplied to the combustion analyzer and combusted to produce combustion products, comprising a yield of sulphur dioxide for detection. Nitrogen monoxide or a source of nitrogen monoxide is supplied to the combustion analyzer to improve the yield of sulphur dioxide in the combustion products. The yield improver may be supplied before and/or during the combusting step. A proportion of yield improver is preferably greater than the (expected) proportion of sulphur. Ozone may be supplied to the combustion products to convert at least a proportion of any nitrogen monoxide in the combustion products to nitrogen dioxide, before detection.Type: ApplicationFiled: March 11, 2014Publication date: July 10, 2014Applicant: THERMO FISHER SCIENTIFIC INC.Inventors: David Marco Gertruda Alberti, Maurice Stephan van Doeselaar
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Publication number: 20140154811Abstract: Technologies are generally described for gas filtration and detection devices. Example devices may include a graphene membrane and a sensing device. The graphene membrane may be perforated with a plurality of discrete pores having a size-selective to enable one or more molecules to pass through the pores. A sensing device may be attached to a supporting permeable substrate and coupled with the graphene membrane. A fluid mixture including two or more molecules may be exposed to the graphene membrane. Molecules having a smaller diameter than the discrete pores may be directed through the graphene pores, and may be detected by the sensing device. Molecules having a larger size than the discrete pores may be prevented from crossing the graphene membrane. The sensing device may be configured to identify a presence of a selected molecule within the mixture without interference from contaminating factors.Type: ApplicationFiled: November 30, 2012Publication date: June 5, 2014Inventors: Angele Sjong, Kraig Anderson, Gary L. Duerksen, Seth Adrian Miller
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Publication number: 20140127823Abstract: The invention relates to a device for producing CO2, N2 and/or SO2 from a sample for a quantitative analysis of the sample, comprising a reactor structure and metals acting in an oxidizing manner or metal oxides in the reactor. According to the invention, the reactor structure has at least two zones through which the sample can flow, which is to say a first zone with reactor metal and reservoir metal, or only reactor metal, and following the first zone, a second zone with reactor metal and reservoir metal, or only reservoir metal, wherein both metals can form oxides, and wherein the ratio of the reactor metal to the reservoir metal in the first zone is greater than in the second zone.Type: ApplicationFiled: January 9, 2014Publication date: May 8, 2014Applicant: Thermo Fisher Scientific (Bremen) GmbHInventor: Michael Krummen
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Patent number: 8703059Abstract: A method and apparatus for combustion analysing a sample in a combustion analyzer (120,160,180), where the sample comprises a proportion of sulphur. The sample is supplied to the combustion analyzer and combusted to produce combustion products, comprising a yield of sulphur dioxide for detection. Nitrogen monoxide or a source of nitrogen monoxide is supplied to the combustion analyzer to improve the yield of sulphur dioxide in the combustion products. The yield improver may be supplied before and/or during the combusting step. A proportion of yield improver is preferably greater than the (expected) proportion of sulphur. Ozone may be supplied to the combustion products to convert at least a proportion of any nitrogen monoxide in the combustion products to nitrogen dioxide, before detection.Type: GrantFiled: December 31, 2007Date of Patent: April 22, 2014Assignee: Thermo Fisher Scientific Inc.Inventors: David Marco Gertruda Alberti, Maurice Stephan Van Doeselaar
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Patent number: 8642350Abstract: A sensor material of the type comprising a long-decay photoluminescent, protonable dye embedded in a suitable polymeric matrix, is used for generating a specific optical response to two different analytes present in a sample, thus allowing selective determination of the two analytes in the sample. Also described is a method for the simultaneous sensing of a first and second analyte in a sample. The method comprises the steps of irradiating a sensor material of the type comprising a long-decay photoluminescent protonable dye embedded in a suitable polymeric matrix with light of one or two wavelengths, determining photoluminescence intensity and lifetime signals originating from the sensor, and correlating the photoluminescence intensity signal with a concentration of the first analyte and the photoluminescence lifetime signal(s) with the concentration of the second analyte.Type: GrantFiled: March 29, 2011Date of Patent: February 4, 2014Assignee: University College Cork, National University of Ireland, CorkInventor: Dmitri Papkovsky
