公开(公告)号：US11796458B2

公开(公告)日：2023-10-24

申请号：US17423500

申请日：2020-01-21

Applicant: FUJIKIN INCORPORATED

Inventor： Masaaki Nagase ,  Kazuteru Tanaka ,  Masahiko Takimoto ,  Kouji Nishino ,  Nobukazu Ikeda

IPC: G01N21/3504

CPC classification number: G01N21/3504 ,  G01N2201/062 ,  G01N2201/1211 ,  G01N2201/1218

Abstract: A Concentration measurement device 100 comprises: a measurement cell 4 having a flow path through which a gas flows, a light source 1 for generating incident light to the measurement cell, a photodetector 7 for detecting light emitted from the measurement cell, a pressure sensor 20 for detecting a pressure of the gas in the measurement cell, a temperature sensor 22 for detecting a temperature of the gas in the measurement cell, and an arithmetic circuit 8 for calculating a concentration of the gas based on an output P of the pressure sensor, an output T of the temperature sensor, an output I of the photodetector, and an extinction coefficient α, wherein the arithmetic circuit 8 is configured to calculate the concentration using the extinction coefficient α determined on the basis of the output of the temperature sensor 22.

公开(公告)号：US09618391B2

公开(公告)日：2017-04-11

申请号：US14634364

申请日：2015-02-27

Applicant: Spectrasensors, Inc.

Inventor： Alfred Feitisch ,  Xiang Liu ,  Hsu-Hung Huang ,  Wenhai Ji ,  Richard L. Cline

IPC: G01J3/02 ,  G01N21/3504 ,  G01N21/05 ,  G01N21/27 ,  G01J3/42 ,  G01N21/39 ,  G01N21/03

CPC classification number: G01J3/0297 ,  G01J3/42 ,  G01N21/05 ,  G01N21/274 ,  G01N21/3504 ,  G01N21/39 ,  G01N2021/0314 ,  G01N2021/399 ,  G01N2201/1211 ,  G01N2201/1218 ,  G01N2201/127

Abstract: Validation verification data quantifying an intensity of light reaching a detector of a spectrometer from a light source of the spectrometer after the light passes through a validation gas across a known path length can be collected or received. The validation gas can include an amount of an analyte compound and an undisturbed background composition that is representative of a sample gas background composition of a sample gas to be analyzed using a spectrometer. The sample gas background composition can include one or more background components. The validation verification data can be compared with stored calibration data for the spectrometer to calculate a concentration adjustment factor, and sample measurement data collected with the spectrometer can be modified using this adjustment factor to compensate for collisional broadening of a spectral peak of the analyte compound by the background components. Related methods, articles of manufacture, systems, and the like are described.

公开(公告)号：US20140067282A1

公开(公告)日：2014-03-06

申请号：US14013788

申请日：2013-08-29

Applicant: SICK AG

Inventor： Thomas BEYER ,  Julian EDLER

IPC: G01N21/25

CPC classification number: G01N21/255 ,  G01J3/28 ,  G01J3/433 ,  G01N21/274 ,  G01N21/3504 ,  G01N21/39 ,  G01N2021/399 ,  G01N2201/0691 ,  G01N2201/1211 ,  G01N2201/1215 ,  G01N2201/1218

Abstract: A method of determining a concentration of a gas in a sample and/or of the composition of a gas by means of a spectrometer includes measuring an absorption signal of the gas as a function of the wavelength. The wavelength substantially continuously runs through a wavelength range and is superimposed by a harmonic wavelength modulation, wherein the influence of the wavelength modulation on the absorption signal via the light source modulation properties and the detection properties of the spectrometer is dependent on the device properties of the respective spectrometer. The method includes converting the absorption signal into at least one first derivative signal; deriving a gas concentration measurement parameter from the first derivative signal; determining the concentration and/or composition of the gas from at least the gas concentration measurement parameter and from a calibration function compensating for influences of state variables of the gas and of the spectrometer properties.

