Fiberoptic sensing of temperature and/or other physical parameters
First Claim
1. A system for simultaneously measuring temperature and another physical parameter, comprising:
- a length of optical fiber transmission medium,means including a source of visible or near visible electromagnetic radiation pulses positioned at one end of said optical fiber medium for directing said radiation along said medium to another end thereof,a sensor positioned at said another end of said optical fiber medium in a manner to receive said source radiation, modulate it by the physical parameter and temperature being measured, and redirect the modulated radiation through the optical fiber medium to said one end thereof, said sensor comprising;
a vibrating element in the path of said source radiation that is characterized by vibrating with either a frequency or an amplitude that is proportional to the magnitude of the physical parameter being measured, anda quantity of luminescent material also in the path of said source radiation, said luminescent material characterized by emitting, when excited, electromagnetic radiation having an intensity that decays, after termination of an excitation pulse from said excitation source, at a rate that is proportional to the temperature of the sensor, said source radiation being characterized by directing periodic pulses of radiation along said optical fiber medium, thereby exciting the luminescent material to emit a decaying electromagnetic radiation signal after each pulse as said modulated radiation, andmeans positioned at said one end of said optical fiber medium and receiving said modulated radiation for (1) measuring a function related to the time of the resulting luminescent radiation intensity decay after an excitation pulse, thereby to obtain an indication of the temperature of the sensor, and (2) measuring an intensity level of the decaying luminescent radiation intensity at an instant fixed with respect to an excitation pulse thereby to obtain an indication of the magnitude of the desired physical parameter.
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Accused Products
Abstract
Several specific types of optical sensors capable of measuring temperature, pressure, force, acceleration, radiation and electrical fields, fluid level, vapor pressure, and the like, are disclosed, along with an electro-optical system for detecting the optical signal developed by the sensor. One such probe utilizes a convex shaped structure consisting of an elastomeric material attached to an end of an optical fiber, the elastomeric material being coated with a luminescent material, a combination that is capable of measuring both temperature and pressure. Such a probe is also specifically adapted for measuring surface temperature by making a good physical contact with the surface being measured. Another such probe utilizes a similar structure but of a non-elastomeric material for the purpose of detecting both temperature and either index of refraction of vapor pressure changes. Improvements in other existing sensors of a wide variety of physical parameters other than temperature are also described wherein temperature is simultaneously measured for correcting such physical parameter measurements that are affected by temperature variations.
173 Citations
24 Claims
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1. A system for simultaneously measuring temperature and another physical parameter, comprising:
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a length of optical fiber transmission medium, means including a source of visible or near visible electromagnetic radiation pulses positioned at one end of said optical fiber medium for directing said radiation along said medium to another end thereof, a sensor positioned at said another end of said optical fiber medium in a manner to receive said source radiation, modulate it by the physical parameter and temperature being measured, and redirect the modulated radiation through the optical fiber medium to said one end thereof, said sensor comprising; a vibrating element in the path of said source radiation that is characterized by vibrating with either a frequency or an amplitude that is proportional to the magnitude of the physical parameter being measured, and a quantity of luminescent material also in the path of said source radiation, said luminescent material characterized by emitting, when excited, electromagnetic radiation having an intensity that decays, after termination of an excitation pulse from said excitation source, at a rate that is proportional to the temperature of the sensor, said source radiation being characterized by directing periodic pulses of radiation along said optical fiber medium, thereby exciting the luminescent material to emit a decaying electromagnetic radiation signal after each pulse as said modulated radiation, and means positioned at said one end of said optical fiber medium and receiving said modulated radiation for (1) measuring a function related to the time of the resulting luminescent radiation intensity decay after an excitation pulse, thereby to obtain an indication of the temperature of the sensor, and (2) measuring an intensity level of the decaying luminescent radiation intensity at an instant fixed with respect to an excitation pulse thereby to obtain an indication of the magnitude of the desired physical parameter. - View Dependent Claims (2, 3)
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4. A system for simultaneously measuring temperature and another physical parameter, comprising:
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a length of optical fiber transmission medium, means including a source of visible or near visible electromagnetic radiation pulses positioned at one end of said optical fiber medium for directing said radiation along said medium to another end thereof, a sensor positioned at said another end of said optical fiber medium in a manner to receive said source radiation, modulate it by the physical parameter and temperature being measured, and redirect the modulated radiation through the optical fiber medium to said one end thereof, said sensor comprising; at least one optical element in the path of said source radiation whose optical properties vary in response to the magnitude of said physical parameter, and a quantity of luminescent material also in the path of said source radiation, said luminescent material characterized by emitting, when excited, electromagnetic radiation having an intensity that decays, after termination of an excitation pulse from said excitation source, at a rate that is proportional to the temperature of the sensor, said source radation being characterized by directing periodic pulses of radiation along said optical fiber medium, thereby exciting the luminescent material to emit a decaying electromagnetic radiation signal after each pulse as said modulated radiation, and means positioned at said one end of said optical fiber medium and receiving said modulated radiation for (1) measuring a function related to the time of the resulting luminescent radiation intensity decay after an excitation pulse, thereby to obtain an indication of the temperature of the sensor, and (2) measuring an intensity level of the decaying luminescent radiation intensity, at an instant fixed with respect to an excitation pulse thereby to obtain an indication of the magnitude of the desired physical parameter. - View Dependent Claims (5, 6, 7, 8)