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Patent number: 8632726Abstract: The invention relates to a device for producing CO2, N2 and/or SO2 from a sample for a quantitative analysis of the sample, comprising a reactor structure and metals acting in an oxidizing manner or metal oxides in the reactor. According to the invention, the reactor structure has at least two zones through which the sample can flow, which is to say a first zone with reactor metal and reservoir metal, or only reactor metal, and following the first zone, a second zone with reactor metal and reservoir metal, or only reservoir metal, wherein both metals can form oxides, and wherein the ratio of the reactor metal to the reservoir metal in the first zone is greater than in the second zone.Type: GrantFiled: March 25, 2009Date of Patent: January 21, 2014Assignee: Thermo Fischer Scientific (Bremen) GmbHInventor: Michael Krummen
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Patent number: 8609427Abstract: A sulfur dioxide sensor comprising a first beam having a functionalized sensing surface capable of sensing sulfur dioxide, the first beam capable of producing a first resonant frequency; and a second beam having a functionalized reference surface not capable of sensing sulfur dioxide, the second beam capable of producing a second resonant frequency, wherein differential sensing of sulfur dioxide may be performed, further wherein the first beam is functionalized with a liquid phase of a first polymeric compound and the second beam is functionalized with a liquid phase of a second polymeric compound is provided. In one embodiment, the sensor is a nano-sensor capable of low drift accurately detecting sulfur dioxide levels at the zeptograms level. Methods of making and using a sulfur dioxide sensor are also provided.Type: GrantFiled: December 7, 2010Date of Patent: December 17, 2013Assignee: Honeywell Romania s.r.l.Inventors: Bogdan Catalin Serban, Cornel P. Cobianu, Mihai N. Mihaila, Viorel Georgel Dumitru
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Patent number: 8288161Abstract: Articles of manufacture and methods of making and using same concern a container having an internal space and a passivated internal metal surface. The container contains a composition of an acid gas and a balance gas contained within the internal space and in contact with the passivated internal metal surface. The stability of the acid gas concentration over time is enhanced.Type: GrantFiled: October 26, 2010Date of Patent: October 16, 2012Assignee: American Air Liquide, Inc.Inventors: Robert Benesch, Malik Haouchine, Tracey Jacksier
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Patent number: 8048682Abstract: The present invention relates to a method for selectively detecting and/or measuring gaseous SO2 at a temperature of at least 500° C.Type: GrantFiled: April 29, 2008Date of Patent: November 1, 2011Assignee: UT-Battelle, LLCInventors: David L. West, Frederick C. Montgomery, Timothy R. Armstrong
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Publication number: 20110263034Abstract: The invention relates to a method and to a device for sulfur characterization and quantification in a sample of sedimentary rocks or of petroleum products wherein the following stages are carried out: heating said sample in a pyrolysis oven (1) in a non-oxidizing atmosphere, oxidizing part of the pyrolysis effluents and continuously measuring the amount of SO2 generated by said part after oxidation, then transferring the pyrolysis residue of said sample into an oxidation oven (1?) and continuously measuring the amount of SO2 contained in the effluents resulting from said oxidation heating.Type: ApplicationFiled: October 27, 2009Publication date: October 27, 2011Inventors: Jean Espitalie, Roland Antonas, Violaine Lamoureux-Var, Gérémie Letort, Daniel Pillot, Valérie Beaumont, Frank Haeseler
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Patent number: 8021617Abstract: Systems and methods are disclosed for measuring sulfur trioxide/sulfuric acid content of flue gas. A probe is provided that extracts two separate lines of gas samples simultaneously from the flue gas. One of the two lines is dynamically spiked with a known quantity of sulfur trioxide, preferably generated in the probe. A comparison of sulfur trioxide/sulfuric acid content measurements from the spiked and unspiked lines helps identify and adjust for inherent biases in the measuring system. Also disclosed are catalyst structures and methods for use thereof for generating sulfur trioxide at known concentration.Type: GrantFiled: October 27, 2009Date of Patent: September 20, 2011Assignee: Clean Air Engineering, Inc.Inventors: Scott A. Evans, Daniel H. Roesler
