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Online since: June 2013
Authors: Denis Mazuyer, Tarek Mabrouki, Joël Rech, Fabien Perrard, Enrico D'Eramo, Cédric Courbon
Materials Science and Engineering
A, 374(1-2):90 - 100, 2004
International Journal of Material Forming, 3:439-442, 2010
Journal of Materials Processing Technology, 122(2-3):322 - 330, 2002
Journal of Materials Processing Technology, 140(1-3):84 - 89, 2003
Advanced Materials Research, 223:286 - 295, 2011
International Journal of Material Forming, 3:439-442, 2010
Journal of Materials Processing Technology, 122(2-3):322 - 330, 2002
Journal of Materials Processing Technology, 140(1-3):84 - 89, 2003
Advanced Materials Research, 223:286 - 295, 2011
Online since: June 2019
Authors: Daniel Hülsbusch, Frank Walther, Patrick Striemann, Michael Niedermeier
Olmi, Experimental characterization and analytical modelling of the mechanical behavior of fused deposition processed parts made of ABS-M30, Computational Materials Science 79 (2013) 506-518
Holzer, Parametric optimization of intra- and inter-layer strengths in parts produced by extrusion-based additive manufacturing of poly(lactic acid), Journal of Applied Polymer Science 134 (2017) 1-15
Walther, Compression testing of additively manufactured continuous carbon fiber-reinforced sandwich structures, Materials Testing 60 (2018) 801-808
Renaud, Mechanical behavior of acrylonitrile butadiene styrene (ABS) fused deposition materials.
Experimental investigation, Rapid Prototyping Journal 7 (2001) 148-158.
Holzer, Parametric optimization of intra- and inter-layer strengths in parts produced by extrusion-based additive manufacturing of poly(lactic acid), Journal of Applied Polymer Science 134 (2017) 1-15
Walther, Compression testing of additively manufactured continuous carbon fiber-reinforced sandwich structures, Materials Testing 60 (2018) 801-808
Renaud, Mechanical behavior of acrylonitrile butadiene styrene (ABS) fused deposition materials.
Experimental investigation, Rapid Prototyping Journal 7 (2001) 148-158.
Online since: December 2013
Authors: Ji Tai Niu, Qiang Li, Peng Wang
Lavernia,”Processing Techniques for Particulate Reinforced Metal Aluminium Matrix Composites” Journal of Materials Science, 1991,26 (22): 5965–5978
Lavernia,”Particulate Reinforced Metal Matrix Composites—A Review” Journal of Materials Science, 1991,26(5): 1137–1156
[5] Lu Jin-Bin, MU Yun-Chao, LUO Xiang-Wei, Niu Ji-Tai, ”A new method for soldering particle-reinforced aluminum metal matrix” Materials Science and Engineering B, 2012,177(20): 1759- 1763
[8] FENG Tao, CHEN Xi-Zhang, WU Lu-Hai, LOU Song-Nian, ”Diffusion welding of SiCp/2014Al compositesusing Ni as interlayer” Journal of University of Science and Technology Beijing,Mineral,Metallurgy,Material, 2006,13(3): 267-271
Maitic,”Transient liquid phase diffusion bonding of 6061-15wt%SiCp in argon environment” Journal of Materials Processing Technology, 2009,209(7): 3568–3580
Lavernia,”Particulate Reinforced Metal Matrix Composites—A Review” Journal of Materials Science, 1991,26(5): 1137–1156
[5] Lu Jin-Bin, MU Yun-Chao, LUO Xiang-Wei, Niu Ji-Tai, ”A new method for soldering particle-reinforced aluminum metal matrix” Materials Science and Engineering B, 2012,177(20): 1759- 1763
[8] FENG Tao, CHEN Xi-Zhang, WU Lu-Hai, LOU Song-Nian, ”Diffusion welding of SiCp/2014Al compositesusing Ni as interlayer” Journal of University of Science and Technology Beijing,Mineral,Metallurgy,Material, 2006,13(3): 267-271
Maitic,”Transient liquid phase diffusion bonding of 6061-15wt%SiCp in argon environment” Journal of Materials Processing Technology, 2009,209(7): 3568–3580
Online since: February 2014
Authors: Zheng Yi Jiang, Xiaofeng He, Dong Bin Wei, Liang Luo
Tan: Fluid-Pressure-Assisted Deep Drawing, Journal of Materials Processing Technology, vol. 192–193 (2007) pp. 8-12
Estrin: Size Effects in Micro Cup Drawing, Materials Science and Engineering: A, vol. 550 (2012) pp. 312-319
Jiang: A Multi-Region Model for Numerical Simulation of Micro Bulk Forming, Journal of Materials Processing Technology, vol. 212 (2012) pp. 678-684
Geers: Size Effects from Grain Statistics in Ultra-Thin Metal Sheets, Journal of Materials Processing Tech, vol. 174 (2006) pp. 233-238
Lu: Study of Thickness and Grain Size Effects on Material Behavior in Micro-Forming, Journal of Materials Processing Technology, vol. 201 (2008) pp. 237-241
Estrin: Size Effects in Micro Cup Drawing, Materials Science and Engineering: A, vol. 550 (2012) pp. 312-319
Jiang: A Multi-Region Model for Numerical Simulation of Micro Bulk Forming, Journal of Materials Processing Technology, vol. 212 (2012) pp. 678-684
Geers: Size Effects from Grain Statistics in Ultra-Thin Metal Sheets, Journal of Materials Processing Tech, vol. 174 (2006) pp. 233-238
Lu: Study of Thickness and Grain Size Effects on Material Behavior in Micro-Forming, Journal of Materials Processing Technology, vol. 201 (2008) pp. 237-241
Online since: February 2014
Authors: Rosli Hussin, Nurhashimah Hassim, Wan Nurulhuda Wan Shamsuri, Nur Liyana Amiar Rodin, Karim Deraman, Bakar Ismail
The raw materials were ball milled for 20 hours and sintered at 1000°C.
