nach oben

Experimental Mechanics

Erschienen in:

12.02.2018

Strain Localization in Mild (Low Carbon) Steel Observed by Acoustic Emission - ESPI Coupling during Tensile Test

verfasst von: J. Petit, G. Montay, M. François

Erschienen in: Experimental Mechanics | Ausgabe 5/2018

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Two strain localization modes: the Piobert-Lüders band propagation and the development of necking, were investigated in uniaxial tensile tests for a low alloyed and low carbon steel. These two macroscopic localization phenomena were simultaneously monitored by speckle interferometry (ESPI) and acoustic emission (AE). The coupling of these two experimental techniques gives complementary information about strain localization features and mechanisms. For Lüders bands, it was found that the acoustic activity heard during the travel of the Piobert-Lüders band varies in closely correlated to the tensile force fluctuations, the relations between strain rate, band velocity, band width and plastic strain were investigated. Although the strain rate in the wake of the wave front is not always zero, the acoustic activity remains concentrated in the wave front itself. For necking, the acoustic activity is found to decrease regularly through the homogeneous plasticity stage and the diffuse necking stage and then increases when the localized necking starts, while ESPI patterns show a gradual strain concentration.

Vorheriger Artikel Asymptotical Correction to Bottom Substrate Effect Arising in AFM Indentation of Thin Samples and Adherent Cells Using Conical Tips

Nächster Artikel Multicycle Indentation for Evaluation of Polymer Material Viscoelastic Characteristics

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Hähner P (1994) Theory of solitary plastic waves – part I: Lüders bands in polycrystals. Appl Physics A Solids Surf 58:41–48CrossRef

Wattrisse B, Chrysochoos A, Muracciole J-M, Némoz-Gaillard M (2001) Kinematic manifestations of localisation phenomena in steels by digital image correlation. Eur J Mech A Solids 20:189–211CrossRefMATH

Plekhov OA, Naimark OB, Saintier N, Palin-Luc T (2009) Elastic–plastic transition in iron: structural and thermodynamic features. Tech Phys 54(8):1141–1146CrossRef

Shabadi R, Kumar S, Roven HJ, Dwarakadasa ES (2004) Characterisation of PLC and parameters using laser speckle technique. Mater Sci Eng A 364:140–150CrossRef

Neuhäuser H, Klose FB, Hagemanna F, Weidenmüller J, Dierke H, Hähner P (2004) On the PLC effect in strain-rate and stress-rate controlled tests–studies by laser scanning extensometry. J Alloys Compd 378:13–18CrossRef

Klose FB, Hagemann F, Hähner P, Neuhäuser H (2004) Investigation of the Portevin-le Châtelier effect in al-3wt.%mg alloys by strain-rate and stress-rate controlled tensile tests. Mater Sci Eng A 387–389:93CrossRef

Jiang Z, Zhang Q, Jiang H, Chen Z, Wu X (2005) Spatial characteristics of the Portevin-le Chatelier deformation bands in al-4 at%cu polycrystals. Mater Sci Eng A 403:154–164CrossRef

Dierke H, Krawehl F, Graff S, Forest S, Săchl J, Neuhäuser H (2007) Portevin–le Chatelier effect in al–mg alloys: influence of obstacles – experiments and modelling. Comput Mater Sci 39:106–112CrossRef

N. Ranc, D. Wagner (2008) Experimental study by pyrometry of Portevin–Le Châtelier plastic instabilities − Type A to type B transition. Mater Sci Eng A, 474(1–2):188–196

10.

Min J, Hector LG, Carsley JE, Stoughton TB, Carlson BE, Lin J (2015) Spatio-temporal characteristics of plastic instability in AA5182-O during biaxial deformation. Mater Des 83:786–794CrossRef

11.

Cottrell AH, Bilby BA (1948) Dislocation theory of yielding and strain ageing of iron. Proc Phys Soc 62:49–62CrossRef

12.

Lomer WM (1952) The yield phenomenon in polycrystalline mild steel. J Mech Phys Solids 1:64–73CrossRef

13.

