Method and sheet like sensor for measuring stress distribution

US 20030196485A1
Filed: 10/23/2002
Published: 10/23/2003
Est. Priority Date: 04/16/2002
Status: Active Grant

First Claim

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1. A sheet-like sensor for measuring stress distribution comprising:

a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs; and

an analyzer electrically connected only to the boundary nodes and configured to calculate any change in resistance in all of the legs based solely on the measured resistance of the legs between the boundary nodes.

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Abstract

A method and sheet-like sensor for measuring stress distribution including a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs. An analyzer is electrically connected only to the boundary nodes and configured to calculate any change in resistance in all of the legs based solely on the measured resistance of the legs between the boundary nodes.

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34 Claims

1. A sheet-like sensor for measuring stress distribution comprising:
- a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs; and
  
  an analyzer electrically connected only to the boundary nodes and configured to calculate any change in resistance in all of the legs based solely on the measured resistance of the legs between the boundary nodes.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16)
- - 2. The sensor of claim 1 in which the members are wires or traces.
  - 3. The sensor of claim 2 in which the wires are made of copper.
  - 4. The sensor of claim 2 in which the wires are made of pseudoelastic shape memory alloy material.
  - 5. The sensor of claim 1 in which the grid of members is encapsulated in an encapsulation material.
  - 6. The sensor of claim 5 in which the encapsulation material is Kapton.
  - 7. The sensor of claim 5 in which the analyzer is a circuit integral with the encapsulation material.
  - 8. The sensor of claim 1 in which the grid is in the shape of a polygon.
  - 9. The sensor of claim 8 in which polygon is a rectangle.
  - 10. The sensor of claim 9 in which the rectangle is a square.
  - 11. The sensor of claim 1 in which the analyzer is configured to:
    - a) measure the resistances of the legs between the boundary nodes, b) estimate the resistances of all of the legs, c) calculate the resistances of all of the legs based on the measured resistances of the legs between the boundary nodes and the estimated resistances of all of the legs, d) compare the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes, e) based on the comparison, re-estimate the resistances of all of the legs, and f) iteratively repeat steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes to thus accurately determine the resistances of the legs between or connected to the internal nodes.
  - 12. The sensor of claim 11 in which the analyzer is further configured to calculate the strain experience by each leg.
  - 13. The sensor of claim 12 in which the analyzer is further configured to identify any leg which has failed based on a very high determined resistance.
  - 14. The sensor of claim 11 in which the estimate is based on the step a).
  - 15. The sensor of claim 14 in which the estimate is set to the mean of the measured resistances.
  - 16. The sensor of claim 11 in which relaxation is used in step f).

17. A sheet-like sensor for measuring stress distribution comprising:
- a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs; and
  
  an analyzer connected only to the boundary nodes.
- View Dependent Claims (18)
- - 18. The sensor of claim 17 in which the analyzer is configured to:
    - a) measure the resistances of the legs between the boundary nodes, b) estimate the resistances of all of the legs, c) calculate the resistances of all of the legs based on the measured resistances of the legs between the boundary nodes and the estimated resistances of all of the legs, d) compare the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes, e) based on the comparison, re-estimate the resistances of all of the legs; and
      
      f) iteratively repeat steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes to thus accurately determine the resistances of the legs between or connected to the internal nodes.

19. A sheet-like sensor for measuring stress distribution comprising:
- a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs; and
  
  an analyzer connected to the boundary nodes and configured to measure any change in resistance of the legs between the boundary nodes and, based on the measured resistances, to calculate any change in resistance in all of the legs.

20. A sensor system for measuring stress distribution comprising:
- a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs; and
  
  an analyzer electrically connected to the boundary nodes and configured to;
  
  a) measure the resistances of the legs between the boundary nodes, b) estimate the resistances of all of the legs, c) calculate the resistances of all of the legs based on the measured resistance of the legs between the boundary nodes and the estimated resistances of all of the legs, d) compare the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes, e) based on the comparison, re-estimate the resistances of all of the legs, and f) iteratively repeat steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes to thus accurately determine the resistances of the legs between or connected to the internal nodes.

21. A sensor system comprising:
- a grid including internal nodes and boundary nodes at the periphery of the grid defining a plurality of legs; and
  
  an analyzer electrically connected to the boundary nodes and configured to;
  
  a) measure a characteristic of the legs between the boundary nodes, b) estimate the same characteristic of all of the legs, c) calculate the same characteristic of all of the legs based on the measured characteristic of the legs between the boundary nodes and the estimated characteristic of all of the legs, d) compare the calculated characteristic of the legs between the boundary nodes with the measured characteristic of the legs between the boundary nodes, e) based on the comparison, re-estimate the characteristic of all of the legs; and
  
  f) iteratively repeat steps c)-e) until the measured characteristic of the legs between the boundary nodes converge to the calculated characteristic of the legs between the boundary nodes.
- View Dependent Claims (22)
- - 22. The sensor system of claim 21 in which the members change in resistance when subjected to strain and the characteristic is resistance.