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Publication number: 20110177607Abstract: The present invention relates to a sulfur assaying method comprising converting carbon monoxide in a sample gas generated by combustion of the sample to nitrogen dioxide by a pretreatment, and then measuring the intensity of fluorescence of sulfur dioxide in the sample gas, the pretreatment comprising irradiating the sample gas with light from a low pressure mercury lamp, and also relates to a sulfur assaying apparatus comprising a combustor (1) which generates a sample gas from a sample, a pretreatment means (2) for converting nitrogen monoxide in the sample gas to nitrogen dioxide, and an ultraviolet fluorescence detector (4) for measuring the intensity of fluorescence of sulfur dioxide in the sample gas, the pretreatment means (2) comprising a low pressure mercury lamp (3) disposed in a container (20).Type: ApplicationFiled: March 22, 2011Publication date: July 21, 2011Applicant: MITSUBISHI CHEMICAL ANALYTECH CO., LTD.Inventors: Shuichi Akasaka, Tamaki Tomoyose
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Publication number: 20110143448Abstract: A sulfur dioxide sensor comprising a first beam having a functionalized sensing surface capable of sensing sulfur dioxide, the first beam capable of producing a first resonant frequency; and a second beam having a functionalized reference surface not capable of sensing sulfur dioxide, the second beam capable of producing a second resonant frequency, wherein differential sensing of sulfur dioxide may be performed, further wherein the first beam is functionalized with a liquid phase of a first polymeric compound and the second beam is functionalized with a liquid phase of a second polymeric compound is provided. In one embodiment, the sensor is a nano-sensor capable of low drift accurately detecting sulfur dioxide levels at the zeptograms level. Methods of making and using a sulfur dioxide sensor are also provided.Type: ApplicationFiled: December 7, 2010Publication date: June 16, 2011Applicant: Honeywell Romania S.R.L.Inventors: Bogdan Catalin Serban, Cornel P. Cobianu, Mihai N. Mihaila, Viorel Georgel Dumitru
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Patent number: 7771654Abstract: An apparatus for monitoring ammonia in gaseous streams, particularly in flue gas streams. The apparatus is transportable but can be permanently installed. The flue gas can be monitored in real time.Type: GrantFiled: September 7, 2006Date of Patent: August 10, 2010Inventors: Randall P. Moore, Robert L. Mullowney, Jr.
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Patent number: 7772004Abstract: The invention relates to a method allowing to determine at least one petroleum characteristic of a geologic sediment sample, wherein the sample is heated in an oxidizing atmosphere, its temperature being successively raised to a first, then to a second value, said first value below 200° C. being reached very quickly, then maintained substantially constant for a certain time, said second value ranging between 600° C. and 850° C. being reached with a temperature gradient ranging between 1 and 30° C./min, from said first value. According to the invention, the amount of SO2 contained by the effluent resulting from said oxidizing heating is measured continuously, every moment of the heating period of said sample.Type: GrantFiled: April 15, 2005Date of Patent: August 10, 2010Assignee: Institut Francais du PetroleInventor: François Lorant
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Publication number: 20100047917Abstract: The present invention relates to a sulfur assaying method comprising converting carbon monoxide in a sample gas generated by combustion of the sample to nitrogen dioxide by a pretreatment, and then measuring the intensity of fluorescence of sulfur dioxide in the sample gas, the pretreatment comprising irradiating the sample gas with light from a low pressure mercury lamp, and also relates to a sulfur assaying apparatus comprising a combustor (1) which generates a sample gas from a sample, a pretreatment means (2) for converting nitrogen monoxide in the sample gas to nitrogen dioxide, and an ultraviolet fluorescence detector (4) for measuring the intensity of fluorescence of sulfur dioxide in the sample gas, the pretreatment means (2) comprising a low pressure mercury lamp (3) disposed in a container (20).Type: ApplicationFiled: May 11, 2009Publication date: February 25, 2010Applicant: MITSUBISHI CHEMICAL ANALYTECH CO., LTD.Inventors: Shuichi Akasaka, Tamaki Tomoyose
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Patent number: 7514265Abstract: The present application describes a reagent system for detecting presence of aldehyde in a sample that includes (i) Component A, which includes bisulfite, pararosalinine, and hydrochloric acid; and (ii) Component B, which includes a solution of hydroxide, wherein the Component A has a pH of from about 1.4 to 1.6.Type: GrantFiled: October 5, 2004Date of Patent: April 7, 2009Assignee: Marine Products TechInventors: Min Jin Yoon, Joong Cheol Lee, Yang Seo Ku
