Acoustic Mapping of Discharges in EDM

Applications of Acoustic Mapping in Electrical Discharge Machining

Craig Smith, Philip KoshyMcMaster University

Canada

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Applications of acoustic mapping in EDMC. Smith, P. Koshy

63rd CIRP General AssemblyCopenhagen, August 20, 2013

Acoustic emission monitoring of EDM

Information gleaned from AE could constitute an important additional dimension in advancing intelligent adaptive process control

Relative to cutting, grinding and forming processes, little is known about acoustic emission (AE) in EDM

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Scope of present work

This work proves the concept of the acoustic mapping of discharges in EDM

(x,y)

XY

Application of the concept towards the estimation of electrode length in fast hole EDM, and workpiece height in wire EDM are demonstrated

practicalmachinist.comjauvtismp.com

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Kunieda & Kojima (1990)

current method

discharge

tool electrode

R1 R2

workpiece

branch 1 branch 2

current sensor 1 current sensor 2

Han & Kunieda (2008)

potential method

L1 L2

workpieceP1 P2

branch 1 branch 2

discharge

tool electrode

Previous work on discharge location: 1

electromagnetic method

Qiang et al (2002)

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Okada et al (2010)

high speed imaging

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Ydreskog & Novak (1989) Muto et al (1989)

t1

t2

acoustic emission method

AE sensor with a resonant frequency of 20 MHzSingle spark experiments that did not consider the superposition of AE from successive discharges

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Experimental

AE acquired @ 10 MHz

sensor 1 sensor 2

wire

wire and fast hole experiments were simulated on a sinker

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AE discharge location

AE sensor 2

wire

AE sensor 1

0 50 100 150 200

0.00.51.0

time (µs)

current signal

discharge

-2

sign

al v

olta

ge (V

)

02

-202

EMI

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Estimation of arrival time & time lag

-2

sign

al v

olta

ge (V

)

02

-202

0 50 100 150 200time (µs)

Estimation of arrival time and time lag with reference to preset voltage thresholds and cross-correlation, respectively, referred to location errors > 10 mm

arrival time

time lag

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AE frequency contentEMI AE

0.20

0 250 500 750 10000.00

0.05

0.10

0.15

frequency (kHz)

ampl

itude

(V)

0 250 500 750 10000.00

0.05

0.10

0.15

0.20

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Typical spectrogram

The peak in the spectrogram serves a consistent reference for the reliable estimation of arrival time

EMI AE

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Speed calibration

Propagation of AE entails shear, longitudinal and surface (Raleigh) wave modes that travel at different velocities; the sensor used responds to the latter twoUse of relative rather than absolute speeds enables the use of commercial AE sensors

3300 m/s

3452 m/s

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Electrode length estimation in fast hole EDM

estimation error ~1 mm

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Handling wave superposition

AE from discharges struck 12.9 µs apart

spectrogram

computed time lag 81.5 - 68.8 = 12.7 µs

power spectral density @ 300 kHz

PS

D (x

10-6

V2 /H

z)

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Superposed AE

0.0

0.3

0.6 current signal

1 2 3 4 5 6 7 8 9 10

105.8 µs

ton 1 µs; toff 10 µs

time (µs)0 50 100 150 200

-4-2024 AE sensor 2 169.1 µs

4161.9 µs

sign

al v

olta

ge (V

)

-4-202

AE sensor 1

0 50 100 150 200

Current spike

x1 (mm)

x2 (mm)

x1+ x2 (mm)

5 216.9 240.6 457.56 159.1 183.9 343.17 112.9 136.7 249.78 103.0 126.8 229.93

x1

x2

sensor 1

sensor 2

wire

250 mm

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Workpiece height identification in wire EDM

The envelope of discharge locations refers to the workpiece height in wire EDMIdentification of workpiece height is important for on-line process optimization

50 mm

90 mm

23 mm

actualw/p height

cumulativedistribution

histogram ofdetected locations

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Difficulties associated with handling the superposition of acoustic wavetrains from successive discharges have hitherto hindered the development of AE discharge locationThe maximum intensity in the spectrogram of the AE signal constitutes a reliable frame of reference for the determination of acoustic time lag, even when several signals are superposedThe proof-of-concept of the application of the determination of acoustic time lag in the estimation of electrode length and workpiece height in fast hole EDM and wire EDM, respectively, highlight the potential of the techniqueFundamental investigations into the nature of acoustic emission in EDM is warranted

Conclusions



Thank you for your kind attention!

Natural Sciences & Engineering Research Council of Canada

Canadian Network forResearch & Innovation in

Machining Technology