Johnston WG, Gilman JJ (1959) Dislocation velocities, dislocation densities, and plastic flow in lithium fluoride crystals. J Appl Phys 30:129–144CrossRef

14.

Butler JF (1962) Lüders front propagation in low carbon steels. J Mech Phys Solids 10:313–334CrossRef

15.

Hall EO (1970) Yield point phenomena in metals and alloys. Plenum Press, New YorkCrossRef

16.

Zhang J, Jiang Y (2005) Lüders bands propagation of 1045 steel under multiaxial stress state. Int J Plast 21(3):651–670CrossRefMATH

17.

Coër J, Manach PY, Laurent H, Oliveira MC, Menezes LF (2013) Piobert–Lüders plateau and Portevin–le Chatelier effect in an al–mg alloy in simple shear original research. Mech Res Commun 48:1–7CrossRef

18.

Sun HB, Yoshida F, Ohmori M, Ma X (2003) Effect of strain rate on Lüders band propagating velocity and Lüders strain for annealed mild steel under uniaxial tension. Mater Lett 57(29):4535–4539CrossRef

19.

Hutanu R, Clapham L, Rogge RB (2005) Intergranular strain and texture in steel Lüders bands. Acta Mater 53(12):3517–3524CrossRef

20.

Louche H, Chrysochoos A (2001) Thermal and dissipative effects accompanying Lüders band propagation. Mater Sci Eng A 307(1–2):15–22CrossRef

21.

Considère A (1885) Mémoire sur l’Emploi du Fer et de l’Acier dans les Constructions. Annales des Ponts et Chaussées 9:574–775

22.

Swift HW (1952) Plastic instability under plane stress. J Mech Phys Solids 1:1–18CrossRef

23.

Hill R (1952) On discontinuous plastics states, with special reference to localized necking in thin sheets. J Mech Phys Solids 1:19–30MathSciNetCrossRef

24.

Rudnicki JW, Rice JR (1975) Conditions for the localization of deformation in pressure-sensitive dilatant materials. J Mech Phys Solids 23:371–394CrossRef

25.

Chien WY, Pan J, Tang SC (2004) A combined necking and shear localization analysis for aluminium sheets under biaxial stretching conditions. Int J Plast 20:1953–1981CrossRefMATH

26.

Dunand M, Mohr D (2010) Hybrid experimental–numerical analysis of basic ductile fracture experiments for sheet metals. Int J Solids Struct 47:1130–1143CrossRefMATH

27.

Mellor PB (1956) Stretch forming under fluid pressure. J Mech Phys Solids 5(1):41–56CrossRef

28.

Mahmudi R (1996) Plastic instability in equi-biaxial deformation of aluminium alloy sheet. J Mater Process Technol 57:266–271CrossRef

29.

Marciniak Z, Kuczyński K (1967) Limit strains in the processes of stretch-forming sheet metal. Int J Mech Sci 9:609–620CrossRefMATH

30.

D. Banabic, H.-J. Bunge, K. Pöhlandt A.E. Tekkaya (2000) Formability of metallic materials, Engineering Materials, Springer, Berlin

31.

Guelorget B, François M, Vial-Edwards C, Montay G (2006) Strain rate measurement by ESPI: a new look at the strain localization onset. Mater Sci Eng A 415:234–241CrossRef

32.

Labergère C, Guelorget B, François M (2014) Strain rate distribution and localization band width evolution during tensile test. Int J Solids Struct 51:3944–3961CrossRef

33.

Montay G, François M, Tourneix M, Guelorget B, Vial-Edwards C, Lira I (2007) Analysis of plastic strain localization by a combination of the speckle interferometry with the bulge test. Opt Lasers Eng 45:222–228CrossRef

34.

Montay G, François M, Tourneix M, Guelorget B, Vial-Edwards C, Lira I (2007) Strain and strain rate measurement during the bulge test by electronic speckle pattern interferometry. J Mater Process Technol 18:428–435CrossRef

35.

Wang ZJ, Liu Y (2010) Investigation on deformation behavior of sheet metals in viscous pressure bulging based on ESPI. J Mater Process Technol 210:1536–1544CrossRef

36.