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Patent number: 7427378Abstract: An analysis method and analysis apparatus involve analysis for a sulfur component using ultraviolet fluorescence capable of removing the interferential influence of NO with good efficiency and certainty to thereby measure a concentration of only sulfur components such as SO2 and others even in continuous measurement over a long term with a high precision. An analysis method involves analysis for a sulfur component using ultraviolet fluorescence. A sample gas is illuminated with ultraviolet and fluorescence is emitted by the ultraviolet illumination and detected to measure concentrations of sulfur components including at least SO2 in the sample gas. NO, which is an interferential component in the sample gas, is oxidized to nitrogen dioxide, followed by the illuminating of the sample gas with ultraviolet.Type: GrantFiled: August 13, 2004Date of Patent: September 23, 2008Assignee: Horiba, Ltd.Inventors: Kotaro Akashi, Hitoshi Hirai
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Publication number: 20080213913Abstract: A method and apparatus for combustion analysing a sample in a combustion analyzer (120,160,180), where the sample comprises a proportion of sulphur. The sample is supplied to the combustion analyzer and combusted to produce combustion products, comprising a yield of sulphur dioxide for detection. Nitrogen monoxide or a source of nitrogen monoxide is supplied to the combustion analyzer to improve the yield of sulphur dioxide in the combustion products. The yield improver may be supplied before and/or during the combusting step. A proportion of yield improver is preferably greater than the (expected) proportion of sulphur. Ozone may be supplied to the combustion products to convert at least a proportion of any nitrogen monoxide in the combustion products to nitrogen dioxide, before detection.Type: ApplicationFiled: December 31, 2007Publication date: September 4, 2008Applicant: THERMO FISHER SCIENTIFIC INC.Inventors: David Marco Gertruda ALBERTI, Maurice Stephan Van Doeselaar
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Patent number: 7297549Abstract: A method of determining bias in a measurement of a constituent concentration level in a sample gas is provided. The method comprises establishing a sample gas flow from an emission stream into a sample gas line of an emissions monitoring system. The method further comprises removing water from the sample gas flow and cooling the sample gas flow to a temperature below about 41° F. to produce a cooled, dried sample gas flow. The constituent concentration level is then determined for the cooled, dried sample gas flow. The method further comprises introducing a span gas having a known span gas constituent concentration level into the sample gas flow to form a combined sample and span gas flow, the span gas being introduced at a desired span gas flow rate. The method still further comprises removing water from the combined sample and span gas and cooling the combined sample and span gas to a temperature below about 41° F. to produce a cooled, dried, combined sample and span gas flow.Type: GrantFiled: March 6, 2002Date of Patent: November 20, 2007Assignee: General Electric CompanyInventors: William Steven Lanier, Glenn England
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Patent number: 7062385Abstract: The present invention generally relates to nucleic acid-based sensors and methods for detecting volatile analytes. More particularly, this invention relates to nucleic acid-based optical sensors, sensor arrays, sensing systems and sensing methods for intelligent sensing and detection of unknown materials by way of real-time feedback and control of sampling conditions.Type: GrantFiled: November 25, 2002Date of Patent: June 13, 2006Assignee: Tufts UniversityInventors: Joel E. White, John S. Kauer
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Patent number: 7029920Abstract: A method and system for determining a concentration level of NOx in an exhaust stream from a combustion source. The method comprises capturing sample gas from the exhaust stream using a sampling device. NO2 in the sample gas is converted to NO by passing the sample gas through a catalytic NO2 converter. The method also comprises removing water from the sample gas by passing the sample gas through a dryer and determining a sample gas NO concentration level. The step of converting NO2 is performed at a temperature above the dew point temperature of the sample gas.Type: GrantFiled: October 31, 2001Date of Patent: April 18, 2006Assignee: General Electric CompanyInventors: William Steven Lanier, Glenn England
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Patent number: 6933151Abstract: A diagnostic system for monitoring catalyst performance in an exhaust system comprises a plurality of treatment devices catalytically treating an exhaust gas stream, and a plurality of gas sensors for monitoring the catalyst performance of the treatment devices to determine when sulfur poisoning occurs. An on-board diagnostic system receives signals from the gas sensors, and, based upon response time differentials between sensors, determines whether the treatment devices are experiencing sulfur poisoning.Type: GrantFiled: October 7, 2004Date of Patent: August 23, 2005Assignee: Delphi Technologies, Inc.Inventors: Owen H. Bailey, Jean J. Balland, Sergio Quelhas, Bart Schreurs