Tainan: Materials Research Bulletin
Foundations of Materials Science and Engineering (4th Edition ed.).
Materials Science and Engineering B, 116-120
Journal of Alloys and Compounds , 3089-3095
Tainan: Materials Research Bulletin
Foundations of Materials Science and Engineering (4th Edition ed.).
Materials Science and Engineering B, 116-120
Journal of Alloys and Compounds , 3089-3095
Online since: June 2014
Authors: A. Nurulhuda, Arshad Azrina, Shaiful Anuar Ismail, Ali Rafidah, Yacob Suhaila
There have been growing interests in high temperature microwave for the processing of materials since the 1980’s [4].
Iuliano (2008), Microwave assisted sintering of green metal parts, Journal of Materials Processing Technology, vol 205, Issues 1-3, pg 489-496 [2] M.
Agrawal (2003), Microwave and conventional sintering of premixed and prealloyed Cu-12Sn Bronze, Journal of Science of Sintering, No. 35, 49-65
Agrawal (2005), Comparison between microwave and conventional sintering of WC/Co composites, Journal of Materials science and Engineering A 391, 285-295
Rao (2002), Microwave sintering of MoSi 2-SiC composites, Journal of Materials Science and Engineering A356, 267-273 [16] M.
Iuliano (2008), Microwave assisted sintering of green metal parts, Journal of Materials Processing Technology, vol 205, Issues 1-3, pg 489-496 [2] M.
Agrawal (2003), Microwave and conventional sintering of premixed and prealloyed Cu-12Sn Bronze, Journal of Science of Sintering, No. 35, 49-65
Agrawal (2005), Comparison between microwave and conventional sintering of WC/Co composites, Journal of Materials science and Engineering A 391, 285-295
Rao (2002), Microwave sintering of MoSi 2-SiC composites, Journal of Materials Science and Engineering A356, 267-273 [16] M.
Online since: December 2006
Authors: Su Juan Hua, Liu Ping, Dong Qi Ming, Li He Jun, Xu Ying Ying
Numerical Simulation of Residual Stress in Cu-Fe-P Alloy
Su Juan Hua
1,2
*, Liu Ping1 , Dong Qi Ming1, Li He Jun2 , Xu Ying Ying1
1 College of Material Science and Engineering,
Henan University of Science and Technology, Luoyang 471003,China;
2 College of Materials Science and Engineering,
Northwestern Polytechnical University, Xi'an 710072, China
*sujh@mail.haust.edu.cn
Keywords: fe particle density, cu-fe-p alloy, finite element method, residual stress
Abstract.
Refrtences [1] J H Su and Q M Dong, Materials Science and Enineering A392, 422 (2005) [2] F X Huang ,J S Ma and H L Ning, Materials Letters57, 2135(2003) [3] H.Y.
Lee, Materials Science and Engineering A311, 217 (2001) [4] M Motohisa, Journal of the Japan Copper and Brass Research Association29, 224(1990)
[5] E.Batawi, D.G.Morris, M.A.Morris, Materials Science and Technology6, 892(1999) [6] N.Y.Tang, N.M.Taplin, G.L.Dunlop, Materials Science and Technology1, 270(1985) [7] P Zhao, M Pecht, Microelectronics Reliability43, 775(2003) [8] G.