Ding L, Lin JP, Min JY, Pang Z, Ye Y (2013) Necking of Q&P Steel during uniaxial tensile test with the aid of DIC technique. Chin J Mech Eng 26:1–6CrossRef

37.

Tvergaard V (1993) Necking in tensile bars with rectangular cross-section. Comput Methods Appl Mech Eng 103:273–290CrossRef

38.

Petit J, Montay G, François M (2014) Strain rate measurements by speckle interferometry for necking investigation in stainless steel. Int J Solids Struct 51:540–550CrossRef

39.

Bao C, Francois M, Le Joncour L (2015) Influence of specimen geometry on strain localization phenomena in steel sheets. Appl Mech Mater 784:514–519CrossRef

40.

Petit J, Montay G, Francois M (2011) Localisation phenomenon investigation on SMATed stainless steel samples by speckle interferometry. Strain 47:363–371CrossRef

41.

Richefeu V, Chrysochoos A, Huon V, Monerie Y, Peyroux R, Wattrisse B (2012) Toward local identification of cohesive zone models using digital image correlation. Eur J Mech A Solids 34:38–51CrossRef

42.

Akhmetzyanov M, Albaut G (2004) Study of large plastic strains and fracture in metal elements by photoelastic coating method. Int J Fract 128:223–231CrossRefMATH

43.

Chrysochoos A, Louche H (2000) An infrared image processing to analyse the calorific effects accompanying strain localization. Int J Eng Sci 38:1759–1788CrossRef

44.

Creath K (1985) Phase-shifting speckle interferometry. Appl Opt 24(18):3053–3058CrossRef

45.

Guelorget B, François M, Montay G (2009) Strain localization band width evolution by electronic speckle pattern interferometry strain rate measurement. Scr Mater 60(8):647–650CrossRef

46.

Bao C, François M, Le Joncour L (2016) A closer look at the diffuse and localized necking of a metallic thin sheet evolution of the two bands pattern. Strain 52:244–260CrossRef

47.

Murav’ev TV, Zuev LB (2008) Acoustic emission during the development of a Lüders band in a low-carbon steel. Tech Phys 53(8):1094–1098CrossRef

48.

Sachse W, Yamaguchi K, Roget J (1991) Acoustic emission: current practice and future directions. ASTM Spec Tech Publ 1077:45

49.

Malen K, Bolin L (1974) A theoretical estimate of acoustic emission stress amplitudes. Phys Status Solidi B 61:645–697CrossRef

50.

Hsu NN, Simmons JA, Hardy SC (1977) An approach to acoustic emission signal analysis. Theory and experiment. Mater Eval 95:100–106

51.

Scruby CB, Wadley HNG, Hill JJ (1983) Dynamic elastic displacement at tile surface of an elastic half-space due to defect sources. J Phys D Appl 16:1069–1083CrossRef

52.

Rouby D, Fleischmann P, Duvergier C (1983) Un modèle de source d'émission acoustique pour l'analyse de l'émission continue et de l'émission par salves. Philos Mag A 47:671–687 and 689–705

53.

Gillis PP (1972) Acoustic emission. ASTM Spec Tech Publ 505:20

54.

Fitzgerald ER (1960) Mechanical resonance dispersion and plastic flow in crystalline solids. J Acoust Soc Am 32:1270

55.

James DR, Carpenter SH (1971) Relationship between acoustic emission and dislocation kinetics in crystalline solids. J Appl Phys 42:4685

56.

Fleischmann P, Lakestani F, Baboux JC (1977) Analyse Spectrale et Energétique d'une Source Ultrasonore en Mouvement – Application à l'Emission Acoustique de l'Aluminium soumis à Déformation Plastique. Mater Sci Eng 29:205–212CrossRef

57.

Kotoul M, Bilek Z (1990) Acoustic emission during deformation and crack loading in structural steels. Int J Press Vessel Pip 44:291–307CrossRef

58.

Sehofield BH (1964) ASD-TDR-63-509, part II. Lessels and Associates, Waltham Massachusetts

59.

