GMR sensor with flux concentrators

US 7,112,957 B2
Filed: 06/16/2004
Issued: 09/26/2006
Est. Priority Date: 06/16/2004
Status: Active Grant

First Claim

Patent Images

1. A proximity sensor for detecting the proximity of a moving target, comprising:

a first magnetoresistive resistor;

a second magnetoresistive resistor spaced from the first magnetoresistive resistor along a path of the moving target;

a first flux concentrator positioned proximate the first magnetoresistive resistor; and

a second flux concentrator positioned proximate the second magnetoresistive resistor;

wherein, the first magnetoresistive resistor and the second magnetoresistive resistor are electrically coupled in a bridge configuration;

wherein at least one of the first magnetoresistive resistor and the second magnetoresistive resistor is a giant magneto resistance resistor having an in-plane first axis direction and an orthogonal in-plane second axis direction;

wherein the first flux concentrator redirects a magneric field component along the first axis direction through the first magnetoresistive resistor along the second axis direction.

View all claims

1 Assignment

Timeline View

Assignment View

0 Petitions

Accused Products

Abstract

A proximity sensor that is capable of producing a relatively larger output signal than past proximity sensors, and in some cases, an output signal that is relatively independent of the speed at which a target passes the sensor. In one illustrative embodiment, the proximity sensor includes a first magnetoresistive resistor and a second magnetoresistive resistor connected in a bridge configuration. The first magnetoresistive resistor is spaced from the second magnetoresistive resistor along the path of a moving ferrous target. A bias magnet source is positioned behind the proximity sensor, and the ferrous target passes in front of the proximity sensor. The ferrous target alters the direction of the bias magnetic field in the vicinity of the first and second magnetoresistive resistors as the ferrous target passes by the proximity sensor. Flux concentrators are positioned proximate to each of the first and second magnetoresistive resistors. The flux concentrators may help redirect or shunt the magnetic field component produced by the bias magnet source that is perpendicular to the direction of motion of the target through the first and second magnetoresistive resistors in a direction that is parallel to the direction of motion of the target.

Citations

43 Claims

1. A proximity sensor for detecting the proximity of a moving target, comprising:
- a first magnetoresistive resistor;
  
  a second magnetoresistive resistor spaced from the first magnetoresistive resistor along a path of the moving target;
  
  a first flux concentrator positioned proximate the first magnetoresistive resistor; and
  
  a second flux concentrator positioned proximate the second magnetoresistive resistor;
  
  wherein, the first magnetoresistive resistor and the second magnetoresistive resistor are electrically coupled in a bridge configuration;
  
  wherein at least one of the first magnetoresistive resistor and the second magnetoresistive resistor is a giant magneto resistance resistor having an in-plane first axis direction and an orthogonal in-plane second axis direction;
  
  wherein the first flux concentrator redirects a magneric field component along the first axis direction through the first magnetoresistive resistor along the second axis direction.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The proximity sensor according to claim 1, wherein the first flux concentrator and second flux concentrator each include a pair of ferrous material regions.
  - 3. The proximity sensor according to claim 1, wherein the first flux concentrator and second flux concentrator include a permalloy material.
  - 4. The proximity sensor according to claim 2, wherein the first magnetoresistive resistor is disposed between the first flux concentrator pair of ferrous material regions.
  - 5. The proximity sensor according to claim 4, wherein the second magnetoresistive resistor is disposed between the second flux concentrator pair of ferrous material regions.
  - 6. The proximity sensor according to claim 1, wherein the second flux concentrator redirects a magnetic field component along she first axis direction through the second magnetoresistive resistor along the second axis direction.
  - 7. The proximity sensor according to claim 1, wherein the first and second flux concentrators direct magnetic flux across the first and second magnetoresistive resistors along the second axis direction.
  - 8. The proximity sensor according to claim 4, wherein the first flux concentrator pair of ferrous material regions each include an inner face proximate the first magnetoresistive resistor and an opposing outer face, wherein each inner face is planar or substantially planar and parallel to the first axis.
  - 9. The proximity sensor according to claim 5, wherein the second flux concentrator pair of ferrous material regions each include an inner face proximate the second magnetoresistive resistor and an opposing outer face, wherein each inner face is planar or substantially planar and parallel to the first axis.
  - 10. The proximity sensor according to claim 8, wherein at least a portion of the first flux concentrator pair of ferrous material regions opposing outer face is non-planar.
  - 11. The proximity sensor according to claim 9, wherein at least a portion of the second flux concentrator pair of ferrous material regions opposing outer face is non-planar.

