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Online since: August 2013
Authors: Lenka Kunčická, Radim Kocich
Journal of Materials Processing Technology. 2007; 187-188: 761–765
[4] M.
Materials Science and Engineering: A. 2013; 560: 787-791
Materials Science and Engineering: A. 2013; 560: 473-480
Materials Science and Engineering: A. 2011;528;4312-4317
Journal of Materials Science & Technology. 2011;27;7;633-640
Materials Science and Engineering: A. 2013; 560: 787-791
Materials Science and Engineering: A. 2013; 560: 473-480
Materials Science and Engineering: A. 2011;528;4312-4317
Journal of Materials Science & Technology. 2011;27;7;633-640
Online since: April 2022
Authors: Yao Wang, Wei Qiang, Shahrukh Khan, Foyjullah Sumon
Introduction
Fiber Metal Laminate (FMLs) materials are made of alternative stratums, including fiber-reinforced composite materials and metals.
These hybrid structures as materials can be utilized for different required properties using different materials constituents.
Materials and Design, 2011, 32: 3671-3685 [3] Vogelesang, L.B. and Vlot, A.
Journal of Materials Processing Technology, 2000, 103(1): 1-5 [4] Alderliesten R.
September 2012,Journal of Materials Processing Technology 212(9):1840-1849,DOI:10.1016/j.jmatprotec.2012.04.002
These hybrid structures as materials can be utilized for different required properties using different materials constituents.
Materials and Design, 2011, 32: 3671-3685 [3] Vogelesang, L.B. and Vlot, A.
Journal of Materials Processing Technology, 2000, 103(1): 1-5 [4] Alderliesten R.
September 2012,Journal of Materials Processing Technology 212(9):1840-1849,DOI:10.1016/j.jmatprotec.2012.04.002
Online since: February 2011
Authors: Mohamed Nor Sabirin, Mazdida Sulaiman, Azilah Abd Rahman
Wu: Materials Science Vol. 50 (2005), p. 881
[5] N.F.
Vanek: Journal of Materials Synthesis and Processing Vol. 8 (2000), p. 319 [6] N.F.
Park: Journal of Nuclear Materials Vol. 246 (1997), p. 131 [13] M.
Naskar: Journal of Materials Science Letters Vol. 22 (2003), p. 1747 [14] R.M.
Gupta: Journal of Material Science Vol. 34 (1999), p.1131
Vanek: Journal of Materials Synthesis and Processing Vol. 8 (2000), p. 319 [6] N.F.
Park: Journal of Nuclear Materials Vol. 246 (1997), p. 131 [13] M.
Naskar: Journal of Materials Science Letters Vol. 22 (2003), p. 1747 [14] R.M.
Gupta: Journal of Material Science Vol. 34 (1999), p.1131
Online since: May 2013
Authors: S.W. Puasa, M.S. Ruzitah, A.S.A.K. Sharifah
Materials and methods
Experimental materials.
De: Journal of Hazardous Materials Vol. 136 (2006), p. 972
Zhou: Journal of Hazardous Materials Vol. 173 (2010), p. 455
De: Journal of Colloid and Interface Science Vol. 285 (2005), p. 395
Xie: Journal of Environmental Sciences Vol. 24 (2012), p. 2068
De: Journal of Hazardous Materials Vol. 136 (2006), p. 972
Zhou: Journal of Hazardous Materials Vol. 173 (2010), p. 455
De: Journal of Colloid and Interface Science Vol. 285 (2005), p. 395
Xie: Journal of Environmental Sciences Vol. 24 (2012), p. 2068
Online since: April 2013
Authors: Mohd Imran Ghazali, Shahruddin Mahzan, Prasath Kesavan Prabagaran, Ahmad Mujahid Ahmad Zaidi, S. Kanna Subramaniyan
Experimental
Materials.
Energy absorption of structures and materials.
Journal of Achievements in Materials and Manufacturing Engineering 24 (1) (2007) 36 - 42
Materials and Design 30 (2009) 2393 - 2403
International Journal of Mechanical Sciences 43 (2001) 153 - 76
Energy absorption of structures and materials.
