Hot annealed weld inspection

US 4,644,272 A
Filed: 07/31/1984
Issued: 02/17/1987
Est. Priority Date: 07/31/1984
Status: Expired due to Fees

First Claim

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1. A weld flaw detection system for use in connection with welded workpiece manufacturing apparatus incorporating circuitry and apparatus for induction annealing of welds by the production of strong alternating electromagnetic annealing fields in a region of the weld, said flaw detection system comprising:

(a) exciter circuitry capable of generating alternating test eddy currents in a workpiece at a carrier frequency;

(b) detection circuitry including a demodulator for detecting variation in eddy currents to produce a flaw signal modulated on the carrier frequency indicating presence of a workpiece weld defect;

(c) control circuitry for varying the frequency of the induction annealing electromagnetic field, and(d) regulation circuitry for adjusting the alternating carrier frequency of said test eddy currents as a function of the induction annealing field frequency.

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Abstract

An eddy current system and method for hot annealed weld inspection is disclosed for use on metallic workpieces such as steel pipe. An annealer produces strong alternating fields to heat the weld. A nearby exciter coil produces test eddy currents within the workpiece at a carrier frequency. Detector circuitry including a demodulator and a detector coil senses defects within the workpiece as evidenced by nonuniformities in the test eddy currents, in response to which the detector coil produces a flaw indicating signal modulated on the carrier frequency. The carrier frequency is automatically maintained at a non-integral multiple of the annealer alternating frequency. A variable band pass filter between the demodulator and detector coil is automatically maintained with its pass band substantially centered upon the carrier frequency.

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38 Claims

1. A weld flaw detection system for use in connection with welded workpiece manufacturing apparatus incorporating circuitry and apparatus for induction annealing of welds by the production of strong alternating electromagnetic annealing fields in a region of the weld, said flaw detection system comprising:
- (a) exciter circuitry capable of generating alternating test eddy currents in a workpiece at a carrier frequency;
  
  (b) detection circuitry including a demodulator for detecting variation in eddy currents to produce a flaw signal modulated on the carrier frequency indicating presence of a workpiece weld defect;
  
  (c) control circuitry for varying the frequency of the induction annealing electromagnetic field, and(d) regulation circuitry for adjusting the alternating carrier frequency of said test eddy currents as a function of the induction annealing field frequency.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
- - 2. The system of claim 1, wherein:
    - said regulation circuitry includes circuitry for maintaining said test eddy current carrier frequency as a non-integral multiple of said induction annealing field frequency.
  - 3. The system of claim 2, wherein:
    - said regulation circuitry maintains said test eddy current carrier frequency at a multiple of approximately of 4.5 times the induction annealing field frequency.
  - 4. The system of claim 1, further comprising:
    - a second ultrasonic pipe testing system for providing additional flaw detection.
  - 5. The system of claim 1, further comprising:
    - (a) an electrical filter interposed in the detection circuitry for selectively passing electrical signals having frequencies lying within a predetermined range, and(b) means for adjusting said frequency range of said filter as a function of the induction annealing field frequency.
  - 6. The system of claim 5, wherein:
    - said electrical filter comprises a band pass filter defining a pass band.
  - 7. The system of claim 6, wherein:
    - said range adjusting circuitry for said filter comprises circuitry for centering the pass band of said filter at approximately the carrier frequency.
  - 8. The system of claim 7, wherein said electrical filter comprises a digital band pass filter.
  - 9. The system of claim 1, further comprising:
    - circuitry responsive to turn-on of the annealing circuitry for disabling said frequency adjustment circuitry for a predetermined time.
  - 10. The system of claim 1, wherein:
    - said regulation circuitry includes means for adjusting said carrier frequency to a predetermined value in the absence of an induction annealing field frequency.
  - 11. The system of claim 1, further comprising:
    - circuitry coupled to the detector circuitry for producing a signal indicating temperature of a region of the pipe.

