Patents by Inventor Robert Jahns
Robert Jahns has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 11984739Abstract: A system and methods including workstations for use in office spaces where the workstations include electrical couplers and power distribution systems for coupling portable and rechargeable batteries to the arrangements and delivering electrical charge to affordance devices where battery charging stations are located at different locations throughout a facility and alerts including nearest charging station with fully charged batteries are provided to employees at the stations when battery depletion thresholds are met or where batteries are automatically delivered to facility locations via automated robotic carts when needed.Type: GrantFiled: July 30, 2021Date of Patent: May 14, 2024Assignee: STEELCASE INC.Inventors: Bruce Smith, Bo Anderson, Karl Jahn Mead, Robert Scheper, Hyun Yoo, Michael Held, Justin Glen Beitzel
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Publication number: 20240118160Abstract: A device and a process detect a leak during artificial ventilation of a patient. A measurement system with a sensor arrangement and a sensor fluid guide unit is monitored. A fluid connection is established between a patient-side coupling unit and a medical device with a patient fluid guide unit. A gas sample is branched off from the patient fluid guide unit and guided through the sensor fluid guide unit to the sensor arrangement. A thermal conductivity time course of the gas sample reaching the sensor arrangement is determined with sensor arrangement measured values. Depending on a temporal change in the determined thermal conductivity, a decision is made as to whether there is an indication of a leak between the patient's fluid-guiding unit and the sensor arrangement. The leak establishes a fluid connection between the sensor fluid guide unit and/or the sensor arrangement and the environment.Type: ApplicationFiled: September 28, 2023Publication date: April 11, 2024Inventors: Gerd PETER, Bernd-Michael DICKS, Tobias HEISE, Robert JAHNS, Martin KROH
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Publication number: 20230349822Abstract: A gas measuring device (1000) for determining the concentration of a gas component in a breathing gas mixture includes a radiation source (1) with a illuminant (2) and a mirror arrangement (3) for emitting light radiation. A sample gas cuvette (5) is formed as a hollow body. A detector arrangement (15) with at least two bandpass filter elements (17, 18) and at least two detector elements (20, 21) receives the filtered light radiation. A control unit (42) is configured to detect signals from the detector elements (20, 21) and determine a concentration of a gas component in the breathing gas mixture. A light guide element (11) is provided in the form of a hollow body.Type: ApplicationFiled: April 20, 2023Publication date: November 2, 2023Inventors: Gerd PETER, Bernd-Michael DICKS, Robert JAHNS, Martin KROH, Lucas SCHNELLE
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Publication number: 20230114548Abstract: A measurement system (100) determines gas concentrations in a gas mixture of a gas sample by utilizing thermal conductivities and paramagnetic effects of thermal conductivities in the gas mixture involving data sets (203). A circuit arrangement provides measured values with an AC signal component and with a DC signal component to a calculation and control unit (200). An oxygen concentration in the gas mixture of the gas sample is determined based on the standardized AC signal components and a concentration of another gas in the gas mixture of the gas sample is determined based on the standardized DC voltage signal components. Output signals are generated by the calculation and control unit, which indicate the determined oxygen concentration and the determined concentration of another gas in the gas mixture of the gas sample.Type: ApplicationFiled: October 5, 2022Publication date: April 13, 2023Inventors: Hartmut STARK, Günter STEINERT, Hans-Ullrich HANSMANN, Tobias HEISE, Robert JAHNS
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Patent number: 11555780Abstract: A photoacoustic sensor (100) is capable of detecting a predefined target gas in an area (Um). A process is capable of detecting the target gas with the use of such a sensor (100). A sample chamber (3) holds a gas sample (Gp) to be tested. Electromagnetic waves (eW) from a radiation source (1) pass through the sample chamber (3) and the detection chamber (4). The waves elicit in the detection chamber (4) an acoustic effect, which is measured by an acoustic sensor (7). The acoustic effect is correlated with the concentration of the target gas in the sample chamber (3). The detection chamber (4) is fluid-tightly sealed, is free from target gas and is filled with a replacement gas (Eg). The transmission of the replacement gas (Eg) has a spectral response similar to that of the transmission of the target gas in a predefined target gas wavelength range.Type: GrantFiled: July 20, 2021Date of Patent: January 17, 2023Assignee: Drägerwerk AG & Co. KGaAInventors: Ralf Buchtal, Gerd Peter, Bernd-Michael Dicks, Björn Spilker, Robert Jahns, Martin Kroh
