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International Journal of Material Forming

Erschienen in:

17.09.2016 | Original Research

Influences of temperature and grain size on the material deformability in microforming process

verfasst von: Zhengyi Jiang, Jingwei Zhao, Haina Lu, Dongbin Wei, Ken-ichi Manabe, Xianming Zhao, Xiaoming Zhang, Di Wu

Erschienen in: International Journal of Material Forming | Ausgabe 5/2017

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Abstract

This paper investigated the influences of temperature and grain size on the deformability of pure copper in micro compression process. Based on the dislocation theory, a constitutive model was proposed taking into account the influences of forming temperature, Hall-Petch relationship and surface layer model. Vacuum heat treatment was employed to obtain various grain sizes of cylindrical workpieces, and then laser heating method was applied to heat workpieces during microforming process. Finite element (FE) simulation was also performed, with simulated values agreed well with the experimental results in terms of metal flow stress. Both the FE simulated and experimental results indicate that forming temperature and grain size have a significant influence on the accuracy of the produced product shape and metal flow behaviour in microforming due to the inhomogeneity within the deformed material. The mechanical behaviour of the material is found to be more sensitive to forming temperature when the workpieces are constituted of fine grains.

Vorheriger Artikel Formability enhancement of Al 6060 sheets through fiber laser heat treatment

Nächster Artikel Free-stretch-blow investigation of poly(ethylene terephthalate) over a large process window

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Geiger M, Kleiner M, Eckstein R, Tiesler N, Engle U (2001) Microforming. CIRP Manuf Technol 50:445–462CrossRef

Vollertsen F, Schulze Niehoff H, Hu Z (2006) State of the art in micro forming. Int J Mach Tools Manuf 46:1172–1179CrossRef

Vollertsen F, Biermann D, Hansen HN, Jawahir IS, Kuzman K (2009) Size effects in manufacturing of metallic components. CIRP Manuf Technol 50:566–587CrossRef

Xie HB, Manabe K, Furushima T, Tada K, Jiang ZY (2016) An experimental and numerical investigation on micro rolling for ultra-thin strip. Int J Mater Form 9:405-412

Barbier C, Thibaud S, Richard F, Picart P (2009) Size effects on material behavior in microforming. Int J Mater Form 2(Suppl 1):625–628CrossRef

Arentoft M, Bruschi S, Ghiotti A, Paldan NA, Holstein JV (2008) Microforming of lightweight metals in warm conditions. Int J Mater Form 1(Suppl 1):435–438CrossRef

Chan WL, Fu MW, Lu J, Liu JG (2010) Modeling of grain size effect on micro deformation behaviour in microforming of pure copper. Mater Sci Eng A 527:6638–6648CrossRef

Zhao R, Han JQ, Liu BB, Wan M (2016) Interaction of forming temperature and grain size effect in micro/meso-scale plastic deformation of nickel-base superalloy. Mater Des 94:195–206CrossRef

Chang CC, Lin JC (2011) Influence of grain size and temperature on micro upsetting of copper. Key Eng Mater 450:149–152CrossRef

10.

Eichenhueller B, Egerer E, Engle U (2007) Microforming at elevated temperature - forming and material behaviour. Int J Adv Manuf Technol 33:119–124CrossRef

11.

Parasiz SA, Kinsey BL, Mahayatsanun N, Cao J (2011) Effect of specimen size and grain size on deformation in microextrusion. J Manuf Process 13:153–159CrossRef

12.

Xu J, Zhu X, Shan D, Guo B, Langdon TG (2015) Effect of grain size and specimen dimensions on micro-forming of high purity aluminum. Mater Sci Eng A 646:207–217CrossRef

13.

Wulfsberg JP, Terzi M (2007) Investigation of laser heating in microforming applying sapphire tools. Ann CIRP 56:321–326CrossRef

14.

Stachowicz F, Trzepiecinski T (2010) Warm forming of stainless steel sheet. Arch civ Mech Eng 4:85–94CrossRef

15.

Peng X, Qin Y, Balendra R (2004) Analysis of laser heating methods for micro-parts stamping applications. J Mater Process Technol 150:84–91CrossRef

16.

Sugioka K, Meunier M, Pique A (2010) Laser Precision Microfabrication. Springer, Verlag, Berlin

17.

Holtkamp J (2015) Laser-assisted micro-forming. In: Qin Y (ed) Micromanufacturing engineering and technology, 2nd edn. Elsevier, Netherlands, pp 347–364

18.

Samm K, Terzi M, Ostendorf A, Wulfsberg J (2009) Laser-assisted micro-forming process with miniaturised structures in sapphire dies. Appl Surf Sci 255:9830–9834CrossRef

19.