12. An eddy current pipe weld flaw detector system for evaluating the quality of pipe welds annealed by electrical induction heating, past which a pipe is propelled along a path, said system comprising:
- (a) exciter circuitry for producing eddy currents within a pipe propelled along the path;
  
  (b) detector circuitry for sensing defects in said pipe as evidenced by variations in the eddy currents produced by the exciter circuitry;
  
  (c) said exciter and detection circuitry comprising exciter and detector coils, respectively, both located along the path downstream of and proximate the annealing circuitry;
  
  (d) an enclosure at least partially surrounding said exciter and detector coils containing a liquid coolant for cooling said coils;
  
  (e) means for sensing the level of said coolant, and(f) means coupled to the coolant level sensor means for producing an indication in response to the coolant level falling below a predetermined value.

13. A system for testing hot annealed pipe welds by the use of eddy currents, said system comprising:
- (a) a test probe including;
  
  (i) an exciter coil, and(ii) a detector coil;
  
  (b) means for relatively moving a pipe with respect to the probe along a path near the coils;
  
  (c) circuitry for causing the exciter coil to induce eddy currents in a pipe when moving along the path;
  
  (d) circuitry coupled to the detector coil for sensing defects in a tested pipe in response to variations in said eddy currents;
  
  (e) means for sensing the temperature proximate the tested zone of such a pipe, said temperature sensing means comprising said detector coil circuitry being coupled for sensing resistivity of a portion of the pipe independently of direction of an electromagnetic field through said workpiece.
- View Dependent Claims (14, 15, 16)
- - 14. The system of claim 13, wherein:
    - (a) said detector coil is differentially wound, and(b) said resistivity measuring circuitry comprises circuitry for sensing the degree of imbalance produced by said differentially wound coil.
  - 15. The system of claim 13, wherein:
    - said temperature measuring means comprises circuitry for sensing resistivity of a portion of the pipe.
  - 16. The system of claim 15, wherein:
    - (a) said detector coil is differentially wound, and(b) said resistivity measuring circuitry comprises circuitry for sensing the degree of imbalance produced by said differentially wound coil.

17. A pipe processing system comprising:
- (a) apparatus for forming strip metal into a generally cylindrical shape, defining a longitudinal seam;
  
  (b) apparatus for moving the formed metal longitudinally along a path;
  
  (c) apparatus downstream along said path from said forming apparatus for effecting a weld along a seam;
  
  (d) induction annealing apparatus and circuitry downstream along said path from said welding apparatus for annealing a seam weld by induction heating at a first alternating frequency;
  
  (e) a test probe comprising;
  
  (i) an exciter coil, and(ii) circuitry coupled to the exciter coil for inducing eddy currents in a region of an annealed welded seam at a second alternating frequency which is a nonintegral multiple of said first frequency;
  
  (iii) said probe being located downstream along the path from said annealing circuitry and apparatus and at a location at which the temperature of an annealed weld region of a pipe being tested is above the Curie temperature for the pipe material;
  
  (f) detection circuitry for producing indications of defects in a pipe weld region moved along the path in response to variations in said eddy currents, and(g) a supplementary test apparatus for detecting flaws in a pipe downstream along the path from said detector probe by the use of ultrasonic energy.

18. A hot annealed pipe weld flaw detection system for use in connection with electrical induction weld annealing apparatus and circuitry which anneals the pipe weld by the use of strong alternating electromagnetic fields having a first frequency, said system comprising:
- (a) exciter circuitry located proximate the annealer apparatus for producing eddy currents in a pipe when near the exciter circuitry at a second frequency which is a non-integral multiple of said first frequency, and(b) detector circuitry responsive to variations in the eddy currents generated by said exciter circuitry to provide indication of flaws in a tested pipe.

19. A system for detecting defects in a metallic workpiece wherein such workpiece, during its production, is subject to acquisition of a series of discrete defects approximately uniformly spaced along the workpiece, said system comprising:
- (a) apparatus adapted to propel a workpiece along a path extending past at least a portion of the detector system;
  
  (b) a detector probe for producing an indication of a defect each time a defect passes by the probe, and(c) discrimination circuitry for producing a recurrent flaw indicating signal only in response to the occurrence of a series of defect indicating signals at approximately a predetermined frequency for a predetermined length of time.
- View Dependent Claims (20)
- - 20. The system of claim 19, wherein said discrimination circuitry produces a recurrent flaw signal in response to the occurrence of defect indicating signals at a frequency of about 30 to 90 Hz.