23. A method for determining impedances in a grid of leg impedances, the legs intersecting at boundary nodes at the periphery of the grid and intersecting at internal nodes within the grid, the method comprising:
- a) measuring the resistances of the legs between the boundary nodes, b) estimating the resistances of all of the legs, c) calculating the resistances of all of the legs based on the measured resistances of the legs between the boundary nodes and the estimated resistances of all of the legs, d) comparing the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes, e) based on the comparison, re-estimating the resistances of all of the legs, and f) iteratively repeating steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes to thus accurately determine the resistance of the legs between or connected to the internal nodes.
- View Dependent Claims (24, 25, 26, 27, 28)
- - 24. The method of claim 23 further including the step of calculating the strain experience by each leg.
  - 25. The method of claim 23 further including identifying any leg which has failed based on a very high determined resistance.
  - 26. The method of claim 23 in which the estimate of step b) is based on step a).
  - 27. The method of claim 23 in which the estimate is set to the mean of the measured resistances.
  - 28. The method of claim 23 in which relaxation is used in step f).

29. A sheet-like sensor for measuring stress distribution comprising:
- a grid of members which change in resistance when subjected to strain, the members intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs; and
  
  means connected to the boundary nodes, for calculating any change in resistance in all of the legs based solely on the measured resistance of the legs between the boundary nodes.

30. A sheet-like sensor for measuring stress distribution comprising:
- a grid of wires which change in resistance when subjected to strain, the wires intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs, the wires encapsulated in an encapsulation material; and
  
  an analyzer connected to the boundary nodes and configured to;
  
  a) measure the resistances of the legs between the boundary nodes, b) estimate the resistances of all of the legs, c) calculate the resistances of all of the legs based on the measured resistances of the legs between the boundary nodes and the estimated resistances of all of the legs, d) compare the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes, e) based on the comparison, re-estimate the resistances of all of the legs; and
  
  f) iteratively repeat steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes to thus accurately determine the resistances of the legs between or connected to the internal nodes.

31. A method of measuring stress distribution in a grid of wires which change in resistance when subjected to strain, the wires intersecting at internal nodes and intersecting at boundary nodes at the periphery of the grid defining a plurality of legs, the method comprising:
- a) measuring the resistances of the legs between the boundary nodes, b) estimating the resistances of all of the legs, c) calculating the resistances of all of the legs based on the measured resistances of the legs between the boundary nodes and the estimated resistances of all of the legs, d) comparing the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes, e) based on the comparison, re-estimating the resistances of all of the legs; and
  
  f) iteratively repeating steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes to thus accurately determine the resistances of the legs between or connected to the internal nodes.

32. An analysis method comprising:
- a) measuring the resistances of legs between boundary nodes;
  
  b) estimating the resistances of all of the legs;
  
  c) calculating the resistances of all of the legs based on the measured resistances of the legs between the boundary nodes and the estimated resistances of all of the legs;
  
  d) comparing the calculated resistances of the legs between the boundary nodes with the measured resistances of the legs between the boundary nodes;
  
  e) based on the comparison, re-estimating the resistances of all of the legs; and
  
  f) iteratively repeating steps c)-e) until the measured resistances of the legs between the boundary nodes converge to the calculated resistances of the legs between the boundary nodes.

33. An analysis method comprising:
- a) measuring a characteristic of legs between boundary nodes;
  
  b) estimating the same characteristic of all of the legs;
  
  c) calculating the same characteristic of all of the legs based on the measured characteristic of the legs between the boundary nodes and the estimated characteristic of all of the legs;
  
  d) comparing the calculated characteristic of the legs between the boundary nodes with the measured characteristic of the legs between the boundary nodes, e) based on the comparison, re-estimating the characteristic of all of the legs; and
  
  f) iteratively repeating steps c)-e) until the measured characteristic of the legs between the boundary nodes converge to the calculated characteristic of the legs between the boundary node.
- View Dependent Claims (34)
- - 34. The analysis method of claim 33 in which the characteristic is a complex impedence.

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Current Assignee
Mide Technology Corporation (Totalenergies Se)
Original Assignee
Mide Technology Corporation (Totalenergies Se)
Inventors
Schoor, Marthinus van, Lengyel, Attila, Muller, Gert Johannes, Radighieri, Brooks

Granted Patent

US 6,802,216 B2
Time in Patent Office

Days
Field of Search
US Class Current

73/159
CPC Class Codes

G01L 1/205 using distributed sensing e...

Method and sheet like sensor for measuring stress distribution

First Claim

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Abstract

21 Citations

34 Claims

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Method and sheet like sensor for measuring stress distribution

First Claim

1 Assignment

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0 Petitions

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Accused Products

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Abstract

21 Citations

34 Claims

Specification

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Solutions

Use Cases

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