Optical reflectors for spectrometer gas cells
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01N-021/00
G01J-003/28
G01N-021/35
G01J-003/42
G01N-021/03
G01N-021/09
출원번호
US-0712923
(2012-12-12)
등록번호
US-8842282
(2014-09-23)
발명자
/ 주소
Keller, Lutz
Feitisch, Alfred
Scott, Peter
Schrempel, Mathias
St. John, Nathan
출원인 / 주소
Spectrasensors, Inc.
대리인 / 주소
Mintz Levin Cohn Ferris Glovsky and Popeo, P.C.
인용정보
피인용 횟수 :
1인용 특허 :
8
초록▼
A spectrometer cell can include a spacer, at least one end cap, and at least one mirror with a reflective surface. The end cap can be positioned proximate to a first contact end of the spacer such that the end cap and spacer at least partially enclose an internal volume of the spectrometer cell. The
A spectrometer cell can include a spacer, at least one end cap, and at least one mirror with a reflective surface. The end cap can be positioned proximate to a first contact end of the spacer such that the end cap and spacer at least partially enclose an internal volume of the spectrometer cell. The mirror can be secured in place by a mechanical attachment that includes attachment materials that are chemically inert to at least one reactive gas compound. The mechanical attachment can hold an optical axis of the reflective surface in a fixed orientation relative to other components of the spectrometer cell and or a spectrometer device that comprises the spectrometer cell. The mirror can optionally be constructed of a material such as stainless steel, ceramic, or the like. Related methods, articles of manufacture, systems, and the like are described.
대표청구항▼
1. A spectrometer cell having an internal volume for containing a sample gas, the spectrometer cell comprising: a spacer, the spacer at least partially defining the internal volume and comprising a first contact end;an end cap, the end cap positioned proximate to and contacting the first contact end
1. A spectrometer cell having an internal volume for containing a sample gas, the spectrometer cell comprising: a spacer, the spacer at least partially defining the internal volume and comprising a first contact end;an end cap, the end cap positioned proximate to and contacting the first contact end and at least partially enclosing the internal volume; anda mirror, the mirror comprising a reflective surface for receiving and redirecting a beam of light at least once along an optical path length that originates from at least one light source, the reflective surface having an optical axis, the optical path length passing at least once through the internal volume, the mirror being secured in place by a mechanical attachment comprising attachment materials that are chemically inert to at least one reactive gas compound, the mechanical attachment holding the optical axis in a fixed orientation relative to other components of the spectrometer cell and of a spectrometer device that comprises the spectrometer cell. 2. A spectrometer cell as in claim 1, wherein the spacer piece and at least one of the end cap and the mirror have a similar thermal expansion coefficient. 3. A spectrometer cell as in claim 1, wherein the reflective surface is formed of a material comprising at least one of stainless steel and ceramic. 4. A spectrometer cell as in claim 1, wherein the mirror further comprises one or more additional reflective coatings on the reflective surface. 5. A spectrometer cell as in claim 1, wherein the at least one reactive gas compound comprises at least one of an acid gas compound, a basic gas compound, a fluorinated compound, and a chlorinated gas compound. 6. A spectrometer cell as in claim 1, wherein the reflective surface has a surface roughness in one or more of the following ranges: less than approximately 10 Å rms, approximately 10 Å rms to approximately 25 Å rms, approximately 25 Å rms to approximately 50 Å rms, approximately 50 Å rms to approximately 100 Å rms, approximately 100 Å rms to approximately 250 Å rms, and approximately 250 Å rms to approximately 500 Å rms. 7. A spectrometer cell as in claim 1, wherein the reflective surface comprises at least one of a planar surface, a spherical curvature, and a parabolic curvature. 8. A spectrometer cell as in claim 1, wherein the reflective surface is integral to an inner face of the end cap, the inner face being directed inward toward the internal volume, and wherein the mechanical attachment comprises a direct and stable physical contact between the end cap and the spacer secured by at least one attachment device, the direct and stable physical contact ensuring at least one of a reproducible alignment and a reproducible orientation of the optical axis relative to the beam of light when the spacer and the end cap are assembled. 9. A spectrometer cell as in claim 1, wherein the reflective surface is disposed on a detachable mirror part, the detachable mirror part being mechanically connectable to a face of the end cap, the detachable part and an inner face of the end cap having mating reference surfaces that ensure at least one of a specific alignment and a specific orientation of the optical axis relative to the beam of light when the detachable mirror part and the end cap are joined and the end cap is assembled to the spacer and a direct and stable physical contact between the end cap and the spacer is secured by at least one attachment device. 10. An spectrometer cell as in claim 1, further comprising an inner spacer disposed within the internal volume, the inner spacer having a contact end, wherein the mirror comprises a mirror piece that is not directly attached to the end cap, the mirror piece comprising a front contact surface on a same side of the mirror piece as the reflective surface and a rear contact surface opposite the front contact surface, the mirror piece being disposed proximate an inner face of the end cap such that the inner face contacts the rear contact surface and the contact end of the inner spacer contacts the front contact surface to thereby hold the mirror piece secure such that at least one of a reproducible alignment and a reproducible orientation of the optical axis relative to the beam of light are ensured when the spacer, the inner spacer, the mirror piece, and the end cap are assembled. 