21. A pipe weld quality testing method for use in connection with welded pipe manufacturing apparatus and alternating induction weld annealing equipment, said method comprising the steps of:
- (a) generating alternating test eddy currents in a pipe subsequent to the induction annealing;
  
  (b) producing a signal indicating a defect in the pipe in response to a variation in said test eddy currents;
  
  (c) varying the frequency of the induction annealing field, and(d) adjusting the frequency of said test eddy currents as a function of the induction annealing field frequency.
- View Dependent Claims (22, 23, 24, 25, 26, 27, 28, 29, 30, 31)
- - 22. The method of claim 21, wherein:
    - said frequency adjustment step comprises maintaining said test eddy current frequency at a non-integral multiple of the induction annealing field frequency.
  - 23. The method of claim 22, wherein:
    - said frequency adjustment step comprises maintaining said test eddy current frequency at a multiple of approximately 4.5 times the induction annealing field frequency.
  - 24. The method of claim 21, further comprising the step of:
    - ultrasonically testing the pipe for defects.
  - 25. The method of claim 21, wherein:
    - (a) said detection step includes filtering electrical signals having frequencies lying outside of a predetermined pass band, and(b) said method further comprises the step of adjusting the pass band as a function of the induction annealing field frequency.
  - 26. The method of claim 25, wherein:
    - said pass band adjustment step comprises centering the pass band at approximately the eddy current test frequency.
  - 27. The method of claim 21, further comprising the step of:
    - refraining from execution of said frequency adjustment step for a predetermined time following turn on of said induction annealing equipment.
  - 28. The method of claim 21, further comprising the step of:
    - adjusting said exciter test eddy current frequency to a predetermined value in the absence of an induction annealing field frequency.
  - 29. The method of claim 21, further comprising the step of:
    - producing a signal indicating temperature of a tested region of the pipe.
  - 30. The method of claim 21, wherein:
    - said eddy current generation and defect detection steps are performed with respect to a region of a pipe having a temperature in excess of its Curie temperature.
  - 31. The method of claim 21, wherein said step of producing a defect indicating signal comprises:
    - producing indications of pipe flaws only in response to waveforms having predetermined polarity sequence characteristics.

32. A hot annealed pipe weld flaw detection method for use in connection with electrical induction weld annealing apparatus producing induction annealing fields at a first frequency, said method comprising the steps of:
- (a) producing eddy currents at varying locations in a pipe at a second frequency which is a non-integral multiple of said first frequency; and
  
  (b) producing indication of flaws in the pipe in response to variations in said test eddy currents.

33. A method for detecting defects in a metallic workpiece wherein the workpiece, during its production, is subject to acquisition of series of discrete similar defects spaced along a portion of the workpiece, said method comprising the steps of:
- (a) propelling a workpiece along the path extending past at least a portion of the detector system comprising a probe;
  
  (b) producing an indication of a defect each time a defect passes by the probe, and(c) producing a recurrent flaw indicating signal only in response to the recurrence of defect indications in a predetermined frequency range for a predetermined length of time.

34. A pipe weld flaw detection system for use in connection with welded pipe manufacturing apparatus incorporating circuitry and apparatus for induction annealing of pipe welds by the production of strong alternating electromagnetic fields in a region of the pipe weld, said flaw detection system comprising:
- (a) exciter circuitry adapted for generating alternating test eddy currents in a pipe at a carrier frequency;
  
  (b) circuitry, including a differentially wound detection coil, for detecting variation in eddy currents to produce a flaw indicating signal;
  
  (c) apparatus for moving a pipe along a path relative to and proximate the detection circuitry;
  
  (d) circuitry for varying the frequency of the induction annealing electromagnetic fields;
  