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Patent number: 6852543Abstract: A method and apparatus for sulfate analysis in a sample are provided. A portion of the sulfate contained in the sample is converted to sulfur dioxide, and at least a portion of the sulfur dioxide can be determined. The amount of sulfur dioxide determined can be used to quantify the amount of sulfate in the sample.Type: GrantFiled: July 1, 2003Date of Patent: February 8, 2005Assignee: President and Fellows of Harvard CollegeInventors: George Allen, David Harrison
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Patent number: 6803236Abstract: A diagnostic system for monitoring catalyst performance in an exhaust system comprises a plurality of treatment devices catalytically treating an exhaust gas stream, and a plurality of gas sensors for monitoring the catalyst performance of the treatment devices to determine when sulfur poisoning occurs. An on-board diagnostic system receives signals from the gas sensors, and, based upon response time differentials between sensors, determines whether the treatment devices are experiencing sulfur poisoning.Type: GrantFiled: August 10, 2001Date of Patent: October 12, 2004Assignee: Delphi Technologies, Inc.Inventors: Owen H. Bailey, Jean J. Balland, Sergio Quelhas, Bart Schreurs
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Publication number: 20040121478Abstract: An optical gas sensor for determining a gas, in particular in air, having a radiation source, a detector and a sensitive layer in the beam path of the radiation source. The sensitive layer contains at least one oligomer or polymer having at least one side chain, the side chain having at least one basic or acidic functional group.Type: ApplicationFiled: July 1, 2003Publication date: June 24, 2004Inventors: Thomas Brinz, Mary Lewis
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Publication number: 20040082072Abstract: A method and apparatus for sulfate analysis in a sample are provided. A portion of the sulfate contained in the sample is converted to sulfur dioxide, and at least a portion of the sulfur dioxide can be determined. The amount of sulfur dioxide determined can be used to quantify the amount of sulfate in the sample.Type: ApplicationFiled: July 1, 2003Publication date: April 29, 2004Applicant: President and Fellows of Harvard CollegeInventors: George Allen, David Harrison
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Patent number: 6649356Abstract: Solid phase methods for the identification of an analyte in a biological medium, such as a body fluid, using bioluminescence are provided. A chip designed for performing the method and detecting the bioluminescence is also provided. Methods employing biomineralization for depositing silicon on a matrix support are also provided. A synthetic synapse is also provided.Type: GrantFiled: April 19, 2002Date of Patent: November 18, 2003Assignee: Prolume, Ltd.Inventors: Bruce J. Bryan, Stephen Gaalema, Randall B. Murphy
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Patent number: 6623699Abstract: An analyzer compensates for gas flow perturbations by providing a makeup flow of carrier gas to maintain the pressure and/or flow rate of analyte and inert gas through a detector constant such that a accurate determination of a low concentration of an analyte in the presence of a high concentration of a second analyte can be accurately determined. In one embodiment, a carrier gas is introduced through a valve responsive to the detected pressure in the gas flow stream between a scrubber and a subsequent detector for maintaining the pressure constant during an analysis. In another embodiment of the invention, a flow transducer is positioned in the gas flow path between the scrubber and detector and coupled to a flow control valve coupled to introduce carrier gas as a function of detected gas flow such that the flow rate of gas into the detector is maintained constant.Type: GrantFiled: November 15, 2000Date of Patent: September 23, 2003Assignee: Leco CorporationInventors: Brian W. Pack, Carlos Guerra, Peter M. Willis, Joel C. Mitchell
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Publication number: 20030049854Abstract: An improved on-stream analyzer for monitoring sulfur or nitrogen content of liquid petroleum or beverage products is described. It consists of the following main components: a sample injector for injecting predetermined fixed volumes of the liquid into a thermal oxidizer (pyrolyzer) at a preset, controlled rate, a thermal oxidizer in which an inert carrier gas and oxygen are introduced at measured and preset, controlled rates to thermally oxidize the sample at a temperature of about 1050° C., sample conditioner to control the relative humidity and temperature of the resulting gas mixture, an electrochemical cell sensitive to sulfur dioxide (SO2) or NO to measure the concentration of SO2 or NO in the gas mixture, and a programmable logic controller (PLC) to calculate the sulfur content of the original sample and manage the analyzer.Type: ApplicationFiled: September 11, 2001Publication date: March 13, 2003Inventor: John R. Rhodes