12. A proximity sensor comprising;
- a first pair of magnetoresistive resistors;
  
  a second pair of magnetoresistive resistors;
  
  a first flux concentrator positioned proximate the first pair of magnetoresistive resistors; and
  
  a second flux concentrator positioned proximate the second pair of magnetoresistive resistors;
  
  wherein the first pair of magnetoresistive resistors and the second pair of magnetoresistive resistors are electrically coupled in a bridge configuration;
  
  wherein the first flux concentrator redirects a magnetic field component along a standard axis through the first pair of magnetoresistive resistors in a cross-axis direction.
- View Dependent Claims (13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23)
- - 13. The proximity sensor according to claim 12, wherein the first pair of magnetoresistive resistors and second pair of magnetoresistive resistors are giant magneto resistance resistors and each giant magneto resistance resistor has an in-plane standard axis direction and an orthogonal in-plane cross-axis direction.
  - 14. The proximity sensor according to claim 13, wherein the first flux concentrator and second flux concentrator are each formed from a pair of ferrous material regions.
  - 15. The proximity sensor according to claim 12, wherein the first flux concentrator and second flux concentrator are formed from petmalloy material.
  - 16. The proximity sensor according to claim 14, wherein the first pair of magnetoresistive resistors is disposed between the first flux concentrator pair of ferrous material regions.
  - 17. The proxinuty sensor according to claim 16, wherein the second pair of magnetoresistive resistors is disposed between the second flux concentrator pair of ferrous material regions.
  - 18. The proximity sensor according to claim 12, wherein the second flux concentrator redirects a magnetic field component along the standard axis direction through the second pair of magnetoresistive resistors in the cross-axis direction.
  - 19. The proximity sensor according to claim 12, wherein the first and second flux concentrators direct magnetic flux across the first and second pair of magnetoresistive resistors in the cross-axis direction.
  - 20. The proximity sensor according to claim 14, wherein the first flux concentrator pair of ferrous material regions each include an inner face proximate the first pair of magnetoresistive resistors and an opposing outer face, wherein each inner face is planar and parallel to the standard axis.
  - 21. The proximity sensor according to claim 20, wherein the second flux concentrator pair of ferrous material regions each include an inner face proximate the second pair of magnetoresistive resistors and an opposing outer face, wherein each inner face is planar and parallel to the standard axis.
  - 22. The proximity sensor according to claim 20, wherein at least a portion of the first flux concentrator pair of ferrous material regions opposing outer face is non-planar.
  - 23. The proximity sensor according to claim 21, wherein at least a portion of the second flux concentrator pair of ferrous material regions opposing outer face is non-planar.

24. A proximity transducer for detecting a position of a ferromagnetic target, comprising:
- a magnetic field biasing source having an end and an axis, the magnetic field biasing source producing a radial magnetic field component in a direction perpendicular to the axis at the end; and
  
  a proximity sensor lying in a plane perpendicular or substantially perpendicular to the axis of the magnetic field biasing source and disposed between the end of the magnetic field biasing source and a ferromagnetic target, the proximity sensor comprising;
  
  a first pair of magnetoresistive resistors;
  
  a second pair of magnetoresistive resistors;
  
  a first flux concentrator positioned proximate the first pair of magnetoresistive resistors; and
  
  a second flux concentrator positioned proximate the second pair of magnetoresistive resistors;
  
  wherein, the first pair of magnetoresistive resistors and the second pair of magnetoresistive resistors are electrically coupled in a bridge configuration;
  
