Fiber optics condition sensor and method of making same

US 4,588,886 A
Filed: 11/14/1983
Issued: 05/13/1986
Est. Priority Date: 11/14/1983
Status: Expired due to Fees

First Claim

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1. A method of producing fiber optics condition sensors operable to sense changes in condition through a predetermined range of conditions comprising providing fiber optics transmitters adapted to connect a light source and a light detector in which said transmitters provide a planar termination at an end remote from said transmitter and detector, determining the range of distance through which a substantially planar reflective surface moves toward and away from said termination to produce minimum and maximum values of reflected light transmitted through said fiber optics transmitter from said source to said detector, forming metal diaphragms with a precurvature so that a substantially planar center portion thereof moves between two predetermined positions through substantially said entire range of distance in response to said predetermined range of conditions, mounting said terminations on body assemblies, mounting the peripheries of a diaphragm on one of said body assemblies and positioning said termination and periphery so that said center portion in one of said predetermined positions is positioned substantially against said termination and when in the other of said predetermined positions is substantially spaced therefrom so that the value of light reflected to said detector varies from substantially said minimum value to substantially said maximum value when said diaphragm is exposed to said predetermined range of conditions.

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Abstract

A fiber optics condition sensor and a method of producing such a device is disclosed. A bundle of optical fibers provides a planar termination on one end and is bifurcated to provide one group adapted to be connected to a light source and another group adapted to be connected to a detector. A shallow, curved, thin metallic diaphragm provides a central portion movable toward and away from the termination in response to the condition being sensed in order to vary the light reflected to the detector and therefore produce a detector output signal which is a function of the changes in conditions being sensed. The diaphragm may be formed of bimetal for sensing temperature conditions, or of a homogeneous metal to sense pressure. The curvature formed in the diaphragm is selected to provide movement of the central portion of the diaphragm through a distance selected to match the reflective light intensity versus spacing curve so that the system provides substantially the maximum response over a predetermined range of conditions being sensed. Variations in the curvature of the diaphragm are compensated for in the mounting of the diaphragm with respect to the fiber optics termination so as to ensure maximum response in the total system.

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17 Claims

1. A method of producing fiber optics condition sensors operable to sense changes in condition through a predetermined range of conditions comprising providing fiber optics transmitters adapted to connect a light source and a light detector in which said transmitters provide a planar termination at an end remote from said transmitter and detector, determining the range of distance through which a substantially planar reflective surface moves toward and away from said termination to produce minimum and maximum values of reflected light transmitted through said fiber optics transmitter from said source to said detector, forming metal diaphragms with a precurvature so that a substantially planar center portion thereof moves between two predetermined positions through substantially said entire range of distance in response to said predetermined range of conditions, mounting said terminations on body assemblies, mounting the peripheries of a diaphragm on one of said body assemblies and positioning said termination and periphery so that said center portion in one of said predetermined positions is positioned substantially against said termination and when in the other of said predetermined positions is substantially spaced therefrom so that the value of light reflected to said detector varies from substantially said minimum value to substantially said maximum value when said diaphragm is exposed to said predetermined range of conditions.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. A method as set forth in claim 1, including selecting the relative position of said mounting of said terminations and said periphery of said diaphragms to compensate for differences in curvatures preformed in said diaphragms.
  - 3. A method as set forth in claim 2, including providing said body assemblies with a body member having two locating surfaces, one of said locating surfaces operating to locate said termination and the other of said locating surfaces operating to locate said periphery of said diaphragm, and compensating for the difference in curvature of said diaphragms selecting the spacing of said locating surfaces.
  - 4. A method as set forth in claim 2, including forming said body assemblies with first and second telescoping body members, mounting one of said terminations on a said first body member, mounting said periphery on one of said diaphragms on a said second body member;
    - and while said transmitter is connected to a standard light source and to a standard light detector and said diaphragm is maintained at a standard sensed condition telescoping said members together until a calibrated position is reached when said detector establishes that a predetermined light intensity is reflected through said transmitter, and locking body members in said calibrated position.
  - 5. A method as set forth in claim 1, including forming said diaphragms with precurvature to cause said central portion to move with snap action in response to predetermined conditions, and positioning said diaphragms so that the center portion thereof is spaced from said termination when it snaps toward said termination to prevent impacting of said center portion against said termination.
  - 6. A method as set forth in claim 1, wherein said sensors are operable to sense temperature and said diaphragms are formed of bimetal.
  - 7. A method as set forth in claim 1, wherein said sensors are operable to sense pressure and said diaphragms are formed of a homogeneous metal.
  - 8. A method as set forth in claim 1 wherein said transmitters includes a first group of optical fibers adapted to be connected to said light source and a second group of optical fibers adapted to be connected to said light detector, said groups being joined in a single bundle providing said planar termination.

