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A highly accurate, long life, low cost gas sensor is disclosed, particularly useful for measuring carbon monoxide and other toxic gases in an environment. The gas sensor has a first, sensing electrode and a second, counting electrode. Positioned between the first and second electrodes is an ion cond

A highly accurate, long life, low cost gas sensor is disclosed, particularly useful for measuring carbon monoxide and other toxic gases in an environment. The gas sensor has a first, sensing electrode and a second, counting electrode. Positioned between the first and second electrodes is an ion conducting, solid electrolyte membrane. In response to the presence of a toxic gas introduced to the first electrode, an electric signal is produced between the first electrode and the second electrode. The electric signal changes in response to changes in the concentration of the toxic gas. Detection circuitry measures the electric signal to determine the concentration of the toxic gas. An electrically conductive, hydrophobic top membrane electrically connects the first electrode to the detection circuitry while preventing liquid water from contacting the first electrode. An electrically conductive, hydrophobic bottom membrane electrically connects the second electrode to the detection circuitry. The top and bottom membranes, though hydrophobic, are preferably also microporous so as to be gas permeable, including permeable to water vapor. Preferably the top and bottom membranes are ion insulating as well. Optionally the sensor is provided with a water reservoir to maintain constant relative humidity at the ion conducting electrolyte membrane. The sensor may also have a heating element. Internal and external self-diagnostic features to ensure that the sensor is functioning normally are disclosed, as well as self-calibration features, so as to ensure sensor accuracy.

대표청구항 ▼

1. A gas sensor comprising, in combination:a first electrode and a second electrode; an ion conducting, solid electrolyte membrane positioned between the first electrode and the second electrode, wherein an electric signal is produced between the first electrode and the second electrode in response

