[MW:653] Re: 327] Re: AUT Vs TOFD

Dear all,

 

I have looked in detail on the ES Bean tool2 during my recent visit to Waterloo in Canada to meet Mr. Ginzel of Eclipse Scientific. The tool is both a reference guide for selecting the right probes and ensuring 100% weld coverage and also acts as a database where the content/test results can be stored for future comparative evaluation. Should anyone have a more specific question, i'd be happy to either respond directly or get Mr. Ginzel's opinion on the same.

 

TCR Engineering, the company I represent actually has its own custom designed tool to make rapid inspection scan plans as well as help/assist in probe selection. What our tool does not do is scanner selection. As anyone in this business will tell you, the selection of the right scanner is very important as well. There are a number of hand scannerrs, crawlers and large scanners out there.

 

Regards

Rohit Bafna

TCR Engineering

www.tcreng.com

On Tue, Mar 4, 2008 at 10:39 PM, Bathula Raghuram (Mumbai - PIPING) <R.Bathula@ticb.com> wrote:

Attached document is interesting "Ultrasonic Phased Array Inspection Technique Development Tools"

 

Members, if any body is using the software (ES Beam tool2) developed by www.eclipsescientific.com, please share your views on this.

 

 

 

-----Original Message-----
From: materials-welding@googlegroups.com [mailto:materials-welding@googlegroups.com] On Behalf Of Raghuram Bathula
Sent: Saturday, October 06, 2007 4:39 PM
To: Materials & Welding
Subject: [MW:327] Re: AUT Vs TOFD

 

 

It is obvious that considerable differences exist in the

standardization of ultrasound inspection on pipeline welds.

Differences in applied techniques, calibration procedures, acceptance

criteria and evaluation procedures are noted, when comparing standards

for longitudinal welds with those for girth welds, but also if

national standards are compared with European or other international

standards. With regard to the ultrasonic inspection of pipeline

girth welds it is necessary, to consider as well the various owner

specific standards, which if applicable on a pipeline project may

differ notably from other national or international standards for weld

inspection.

 

It must be the goal of any UT standardisation including the ultrasonic

inspection of girth welds, to specify the technical requirements (i.e.

probes, scanning, frequencies, quality level), the calibration

procedure and the acceptance level in such a manner, that definite

inspection results can be maintained, when an ultrasonic inspection is

performed in strict accordance with the specified requirements. It is

advisable to specify only such parameters

which can be met reliably. Calibration reflectors should be specified

such, that an easy manufacturing within limited manufacturing

tolerances can be maintained. To avoid discrepancies in reported

results, an unambiguous evaluation of UT signals should be specified

and it shouldn't be the case that individual interpretation leads to

operator dependent differences in the results.

 

In many cases ultrasonic inspection potentials are being claimed which

cannot be met. While ultrasonic inspection has proven its capability

to reliably detect and evaluate defects resulting in definite signal

response compared to a specified reference response, it failed to be a

measuring tool for defect sizes and positional values. Whatever

technique was applied and results were reported, it must be expected,

that sizing errors are in such a range as to be qualified as not

accurate.

 

Decision making based on obtainable size information from ultrasonic

inspection requires the comprehensive knowledge of expected defect

types and the respective method dependent sizing errors. In case of

ultrasonic inspections of anisotropic materials the majority of

physical laws to predict the physical interaction of ultrasound with

reflectors within an isotropic product are not further valid and

applicable.

 

For UT line scan techniques applied on unsisotropic materials, the

propagation of sound within the product, the beam field characteristic

and the associated physical interactions as reflectivity, directivity,

scattering, diffraction and mode conversions cannot be based upon

research or experimental results on isotropic materials. The inherent

variations of elastic properties and the resulting sound velocity

changes in thermo-mechanical rolled pipeline

materials caused by the process itself and the unavoidable variations

of manufacturing parameters does not allow reliable theoretical

predictions without practical investigations.

 

Before trusting an UT technique and method, it must be proven, that

all reflectors responses exceeding the specified acceptance criteria

(signal height and/or length) are reliable and repeatable obtained. If

any other property of a signal response such as distribution over

distance or associated transit times is

specified to be interpreted it is even more necessary, to analyse all

influences which may occur under practical conditions. A belief in

unproven physical interactions in line pipes may lead to unreliable UT

results which are useless for appropriate acceptance decisions. The

believes created such considerable differences that it is likely, that

the applied techniques were not capable of gaining the data required

and identical quality levels were not achieved, which means that

accept and reject decisions are UT technique respectively UT

company dependent.

 

The amount of publications including NDT company brochures convey the

impression, that with line scan UT and zonal approach height sizing is

a standard procedure and it is no problem, to obtain accurate values.

The top requirement found in this area was an allowable height sizing

tolerance of 0,3 mm to get accepted as a UT contractor. Such

statements compared

with the results gained from practical applications are most likely in

the position to discredit the application of ultrasonic inspection on

girth welds in general. It is advisable, to draw attention to all

limits of correlation for a NDT applied, rather than claiming beliefs

and not properly proven properties.

 

 

References

[1] AD Merkblatt HP 5/3,

[2] ASME Section VIII - Appendix 12 - ULTRASONIC EXAMINATION OF WELDS

(UT)

[3] EN 12062 : 1997, Non-destructive examination of welds - General

rules for metallic materials

[4] EN 1714 : 1997 + A1 : 2002, Non-destructive testing of welds -

Ultrasonic testing of welded joints

[5] EN 1712 : 1997 + A1 : 2002, Non-destructive testing of welds -

Ultrasonic testing of welded joints -Acceptance levels

[6] API SPECIFICATION 5L - FORTY-THIRD EDITION, MARCH 2004 -

Specification for Line Pipe

[7] EN 10208-2 : 1998, Steel pipes for pipe lines for combustible

fluids - Technical delivery conditions

- Part 2: Pipes of requirements class B

[8] EN 10246-9 : 2000, Non-destructive testing of steel tubes - Part

9: Automatic ultrasonic testing of the weld

seam of submerged arc-welded tubes for the detection of longitudinal

and/or transverse imperfections

[9] API STANDARD 1104 - NINETEENTH EDITION, SEPTEMBER 1999 - Welding

of Pipelines and Related Facilities

[10] ASTM E 164 - 03, "Standard Practice for Ultrasonic Contact

Examination of Weldments", American Society for Testing and Materials.

