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Title: Humidity sensing element and method of manufacture thereof
Claims: I claim: 1. A humidity sensing element for gaseous fluids comprising a first electron conductive electrode, a porous coating of dielectric suitable for hydrolization formed on and from said first electrode, atoms of electron conductive material randomly deposited and adhered in generally non-short-circuiting mutual relation in the interstices of the porosity of said dielectric as formed, ion-forming material formed from at least partial conversion of said coating to said ion-forming material by hydrolization of said coating, said dielectric being in a hydrolized state and a second electron conductive electrode pervious to moisture vapor and disposed on said hydrolized dielectric coating on the opposite side thereof from said first electrode, said ion-forming material commonly contacting said dielectric, said atoms, and said second electrode. 2. A humidity element for gaseous fluids according to claim 1 and characterized further in that said first electrode is formed from commercially pure anodizable metal. 3. A humidity element for gaseous fluids according to claim 2 and characterized further in that said anodizable metal is aluminum. 4. A humidity element for gaseous fluids according to claim 3 and characterized further in that said first electrode had an initial surface finish roughness approximating 8 micro inches root mean square in the area to be beneath said second electrode. 5. A humidity element for gaseous fluids according to claim 1 in which said first electrode is formed from commercially pure anodizable metal and characterized further in that said coating of dielectric comprises an anodized layer. 6. A humidity element for gaseous fluids according to claim 5 and characterized further in that said anodized layer is oxalic acid anodized. 7. A humidity element for gaseous fluids according to claim 6 and characterized further in that said anodized layer has a thickness in the approximate range of 0.02 to 0.08 millimeters. 8. A humidity element for gaseous fluids according to claim 1 and characterized further in that said first electrode is formed from commercially pure anodizable metal, said coating is an anodized layer, and said atoms are composed of nickel. 9. A humidity element for gaseous fluids according to claim 8 and characterized further in that the quantity of said atoms is equivalent to an amount calculated to deposit on a smooth non-porous surface a layer of thickness between 5 and 10 Angstrom units. 10. A humidity element for gaseous fluids according to claim 1 and characterized further in that said first electrode is formed from commercially pure anodizable metal, said coating is an anodized layer, and said atoms are metal. 11. A humidity element for gaseous fluids according to claim 1 and characterized further in that said first electrode is formed from commercially pure anodizable metal, said dielectric is formed by an anodized layer, said atoms are metal, and the impedance between said electrodes comprises a capacitance-resistance combination. 12. A humidity element for gaseous fluids according to claim 11 and characterized further by suitability for excitation for sensing by an alternating current sine wave voltage in the order of ten Hertz, for providing substantial linearity of the relation of said impedance to the relative humidity of said gaseous fluids. 13. A humidity element for gaseous fluids according to claim 1 and characterized further in that said first electrode is formed from commercially pure anodizable metal, said dielectric is formed by an anodized layer, said atoms are nickel, and said second electrode comprises metal disposed by vacuum deposition from a plate hot filament. 14. A humidity element for gaseous fluids according to claim 13 and characterized further in that said second electrode metal deposit is composed of a quantity of nickel equivalent to an amount calculated to deposit a layer of thickness approximating 100 Angstrom units on a smooth non-porous surface. 15. A humidity element for gaseous fluids according to claim 13 and characterized further by an insulating and cushioning element adhered to said sensing element, a coating of electrically conductive material covering a portion of said second electrode and covering a portion of said insulating and cushioning element not adhered to said second electrode to provide for pressure contact electrical connection to said conductive coating material and thereby to said second electrode without shorting said second electrode to said first electrode upon inadvertent crushing of said dielectric between said electrodes. 16. A humidity sensing element for gaseous fluids in the form of a doped capacitance-resistance member comprising a first electrode of commercially pure anodizable metal, a porous dielectric layer of an oxalic acid anodized coating formed on said electrode, atoms of metal randomly deposited and adhered in generally non-short-circuiting mutual relation within the interstices of said anodized coating as formed, said anodized coating hydrolized and sealed to contact said atoms with ion-forming material while retaining but decreasing the porosity of said coating, and a second electrode formed by a moisture-vapor-pervious electron-conductive deposit of metal on said sealed anodized coating on the opposite side thereof from said first electrode, said capacitance-resistance member having an impedance between said electrodes varying inversely and generally proportionally to the relative humidity of the surrounding gaseous atmosphere in a suitable range of interest when excited by a suitable alternating current voltage. 17. A method of manufacturing a humidity sensing element for gaseous fluids comprising the steps of coating at least a portion of a first electron-conductive electrode with a porous coating of hydrolizable dielectric formed therefrom, depositing and adhering atoms of electron-conductive material randomly in generally non-short-circuiting mutual relation in the interstices of the porosity of said dielectric as formed, commonly contacting said dielectric and said atoms in said interstices with ion-forming material by at least partial conversion of said dielectric thereto by hydrolization thereof, and forming a second electron-conductive electrode contacting said ion-forming material and being pervious to moisture vapor and disposed on said hydrolized dielectric coating on the opposite side thereof from said first electrode. 18. A method of manufacturing a humidity element for gaseous fluids according to claim 17 and characterized further in that said first electrode is of commercially pure aluminum and said step of coating comprises anodizing said aluminum to form said dielectric coating thereon, said step of depositing comprises vacuum deposition of atoms of nickel from a hot filament into said interstices in a quantity equivalent to an amount calculated to deposit a layer of thickness between 5 and 10 Angstrom units on a smooth non-porous surface, and said step of forming said second electrode comprises vacuum depositing nickel onto said hydrolized dielectric coating to form said second electrode. 19. A method of manufacturing a humidity element for gasous fluids according to claim 18 and characterized further in that said anodizing comprises oxalic acid anodizing said aluminum to a thickness of about 0.02 to 0.08 millimeters, and said second electrode depositing comprises depositing nickel in a quantity equivalent to an amount calculated to deposit a layer of thickness of about 100 Angstrom units on a smooth non-porous surface. Other info: Inventors: Gallant, Donald A. (Charlotte, NC, US) Application Number: 828895 Filing Date: 1977-08-29 Publication_date: 1979-05-22 Assignee: Longwood Machine Works, Inc. (Woodside, NY) Primary Class(es): 361/286 29/25.42, 73/335.04, 205/201, 205/203, 205/917, 361/312, 361/322 Other Classes: US Patent Ref:
Other Refs:
Primary Examiner: Goldberg, E. A. Assistant Examiner: Attorney: Richards, Shefte & Pinckney |
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