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Publication number: 20030032188Abstract: A diagnostic system for monitoring catalyst performance in an exhaust system comprises a plurality of treatment devices catalytically treating an exhaust gas stream, and a plurality of gas sensors for monitoring the catalyst performance of the treatment devices to determine when sulfur poisoning occurs. An on-board diagnostic system receives signals from the gas sensors, and, based upon response time differentials between sensors, determines whether the treatment devices are experiencing sulfur poisoning.Type: ApplicationFiled: August 10, 2001Publication date: February 13, 2003Inventors: Owen H. Bailey, Jean J. Balland, Sergio Quelhas, Bart Schreurs
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Patent number: 6495341Abstract: The present invention is a method and apparatus for monitoring, preferably in real time, the physical or chemical conversion of a grain material. The method employs multivariate analysis of a collected sample. In a preferred embodiment a steeping conversion is monitored by multicomponent chemical analysis of the steepwater.Type: GrantFiled: December 28, 2000Date of Patent: December 17, 2002Assignee: Alpha MOSInventor: Frederic Zenhausern
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Publication number: 20020164814Abstract: The present invention provides a method and apparatus for accurately determining weight loss of a sample during heating in a furnace. The method includes the steps of placing a sample in a heated furnace, heating the sample while measurements of sample weight are made, determining rate function from the sample weight measurements, producing a weight loss correction factor using the rate function and using the weight loss correction factor to obtain a corrected weight loss for the sample.Type: ApplicationFiled: June 25, 2002Publication date: November 7, 2002Applicant: Troxler Electronic Laboratories, Inc.Inventor: Robert Ernest Troxler
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Patent number: 6472223Abstract: A method for directly monitoring and controlling a continuous process stream for dechlorination residual is provided. A sample stream to which a dechlorination agent has been added to completely eliminate a residual disinfectant is continuously drawn off. An analyzing agent of iodine is provided by introducing an iodide solution, a chloramine-T solution, and an acetic acid buffer into the sample stream. The reagents quickly react to produce iodine that reacts with any residual disinfectant removal agent residual that may be present. Thereafter, the sample stream is continuously analyzed to determine the amount of unreacted iodine remaining in the process sample. Based on the amount of iodine added to the process sample and the amount of unreacted iodine remaining in the sample after reaction, the amount of dechlorination residual is continuously determined.Type: GrantFiled: January 3, 2000Date of Patent: October 29, 2002Assignee: United States Filter CorporationInventors: James W. Stannard, Kevin Anthony Foster, David MacDonald Bonnick
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Patent number: 6399391Abstract: A system and apparatus for analyzing stack gas for total reduced sulfur. The gas is withdrawn from a stack through a probe, filtered and regulated to a known temperature. The gas is then passed through a scrubbing column to remove sulfur dioxide and split into first and second portions. The first portion is oxidized to covert total reduced sulfur compounds to SO2, and the gas is then passed to an electrochemical sensor for SO2 which is maintained at a temperature at least equal to the temperature of the regulated gas. The second portion of the scrubbed gas is passed through an electrochemical sensor for oxygen which is maintained at substantially the same temperature as the sensor for SO2.Type: GrantFiled: October 25, 1994Date of Patent: June 4, 2002Inventor: Robert L. Tomlin
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Publication number: 20020031447Abstract: An optical gas sensor for determining a gas in a gas mixture, especially for determining a gas component in the air, is described, having a radiation source and having a sensitive layer positioned on a substrate. The sensitive layer of the sensor is porous and contains particles, which are optically transparent to a radiation emitted by radiation source and which lengthen the optical path of the radiation.Type: ApplicationFiled: June 22, 2001Publication date: March 14, 2002Inventors: Thomas Brinz, Heidrun Potthast