  (e) circuitry for adjusting the carrier frequency of said test eddy currents as a function of the induction annealing field frequency, said adjustment circuitry maintaining the carrier frequency at a non-integral multiple of the annealing frequency and approximately centered between successive harmonics of the annealing frequency;
  
  (f) signal verification circuitry responsive to only those flaw indicating signals having predetermined polarity sequence characteristics;
  
  (g) apparatus and circuitry for monitoring temperature of a pipe weld when located in the region of the detection coil;
  
  (h) an adjustable band pass filter coupled to said detection coil for reduction of interference;
  
  (i) circuitry responsive to the annealer frequency to maintain the pass band of the adjustable filter centered at approximately the carrier frequency;
  
  (j) a marker located downstream from said detection coil;
  
  (k) marker delay circuitry for actuating the marker capable of marking a workpiece at a predetermined delay increment following occurrence of a flaw indicating signal;
  
  (l) means for sensing velocity of relative movement between the detector coil and a workpiece, and(m) circuitry for adjusting the marker delay time as a function of said sensed velocity.

35. A system for detecting flaws in metallic workpieces, said system comprising:
- (a) a test probe;
  
  (b) apparatus capable of effecting relative motion between a workpiece and the test probe;
  
  (c) circuitry associated with the test probe for producing a flaw indicating signal modulated upon a carrier frequency in response to passage of a workpiece flaw past the test probe;
  
  (d) a demodulator coupled to said probe associated circuitry for detecting the flaw indicating signal;
  
  (e) an adjustable band pass electrical filter interposed between said demodulator and said associated circuitry, and(f) circuitry responsive to the carrier frequency for maintaining the pass band of the adjustable filter centered approximately upon the carrier frequency.

36. A weld flaw detection system for use in connection with welded workpiece manufacturing apparatus incorporating circuitry and apparatus for induction annealing of welds by the production of strong alternating electromagnetic annealing fields in a region of the weld and including means for adjusting the frequency of said strong alternating electromagnetic annealing fields, said flaw detection system comprising:
- (a) exciter circuitry capable of generating alternating test eddy currents in a workpiece at a carrier frequency;
  
  (b) detection circuitry including a demodulator for detecting variation in eddy currents to produce a flaw signal modulated on the carrier frequency indicating presence of a workpiece weld defect, and(c) regulation circuitry for adjusting the alternating carrier frequency of said test eddy currents as a function of the induction annealing field frequency.

37. A method of eddy current testing of metallic workpieces, said method comprising the steps of:
- (a) inducing eddy current flow in a workpiece by use of a test probe;
  
  (b) relatively moving the workpiece with respect to the probe along a path;
  
  (c) producing a workpiece flaw indication in response to a nonuniformity in the eddy currents, and(d) measuring the temperature proximate the tested region of the workpiece by sensing the resistivity of a portion of the workpiece independently of transmission of electromagnetic fields through said workpiece by the use of detector coil circuitry.
- View Dependent Claims (38)
- - 38. The method of claim 37, wherein said step of producing a defect indicating signal comprises:
    - producing indications of pipe flaws only in response to waveforms having predetermined polarity sequence characteristics.

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Current Assignee
LTV Steel Company, Inc. (LTV Corp.)
Original Assignee
Republic Steel Corp. (LTV Corp.)
Inventors
Janos, Wilbert J.
Primary Examiner(s)
Eisenzopf, Reinhard J.
Assistant Examiner(s)
NOT, DEFINED

Application Number

US06/636,301
Time in Patent Office

931 Days
Field of Search

324/228, 324/232, 324/234, 324/236, 324/237, 324/238, 324/239, 324/240, 324/242, 324/243, 324/225, 324/226, 324/227, 324/224, 324/233, 148/154, 266/103
US Class Current

324/240
CPC Class Codes

G01N 27/9046 by analysing electrical sig...

Hot annealed weld inspection

First Claim

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Abstract

39 Citations

38 Claims

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Hot annealed weld inspection

First Claim

2 Assignments

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0 Petitions

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Accused Products

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Abstract

39 Citations

38 Claims

Specification

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Solutions

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