Journal of Achievements in Materials and Manufacturing Engineering 24 (1) (2007) 36 - 42
Materials and Design 30 (2009) 2393 - 2403
International Journal of Mechanical Sciences 43 (2001) 153 - 76
Online since: July 2012
Authors: Lin Hua, Yan Li Song, Shan Yang
Numerical Investigation of Fine Blanking of a Helical Gear
Shan Yang1,a, Lin Hua2,b, Yanli Song3,c
1 3School of Materials Science and Engineering, Wuhan University of Technology, Wuhan, Hubei, 430070, China
2Hubei Key Laboratory of Advanced Technology of Automotive Parts, Wuhan University of Technology, Wuhan, Hubei, 430070, China
ayangshan05@yahoo.cn, bhualin@whut.edu.cn, cyanlisong@whut.edu.cn
Keywords: Rotational fine blanking; helical gear; numerical simulation
Abstract.
Acknowledgements The authors would like to thank the Natural Science Foundation of China (No. 51105287), State Key Laboratory of Materials Processing and Die & Mould Technology, Huazhong University of Science and Technology (No. 2011-P05) and the Fundamental Research Funds for the Central Universities (No. 2011-IV-009) for the support given to this research.
Prediction of fineblanked surface characteristics using the finite element method (FEM), Journal of Materials Processing Technology, 198 (2008) 391-398
An investigation of material flow analysis in fineblanking process, Journal of Materials Processing Technology, 192-193 (2007) 237-242
Fineblanking of high strength steels: Control of material properties for tool life, Journal of Materials Processing Technology, 211 (2011) 717-728
Acknowledgements The authors would like to thank the Natural Science Foundation of China (No. 51105287), State Key Laboratory of Materials Processing and Die & Mould Technology, Huazhong University of Science and Technology (No. 2011-P05) and the Fundamental Research Funds for the Central Universities (No. 2011-IV-009) for the support given to this research.
Prediction of fineblanked surface characteristics using the finite element method (FEM), Journal of Materials Processing Technology, 198 (2008) 391-398
An investigation of material flow analysis in fineblanking process, Journal of Materials Processing Technology, 192-193 (2007) 237-242
Fineblanking of high strength steels: Control of material properties for tool life, Journal of Materials Processing Technology, 211 (2011) 717-728
Microstructure and Grain Abrasion Properties of Cr3C2-NiCr Coating Prepared by Laser Cladding Method
Online since: December 2012
Authors: Xin Zhi Li, Ming Ming Yuan, Cheng Yuan Zhong, Long Wei, Zong De Liu
Abrasion tests were performed to contrast the wear resistance of two materials.
It requires materials with excellent high temperature wear resistance.
At present, the alloy is still accepted as a good material to apply in industry to prolong the life of the materials.
Materials loss is in a small range in the process of abrasion.
Kuk: Metallurgical and Materials Transactions A Vol. 28A (1997), p. 1223
It requires materials with excellent high temperature wear resistance.
At present, the alloy is still accepted as a good material to apply in industry to prolong the life of the materials.
Materials loss is in a small range in the process of abrasion.
Kuk: Metallurgical and Materials Transactions A Vol. 28A (1997), p. 1223
Online since: September 2012
Authors: Jacques Desbrieres, Stephanie Reynaud, Pierre Marcasuzaa, Francis Ehrenfeld
Beppu, Evaluation of batch adsorption of chromium ions on natural and crosslinked chitosan membranes, Journal of Hazardous Materials 152 (2008) 1155-1163
[13] I.
Arvanitoyannis, Totally and partially biodegradable polymer blends based on natural and synthetic macromolecules: Preparation, physical properties, and potential as food packaging materials, Journal of Macromolecular Science – Reviews in macromolecular chemistry and Physics 39C (1999) 205-271 [14] C.
Adhikari, Polyaniline as a gas-sensor material, Materials and Manufacturing Processes 21 (2006) 263-270 [25] J.
Chen, Self-assembly of polyaniline-grafted chitosan/glucose oxidase nanolayered films for electrochemical biosensor applications, Journal of Materials Science 41 (2006) 4974-4977 [32] S.R.
