comparison of fmc/tfm and phased array ultrasonic … · paut thin wall in: iso 20601 • both...

© 2019 Eddyfi Technologies

COMPARISON OF FMC/TFM AND PHASED ARRAY

ULTRASONIC TESTING OF WELDS IN THIN WALLED

MATERIALS

CASPER WASSINK, EDDYFI & KAROLINA GALON, MISTRAS

Content

1. General introduction

2. ISO 20601 vs ISO DIS 23864

3. Procedure development

4. Testing results

5. Conclusions

ISO system structure

FMC/TFM in:

ISO DIS 23865 (general technique)

ISO DIS 23864 (weld testing)

PAUT thin wall in:

ISO 20601

• Both standards have same lower

Wall Thickness limit of 3.2mm

• Many textual similarities

WHERE ARE FMC/TFM AND PAUT?

FMC/TFM standardization status

FMC/TFM is now recognized within the NDT community

• More than a decade since first publications began to emerge

• Almost all papers at ECNDT 2018 in the Phased Array sessions were actually on

FMC/TFM

• each paper started with the same 5 minute explanation of how FMC/TFM works

• Confusion on name getting to an end: IWEX, SPA, TFM etc. basically all the same thing

• First standards have been developed

• ASME special working group on FMC, Paul Hayes (chair), Kimberley Hayes (vice chair)

• IIW working group on FMC/TFM, Daniel Chauveau (chair), Casper Wassink (vice chair)

• Significant exchange between the two committees

What is FMC

FMC: Full Matrix Capture

Pulse with one element, receive with all

Repeat until all elements are fired

N emitters

N r

eceiv

ers

What is TFM

TFM: Total Focussing Method

𝑠𝑛1 𝑡 … 𝑠𝑁1 𝑡…

1. Define a region of interest in the component

2. Time-of-flight calculation for all tx-rx combinations

Px

𝐸i 𝑅j

3. Amplitude extraction from each signal at time tij(P)

4. Sum of the N x N amplitudes

5. Perform the steps above for all pixels

N emitters

N r

eceiv

ers

𝑡𝑖𝑗 = 𝑡𝐸𝑖𝑃 + 𝑡𝑃𝑅𝑗

Aij

Px

Which time of flight?

WHAT PATH DO WE ASSUME FOR THE ULTRASOUND

ISO 20601 versus ISO DIS 23864 – 4. Testing levels

ISO 20601

MAIN DIFFERENCES REGARDING PROCEDURE DEVELOPMENT

ISO DIS 23864

Next slide

Testing level table ISO DIS 23864

KEEPING THE BALANCE BETWEEN TECHNIQUES

ISO 20601 versus ISO DIS 23864 – 6. Personnel and equipment

ISO 20601

6.1. skills listed as suggested by Phase A of

the KINT project for acceptance criteria

6.2.3. Suitable search unit frequency

MAIN DIFFERENCES REGARDING PROCEDURE DEVELOPMENT

ISO DIS 23864

6.1. General formulation regarding knowledge

needed

6.2.2. Suggested special resolution of image

6.2.3. General properties to take into consideration

7.2.2. Suggested imaging paths for defect types

ISO 20601 versus ISO DIS 23864 – 9. Gain Correction

ISO 20601

General TCG of DAC approach

MAIN DIFFERENCES REGARDING PROCEDURE DEVELOPMENT

ISO DIS 23864

Similar gain correction based on the TFM

image of the side drilled holes

Verification of the image grid

(ISO DIS 23865 annex C)

See also next slide

ISO DIS 23865 – grid verification

MOVING THE PROBE IN 0.1MM STEPS

33mm x 33mm grid, 5 MHz Probe

0.26mm grid increment (λ/5)

164mm x 164mm grid, 5 MHz Probe

0.64mm grid increment (λ/2)

0

20

40

60

80

100

120

0 0.2 0.4 0.6 0.8 1 1.2

Amplitude (λ/5 grid increment)

0

20

40

60

80

100

120

0 0.2 0.4 0.6 0.8 1 1.2

Amplitude (λ/2 grid increment)

Test setup

SAMPLE AND PROBES

3.2mm Wall Thickness

4” diameter

Olympus 10CCEV35 probes

10 MHz, 0.3mm pitch

Jireh Rotix chain scanner

Same probe position for PAUT

and FMC/TFM

Set-up dialog

TFM settings

Setting the region of interest

Defect 1

RT

Defect 1

PAUT

Defect 1

FMC/TFM

Defect 1

COMPARISON OF IMAGES

Defect 2

RT

Defect 2

PAUT

Defect 2

FMC/TFM

Defect 2

COMPARISON OF IMAGES

Defect 3

RT

Defect 3

PAUT

Defect 3

FMC/TFM

Defect 3

COMPARISON OF IMAGES

Conclusion

Standards for FMC/TFM are now available, ISO standard in DIS stage

In the standardization process, several properties of FMC/TFM are now

better understood

Setting up FMC/TFM to ISO DIS 23864 is straight forward

Even with a non-optimized setup, FMC/TFM creates images with much better

resolution than PAUT. This is a benefit for testing welds in low wall thickness

components