Chung, Engineering Structures26, 1249 (2004) [10] J L Bobet, J Lamon, Journal of Alloys and Compounds259, 260 (1997) [11] Y B Guo; M E Barkey, International Journal of Mechanical Sciences 46, 371 (2004) [12] Z H Jiang, J Lian, D Z Yang, Materials Science and Engineering A248, 256 (1998)
Refrtences [1] J H Su and Q M Dong, Materials Science and Enineering A392, 422 (2005) [2] F X Huang ,J S Ma and H L Ning, Materials Letters57, 2135(2003) [3] H.Y.
Lee, Materials Science and Engineering A311, 217 (2001) [4] M Motohisa, Journal of the Japan Copper and Brass Research Association29, 224(1990)
[5] E.Batawi, D.G.Morris, M.A.Morris, Materials Science and Technology6, 892(1999) [6] N.Y.Tang, N.M.Taplin, G.L.Dunlop, Materials Science and Technology1, 270(1985) [7] P Zhao, M Pecht, Microelectronics Reliability43, 775(2003) [8] G.
Chung, Engineering Structures26, 1249 (2004) [10] J L Bobet, J Lamon, Journal of Alloys and Compounds259, 260 (1997) [11] Y B Guo; M E Barkey, International Journal of Mechanical Sciences 46, 371 (2004) [12] Z H Jiang, J Lian, D Z Yang, Materials Science and Engineering A248, 256 (1998)
Online since: October 2013
Authors: Dan Wang, Rui Fan, Wu Yi Chen, Jiang Zhen Guo, Yong Sheng Sun
Introduction
Nowadays, material tests are mostly undertaken using machines which apply load and strain in tension, torsion, compression, shear or bending to material specimens or to whole manufactured components[1].
Material testing machines are mostly designed in uniaxial form[2].
For most of material testing machine, the accuracy may become a critical issue[6].
Acknowledgement The authors would like to thank National Science and Technology Major Project of the Ministry of Science and Technology of China (2012ZX04010-021) and Basic Scientific Research Funds of Beihang University (501LKGY2012107010) for financial support.
Tokuda: Journal of Biomechanics, Vol.39 (2006),p.104
Material testing machines are mostly designed in uniaxial form[2].
For most of material testing machine, the accuracy may become a critical issue[6].
Acknowledgement The authors would like to thank National Science and Technology Major Project of the Ministry of Science and Technology of China (2012ZX04010-021) and Basic Scientific Research Funds of Beihang University (501LKGY2012107010) for financial support.
Tokuda: Journal of Biomechanics, Vol.39 (2006),p.104
Online since: January 2022
Authors: Inomjon Tojiev
Materials and construction technologies are captured in these national monuments.
Tojiev, A mixture of ceramic bricks and blocks used in construction of mausoleum of Ismail Samani, Journal of Development of science and technology. 5 (2019) 82-87
Tojiev, Physical-chemical research of building materials of architectural monuments of Ancient Bukhara, Materials of the XIII International Scientific and Practical Conference.
Materials of the international symposium “Modern resource-saving materials and technologies: prospects and application”.
Tojiev, Creation of mortars, corresponding parameters to the original, Polish science journal. 1 (34) 2021.
Tojiev, A mixture of ceramic bricks and blocks used in construction of mausoleum of Ismail Samani, Journal of Development of science and technology. 5 (2019) 82-87
Tojiev, Physical-chemical research of building materials of architectural monuments of Ancient Bukhara, Materials of the XIII International Scientific and Practical Conference.
Materials of the international symposium “Modern resource-saving materials and technologies: prospects and application”.
Tojiev, Creation of mortars, corresponding parameters to the original, Polish science journal. 1 (34) 2021.
Online since: May 2014
Authors: Matthias Weiss, Bernard F. Rolfe, Akbar Abvabi, Joseba Mendiguren
Roll forming is used widely to form AHSS materials.
Kals, A process model for air bending, Journal of Materials Processing Technology, 57 (1996) 48-54
Sasaki, Evaluation of change in material properties due to plastic deformation, Journal of Materials Processing Technology, 151 (2004) 232-236
Li, Effect of the material-hardening mode on the springback simulation accuracy of V-free bending, Journal of Materials Processing Technology, 123 (2002) 209-211
Wagoner, Simulation of springback, International Journal of Mechanical Sciences, 44 (2002) 103-122.
Kals, A process model for air bending, Journal of Materials Processing Technology, 57 (1996) 48-54
Sasaki, Evaluation of change in material properties due to plastic deformation, Journal of Materials Processing Technology, 151 (2004) 232-236
Li, Effect of the material-hardening mode on the springback simulation accuracy of V-free bending, Journal of Materials Processing Technology, 123 (2002) 209-211
Wagoner, Simulation of springback, International Journal of Mechanical Sciences, 44 (2002) 103-122.