Abstract translation: 通过光谱仪测定样品和/或气体组成中的气体的浓度的方法包括测量作为波长的函数的气体的吸收信号。 波长基本上连续地穿过波长范围并通过谐波波长调制叠加，其中波长调制对吸收信号的影响经由光源调制性质和光谱仪的检测特性取决于器件的性质 各自的光谱仪。 该方法包括将吸收信号转换成至少一个一阶导数信号; 从一阶导数信号导出气体浓度测量参数; 从至少气体浓度测量参数和补偿气体的状态变量和光谱仪性质的影响的校准函数确定气体的浓度和/或组成。

公开(公告)号：US20130250301A1

公开(公告)日：2013-09-26

申请号：US13428591

申请日：2012-03-23

Applicant: Alfred Feitisch ,  Xiang Liu ,  Hsu-Hung Huang ,  Wenhai Ji ,  Richard Cline

Inventor： Alfred Feitisch ,  Xiang Liu ,  Hsu-Hung Huang ,  Wenhai Ji ,  Richard Cline

IPC: G06F19/00 ,  G01J3/42

CPC classification number: G01J3/0297 ,  G01J3/42 ,  G01N21/05 ,  G01N21/274 ,  G01N21/3504 ,  G01N21/39 ,  G01N2021/0314 ,  G01N2021/399 ,  G01N2201/1211 ,  G01N2201/1218 ,  G01N2201/127

Abstract: Validation verification data quantifying an intensity of light reaching a detector of a spectrometer from a light source of the spectrometer after the light passes through a validation gas across a known path length can be collected or received. The validation gas can include an amount of an analyte compound and an undisturbed background composition that is representative of a sample gas background composition of a sample gas to be analyzed using a spectrometer. The sample gas background composition can include one or more background components. The validation verification data can be compared with stored calibration data for the spectrometer to calculate a concentration adjustment factor, and sample measurement data collected with the spectrometer can be modified using this adjustment factor to compensate for collisional broadening of a spectral peak of the analyte compound by the background components. Related methods, articles of manufacture, systems, and the like are described.

Abstract translation: 验证验证数据可以收集或接收在光通过已知路径长度的验证气体之后，量化从光谱仪的光源到达光谱仪的检测器的光强度。 验证气体可以包括一定量的分析物化合物和未受干扰的背景组合物，其代表使用光谱仪分析的样品气体的样品气体背景组成。 样品气体背景组合物可以包括一种或多种背景组分。 可以将验证验证数据与存储的光谱仪校准数据进行比较，以计算浓度调节因子，并且可以使用该调整因子修改用光谱仪收集的样品测量数据，以补偿分析物化合物的光谱峰的碰撞展宽 背景组件。 描述了相关方法，制品，系统等。

公开(公告)号：US20120055232A1

公开(公告)日：2012-03-08

申请号：US12876501

申请日：2010-09-07

Applicant: Walter R. Thorson

Inventor： Walter R. Thorson

IPC: G01N21/17

CPC classification number: G01N21/1702 ,  G01N2201/1211 ,  G01N2201/1214 ,  G01N2201/1218 ,  G01N2201/123

Abstract: A flexible gas sensor includes a housing with a predetermined form factor, a photoacoustic gas sensing chamber, and at least one of acoustic, temperature, relative humidity or pressure sensors in combination with processing circuitry which can emulate the characteristic gas response output of a catalytic bead pellistor-type gas sensor in response to a selected gas. The processing circuitry can include a programmable processor and a storage unit. The storage unit can be loaded with data and executable instructions to specify, at least in part, how the signals from the photoacoustic sensor are to be processed by the processing circuitry.

