Strain sensing device and method of measuring strain
First Claim
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1. A strain sensing cable comprising:
- a sub-assembly;
at least one optical fiber within the sub-assembly; and
a metallic coating which encases the sub-assembly, wherein the metallic coating is strain coupled to the at least one optical fiber along an entire length of the at least one optical fiber by a friction coupling force such that strain is translated from the metallic coating to any point along the entire length of the at least one optical fiber,wherein an outer diameter of the sub-assembly is greater than an inside diameter of the metallic coating, and the sub-assembly is compressed so as to fit within the metallic coating such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and such that strain is translated from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, andwherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force.
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Abstract
A strain sensing device has a sub-assembly with at least one optical fiber therein, and a metallic coating encasing the sub-assembly. The metallic coating is strain coupled to the sub-assembly. A strain sensing system and a method of anticipating failure in a structure are provided. The strain sensing system and method of anticipating failure in a structure use the strain on the strain sensing device to calculate the strain on a structure of interest.
14 Citations
25 Claims
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1. A strain sensing cable comprising:
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a sub-assembly; at least one optical fiber within the sub-assembly; and a metallic coating which encases the sub-assembly, wherein the metallic coating is strain coupled to the at least one optical fiber along an entire length of the at least one optical fiber by a friction coupling force such that strain is translated from the metallic coating to any point along the entire length of the at least one optical fiber, wherein an outer diameter of the sub-assembly is greater than an inside diameter of the metallic coating, and the sub-assembly is compressed so as to fit within the metallic coating such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and such that strain is translated from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force. - View Dependent Claims (2, 3, 4, 5, 6, 19)
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7. A strain sensing cable comprising:
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a sub-assembly; at least one optical fiber within the sub-assembly; and a metallic coating which encases the sub-assembly, wherein the metallic coating is strain coupled to the at least one optical fiber along an entire length of the at least one optical fiber by a friction coupling force such that strain is translated from the metallic coating to any point along the entire length of the at least one optical fiber, wherein an outer diameter of the sub-assembly is equal to an inside diameter of the metallic coating, and the sub-assembly is compressed so as to fit within the metallic coating such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and such that strain is translated from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force. - View Dependent Claims (8)
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9. A strain sensing cable comprising:
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a sub-assembly; at least one optical fiber within the sub-assembly; and a metallic coating which encases the sub-assembly, wherein the metallic coating is strain coupled to the at least one optical fiber along an entire length of the at least one optical fiber by a friction coupling force such that strain is translated from the metallic coating to any point along the entire length of the at least one optical fiber, wherein an outer diameter of the sub-assembly is smaller than an inside diameter of the metallic coating, and the metallic coating is compressed onto the sub-assembly such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and so as to translate strain from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force. - View Dependent Claims (10)
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11. A strain sensing cable comprising:
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a sub-assembly; at least one optical fiber within the sub-assembly; a metallic coating which encases the sub-assembly, wherein the metallic coating is strain coupled to the at least one optical fiber along an entire length of the at least one optical fiber by a friction coupling force such that strain is translated from the metallic coating to any point along the entire length of the at least one optical fiber; and an expansion agent located between the metallic coating and the least one optical fiber, wherein the expansion agent is activated to expand outward in thickness to strain couple the metallic coating to the at least one optical fiber together by the friction coupling force induced by the expansion of the expansion agent, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force.
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12. A strain sensing system comprising:
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a strain sensing cable comprising, a sub-assembly; at least one optical fiber within the sub-assembly; and a metallic coating which encases the sub-assembly, wherein the metallic coating is strain coupled to the at least one optical fiber along an entire length of the at least one optical fiber by a friction coupling force such that strain on the metallic coating is translated from the metallic coating to any point along the entire length of the at least one optical fiber; a structure of interest the strain of which is to be measured, wherein the strain sensing cable is connected to said structure; and a strain measuring system which measures the strain in the strain sensing cable along the entire length of the at least one optical fiber, wherein the measured strain on said strain sensing cable is used in determining strain on said structure, and wherein an outer diameter of the sub-assembly is greater than an inside diameter of the metallic coating, and the sub-assembly is compressed so as to fit within the metallic coating such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and such that strain is translated from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force. - View Dependent Claims (13, 14, 15, 16, 17, 18)
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20. A method of making a strain sensing cable, comprising:
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arranging at least one optical fiber within a sub-assembly; encasing the sub-assembly within a metallic coating, such that the metallic coating is strain coupled along an entire length of the at least one optical fiber by a friction coupling force such that strain on the metallic coating is translated from the metallic coating to any point along the entire length of the at least one optical fiber; and configuring the at least one optical fiber to be measured for the strain along the entire length of the at least one optical fiber, wherein an outer diameter of the sub-assembly is greater than an inside diameter of the metallic coating, further comprising compressing the sub-assembly to fit within the metallic coating such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and such that so as to translate strain from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force. - View Dependent Claims (21, 22)
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23. A method of making a strain sensing cable, comprising:
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arranging at least one optical fiber within a sub-assembly; encasing the sub-assembly within a metallic coating, such that the metallic coating is strain coupled along an entire length of the at least one optical fiber by a friction coupling force such that strain on the metallic coating is translated from the metallic coating to any point along the entire length of the at least one optical fiber; and configuring the at least one optical fiber to be measured for the strain along the entire length of the at least one optical fiber, wherein an outer diameter of the sub-assembly is equal to an inside diameter of the metallic coating, further comprising compressing the sub-assembly so as to fit within the metallic coating such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and so as to translate strain from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force.
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24. A method of making a strain sensing cable, comprising:
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arranging at least one optical fiber within a sub-assembly; encasing the sub-assembly within a metallic coating, such that the metallic coating is strain coupled along an entire length of the at least one optical fiber by a friction coupling force such that strain on the metallic coating is translated from the metallic coating to any point along the entire length of the at least one optical fiber; and configuring the at least one optical fiber to be measured for the strain along the entire length of the at least one optical fiber, wherein an outer diameter of the sub-assembly is smaller than an inside diameter of the metallic coating, further comprising compressing the metallic coating onto the sub-assembly such that the metallic coating is strain coupled to the at least one optical fiber by the friction coupling force induced by the compression and so as to translate strain from the metallic coating to the at least one optical fiber at any point along the entire length of the at least one optical fiber, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force.
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25. A method of making a strain sensing cable, comprising:
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arranging at least one optical fiber within a sub-assembly; encasing the sub-assembly within a metallic coating, such that the metallic coating is strain coupled along an entire length of the at least one optical fiber by a friction coupling force such that strain on the metallic coating is translated from the metallic coating to any point along the entire length of the at least one optical fiber; configuring the at least one optical fiber to be measured for the strain along the entire length of the at least one optical fiber; and placing an expansion agent between the metallic coating and the least one optical fiber, and activating the expansion agent to expand outward in thickness to strain couple the metallic coating to the at least one optical fiber together by the friction coupling force induced by the expansion of the expansion agent, and wherein the strain coupling of the metallic coating and the at least one optical fiber is constantly maintained by the friction coupling force.
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Specification
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Current AssigneeAFL Telecommunications LLC (Fujikura Limited)
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Original AssigneeAFL Telecommunications LLC (Fujikura Limited)
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InventorsHerbst, Brian Gerald
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Primary Examiner(s)Peace, Rhonda
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Application NumberUS12/278,140Publication NumberTime in Patent Office1,833 DaysField of Search385/12, 385/13US Class Current385/12CPC Class CodesG01L 1/242 the material being an optic...
