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Powder Metallurgy Volume 43, 2000 - Issue 3
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Regular Papers

High pressure triaxial facility for powder compaction

I.C. SinkaThe Department of EngineeringUniversity of Leicester, University Road, Leicester, LE1 7RH, UK
,
A.C.F. CocksThe Department of EngineeringUniversity of Leicester, University Road, Leicester, LE1 7RH, UK
,
C.J. MorrisonThe Department of EngineeringUniversity of Leicester, University Road, Leicester, LE1 7RH, UK
&
A. LightfootThe Department of EngineeringUniversity of Leicester, University Road, Leicester, LE1 7RH, UK
Pages 253-262 | Published online: 19 Jul 2013

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L. C. R. Schneider & A. C. F. Cocks. (2002) Experimental investigation of yield behaviour of metal powder compacts. Powder Metallurgy 45:3, pages 237-245.
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Articles from other publishers (20)

A.R. Khoei, B. Khajehpour & A. Rezaei Sameti. (2022) Surface oxidization effect on the mechanical behavior of aluminum nanopowders under triaxial compression test. Applied Surface Science 606, pages 154907.
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Qiang Zhou, Shutao Song, Quanfang Chen & Yuanli Bai. (2021) Comprehensive Studies on Hot Compaction and Vibration-Assisted Compaction Tests of Aluminum Powder. Journal of Manufacturing Science and Engineering 143:1.
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R Ogawa, J Fujii & Y Taniguchi. (2020) Yield Parameters for Iron Powder Compaction on Different Particle Size. IOP Conference Series: Materials Science and Engineering 886:1, pages 012060.
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Alexander Krok & Chuan-Yu Wu. (2019) Evolutions of temperature and density during roll compaction of a pharmaceutical excipient. International Journal of Pharmaceutics 572, pages 118822.
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R Ogawa, T Yoshimura, N Yagi, K Mizuta & Y Taniguchi. (2019) Estimation of Yield Surface on Iron Powder Compaction for Finite Element Analysis using Drucker-Prager Cap Model. IOP Conference Series: Materials Science and Engineering 501, pages 012021.
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Mengcheng Zhou, Shangyu Huang, Jianhua Hu, Yu Lei, Yong Xiao, Bei Li, Shiwei Yan & Fangli Zou. (2017) A density-dependent modified Drucker-Prager Cap model for die compaction of Ag57.6-Cu22.4-Sn10-In10 mixed metal powders. Powder Technology 305, pages 183-196.
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Jürgen Almanstötter. (2015) A modified Drucker–Prager Cap model for finite element simulation of doped tungsten powder compaction. International Journal of Refractory Metals and Hard Materials 50, pages 290-297.
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Per LindskogDaniel C. AnderssonPer-Lennart Larsson. (2013) An Experimental Device for Material Characterization of Powder Materials. Journal of Testing and Evaluation 41:3, pages 20120107.
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C. Shang, I. C. Sinka & J. Pan. (2011) Constitutive Model Calibration for Powder Compaction Using Instrumented Die Testing. Experimental Mechanics 52:7, pages 903-916.
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M.M. Rahman, A.K. Ariffin, S.S.M. Nor & H.Y. Rahman. (2011) Powder material parameters establishment through warm forming route. Materials & Design 32:1, pages 264-271.
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Baosheng Zhang, Mukesh Jain, Chenghao Zhao, Michael Bruhis, Roger Lawcock & Kevin Ly. (2010) Experimental calibration of density-dependent modified Drucker-Prager/Cap model using an instrumented cubic die for powder compact. Powder Technology 204:1, pages 27-41.
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I.C. Sinka & A.C.F. Cocks. (2007) Constitutive modelling of powder compaction – II. Evaluation of material data. Mechanics of Materials 39:4, pages 404-416.
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Kendal Pitt & Csaba Sinka. 2007. Granulation. Granulation 735 778 .
Iosif Csaba Sinka, Kendal George Pitt & Alan Charles Francis Cocks. 2007. Particle Breakage. Particle Breakage 941 970 .
P. Doremus. 2007. Modelling of Powder Die Compaction. Modelling of Powder Die Compaction 77 93 .
R. S. RansingR. W. LewisD. T. Gethin. (2004) Using a deformable discrete–element technique to model the compaction behaviour of mixed ductile and brittle particulate systems. Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences 362:1822, pages 1867-1884.
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I.C Sinka, J.C Cunningham & A Zavaliangos. (2003) The effect of wall friction in the compaction of pharmaceutical tablets with curved faces: a validation study of the Drucker?Prager Cap model. Powder Technology 133:1-3, pages 33-43.
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David T Gethin, Roland W Lewis & Rajesh S Ransing. (2003) A discrete deformable element approach for the compaction of powder systems. Modelling and Simulation in Materials Science and Engineering 11:1, pages 101-114.
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I. C. Sinka, A. C. F. Cocks & J. H. Tweed. (2001) Constitutive Data for Powder Compaction Modeling. Journal of Engineering Materials and Technology 123:2, pages 176-183.
Crossref
Alan C.F. Cocks. (2001) Constitutive modelling of powder compaction and sintering. Progress in Materials Science 46:3-4, pages 201-229.
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