Temperature compensated electrochemical gas sensor and method for closely tracking the temperature variations of a gas to be sensed
First Claim
1. An electrochemical gas sensor for sensing the concentration of an electochemically active gas, such as oxygen, in a gas mixture to be analyzed and providing sensor electrical output signals representative of the sensed concentrations, said gas sensor comprisingan insulative sensor container having an open end and adapted for storing a liquid electrolyte in the container,means for defining a gas sensing cathode electrode supported within the container adjacent said open end of the insulative sensor container,a gas permeable, liquid impermeable membrane secured to said open end of said container in intimate contact with the cathode electrode and having a preselected thin thickness for limiting the diffusion of the gases to be sensed and to be conveyed to said cathode,an expansion membrane mounted within said sensor container and being spaced a preselected distance from said open end and for storing an electrolyte in the volume between said gas permeable membrane and the expansion membrane,a liquid electrolyte stored in the volume between said gas permeable membrane and the expansion membrane,means for defining an anode electrode mounted in the electrolyte adjacent the expansion membrane, the improvement comprising thermistor means mounted on the expansion membrane in a substantially thermal isolated relationship with respect to the temperature of the gases to be sensed that are conveyed to said gas permeable membrane so that any change in the temperature of the gas to be sensed is not directly conveyed to the thermistor means except by means of the temperature changes imparted to the electrolyte whereby the sensor and the thermistor means both experience any change in temperature of the gas to be sensed at substantially the same time whereby said thermistor provides electrical output signals in response to the sensed temperature changes without any substantial time delays between the temperature changes and the thermistor electrical output signals useful for temperature compensation of said sensor electrical output signals.
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Accused Products
Abstract
An electrochemical gas sensor having a temperature sensitive element such as a thermistor arranged within the gas sensor in a temperature insulative fashion for preventing any variations in the temperature of the applied gases to be sensed to be immediately conveyed to the temperature sensitive element thereby providing accurate temperature compensation signals to be combined with the generated sensor electrical output signals. The temperature sensitive element or thermistor is mounted in a heat sink to the expansion membrane of the gas sensor to be responsive only to changes in the temperature variations imparted by the sensor electrolyte and not by the variations in the temperature of the gas sensor body and associated elements thereby providing correct temperature compensation signals without error producing time delays.
16 Citations
8 Claims
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1. An electrochemical gas sensor for sensing the concentration of an electochemically active gas, such as oxygen, in a gas mixture to be analyzed and providing sensor electrical output signals representative of the sensed concentrations, said gas sensor comprising
an insulative sensor container having an open end and adapted for storing a liquid electrolyte in the container, means for defining a gas sensing cathode electrode supported within the container adjacent said open end of the insulative sensor container, a gas permeable, liquid impermeable membrane secured to said open end of said container in intimate contact with the cathode electrode and having a preselected thin thickness for limiting the diffusion of the gases to be sensed and to be conveyed to said cathode, an expansion membrane mounted within said sensor container and being spaced a preselected distance from said open end and for storing an electrolyte in the volume between said gas permeable membrane and the expansion membrane, a liquid electrolyte stored in the volume between said gas permeable membrane and the expansion membrane, means for defining an anode electrode mounted in the electrolyte adjacent the expansion membrane, the improvement comprising thermistor means mounted on the expansion membrane in a substantially thermal isolated relationship with respect to the temperature of the gases to be sensed that are conveyed to said gas permeable membrane so that any change in the temperature of the gas to be sensed is not directly conveyed to the thermistor means except by means of the temperature changes imparted to the electrolyte whereby the sensor and the thermistor means both experience any change in temperature of the gas to be sensed at substantially the same time whereby said thermistor provides electrical output signals in response to the sensed temperature changes without any substantial time delays between the temperature changes and the thermistor electrical output signals useful for temperature compensation of said sensor electrical output signals.
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6. A method of compensating an electrochemical gas sensor for sensing the concentration of an electrochemically active gas in a gas mixture applied to the sensor for temperature changes in said gas mixture, the gas sensor providing electrical output signals representative of the sensed electrochemically active gas that vary with the temperature variations of the applied gas mixture, the method includes the steps of providing an electrochemical gas sensor having an insulative container having a gas sensing cathode electrode and an anode electrode mounted in the container with an electrolyte, said container having an open end adjacent the cathode electrode for applying the gas mixture to the cathode electrode and an expansion membrane mounted to said container in a preselected spaced relationship with said open end of the container and containing the electrolyte,
mounting thermistor means on the expansion membrane to be responsive to temperature changes of said applied gas mixture imparted to the electrolyte, securing the thermistor means to the expansion membrane with heat sink means so as to substantially prevent any temperature changes of said applied gas mixture from being directly transmitted to the thermistor means so that said gas sensor and the thermistor means both respond to any temperature changes at substantially the same time, mounting thermal insulative means on the opposite side of the thermistor means from the side secured to the expansion membrane, the thermistor means including insulated lead wires extending therefrom for deriving temperature compensating electrical signals from said gas sensor, and arranging said leads with said thermal insulative means so as to be contained within said insulative means to prevent temperature changes of said applied gas mixture to be conducted to said thermistor means and permitting said leads to be accessible ouside of the gas sensor.
Specification