Tetelman AS, Chow R. (1972) Acoustic emission testing and microcracking processes. Am Soc Test Mater Spec Publ 505, p. 30

60.

Deschanel S, Ben Rhouma W, Weiss J (2013) Study of dislocation and fracture dynamics during fatigue of aluminum from acoustic emission data. Proceedings of ICF13, Session: Statistical Physics and Fracture, Beijing

61.

Baram J, Rosen M (1979) Acoustic emission generated during the tensile testing of Aluminium alloys. Mater Sci Eng 40:21–29CrossRef

62.

Akbari, M, Ahmadi, M. (2009) The application of acoustic emission technique to plastic deformation of low carbon steel. Physics Procedia, 2010, 3:795–801, from International Congress on Ultrasonics, Universidad de Santiago de Chile

63.

Nikitin ES, Semukhin BS, Zuev LB (2008) Localized plastic flow and spatiotemporal distribution of acoustic emission in steel. Tech Phys Lett 34(8):666–667

64.

Fleischmann P (1979) Etude par émission acoustique des propriétés dynamiques des dislocations. Application à la déformation plastique de l’aluminium. PhD Thesis, INSA de Lyon, p. 141

65.

R. Jones, C. Wykes (1989) Holographic and speckle interferometry, 2^nd edn. vol. 6, Cambridge Studies in Modern Optics, Cambridge University Press, Cambridge

66.

Cloud G (1995) Optical methods of engineering analysis. Cambridge University Press, NYCrossRef

67.

Petit J, Wagner D, Ranc N, Montay G, François M (2013) Comparison of different techniques for the monitoring of the Lüders bands development. Proceedings of ICF13, Session: Plasticity, Beijing

68.

Jacquot P (2008) Speckle interferometry: a review of the principal methods in use for experimental mechanics applications. Strain 44:57–69CrossRef

69.

Ghiglia DC, Romero LA (1996) Minimum Lp-norm two-dimensional phase unwrapping. Opt Soc Am 13:1999–2013CrossRef

70.

Petit J (2010) Elastic-plastic behaviour and strain localisation – Multi-scale study by ESPI and acoustic emission. PhD Thesis, University of Technology of Troyes

71.

Haneef T, Lahiri BB, Bagavathiappan S, Mukhopadhyay CK, Philip J, Rao BPC, Jayakumar T (2015) Study of the tensile behavior of AISI type 316 stainless steel using acoustic emission and infrared thermography techniques. J Mater Res Technol 4(3):241–253CrossRef

72.

Mielnik EM (1996) Metalworking science and engineering, McGraw-Hill, pages 156 to 160

73.

Maziere M, Forest S (2015) Strain gradient plasticity modeling and finite element simulation of Luders band formation and propagation. Contin Mech Thermodyn 27(1–2):83–104MathSciNetCrossRefMATH

74.

Zhu Y, Vaillant J, François M, Montay G, Bruyant A (2017) Co-axis digital holography based on sinusoidal phase modulation using generalized lock-in detection. Appl Opt 56(13):F97–F104CrossRef

Titel: Strain Localization in Mild (Low Carbon) Steel Observed by Acoustic Emission - ESPI Coupling during Tensile Test
verfasst von: J. Petit
G. Montay
M. François
Publikationsdatum: 12.02.2018
Verlag: Springer US
Erschienen in: Experimental Mechanics / Ausgabe 5/2018
Print ISSN: 0014-4851
Elektronische ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-018-0379-2

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 5/2018

Application of Moiré Interferometry to the Characterization of Orthotropic Materials in the Antisymmetric Configuration using the Virtual Fields Method

Multicycle Indentation for Evaluation of Polymer Material Viscoelastic Characteristics

Experimental Study of the Effect of Temperature on Strength and Extensibility of Rubberlike Materials

A Robust in situ TEM Experiment for Characterizing the Fracture Toughness of the Interface in Nanoscale Multilayers

Boundary Effects in the Eigenstrain Method

Full-Field Surface 3D Shape and Displacement Measurements Using an Unfocused Plenoptic Camera

Premium Partner

Marktübersichten