11. An spectrometer cell as in claim 1, further comprising an inner spacer disposed within the internal volume, the inner spacer having a contact end, wherein the mirror comprises a mirror piece that is not directly attached to the end cap, the mirror piece comprising a front contact surface on a same side of the mirror piece as the reflective surface and a rear contact surface opposite the front contact surface, the mirror piece being disposed proximate an inner face of the end cap such that the inner face contacts the rear contact surface and the contact end of the inner spacer contacts the front contact surface to thereby hold the mirror piece secure such that at least one of a reproducible alignment and a reproducible orientation of the optical axis relative to the beam of light are ensured when the spacer, the inner spacer, the mirror piece, and the end cap are assembled. 12. A spectrometer cell as in claim 1, wherein the mechanical attachment comprises a direct and stable physical contact such that the fixed orientation is reproducible when the mirror is removed from and replaced into the spectrometer cell. 13. A spectrometer cell as in claim 1, wherein the direct and stable mechanical attachment does not include a flexible adhesive. 14. A method comprising: defining, at least partially, an internal volume of a spectrometer cell with a spacer, the spacer comprising a first contact end;further enclosing the internal volume with an end cap connected to the first contact end; andreceiving and redirecting a beam of light at least once along an optical path length that originates from at least one light source, the optical path length passing at least once through the internal volume, the receiving and redirecting occurring at a mirror comprising a reflective surface, the reflective surface having an optical axis and being secured in place by a mechanical attachment comprising attachment materials that are chemically inert to at least one reactive gas compound, the mechanical attachment holding the optical axis in a fixed orientation relative to other components of the spectrometer cell and of a spectrometer device that comprises the spectrometer cell. 15. A method as in claim 14, wherein the spacer piece and at least one of the end cap and the mirror have a similar thermal expansion coefficient. 16. A method as in claim 15, wherein the at least one reactive gas compound comprises at least one of an acid gas compound, a basic gas compound, a fluorinated compound, and a chlorinated gas compound. 17. A method as in claim 14, wherein the reflective surface is formed of a material comprising at least one of stainless steel and ceramic. 18. A method as in claim 14, wherein the mirror further comprises one or more additional reflective coatings on the reflective surface. 19. A method as in claim 14, wherein the reflective surface has a surface roughness in one or more of the following ranges: less than approximately 10 Å rms, approximately 10 Å rms to approximately 25 Å rms, approximately 25 Å rms to approximately 50 Å rms, approximately 50 Å rms to approximately 100 Å rms, approximately 100 Å rms to approximately 250 Å rms, and approximately 250 Å rms to approximately 500 Å rms. 20. A method as in claim 14, wherein the reflective surface comprises at least one of a planar surface, a spherical curvature, and a parabolic curvature. 21. A method as in claim 14, wherein the reflective surface is integral to an inner face of the end cap, the inner face being directed inward toward the internal volume, and wherein the mechanical attachment comprises a direct and stable physical contact between the end cap and the spacer secured by at least one attachment device, the direct and stable physical contact ensuring at least one of a reproducible alignment and a reproducible orientation of the optical axis relative to the beam of light when the spacer and the end cap are assembled. 22. A method as in claim 14, wherein the reflective surface is disposed on a detachable mirror part, the detachable mirror part being mechanically connectable to a face of the end cap, the detachable part and an inner face of the end cap having mating reference surfaces that ensure at least one of a specific alignment and a specific orientation of the optical axis relative to the beam of light when the detachable mirror part and the end cap are joined and the end cap is assembled to the spacer and a direct and stable physical contact between the end cap and the spacer is secured by at least one attachment device. 23. A spectrometer cell having an internal volume for containing a sample gas, the spectrometer cell comprising: an end cap, comprising an inner face recessed within a spacer structure, the spacer structure and the inner face at least partially defining the internal volumea mirror, the mirror comprising a reflective surface for receiving and redirecting a beam of light at least once along an optical path length that originates from at least one light source, the reflective surface having an optical axis, the optical path length passing at least once through the internal volume, the mirror being secured in place on or proximate to the inner face by a mechanical attachment comprising attachment materials that are chemically inert to at least one reactive gas compound, the mechanical attachment holding the optical axis in a fixed orientation relative to other components of the spectrometer cell and of a spectrometer device that comprises the spectrometer cell.
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