1. A gas sensor comprising, in combination:a first electrode and a second electrode; an ion conducting, solid electrolyte membrane positioned between the first electrode and the second electrode, wherein an electric signal is produced between the first electrode and the second electrode in response to the presence of a gas at the first electrode; means for measurement of the electric signal; and a top membrane comprising an electrically conductive, hydrophobic, gas permeable material electrically connecting the first electrode with the means for measurement of the electric signal, wherein the gas reaches the first electrode by diffusing through the electrically conductive, hydrophobic, gas permeable material. 2. The gas sensor of claim 1 wherein the top membrane is in direct contact with the first electrode.3. The gas sensor of claim 1 wherein the solid electrolyte membrane substantially comprises a solid, perfluorinated polymer.4. The gas sensor of claim 1 wherein the first electrode comprises both an electrically conducting material and an ion conducting material.5. The gas sensor of claim 4 wherein the electrically conducting material of the first electrode comprises platinum and carbon.6. The gas sensor of claim 1 wherein the second electrode comprises both an electronic conducting material and an ion conducting material.7. The gas sensor of claim 6 wherein the second electrode comprises platinum and carbon.8. The gas sensor of claim 1 wherein the means for measurement of the electric signal comprises:an analog to digital converter coupled to at least one electrode for converting the electric signal into a corresponding digital value; and a programmed processor for receiving the corresponding digital value and generating an output which indicates a concentration level of the gas. 9. The gas sensor of claim 8 further comprising an alarm electrically connected to the output of the programmed processor, for indicating that the sensor senses a concentration of the gas greater than or equal to 100 parts per million.10. The gas sensor of claim 8 further comprising a display connected to the output of the programmed processor, for indicating the concentration of the gas.11. The gas sensor of claim 1, wherein in the presence of the gas at the first electrode, an oxidation reaction occurs at the first electrode and a reduction reaction occurs at the second electrode.12. The gas sensor of claim 1 wherein the first electrode, second electrode and ion conducting, solid electrolyte membrane are formed as a single unit with the first electrode and the second electrode positioned on opposite sides of the solid electrolyte membrane.13. The gas sensor of claim 1 further comprising a top washer which cooperates with the top membrane to maintain electrical connection through the sensor.14. The gas sensor of claim 13 wherein the top washer has a sampling hole for allowing gas from the environment to reach the top membrane.15. The gas sensor of claim 13 further comprising a housing and a seal electrically insulating the housing from the top washer.16. The gas sensor of claim 15 wherein the seal comprises an elastomeric material free of chlorine and sulfur.17. The gas sensor of claim 1 further comprising a metal screen positioned proximate the top membrane, wherein gas from the environment diffuses through the metal screen before reaching the top membrane.18. The gas sensor of claim 1 further comprising an electrically conductive, hydrophobic bottom membrane positioned in contact with the second electrode and electrically connected to the second electrode, wherein the top membrane, the first electrode, the ion conducting, solid electrolyte membrane, the second electrode and the bottom membrane form a sensing assembly.19. The gas sensor of claim 18 wherein the sensing assembly is positioned between a top washer and a bottom washer.20. The gas sensor of claim 19 wherein the sensing assembly is assembled under pressure between the top washer and the bottom washer.21. The gas sensor of claim 19 wherein the top washer and the bottom washer are electrically conductive, and are in electrical connection with the sensing assembly.22. The gas sensor of claim 19 further comprising a liquid reservoir positioned on a bottom side of the bottom washer and the sensing assembly is positioned on a top side of the bottom washer opposite the liquid reservoir, and the bottom washer has at least one vapor through-hole, permitting vapor evaporating from the liquid reservoir to reach the sensing assembly.23. The gas sensor of claim 19 further comprising a housing and an electrically insulating seal, wherein the seal is positioned between the housing and the top washer.24. The gas sensor of claim 19 wherein the first electrode is physically separated from the top washer.25. The gas sensor of claim 19 wherein the second electrode is physically separated from the bottom washer.26. The gas sensor of claim 19 wherein the bottom membrane is microporous, permitting water vapor to pass.27. The gas sensor of claim 19 wherein the bottom membrane is ion insulating.28. The gas sensor of claim 1 wherein the gas is carbon monoxide.29. A gas sensor comprising, in combination:a first electrode and a second electrode; an ion conducting, solid electrolyte membrane positioned between the first electrode and second electrode, wherein an electric signal is produced between the first electrode and the second electrode in response to the presence of a gas at the first electrode; means for measurement of the electric signal between the first electrode and the second electrode; and a bottom membrane, comprising a material that is electrically conductive, hydrophobic, and permeable to water vapor, electrically connecting the means for measurement of the electrical signal with the second electrode; wherein the bottom membrane separates the second electrode from a reservoir of an aqueous liquid, the reservoir providing a water vapor source for maintaining constant relative humidity at the ion conducting, solid electrolyte membrane. 30. The gas sensor of claim 29 further comprising a housing containing the reservoir of the aqueous liquid.31. The gas sensor of claim 29 wherein the bottom membrane is in direct contact with the second electrode.32. The gas sensor of claim 29 wherein the first electrode and the second electrode each comprise both an electron conducting material and an ion conducting material.33. The gas sensor of claim 29 wherein in responed to the presence of the gas, protons are conducted across the ion conducting, solid electrolyte membrane.34. A gas sensor comprising, in combination:a first electrode and a second electrode, wherein ions are generated at the first electrode in response to the presence of a gas; a solid electrolyte membrane in electrical communication with the first electrode and the second electrode, conducting ions generated at the first electrode to the second electrode, wherein an electric signal is produced between the first electrode and the second electrode in response to the presence of the gas; means for measurement of the electric signal between the first electrode and to the second electrode; and a bottom membrane, comprising a material that is electrically conductive, hydrophobic, permeable to water vapor, and ion insulating, electrically connecting the means for measurement of the electrical signal with the second electrode; wherein the bottom membrane separates the second electrode from a reservoir of an aqueous liquid, the reservoir providing a water vapor source for maintaining constant relative humidity at the ion conducting, solid electrolyte membrane. 35. The gas sensor of claim 34 wherein the solid electrolyte membrane is sandwiched between the first electrode and the second electrode, further comprising:an electrically conductive top membrane which cooperates with the bottom membrane to sandwich the first electrode and the second electrode; and a top washer and a bottom washer, the top washer cooperating with the bottom washer to sandwich the top membrane and the bottom membrane. 36. The gas sensor of claim 34 further comprising a bottom washer having at least one vapor through hole, positioned between the water reservoir and the bottom membrane, wherein the bottom membrane is positioned over the vapor through hole and prevents water in the liquid phase from the water reservoir from contacting the second electrode.37. The gas sensor of claim 36 wherein the bottom membrane is microporous, permitting water vapor from the water reservoir to reach the second electrode.