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Publication number: 20220206457Abstract: Method and systems for dynamically generating or editing a graphical dashboard via a graphical user interface (GUI) setup are provided. The method includes determining a type of a plant through the GUI setup, determining a configuration of the plant through the GUI setup, determining at least one component of the plant through the GUI setup, and configuring parameters of the at least one component and/or the plant through the GUI setup. The method also includes generating the dashboard including a plant control logic of the plant based on the type, the configuration, the at least one component, and the parameters of the at least one component and/or the plant. The method further includes controlling the plant based on the plant control logic.Type: ApplicationFiled: December 30, 2020Publication date: June 30, 2022Inventors: Brian Meyers, Kathylynn Hanggi Sedro, Anthony W. Bruno, Brian A. Kirkman, Mayra R. Reyes Elizondo, Robert Jahn
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Publication number: 20220111357Abstract: The present invention relates to a method of reducing at least one aqueous organic compound in a triphasic reaction mixture, wherein the reaction mixture comprises at least one solid, at least one liquid and at least one gaseous component, wherein (i) the solid component is (a) a catalytically active composite based on (b) at least one perforated and permeable support, wherein the catalytically active composite is on at least one side of the support and inside the support and (a) the catalytically active composite is obtained by applying a suspension comprising at least one inorganic component of a compound of at least one of the elements Ce, La Sc, Y, Ti, Zr, Hf, Rf, V, Nb, Ta, Db, Cr, Mo, W, Sg, Mn, Tc, Re, Bh, Fe, Co, B, In, Tl, Si, Ge, Sn, Pb, Sb and Bi with at least one of the elements Te, Se, S, O, Sb, As, P, N, Ge, Si, C and Ga and/or a compound of one of the elements Ti, Zr, Ce and Si with oxygen, and/or a metal selected from Pt, Rh, Ru, Ir, Cu, Ni, Co, Zn, and Pd, in suspension in a sol, and (Type: ApplicationFiled: February 6, 2020Publication date: April 14, 2022Inventors: Thomas HAAS, Robert JAHN, Christian HYING, Marc LOCHTHOVE
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Publication number: 20220026346Abstract: A photoacoustic sensor (100) is capable of detecting a predefined target gas in an area (Um). A process is capable of detecting the target gas with the use of such a sensor (100). A sample chamber (3) holds a gas sample (Gp) to be tested. Electromagnetic waves (eW) from a radiation source (1) pass through the sample chamber (3) and the detection chamber (4). The waves elicit in the detection chamber (4) an acoustic effect, which is measured by an acoustic sensor (7). The acoustic effect is correlated with the concentration of the target gas in the sample chamber (3). The detection chamber (4) is fluid-tightly sealed, is free from target gas and is filled with a replacement gas (Eg). The transmission of the replacement gas (Eg) has a spectral response similar to that of the transmission of the target gas in a predefined target gas wavelength range.Type: ApplicationFiled: July 20, 2021Publication date: January 27, 2022Inventors: Ralf BUCHTAL, Gerd PETER, Bernd-Michael DICKS, Björn SPILKER, Robert JAHNS, Martin KROH
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Patent number: 10428035Abstract: In a process for the epoxidation of an olefin by continuously reacting the olefin with hydrogen peroxide in a methanol solvent on a fixed bed epoxidation catalyst comprising a titanium zeolite, the hydrogen peroxide is used as an aqueous hydrogen peroxide solution made by an anthraquinone process, the aqueous hydrogen peroxide solution is mixed with methanol to give a feed mixture and this feed mixture is filtered before being contacted with the fixed bed epoxidation catalyst.Type: GrantFiled: November 1, 2016Date of Patent: October 1, 2019Assignees: Evonik Degussa GmbH, thyssenkrupp Industrial Solutions AGInventors: Matthias Pascaly, Manfred Bärz, Marc Brendel, Robert Jahn, Jürgen Schemel, Michael Dopfer
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Publication number: 20180354923Abstract: In a process for the epoxidation of an olefin by continuously reacting the olefin with hydrogen peroxide in a methanol solvent on a fixed bed epoxidation catalyst comprising a titanium zeolite, the hydrogen peroxide is used as an aqueous hydrogen peroxide solution made by an anthraquinone process, the aqueous hydrogen peroxide solution is mixed with methanol to give a feed mixture and this feed mixture is filtered before being contacted with the fixed bed epoxidation catalyst.Type: ApplicationFiled: November 1, 2016Publication date: December 13, 2018Inventors: Matthias PASCALY, Manfred BÄRZ, Marc BRENDEL, Robert JAHN, Jürgen SCHEMEL, Michael DOPFER