  wherein the first and second flux concentrators are configured to redirect magnetic flux across the first and second pair of magnetoresistive resistors in a cross-axis direction.
- View Dependent Claims (25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37)
- - 25. The proximity transducer according to claim 24, wherein the first pair of magnetoresistive resistors and second pair of magnetoresistive resistors are giant magneto resistance resistors, and each giant magneto resistance resistor has an in-plane standard axis direction and an orthogonal in-plane cross-axis direction.
  - 26. The proximity transducer according to claim 25, wherein the first flux concentrator and second flux concentrator are each formed from a pair of ferrous material regions.
  - 27. The proximity transducer according to claim 26, wherein the first flux concentrator and second flux concentrator are formed from permalloy material.
  - 28. The proximity transducer according to claim 26, wherein the first pair of magnetoresistive resistors is disposed between the first flux concentrator pair of ferrous material regions.
  - 29. The proximity transducer according to claim 28, wherein the second pair of magnetoresistive resistors is disposed between the second flux concentrator pair of ferrous material regions.
  - 30. The proximity transducer according to claim 29, wherein the first flux concentrator redirects a magnetic field component of the magnetic field biasing source that extends along the standard axis tough the first pair of magnetoresistive resistors in the cross-axis direction.
  - 31. The proximity transducer according to claim 30, wherein the second flux concentrator redirects a magnetic field component of the magnetic field biasing, source that extends along the standard axis though the second pair of magnetoresistive resistors in the cross-axis direction.
  - 32. The proximity transducer according to claim 31, wherein the ferromagnetic target is a gear tooth.
  - 33. The proximity transducer according to claim 32, wherein the ferromagnetic target is configured for movement in a direction parallel to the cross-axis direction.
  - 34. The proximity transducer according to claim 33, wherein the first flux concentrator pair of ferrous material regions each include an inner face proximate the first pair of magnetoresistive resistors and an opposing outer face, wherein the each inner face is planar and parallel to the standard axis.
  - 35. The proximity transducer according to claim 34, wherein the second flux concentrator pair of ferrous material regions each include an inner face proximate the second pair of magnetoresistive resistors and an opposing outer face, wherein the each inner face is planar and parallel to the standard axis.
  - 36. The proximity transducer according to claim 35, wherein at least a portion of the first flux concentrator pair of ferrous material regions opposing outer face is non-planar.
  - 37. The proximity transducer according to claim 36, wherein at least a portion of the second flux concentrator pair of ferrous material.

38. A proximity sensor comprising:
- a first magnetoresistive resistor;
  
  a second magnetoresistive resistor spaced from the first magnetoresistive resistor, wherein at least one of the first magnetoresistive resistor and the second magnetoresistive resistor is a giant magneto resistance resistor having an in-plane first axis direction and an orthogonal in-plane second axis direction;
  
  a first flux concentrator positioned proximate the first magnetoresistive resistor;
  
  a second flux concentrator positioned proximate the second magnetoresistive resistor;
  
  wherein, the first magnetoresistive resistor sad the second magnetoresistive resistor are electrically coupled in a bridge configuration; and
  
  wherein the first flux concentrator redirects a magnetic field component along the first axis direction through the first magnetoresistive resistor along the second axis direction.
- View Dependent Claims (39)
- - 39. The proximity sensor according to claim 38, wherein the second flux concentrator redirects a magnetic field component along the first axis direction through the second magnetoresistive resistor along the second axis direction.

40. A proximity sensor for detecting the proximity of a moving target, comprising:
- a first magnetoresistive resistor;
  
  a second magnetoresistive resistor spaced from the first magnetoresistive resistor along a path of the moving target;
  
  a first flux concentrator positioned proximate the first magnetoresistive resistor; and
  
  a second flux concentrator positioned proximate the second magnetoresistive resistor;
  
  the first flux concentrator and second flux concentrator each include a pair of ferrous material regions;
  
  the first magnetoresistive resistor and the second magnetoresistive resistor are electrically coupled in a bridge configuration, wherein at least one of the first magnetoresistive resistor and the second magnetoresistive resistor is a giant magneto resistance resistor having an in-plane first axis direction and an orthogonal in-plane second axis direction;
  
  the first magnetoresistive resistor is disposed between the first flux concentrator pair of ferrous material regions; and
  
  the first flux concentrator pair of ferrous material regions each include an inner face proximate the first magnetoresistive resistor and an opposing outer face, wherein each inner face is planar or substantially planar and parallel to the first axis, and wherein at least a portion of the first flux concentrator pair of ferrous material regions opposing outer face is non-planar.