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Publication number: 20020028518Abstract: An optical sensor is proposed for determining gases in gas mixtures, especially for determining one gas component in the air, having a sensitive layer exposed to the gas and having a means for detecting a change in an optical property of the sensitive layer. The sensitive layer of the sensor contains a phosphorus or nitrogen-containing base having numerous and/or long-chain alkyl groups for the pH adjustment of the sensitive layer.Type: ApplicationFiled: June 28, 2001Publication date: March 7, 2002Inventors: Thomas Brinz, Heidrun Potthast
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Patent number: 6205841Abstract: Mass flow controllers are respectively placed in the middle of a hydrogen gas tube and air tube connected to a FPD. The flow controllers are controlled to supply hydrogen and oxygen from the nozzle to achieve the optimum mixture rate of hydrogen and oxygen for combustion of each target component in a sample. Since the mixture rate of hydrogen gas and air is optimum for each target component, the quantity of light emitted by the combustion increases and detection of each target component improves.Type: GrantFiled: February 19, 1999Date of Patent: March 27, 2001Assignee: Shimadzu CorporationInventor: Shigeaki Shibamoto
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Patent number: 6046054Abstract: The selectivity of response of resistive gas sensors to specific gases or vapors is improved by the selection of specified gas-sensitive materials which are not previously known for the applications described, which include detection of hydrocarbons in the presence of CO, H.sub.2 S, SO.sub.2, chlorine, NO.sub.2, CO.sub.2 (especially in low concentrations), CFC's, ammonia, free oxygen by determination of partial pressures, and numerous organic gases and vapors.Type: GrantFiled: December 9, 1997Date of Patent: April 4, 2000Assignee: Capteur Sensors & Analysers, Ltd.Inventors: Peter McGeehin, Patrick Timothy Moseley, David Edward Williams, Geoffrey Stephen Henshaw, Darryl Hirst Dawson, Laura Jane Gellman
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Patent number: 6010664Abstract: A method for monitoring the oxidation rate in a flue gas desulfurization system having a slurry comprises locating a monitor in the system for accessing the slurry. A sample is periodically drawn from the slurry by the monitor wherein a titration is performed on each sample. The titration performed on each sample comprises adding a potassium iodate KIO.sub.3 solution, a potassium iodide KI starch solution and an acid solution to the sample in the monitor for causing the sample to exhibit a color corresponding to the oxidation rate.Type: GrantFiled: July 12, 1993Date of Patent: January 4, 2000Assignee: The Babcock & Wilcox CompanyInventors: Dennis W. Johnson, Pervaje A. Bhat
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Patent number: 5994144Abstract: When adsorbed gas is analyzed after metal, ceramics or metallic salt has been left in an environmental atmosphere for a predetermined period of time, an average concentration of specific gas over a long period of time can be accurately measured with an inexpensive small apparatus. Especially, porous metal or ceramics (transition metal oxide) are excellent in selective adsorption properties for NO.sub.x, porous ceramics (rare earth element oxide) are excellent in selective adsorption properties for CO.sub.2, and a specific chloride such as copper chloride and silver chloride is excellent in selective adsorption properties for SO.sub.2. A test kit accommodating such test pieces in a case, a protective case for the test kit to put the test kit into practical use, an umbrella and a forced air blowing unit are also disclosed.Type: GrantFiled: January 4, 1994Date of Patent: November 30, 1999Assignee: Fujitsu LimitedInventors: Eiichi Nakajima, Yasuo Udoh, Tsutomu Iikawa, Toshisuke Kitakohji, Teruo Motoyoshi, Takashi Furusawa, Shiori Yamazaki, Masao Nakayama, Michiko Satoh, Shigeru Fukushima, Mayumi Itabashi
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Patent number: 5948689Abstract: In order to provide a thermal coupling between a heat source and a heat sink, an integrated interleaved-fin connector is provided. A first substrate includes a first side surface and a second side surface. A plurality of heat generating devices are formed in the first side surface. A plurality of first channels are etched in the second side surface to form a plurality of first fins. A second substrate has a plurality of second channels etched therein to form a plurality of second fins and a base. The base is for thermally engaging with a heat sink. The first and second fins providing a thermally conductive path from the heat generating devices to the heat sink when interleaved with each other.Type: GrantFiled: November 14, 1997Date of Patent: September 7, 1999Assignee: Digital Equipment CorporationInventors: William R. Hamburgen, John S. Fitch
