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    • 1. 发明专利
    • Carbon monoxide gas measuring instrument and alarm
    • 一氧化碳气体测量仪器和报警
    • JP2010266356A
    • 2010-11-25
    • JP2009118494
    • 2009-05-15
    • Figaro Eng IncTokyo Gas Co LtdYazaki Corpフィガロ技研株式会社東京瓦斯株式会社矢崎総業株式会社
    • NAKAJIMA TADANOBUTAKASHIMA HIROMASANAKAWA YOSHIHARUSUZUKI TAKAYUKIINUZUKA KAZUHIROINOUE TOSHIHIROUKO TOSHIHIRO
    • G01N27/416G01N27/26G01N27/406
    • PROBLEM TO BE SOLVED: To correct the variations in the series internal resistance component of an electrochemical gas sensor. SOLUTION: When the supply of a charge current into the electrochemical gas sensor 1 from a power supply 33 is started, the resistance value of the series internal resistance component Rs in the equivalent circuit of the electrochemical gas sensor 1 is calculated, on the basis of the output voltage outputted from a current/voltage conversion circuit 40 and the resistance value of a resistor by a series internal resistance component calculating means 10a1. Then, the sensitivity data showing the sensitivity of the resistance value of the series internal resistance component Rs in the equivalent circuit with the output of the electrochemical gas sensor 1 is stored in a sensitivity data memory means 10b. Next, the sensitivity of the electrochemical gas sensor 1 is calculated, on the basis of the resistance value calculated by the series internal resistance component calculating means 10a1 and the sensitivity data stored in the sensitivity data memory means 10b by a sensitivity calculating means 10a2, and the concentration of the target gas produced in the electrochemical gas sensor 1 is corrected, on the basis of the sensitivity by a correction means 10a3. COPYRIGHT: (C)2011,JPO&INPIT
    • 要解决的问题:校正电化学气体传感器的串联内阻分量的变化。 解决方案:当开始从电源33向电化学气体传感器1供应充电电流时,计算电化学气体传感器1的等效电路中的串联内部电阻分量Rs的电阻值, 从电流/电压转换电路40输出的输出电压的基础和串联内部电阻分量计算装置10a1的电阻的电阻值。 然后,将表示电化学气体传感器1的输出的等效电路中的串联内部电阻分量Rs的电阻值的灵敏度的灵敏度数据存储在灵敏度数据存储单元10b中。 接下来,基于由串联内部电阻分量计算装置10a1计算的电阻值和由灵敏度计算装置10a2存储在灵敏度数据存储装置10b中的灵敏度数据,计算电化学气体传感器1的灵敏度, 基于校正装置10a3的灵敏度来校正在电化学气体传感器1中产生的目标气体的浓度。 版权所有(C)2011,JPO&INPIT
    • 5. 发明专利
    • MONITORING DEVICE FOR GAS COMBUSTION DEVICE
    • JP2002031338A
    • 2002-01-31
    • JP2000218945
    • 2000-07-19
    • TOKYO GAS CO LTDYAZAKI CORP
    • TANDA RYOJIMOCHIZUKI KAZUTAKASHIMA HIROMASA
    • F23N5/24F23N5/00
    • PROBLEM TO BE SOLVED: To provide a monitoring device for a gas combustion device to effectively detect abnormality of CO concentration, while battery life time is markedly increased. SOLUTION: The monitoring device for a gas combustion device comprises a detecting timing control means 11A and an abnormality cut-off control means 11B. A detection timing control means 11A causes drive of a solid electrolytic type CO sensor 10 immediately after or by a given stabilizing time following the on-timing of a gas combustion device, in response to the on-timing of the gas combustion device and control is effected, such that CO concentration is detected. Furthermore, the detection timing control means 11A effects control, such that CO concentration is detected by drive of the solid electrolytic type CO sensor 10 even when a continuous combustion time is longer than a given continuous combustion reference time after a stabilizing time. Based on the detection result for abnormality of CO concentration by the solid electrolytic type CO sensor 10, the abnormality cutoff control means 11B effects control of cutoff of the gas combustion device.
    • 6. 发明专利
    • CO GAS DETECTING DEVICE
    • JP2001296021A
    • 2001-10-26
    • JP2000110897
    • 2000-04-12
    • YAZAKI CORPTOKYO GAS CO LTD
    • TAKASHIMA HIROMASAMATSUNO MASARUKOSHIMIZU DAISUKEYAHAGI MASAHIRO
    • F23N5/24F23N5/00
    • PROBLEM TO BE SOLVED: To provide a CO gas detecting device to effect correction of a 0-point reference value right after installation of a gas apparatus with high precision by considering the influence of temperature after combustion. SOLUTION: An initial correction means 2a-6 performs initial correction of a 0-point reference value in a way that, not in a combustion state according to a start of operation of the gas apparatus and in a state that a detecting element is heated to a detecting temperature, the detecting output of a CO detector is stored as a fresh 0-point reference value at a 0-point reference value memory means instead of a 0-point reference value before the fresh 0-point reference value to execute initial correction of the 0-point reference value. A first combustion correcting means 2a-7 executes first combustion correction of the 0-point reference value such that the detecting output of the CO detector is stored as a fresh 0-point reference value instead of a 0-point reference value before the fresh 0-point reference value at the 0-point reference value memory means at a point of time when any influence is not exercised on correction of the 0-point reference value by temperature generated by combustion after completion of combustion during completion of the first time combustion of the gas apparatus after initial correction.
    • 10. 发明专利
    • DETECTING AND DRIVING METHOD FOR CARBON MONOXIDE GAS
    • JPH116816A
    • 1999-01-12
    • JP16152397
    • 1997-06-18
    • TOKYO GAS CO LTDYAZAKI CORP
    • KONO TAKASHITANDA RIYOUJIMOCHIZUKI KAZUTAKASHIMA HIROMASA
    • G01N27/416
    • PROBLEM TO BE SOLVED: To obtain a detecting and driving method in which carbon monoxide gas can be detected with high accuracy irrespective of its concentration by a method wherein the temperature of a sensor is set to be low in a measurement for a low-concentration region and to be high in a measurement for a high-concentration region. SOLUTION: The temperature of a sensor is set at a temperature (usually about 300 deg.C) at which an ionic conductivity is generated in stabilized zirconia. When it is set at about 800 deg.C or higher, the stabilized zirconia is damaged, and the life of the sensor becomes short. As a result, the sensor is usually used at about 500 deg.C or lower. The temperature of the sensor is set at least at two stages, i.e., a high-temperature stage and a low-temperature stage. For example, about 400 to 500 deg.C is used as the high-temperature stage, and about 300 to 400 deg.C is used as the lower-temperature stage. Then, carbon monoxide gas in a low- concentration region is measured at the low-temperature stage, and the carbon monoxide gas in a high-concentration region is measured at the high-temperature stage. The interval of a temperature changeover is set at a time or higher in which the output of the sensor is stabilized, and it is usually set at about 5 to 10 seconds. When an especially quick changeover is required, an estimation logic means or the like is installed. By this method, the carbon monoxide gas can be measured with good accuracy even in a concentration of 500 ppm or higher.