9. A method of producing fiber optics condition sensors comprising forming optical fiber transmitters extending to a single planar termination, forming metallic diaphragms with unstressed curvatures selected to cause a substantially planar center portion thereof to move through a predetermined range of movements in response to a predetermined range of sensed conditions, providing a reflective surface on said central portion, and mounting said diaphragm and said optical fiber transmitter on a body assembly with the periphery of said diaphragm in a fixed position relative to said termination in which said reflective surface moves toward and away from said termination and responds to sensed conditions, and compensating for differences in curvature formed in said diaphragms by establishing said fixed position of said periphery of said diaphragm relative to said termination so that said reflective surface is spaced a predetermined distance from said termination under a standard value of said sensed conditions.

10. A method of producing fiber optics condition sensors for sensing a range of conditions comprising providing fiber optics transmitters having a planar termination having a reflective value curve and which are adapted to be connected to a remote light source and a remote light detector, determining the spacing of a reflective surface versus reflection value curve of said termination to establish a range of spacing between said termination and a reflective surface which produces substantially zero reflection between said source and detector and a maximum value of reflection between said source and detector, forming reflective metallic diaphragms with a curvature so that a substantially planar center portion thereof moves through a distance substantially equal to said range of spacing in response to said range of conditions to be sensed, and mounting the periphery of said diaphragms in a fixed position relative to said termination determined by the amount of curvature of said diaphragms so that said center portion of said diaphragms moves through substantially said range of spacing in response to said range of conditions to be sensed.

11. A method of producing fiber optics condition sensors comprising providing an optical fiber transmitter terminating at a termination, connecting said optical fiber transmitter to a standard light source and to a standard light detector, forming a diaphragm with a shallow curvature to provide it with a central substantially planar reflective portion providing the desired response to the conditions being sensed, forming first and second body members so that they can be telescoped together, mounting said termination on said first body member, mounting said diaphragm at its periphery on said second body member, telescoping said body members together to move said reflective portion towards said termination to a position in which said detector indicates a predetermined value of reflective light, and locking said members in said position.
- View Dependent Claims (12)
- - 12. A method as set forth in claim 11, wherein said body members are provided with a press fit to temporarily maintain them in said position until said members are locked in said position.

13. A fiber optics condition sensor comprising a body assembly, an optical fiber transmitter mounted on said body assembly providing a termination located at a predetermined location, said transmitter being adapted to be connected at a location remote from said termination to a light source and to a light detector and operable to transmit light between said termination and said source and detector, a metallic diaphragm mounted on said body assembly, said diaphragm being performed with a curvature providing a substantially planar central portion movable in response to a sensed condition toward and away from said termination, said central portion providing a reflective surface adjacent to said termination operable to reflect light from said source to said detector, said bundle and reflective surface providing a reflective range from a maximum possible reflective value to a minimum possible reflective value as a function of the changing of the spacing between said reflective surface and said termination through a first predetermined range of movement, the relationship between the movement of said reflective surface and the changes of the conditions sensed being an S-curve with substantially greater slope within a second predetermined range of movement than provided by a similar flat diaphragm formed of the same metal, said shallow curvature causing said reflective surface to move through said second predetermined range of movement in response to a predetermined range of sensed conditions, said first and second predetermined ranges of movement being substantially equal, said mounting of said fiber optics bundle and mounting of said diaphragm being selected to cause the light reflected to said termination by said reflective surface to vary through a substantial portion of said reflective range in response to movement of said reflective surface through said second predetermined range of movement.
- View Dependent Claims (14, 15, 16, 17)
- - 14. A condition sensor as set forth in claim 13, wherein said diaphragm moves through said second predetermined range of movement with snap action, said diaphragm being positioned with respect to said termination so that it moves to a position substantially adjacent to but spaced from said termination as it snaps toward said termination to prevent impacting of said termination by said diaphragm.
  - 15. A condition sensor as set forth in claim 13, wherein said diaphragm moves with non-snapping movement through said second predetermined range of movement and at a rate which is a substantially linear function with respect to the change of conditions sensed by said diaphragm.
  - 16. A condition sensor as set forth in claim 13, wherein said diaphragm is formed of bimetal and the condition being sensed is temperature.
  - 17. A condition sensor as set forth in claim 13, wherein said diaphragm is formed of a homogeneous metal and the condition being sensed is pressure.

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Current Assignee
Therm-O-Disc Incorporated (Emerson Electric Company)
Original Assignee
Therm-O-Disc Incorporated (Emerson Electric Company)
Inventors
Snider, Harold F.
Primary Examiner(s)
Nelms, David C.

Application Number

US06/550,817
Time in Patent Office

911 Days
Field of Search

250/231 R, 250/231 P, 250/221, 250/227, 250/229, 73/705, 73/715, 73/717, 73/723, 374/19, 374/143, 374/161, 374/205
US Class Current

250/227.21
CPC Class Codes

G01D 5/268   using optical fibres G01D5/...

G01K 5/70   specially adapted for indic...

G01L 9/0077   for measuring reflected light

Fiber optics condition sensor and method of making same

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

35 Citations

17 Claims

Specification

Solutions

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Fiber optics condition sensor and method of making same

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

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Abstract

35 Citations

17 Claims

Specification

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Solutions

Use Cases

Quick Links