41. A proximity sensor comprising:
- a first pair of magnetoresistive resistors;
  
  a second pair of magnetoresistive resistors;
  
  a first flux concentrator positioned proximate the first pair of magnetoresistive resistors;
  
  a second flux concentrator positioned proximate the second pair of magnetoresistive resistors;
  
  wherein the first pair of magnetoresistive resistors and the second pair of magnetoresistive resistors are electrically coupled in a bridge configuration; and
  
  wherein the first and second flux concentrators direct magnetic flux across the first and second pair of magnetoresistive resistors in the cross-axis direction.

42. A proxinuty sensor comprising:
- a first pair of magnetoresistive resistors;
  
  a second pair of magnetoresistive resistors;
  
  the first pair of magnetoresistive resistors and the second pair of magnetoresistive resistors are electrically coupled in a bridge configuration;
  
  the first pair of magnetoresistive resistors and second pair of magnetoresistive resistors are giant magneto resistance resistors and each giant magneto resistance resistor has an in-plane standard axis direction and an orthogonal in-plane cross-axis direction;
  
  a first flux concentrator positioned proximate the first pair of magnetoresistive resistors;
  
  a second flux concentrator positioned proximate the second pair of magnetoresistive resistors;
  
  wherein the first flux concentrator and second flux concentrator are each fanned from a pair of ferrous material regions; and
  
  the flint flux concentrator pair of ferrous material regions each include an inner face proximate the first pair of magnetoresistive resistors and an opposing outer face, wherein each inner face is planar and parallel to the standard axis, and at least a portion of the first flux concentrator pair of ferrous material regions opposing outer face is non-planar.

43. A proximity transducer for detecting a position of a ferromagnetic target, comprising:
- a magnetic field biasing source having an end and an axis, the magnetic field biasing source producing a radial magnetic field component in a direction perpendicular to the axis at the end; and
  
  a proximity sensor lying in a plane perpendicular or substantially perpendicular to the axis of the magnetic field biasing source and disposed between the end of the magnetic field biasing source and a ferromagnetic target, the proximity sensor comprising;
  
  a first pair of magnetoresistive resistors;
  
  a second pair of magnetoresistive resistors, wherein the first pair of magnetoresistive resistors and the second pair of magnetoresistive resistors are electrically coupled in a bridge configuration;
  
  the first pair of magnetoresistive resistors and second pair of magnetoresistive resistors are giant magneto resistance resistors, and each giant magneto resistance resistor has an in-plane standard axis direction and an orthogonal in-plane cross-axis direction;
  
  a first flux concentrator positioned proximate the first pair of magnetoresistive resistors; and
  
  a second flux concentrator positioned proximate the second pair of magnetoresistive resistors;
  
  the first flux concentrator and second flux concentrator each formed from a pair of ferrous material regions, with the first pair of magnetoresistive resistors disposed between the first flux concentrator pair of ferrous material regions and the second pair of magnetoresistive resistors disposed between the second flux concentrator pair of ferrous material regions; and
  
  wherein the first flux concentrator redirects a magnetic field component of the magnetic field biasing source that extends along the standard axis though the first pair of magnetoresistive resistors in the cross-axis direction.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
Honeywell International Inc.
Original Assignee
Honeywell International Inc.
Inventors
Bicking, Robert E.
Primary Examiner(s)
LEDYNH, BOT L

Application Number

US10/869,741
Publication Number

US 20050280411A1
Time in Patent Office

832 Days
Field of Search

324/207.25, 324/207.21, 324/244
US Class Current

324/207.25
CPC Class Codes

G01B 7/14 for measuring distance or c...

G01D 5/145 influenced by the relative ...

GMR sensor with flux concentrators

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

Citations

43 Claims

Specification

Solutions

Use Cases

Quick Links

GMR sensor with flux concentrators

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

Citations

43 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links