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Patent number: 10125108Abstract: In a process for the epoxidation of propene, comprising the steps: reacting propene with hydrogen peroxide in the presence of a titanium silicalite catalyst and a methanol solvent; separating non-reacted propene and propene oxide from the resulting reaction mixture to provide a solvent mixture comprising methanol and water in a combined amount of at least 90% by weight; and feeding this solvent mixture as a feed stream to a continuously operated methanol distillation column at a feed point in the middle section of said column to provide an overhead product comprising at least 90% by weight methanol and a bottoms product comprising at least 90% by weight water; the addition of a liquid defoamer, having a solubility in the feed stream of less than 10 mg/kg at 25° C. and a surface tension at the liquid air interface of less than 22 mN/m at 20° C.Type: GrantFiled: April 19, 2016Date of Patent: November 13, 2018Assignees: EVONIK DEGUSSA GMBH, THYSSENKRUPP INDUSTRIAL SOLUTIONSInventors: Robert Jahn, Wolfgang Wöll, Bernd Jaeger, Matthias Pascaly
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Publication number: 20180134676Abstract: In a process for the epoxidation of propene, comprising the steps: reacting propene with hydrogen peroxide in the presence of a titanium silicalite catalyst and a methanol solvent; separating non-reacted propene and propene oxide from the resulting reaction mixture to provide a solvent mixture comprising methanol and water in a combined amount of at least 90% by weight; and feeding this solvent mixture as a feed stream to a continuously operated methanol distillation column at a feed point in the middle section of said column to provide an overhead product comprising at least 90% by weight methanol and a bottoms product comprising at least 90% by weight water; the addition of a liquid defoamer, having a solubility in the feed stream of less than 10 mg/kg at 25° C. and a surface tension at the liquid air interface of less than 22 mN/m at 20° C.Type: ApplicationFiled: April 19, 2016Publication date: May 17, 2018Applicants: Evonik Degussa GmbH, THYSSENKRUPP INDUSTRIAL SOLUTIONS AGInventors: Robert JAHN, Wolfgang WÖLL, Bernd JAEGER, Matthias PASCALY
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Publication number: 20180038786Abstract: A device analyzes an anesthesia ventilation gas with an infrared radiation source and includes a gas cuvette, a Fabry-Perot interferometer with a band pass filter function, adjustable with respect to a central transmission wavelength as a function of a control signal, a detector providing a measured signal and a computing and control unit providing the control signal and detecting the measured signal. The computing and control unit is configured to actuate the Fabry-Perot interferometer in a first operating mode by the control signal such that the central transmission wavelength scans a predefined wavelength range, to detect a presence in the ventilation gas sample potential types of anesthetic gases based on the measured signal. In a second operating mode, the control unit controls the central transmission wavelength within a subrange of the predefined wavelength range and determines a plurality of concentration values at consecutive times for detected types of anesthetic gases.Type: ApplicationFiled: August 2, 2017Publication date: February 8, 2018Inventors: Ralf BUCHTAL, Livio FORNASIERO, Robert JAHNS, Heike VÖHRINGER
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Patent number: 9885653Abstract: A device analyzes an anesthesia ventilation gas with an infrared radiation source and includes a gas cuvette, a Fabry-Perot interferometer with a band pass filter function, adjustable with respect to a central transmission wavelength as a function of a control signal, a detector providing a measured signal and a computing and control unit providing the control signal and detecting the measured signal. The computing and control unit is configured to actuate the Fabry-Perot interferometer in a first operating mode by the control signal such that the central transmission wavelength scans a predefined wavelength range, to detect a presence in the ventilation gas sample potential types of anesthetic gases based on the measured signal. In a second operating mode, the control unit controls the central transmission wavelength within a subrange of the predefined wavelength range and determines a plurality of concentration values at consecutive times for detected types of anesthetic gases.Type: GrantFiled: August 2, 2017Date of Patent: February 6, 2018Assignee: Drägerwerk AG & Co. KGaAInventors: Ralf Buchtal, Livio Fornasiero, Robert Jahns, Heike Vöhringer
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Patent number: 9863874Abstract: A method for signal detection with a gas analysis system (1, 1?) includes a radiation source (3); a gas measuring section (9) containing gas to be measured; a Fabry-Perot interferometer (13); a thermal sensor (17) configured to cause a change in voltage between electrodes with electromagnetic radiation falling thereon and arranged such that radiation released by a second interferometer mirror falls on the thermal sensor. The method includes irradiating the gas measuring section with radiation source radiation, continuously increasing or decreasing a distance of interferometer mirrors during a generating of time signal pulses at a constant period of time from one another. After a predefined number of time signal pulses, the voltage generated between the electrodes is detected and stored as a measured signal value. After a further predefined number of time signal pulses, the voltage generated between the electrodes is detected again and stored as a measured signal value.Type: GrantFiled: September 23, 2016Date of Patent: January 9, 2018Assignee: Drägerwerk AG & Co. KGaAInventors: Peter Dreyer, Livio Fornasiero, Arne Tröllsch, Robert Jahns