[11] API RECOMMENDED PRACTICE 2X, Fourth Edition, April 2004,

Recommended Practice for Ultrasonic and Magnetic Examination of

Offshore Structural Fabrication an Guidelines for Qualifications of

Technicians

[12] European Commision, Joint Research Center, Report SCI/LF/9912.061

- PHASE I: Current Status of the Inspection Methodologies

[13] Ginzel E.A., 2000, "Mechanized Ultrasonic Inspections of Pipeline

Girth Welds - A Brief History", NDT.net, 2000, Vol 5. No. 03

[14] A.G. Glover, D.V. Dorling, R.I. Coote, Inspection and assessment

of mechanized pipeline girth welds, Proceedings of the International

Conference on weld failures, London, 1988

[15] B. Gross, J. O'Beirne, B. Delanty, "Comparison of radiographic

and ultrasonic inspection methods on mechanized girth welds", Pipeline

Technology Conference, October 1990, Oostende, Belgium

[16] A. Glover, D. Hodgkinson, D. Dorling, "The application of

mechanized ultrasonic inspection and alternative acceptance criteria

to pipeline girth welds", Pipeline Technology Conference, October

1990, Oostende,

Belgium

[17] J.A.de Raad, "High Speed Ultrasonic Inspection of Field Girth

Welds During Pipeline Construction", Pipeline Technology Conference,

Ostende, Belgium, 1990

[18] E.Ginzel & R.Ginzel, B.Gross, M.Hoff, P.Manuel, Developments in

Ultrasonic Inspection for Total Inspection of Pipeline Girth Welds,

8th Symposium on Pipeline Research, Houston, Texas, August 1993

[19] Helmut Heckhäuser, HerbertRichter, LIMITS OF CORRELATION BETWEEN

DEFECT DEPTHS AND INDICATION HEIGHTS TESTING STEAM GENERATOR TUBING BY

ULTRASONIC TEST METHODS, Proceedings of the third International

Conference on NDE IN THE NUCLEAR INDUSTRY 1980

[20] H. Heckhäuser and S. Schultz, "Advanced Technology in Automated

Ultrasonic Weld Inspection of Pipeline Girth Welds", Insight, vol 37,

no 6, June 1995

[21] Scott Lebsack and Helmut Heckhäuser, "Immersion Probe Arrays for

Rapid Pipeline Weld Inspection", Materials Evaluation / August 1995

[22] M. Wächter, M. Gräf, JP. Mullie and H. Schneider, Modern computer

controlled ultrasonic weld inspection system for large diameter line

pipe at EUROPIPE, Pipeline Technology, Volume II, 1995,

Elsevier Science B.V., Europipe Technical publications, EP/TP 09/95 en

[23] A. Erhard, H. Wuestenberg, G. Engl, J. Kutzner, RELIABILITY AND

REDUNDANCY IN ULTRASONIC FLAW SIZING METHODS, Proceedings of the third

International Conference on NDE IN THE NUCLEAR INDUSTRY 1980

[24] N.F. Haines, S. Crutzen, C.J. Vinche, A REVIEW OF THE MAJOR PISC

II ROUND ROBIN TEST RESULTS ; British Journal of NDT, November 1987

[25] George J. Gruber, W.R. Schick, CHARACTERIZATION OF FLAWS IN

PIPELINE GIRTH WELDS AND AUSTENITIC PIPING WELDS USING SATELLITE

PULSES, Proceedings 6th International Conference on NDE IN THE NUCLEAR

INDUSTRY 1983

[26] C.A. Boothroyd, G.G. Garrett, ULTRASONIC DETECTION VARIABILITY OF

WELD DEFECTS AND THE EFFECT ON FRACTURE MECHANICS PREDICTIONS - AN

EXPERIMENTAL ASSESSMENT, Proceedings 6th International Conference on

NDE IN THE NUCLEAR INDUSTRY 1983

[27] Edward A. Ginzel and Robert K. Ginzel, Study of Acoustic Velocity

Variations in Line Pipe Steel, Materials Evaluation - May 1995

[28] D.S. Kupperman and K.J. Reimann, DEVIATION OF LONGITUDINAL AND

SHEAR WAVES IN AUSTENITIC STAINLESS STEEL WELD METAL, Proceedings of

the third International Conference on NDE IN THE NUCLEAR INDUSTRY 1980

[29] J.L. Thomson, J.M. Farley, ULTRASONIC EXAMINATION OF AUSTENITIC

WELDS: THEORETICAL AND PRACTICAL CONSIDERATIONS, Proceedings 6th

International Conference on NDE IN THE NUCLEAR INDUSTRY 1983

 

On Oct 5, 5:56 pm, "RAGHAVENDRA PEMMARAJU" <r...@hzw.ltindia.com>

wrote:

> Can any one from our group respond to explain what is the difference between AUT ( generally used in piping) and TOFD ( as per CC2235-9) used on pressure vessels manufactured as per ASME Sec VIII div.1 or2.

> 

> As per me, there is a difference in the techniques used as per AUT and as per TOFD alone.

> 

> kindly explain. A reply from Mr.Rohit Bafna shall be highly appreciable.

> 

> regards

 

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