Abstract translation: 柔性气体传感器包括具有预定形状因数的壳体，光声气体检测室以及与处理电路组合的声学，温度，相对湿度或压力传感器中的至少一个，其可以模拟催化珠粒的特征气体响应输出 响应于所选气体的电阻型气体传感器。 处理电路可以包括可编程处理器和存储单元。 存储单元可以被加载数据和可执行指令，以至少部分地指定来自光声传感器的信号将如何由处理电路来处理。

公开(公告)号：US20110270534A1

公开(公告)日：2011-11-03

申请号：US13085346

申请日：2011-04-12

Applicant: George Burba ,  Dayle McDermitt ,  Anatoly Komissarov ,  Tyler G. Anderson ,  Liukang Xu ,  Bradley A. Riensche

Inventor： George Burba ,  Dayle McDermitt ,  Anatoly Komissarov ,  Tyler G. Anderson ,  Liukang Xu ,  Bradley A. Riensche

IPC: G06F19/00

CPC classification number: G01N21/3504 ,  G01N21/39 ,  G01N2201/1211 ,  G01N2201/1214 ,  G01N2201/1218

Abstract: Disclosed embodiments of the present invention provide means to obtain correct gas density and flux measurements using (i) gas analyzer (open-path, or closed-path gas analyzers with short intake tube, for example 1 m long, or any combination of the two); (ii) fast temperature or sensible heat flux measurement device (such as, fine-wire thermocouple, sonic anemometer, or any other device providing fast accurate gas temperature measurements); (iii) fast air water content or latent heat flux measurement device (such as, hygrometer, NDIR analyzer, any other device providing fast accurate gas water content measurements); (iv) vertical wind or sampling device (such as sonic anemometer, scintillometer, or fast solenoid valve, etc.) and (v) algorithms in accordance with the present invention to compute the corrected gas flux, compensated for T-P effects. In case when water factor in T-P effects is negligible, the fast air water content or latent heat flux measurement device (item iii in last paragraph) can be excluded.

Abstract translation: 本发明的公开的实施例提供了使用（i）气体分析仪（具有短进气管的开放路径或闭路气体分析器，例如1米长，或两者的任何组合）获得正确的气体密度和通量测量的方法 ）; （ii）快速温度或显热通量测量装置（例如细线热电偶，声波风速计或提供快速精确气体温度测量的任何其他装置）; （iii）快速空气含水量或潜热通量测量装置（如湿度计，NDIR分析仪，任何其他提供快速准确气体含水量测量的装置）; （iv）垂直风或取样装置（例如声波风速计，闪烁仪或快速电磁阀等）和（v）根据本发明的计算校正气体通量的算法，补偿T-P效应。 在T-P效应中的水分因子可忽略的情况下，可以排除快速空气含水量或潜热通量测量装置（最后一项中的项目iii）。

公开(公告)号：US5245405A

公开(公告)日：1993-09-14

申请号：US922874

申请日：1992-07-31

Applicant: John R. Mitchell ,  Joseph W. Carter ,  Donald E. Gregonis

Inventor： John R. Mitchell ,  Joseph W. Carter ,  Donald E. Gregonis

IPC: G01N21/03 ,  G01N21/05 ,  G01N21/15 ,  G01N21/39 ,  G01N21/65 ,  G01N21/85

CPC classification number: G01N21/15 ,  G01N21/65 ,  G01N2021/151 ,  G01N2021/391 ,  G01N2021/651 ,  G01N2021/8578 ,  G01N21/05 ,  G01N2201/1218

Abstract: A gas analysis cell having a pressure control system eliminates pressure variations in the gas cell regardless of changes in restriction, gas viscosity and barometric pressure. Since optical alignment through the gas cell is sensitive to gas pressure, maintaining a constant pressure in the gas cell makes the system more stable.