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Patent number: 9810749Abstract: A magnetic field measuring device with a holding body and a plurality of magnetoelectric cantilever sensors, each of which is designed to output one electrical voltage signal while it bends in the presence of a magnetic field, the cantilever sensors being non-positively connected or bonded to the holding body.Type: GrantFiled: May 27, 2014Date of Patent: November 7, 2017Assignee: Christian-Albrechts-Universitaet zu KielInventors: Robert Jahns, Holger Runkowske, Reinhard Knoechel
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Publication number: 20170089830Abstract: A method for signal detection with a gas analysis system (1, 1?) includes a radiation source (3); a gas measuring section (9) containing gas to be measured; a Fabry-Perot interferometer (13); a thermal sensor (17) configured to cause a change in voltage between electrodes with electromagnetic radiation falling thereon and arranged such that radiation released by a second interferometer mirror falls on the thermal sensor. The method includes irradiating the gas measuring section with radiation source radiation, continuously increasing or decreasing a distance of interferometer mirrors during a generating of time signal pulses at a constant period of time from one another. After a predefined number of time signal pulses, the voltage generated between the electrodes is detected and stored as a measured signal value. After a further predefined number of time signal pulses, the voltage generated between the electrodes is detected again and stored as a measured signal value.Type: ApplicationFiled: September 23, 2016Publication date: March 30, 2017Inventors: Peter DREYER, Livio FORNASIERO, Arne TRÕLLSCH, Robert JAHNS
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Patent number: 9476791Abstract: A field testable instrument housing connection is made up of an integral instrument housing assembly that includes both an instrument housing and a separate one-piece compression nut portion and a separate modified reducing union. The instrument housing has a mating geometry that is disposed over the downhole portion of the separate modified reducing union and the separate one-piece compression nut portion is then disposed over both the uphole portion of the instrument housing and a downhole portion of the modified reducing union. The complete assembly of the modified reducing union, including primary and secondary seals in combination with the integral instrument housing assembly provide then both an annular seal and a seal of the instrument housing. The entire assembly is field testable via provided test ports.Type: GrantFiled: December 5, 2012Date of Patent: October 25, 2016Assignee: Halliburton Energy Services, Inc.Inventor: Marion Robert Jahn
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Patent number: 9383417Abstract: A method for measuring a time-variant magnetic field using a magnetoelectric sensor having mechanical resonant frequency fR, wherein the magnetic field has at least one component having harmonic time dependence with the measuring signal amplitude to be determined Hmess0 and the measuring signal frequency to be determined fmess in a known frequency interval fmin<fmess<fmax. The method includes: a. superimposing the magnetic field with a modulation magnetic field having harmonic time dependence with the known modulation amplitude Hmess0 and a selectable modulation frequency on the sensor, b. varying (wobbling) the modulation frequency over a complementary frequency interval determined by the known interval limits fmin, fmax and the resonant frequency of the sensor, c. measuring the sensor signal for each selected modulation frequency, d. searching for the at least one modulation frequency fmod, which results in a sensor signal in the mechanical resonance of the sensor, e.Type: GrantFiled: January 13, 2012Date of Patent: July 5, 2016Assignee: Christian-Albrechts-Universitaet zu KielInventors: Robert Jahns, Reinhard Knoechel, Eckhard Quandt
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Publication number: 20160116552Abstract: A magnetic field measuring device with a holding body and a plurality of magnetoelectric cantilever sensors, each of which is designed to output one electrical voltage signal while it bends in the presence of a magnetic field, the cantilever sensors being non-positively connected or bonded to the holding body.Type: ApplicationFiled: May 27, 2014Publication date: April 28, 2016Inventors: Robert Jahns, Holger Runkowske, Reinhard Knoechel