Kim, Surprising shrinkage of expanding gels under an external load, Nature Materials 5 (2006) 48-51
Arvanitoyannis, Totally and partially biodegradable polymer blends based on natural and synthetic macromolecules: Preparation, physical properties, and potential as food packaging materials, Journal of Macromolecular Science – Reviews in macromolecular chemistry and Physics 39C (1999) 205-271 [14] C.
Adhikari, Polyaniline as a gas-sensor material, Materials and Manufacturing Processes 21 (2006) 263-270 [25] J.
Chen, Self-assembly of polyaniline-grafted chitosan/glucose oxidase nanolayered films for electrochemical biosensor applications, Journal of Materials Science 41 (2006) 4974-4977 [32] S.R.
Kim, Surprising shrinkage of expanding gels under an external load, Nature Materials 5 (2006) 48-51
Online since: October 2011
Authors: Lihua Liu, Shao Kun Zhang, Bin Yang
Introduction
Sometimes we need use the mechanical property of hyper-elastic materials, such as water seal of high pressure gate.
Hyper-elastic materials’ constitutive relations is nonlinear, and the state of stress and strain is very complicated, so there are many blank spaces in basic and regular research of it.
This paper describes the theoretical research of the relations from several aspects such as the principle of nonlinear calculation, the mechanical models, the method of model experiment, and have provided a numerical analysis method to fit the relations base on BP neural network. 1 The Constitutive Relations of Hyper-elastic Materials According to mechanics theory of elasticity, elastic materials’ constitutive relations can be described by primary stress tensor and primary strain tensor [1].Hyper-elastic materials can be thought as materials that their modulus of elasticity increase when their stress are increasing.
Seal use rubber material that is a typical hyper-elastic material.
,The decision-making supporting system (DSS) theory method cases [M].Tsinghua University; Science Technique in Guangxi Publishing House, 1996:133-140.
Hyper-elastic materials’ constitutive relations is nonlinear, and the state of stress and strain is very complicated, so there are many blank spaces in basic and regular research of it.
This paper describes the theoretical research of the relations from several aspects such as the principle of nonlinear calculation, the mechanical models, the method of model experiment, and have provided a numerical analysis method to fit the relations base on BP neural network. 1 The Constitutive Relations of Hyper-elastic Materials According to mechanics theory of elasticity, elastic materials’ constitutive relations can be described by primary stress tensor and primary strain tensor [1].Hyper-elastic materials can be thought as materials that their modulus of elasticity increase when their stress are increasing.
Seal use rubber material that is a typical hyper-elastic material.
,The decision-making supporting system (DSS) theory method cases [M].Tsinghua University; Science Technique in Guangxi Publishing House, 1996:133-140.
Online since: June 2012
Authors: Masato Enokizono, Taisuke Matsuda, Yuji Tsuchida
The FSES method can evaluate the electromagnetic properties in materials which were changed after induction heating.
Introduction High frequency induction heating is required to give materials the desired mechanical strength and the surface quality.
References [1] Ladislav Musil, Surface Induction Hardening Models Based on a Novel Computational Method of Artificial Change of Material Parameters, Journal of Materials Science Forum, Applied Electromagnetic Engineering, Vol. 670, December, 2010, p. 517-525
ENOKIZONO, Magnetic evaluation of hardening effect for carbon steel, Journal of Optoelectronics and Advanced Materials Vol. 10, No. 5, May 2008, p. 1078-1084
[7] Shoichiro Nagata, Masato Enokizono, NDE by means of frequency sweep excitation and spectrogram method, Journal of Optoelectronics and Advanced Materials Vol. 10, No. 5, May 2008, p. 1165-1168
Introduction High frequency induction heating is required to give materials the desired mechanical strength and the surface quality.
References [1] Ladislav Musil, Surface Induction Hardening Models Based on a Novel Computational Method of Artificial Change of Material Parameters, Journal of Materials Science Forum, Applied Electromagnetic Engineering, Vol. 670, December, 2010, p. 517-525
ENOKIZONO, Magnetic evaluation of hardening effect for carbon steel, Journal of Optoelectronics and Advanced Materials Vol. 10, No. 5, May 2008, p. 1078-1084
[7] Shoichiro Nagata, Masato Enokizono, NDE by means of frequency sweep excitation and spectrogram method, Journal of Optoelectronics and Advanced Materials Vol. 10, No. 5, May 2008, p. 1165-1168