Abstract translation: 具有压力控制系统的气体分析单元消除了气室中的压力变化，而不管限制，气体粘度和大气压力的变化。 由于通过气室的光学对准对气体压力敏感，因此在气室中保持恒定的压力使得系统更加稳定。

公开(公告)号：US4859859A

公开(公告)日：1989-08-22

申请号：US24769

申请日：1987-03-11

Applicant: Daniel W. Knodle ,  William E. Crone

Inventor： Daniel W. Knodle ,  William E. Crone

IPC: A61B5/083 ,  A61B5/097 ,  G01J1/02 ,  G01J1/18 ,  G01N21/31 ,  G01N21/35

CPC classification number: G01J3/108 ,  A61B5/0836 ,  A61B5/097 ,  G01J3/02 ,  G01J3/0286 ,  G01N21/3504 ,  A61M16/04 ,  A61M2016/102 ,  G01J2001/182 ,  G01N2021/3166 ,  G01N2201/06186 ,  G01N2201/1218

Abstract: Gas analyzers of the non-dispersive infrared radiation type which are designed to measure the concentration of one gas in a mixture of gases containing that gas. A novel, electrically modulated, stable, thick film infrared radiation emitter is employed to emit a beam of collimated, focused energy; and two electrically biased detectors are preferably used so that a ratioed, error eliminating output signal can be supplied to the failsafe, signal processing circuitry of the analyzer. The latter, and a conventional analog-to-digital convertor, supply information to a microcomputer which: (1) turns the infrared radiation emitter on and off; (2) controls a heater which keeps the infrared radiation detectors at a constant, precise temperature; and (3) controls displays of a variety of information concerning the gas being measured and the status of the gas analyzer. The microcomputer also accepts ambient temperature, barometric pressure, and other compensation factors. Typically, a disposable airway adapter will be included in the gas analyzer to confine the mixture of gases being analyzed to a path having a transverse dimension of precise and specific length and to provide an optical path across that stream of gases between the infrared radiation emitter and the infrared radiation detectors. The emitter and detectors are incorporated in a transducer head which can be detachably fixed to the airway adapter.

公开(公告)号：US12105041B2

公开(公告)日：2024-10-01

申请号：US17974832

申请日：2022-10-27

Applicant: UIF (University Industry Foundation), Yonsei University

Inventor： Cheol Min Park ,  Jeongok Park ,  Seung Won Lee ,  Ji Hye Jang ,  Hye Jin Kim ,  Kyoung Jin Lee

IPC: G01N27/06 ,  G01N27/07 ,  G01N27/14 ,  G01N27/22

CPC classification number: G01N27/07 ,  G01N27/14 ,  G01N27/226 ,  G01N2201/1211 ,  G01N2201/1218

Abstract: A detection device includes a substrate, first electrodes formed on a first surface of the substrate, a responsive layer, and second electrodes formed on a first surface of the responsive layer, each of the second electrodes are capacitively coupled to one of the first electrodes and each second electrode is connected to a power supply to provide driving power.

公开(公告)号：US11686671B2

公开(公告)日：2023-06-27

申请号：US17288300

申请日：2019-10-18

Applicant: FUJIKIN INCORPORATED

Inventor： Masaaki Nagase ,  Hidekazu Ishii ,  Kouji Nishino ,  Nobukazu Ikeda

IPC: G01N21/31 ,  G01N21/85 ,  G01N33/00 ,  H01L21/02

CPC classification number: G01N21/31 ,  G01N21/85 ,  G01N33/0037 ,  G01N2201/1211 ,  G01N2201/1218 ,  H01L21/02274

Abstract: A concentration measurement device 100 includes a light source 22 for generating incident light to a measurement space 10A, a photodetector 24 for receiving light emitted from the measurement space, and an arithmetic control circuit 26 for calculating a concentration of a measurement fluid on the basis of an output of the photodetector, and the light source includes a first light-emitting element 22a for generating light having a first wavelength, and a second light-emitting element 22b for generating light having a second wavelength, and the concentration measurement device is configured so as to calculate the concentration using either light of the first wavelength or the second wavelength on the basis of the pressure or temperature of the measurement fluid.