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Patent number: 5869342Abstract: A method for determining the amount of residual disinfectant removing agent in a process stream to which the disinfectant removing agent has been added to completely remove a disinfectant residual, comprising the steps of: (a) drawing off a sample of the process stream; (b) mixing an acidic iodate solution and an iodide solution to produce an iodine analyzing agent; (c) adding to the sample the iodine analyzing agent in an amount sufficient to react with the residual disinfectant removing agent and leave an unreacted amount of residual iodine; (d) allowing sufficient time for the iodine to react with the residual disinfectant removing agent; (e) analyzing the sample to determine the amount of residual iodine remaining in the sample, and (f) determining the amount of residual disinfectant removing agent in the sample based on the amount of iodine analyzing agent added and the amount of residual iodine remaining in the sample after reaction.Type: GrantFiled: November 18, 1996Date of Patent: February 9, 1999Assignee: Wallace & TiernanInventors: James W. Stannard, Jared K. Bryan, Albert Van Grouw, III
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Patent number: 5846831Abstract: In a first embodiment of the present invention, a control method and system are provided in an exhaust emission sampling system for controlling a flow controller in order to compensate for the effects of changing water vapor content in a diluted sample having a predetermined dilution ratio. A water measuring device such as a relative humidity sensor generates a water vapor signal based on the amount of water vapor in the diluted sample. The water vapor signal is then processed within a control unit to obtain a value for the amount of water in the diluted sample. A control signal is generated by the control unit based on the amount of water vapor, flow rate of the exhaust emissions, and also, on the type of fuel used in the combustion process to control the flow controller which is, preferably, a mass flow controller.Type: GrantFiled: April 1, 1997Date of Patent: December 8, 1998Assignee: Horiba Instuments, Inc.Inventor: William M. Silvis
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Patent number: 5739038Abstract: A gas analyzer system for providing a spectroscopic analysis of the sample gas. This analysis is accomplished by first introducing the sample gas into the inlet of the system and transporting it to a spectral analyzer. The sample gas is then spectrally analyzed and the analyzer outputs a signal indicative of a radiation intensity spectrum associated with the analyzed sample gas. A processing unit uses the analyzer signal to detect the presence of one or more prescribed gases and to determine the concentration of each of the prescribed gases in the sample gas. Next, the reacting agent is supplied to the sample gas to convert one or more gases whose presence in the sample gas cannot be detected via spectral analysis due to the masking effects other gases present in the sample gas. The masked gases are converted to secondary gases at least one of which is readily detectable via spectral analysis.Type: GrantFiled: July 26, 1996Date of Patent: April 14, 1998Assignee: Anarad, Inc.Inventor: Donald Edward Burrows
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Patent number: 5661036Abstract: A process and apparatus are disclosed for the detection and measurement of sulfur in both organic and inorganic sulfur-containing compounds. The process includes admixing a sample including a sulfur-containing compound with oxygen, and then exposing the mixture to a source of combustion causing heat in the presence of a combustion supporting reducing agent at a combustion site. The resulting gaseous combustion products are vacuum extracted from the combustion site, and then directed into a darkened low pressure chamber. The combustion products in the low pressure chamber are then contacted with ozone, with the result that the sulfur combustion products are converted to chemiluminescent sulfur dioxide. The emitted chemiluminescence is then detected, and may be measured to provide a quantitative indication of the amount of sulfur in the original sample. The preferred source of oxygen is air, the preferred form of combustion heat is a flame, and the preferred form of reducing agent is hydrogen gas.Type: GrantFiled: May 16, 1995Date of Patent: August 26, 1997Assignee: Sievers Instruments, Inc.Inventors: Richard L. Benner, Donald H. Stedman
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Patent number: 5547876Abstract: Non-toxic combustion decomposition accelerators and processes for their production for elemental analysis. The non-toxic accelerators may be either single component or multicomponent. The single component non-toxic accelerators are glass frit, niobium pentoxide, and inorganic phosphate compounds. The multicomponent accelerators are formed from a combination of the foregoing, and most preferably from (a) one or more of niobium pentoxide, tungsten oxide and mixtures thereof, and (b) one or more of glass frit, inorganic phosphate compounds, and mixtures thereof.Type: GrantFiled: September 27, 1994Date of Patent: August 20, 1996Assignee: Leco CorporationInventors: Ching-Fong Chen, Carlos Guerra