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9. An optical sensor held at an end of an optical fiber and especially adapted for measurement of temperature of a surface, comprising:
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an optically clear lens formed of a solid elastomeric material carried by said fiber end, and a layer of luminescent material positioned on an outside surface of said lens in optical communication with said fiber end, whereby said sensor may be positioned against the surface whose temperature is being measured to deform the elastomeric material and bring about a close contact between the layer of luminescent material and said surface. - View Dependent Claims (10, 11, 12)
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13. A condition measuring system, comprising:
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a length of an optical fiber communciation medium having first and second ends, a sensor at said first end, said sensor including an optically clear lens formed of a solid elastomeric material carried by said one fiber end, and a layer of luminescent material carried on an opposite side of said elastometic lens from the side thereof being carried by said fiber first end, means in optical communication with said second fiber communicating medium end for directing excitation radiation along said fiber to said luminescent material, and means in optical communication with said second fiber communicating medium end for detecting a characteristic of luminescent radiation from said sensor that is related to said condition. - View Dependent Claims (14, 15)
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16. A system for simultaneously measuring temperature and another physical parameter, comprising:
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a length of optical fiber transmission medium, means including a source of visible or near visible electromagnetic radiation positioned at one end of said optical fiber medium for directing pulses of said radiation along said medium to another end thereof, a sensor positioned at said another end of said optical fiber medium in a manner to receive said source radiation, modulate it by the physical parameter and temperature being measured, and redirect the modulated radiation through the optical fiber medium to said one end thereof, said sensor comprising; at least one mechanical element in the path of said source radiation whose position varies in response to the magnitude of the physical parameter being measured, and a quantity of luminescent material also in the path of said source radiation, said luminescent material being characterized by emitting, when excited, electromagnetic radiation having an intensity that decays, after termination of an excitation pulse from said excitation source, at a rate that is proportional to the temperature of the sensor, and means positioned at said one end of said optical fiber medium and receiving the decaying electromagnetic radiation from the sensor for (1) measuring a characteristic of the radiation intensity decay emitted by the luminescent material, thereby to obtain an indication of the temperature of the luminescent material, and (2) measuring an intensity level of the decaying radiation emitted by the luminescent material at an instant that is fixed with respect to the occurance of an excitation pulse, thereby to obtain an indication of the magnitude of the desired physical parameter. - View Dependent Claims (17, 18, 19, 20)
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21. A method of measuring the temperature of a surface, comprising the steps of:
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providing a sensor having a solid elastomeric convex lens carried by an end of an optical fiber communication medium and a thin layer of luminescent material attached to an outer surface of the lens in a position that is in optical communication with said optical fiber end, said luminescent material being characterized by emitting, when excited, electromagnetic radiation having a detectable characteristic that varies as a function of its temperature, urging said luminescent material layer against said surface by applying force thereagainst through the optical fiber sufficient to deform the elastomeric lens by compression, thereby providing intimate contact between the luminescent material and said surface, directing exciting radiation through said fiber and lens onto said luminescent material, thereby causing emissions of electromagnetic radiation having a characteristic that varies as a function of temperature to be emitted by said luminescent material and passed back through the optical fiber communication medium, and detecting the emitted luminescent radiation that passes back through said lens and said optical fiber communication medium, whereby a signal is obtained that is related to the temperature of the surface.
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22. A method of measuring the pressure within a fluid medium, comprising the steps of:
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positioning a sensor within said fluid medium, said sensor having (1) a solid elastomeric convex lens carried by an end of an optical fiber communication medium, (2) a layer of luminescent material attached to an outer surface of the lens in optical communication with said optical fiber end, said luminescent material being characterized by emitting luminescent electromagnetic radiation when excited, and (3) means surrounding said elastomeric element for sealing a space around said lens and luminescent material, said sealing means including a flexible diaphragm positioned across said lens in a manner that differences in pressure between said sealed space and said fluid medium surrounding the sensor causes the elastomeric element to be deformed, directing exciting radiation through said fiber and lens onto said luminescent material, thereby causing electromagnetic radiation to be emitted by said luminescent material and passed back though the optical fiber communication medium in an amount dependent upon the degree of deformation of the lens and thus upon the pressure difference between that of the sealed sensor space and that of the fluid medium surrounding the sensor, and detecting a level of emitted luminescent radiation that passes back through said lens and said optical fiber communication medium, whereby a signal is obtained that is related to the pressure of the fluid medium.
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23. An optical sensor held at an end of an optical fiber and especially adapted for measurement of temperature and force, comprising:
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an optically clear lens formed of a solid elastomeric material carried by said fiber end, and a layer of luminescent material positioned on an outside surface of said lens in optical communication with said fiber end, whereby said sensor may be positioned in an environment wherein any force applied to said lens causes its deformation and a resulting detectable change in optical coupling between the luminescent material and said fiber end and wherein the luminescent material emits optical radiation proportional to its temperature. - View Dependent Claims (24)
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Specification