Edwards KR, Edwardson SP, Carey C, Dearden G, Watkins KG (2010) Laser micro peen forming without a tamping layer. Int J Adv Manuf Technol 47:191–200CrossRef

20.

Qin Y, Brockett A, Ma Y, Razali A, Zhao J, Harrison C, Pan W, Dai X, Loziak D (2010) Micro-manufacturing: research, technology outcomes and development issues. Int J Adv Manuf Technol 47:821–837CrossRef

21.

Hall EO (1951) Deformation and ageing of mild steel. Phys Soc Proc 64:747–753CrossRef

22.

Petch NJ (1953) The cleavage strength of polycrystals. J Iron Steel Inst 174:25–28

23.

Ashby MF (1970) The deformation of plastically non-homogenous materials. Philos Mag 21:339–424CrossRef

24.

Jiang ZH, Liang JS, Baudelet B (1995) A dislocation density approximation for the flow stress-grain relation of polycrystals. Acta Metall Mater 43:3349–3360CrossRef

25.

Gao CY, Zhang LC (2012) Constitutive modelling of plasticity of fcc metals under extremely high strain rate. Int J Plast 32–33:121–133CrossRef

26.

Engle U, Eckstein R (2002) Microforming-from basic research to its realization. J Mater Process Technol 125–126:35–44CrossRef

27.

Bergstrom D, Powell J, Kaplan AF (2007) The absorptance of non-ferrous alloys to Nd:YAG and Nd:YLF laser light at room temperature. Appl Opt 48:1290–1301CrossRef

28.

Bergstrom D (2008) The absorption of laser light by rough Metal Surfaces. Mid Sweden University, Sweden

29.

Hansen N, Ralph B (1982) The strain and grain size dependence of the flow stress of copper. Acta Mater 30:411–417CrossRef

30.

Zerilli FJ, Armstrong RW (1987) Dislocation-mechanics-based constitutive model for material dynamics calculation. J Appl Phys 5:1816–1825CrossRef

31.

Klepaczko JR, Chiem CY (1986) On rate sensitivity of fcc metals instantaneous rate sensitivity and rate sensitivity of strain hardening. J Mech Phys Solids 34:29–54CrossRef

32.

Arsenlisa A, Parksb DM, Beckera R, Bulatova VV (2004) On the evolution of crystallographic dislocation density in non-homogeneously deforming crystals. J Mech Phys Solids 52:1213–1246MathSciNetCrossRef

33.

Lu HN, Wei DB, Jiang ZY, Liu XH, Manabe KI (2013) Modelling of size effects in microforming process with consideration of grained heterogeneity. Comput Mater Sci 77:44–52CrossRef

34.

Fu HH, Benson DJ, Meyers MA (2001) Analytical and computational description of effect of grain size on yield stress of metals. Acta Mater 49:2567–2582CrossRef

35.

Geiger M, Geibdorfer S, Engle U (2007) Mesoscopic model: advanced simulation of micro-forming process. Prod Eng 1:79–84CrossRef

36.

Lennon AM, Ramesh KT (2004) The influence of crystal structure on dynamic behaviour of materials at high temperature. Int J Plast 20:269–290CrossRefMATH

37.

Qu F, Jiang Z, Lu H (2016) Analysis of micro flexible rolling with consideration of material heterogeneity. Int J Mech Sci 105:182–190CrossRef

38.

Cao J, Zhuang W, Wang S, Lin J (2010) Development of a VGRAIN system for CPFE analysis in micro-forming application. Int J Adv Manuf Technol 47:981–991CrossRef

39.

Evers LP, Brekelmans WAM, Geers MGD (2004) Non-local crystal plasticity model with intrinsic SSD and GND effects. J Mech Phys Solids 52:2379–2401CrossRefMATH

40.

Evers LP, Brekelmans WAM, Geers MGD (2004) Scale dependent crystal plasticity framework with dislocation density and grain boundary effects. Int J Solids Struct 41:5209–5230CrossRefMATH

41.

Farrokh B, Khan AS (2009) Grain size, strain rate, and temperature dependence of flow stress in ultra-fine grained and nanocrystalline Cu and Al: synthesis, experiment, and constitutive modelling. Int J Plast 25:715–732CrossRefMATH

Titel: Influences of temperature and grain size on the material deformability in microforming process
verfasst von: Zhengyi Jiang
Jingwei Zhao
Haina Lu
Dongbin Wei
Ken-ichi Manabe
Xianming Zhao
Xiaoming Zhang
Di Wu
Publikationsdatum: 17.09.2016
Verlag: Springer Paris
Erschienen in: International Journal of Material Forming / Ausgabe 5/2017
Print ISSN: 1960-6206
Elektronische ISSN: 1960-6214
DOI: https://doi.org/10.1007/s12289-016-1317-4

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