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Online since: July 2018
Authors: Marina Polyakova, Yulia Efimova
Liskova, “Analysis of pearlitic cold drawn steel wire”, Materials Science Forum, vol. 818, 2015, pp. 288-291, doi:10.4028/www.scientific.net/MSF.818.288
Jiang, “Deformation of dual-structure medium carbon steel in cold drawing”, Materials Science and Engineering A, vol. 583, 2013, pp. 78-83, doi: 10.1016/j.msea.201306.081
Li, “Structure evolution in steel wires during drawing”, Advanced Materials Research, vols. 194-196, 2011, pp. 218-223
Jarl, “Mechanical descaling of wire rod using reverse bending and brushing” Journal of Materials Processing Technology, vol. 172, iss. 3, 2006, pp. 332-340, doi: 10.1016/j.jmatprotec.2005.10.014
Tidu, “Influence of torsion deformation on microstructure of cold-drawn pearlitic steel wire”, Journal of Materials Science, vol. 43, 2008, pp. 1241-1248, doi: 10.1007/s10853-007-2272-8
Jiang, “Deformation of dual-structure medium carbon steel in cold drawing”, Materials Science and Engineering A, vol. 583, 2013, pp. 78-83, doi: 10.1016/j.msea.201306.081
Li, “Structure evolution in steel wires during drawing”, Advanced Materials Research, vols. 194-196, 2011, pp. 218-223
Jarl, “Mechanical descaling of wire rod using reverse bending and brushing” Journal of Materials Processing Technology, vol. 172, iss. 3, 2006, pp. 332-340, doi: 10.1016/j.jmatprotec.2005.10.014
Tidu, “Influence of torsion deformation on microstructure of cold-drawn pearlitic steel wire”, Journal of Materials Science, vol. 43, 2008, pp. 1241-1248, doi: 10.1007/s10853-007-2272-8
Online since: May 2011
Authors: Heng Quan, Zhen Ya Gu
Kim: Journal of materials science Vol. 35 (2000), p. 1579-1583
[4] A.
Jack et al: Journal of Applied Polymer Science Vol. 102 (2006), p. 128-139 [12] J.R.
Chen: Journal of Applied Science Vol. 69 (1998), p. 1563-1574 [13] G.
Lam: Journal of Applied Polymer Science Vol. 50 (1993) p. 1041-1058 [14] W.J.
Yang et al: Materials Letters Vol. 60 (2006), p. 3686- 3692 [15] G.R.
Jack et al: Journal of Applied Polymer Science Vol. 102 (2006), p. 128-139 [12] J.R.
Chen: Journal of Applied Science Vol. 69 (1998), p. 1563-1574 [13] G.
Lam: Journal of Applied Polymer Science Vol. 50 (1993) p. 1041-1058 [14] W.J.
Yang et al: Materials Letters Vol. 60 (2006), p. 3686- 3692 [15] G.R.
Online since: January 2006
Authors: Jui Chang Lin, K.S. Lee, Ming Fang Lu, Chia Ming Yen, Shen Yung Lin
Wang, CAD of Mold cooling in injection Mold Using a Three-dimension Numerical Simulation, Journal of Manufacturing Science and Engineering, 144,
p.p. 213-221, 1992
Wang, CAD of Mold cooling in injection Mold Using a Three-dimension Numerical Simulation, Journal of Manufacturing Science and Engineering, 144, p.p. 213-221, 1992
Park, Thermal and Design Sensitivity Analyses for Cooling System of Injection Mold, Part I: Thermal Analysis, Journal of Manufacturing Science and Engineering, 120, p.p. 287-295, 1998
Tai, J.C Lin, The optimal position for the injection gate of a die-casting die, Journal of Materials Processing Technology, 86, pp.87-100, 1999
Tai, J.C Lin, A runner-optimization design study of a die-casting die, Journal of Materials Processing Technology, 84, pp.1-12, 1998
Wang, CAD of Mold cooling in injection Mold Using a Three-dimension Numerical Simulation, Journal of Manufacturing Science and Engineering, 144, p.p. 213-221, 1992
Park, Thermal and Design Sensitivity Analyses for Cooling System of Injection Mold, Part I: Thermal Analysis, Journal of Manufacturing Science and Engineering, 120, p.p. 287-295, 1998
Tai, J.C Lin, The optimal position for the injection gate of a die-casting die, Journal of Materials Processing Technology, 86, pp.87-100, 1999
Tai, J.C Lin, A runner-optimization design study of a die-casting die, Journal of Materials Processing Technology, 84, pp.1-12, 1998
Online since: June 2013
Authors: Li Li Wang, Nai Xiu Ding, Yong Li, Guang Ye Liu, Pei Yan Zuo
Journal of Applied Polymer Science. 2002,83(8): 1730-1735
Journal of Applied Polymer Science. 2001(82): 1903-1906
International Journal of Polymetric Material. 1976(5): 233-238
Journal of Applied Polymer Science. 2001 (81):562-569
New scaling for ac properties of percolating composite materials.
Journal of Applied Polymer Science. 2001(82): 1903-1906
International Journal of Polymetric Material. 1976(5): 233-238
Journal of Applied Polymer Science. 2001 (81):562-569
New scaling for ac properties of percolating composite materials.
Online since: February 2023
Authors: Faruk Elaldi, Pelin Alabay
The toughened materials will have higher design allowable strains as compared with the conventional materials, hence the structural weight could be reduced and resulted in more economical benefits.
Experimental Materials.
Engineering Science and Technology, an International Journal, 21(3) (2018) 399-407.
Journal of Composite Materials, 45(7) (2011) 803-814.
Canadian International Conference on Composite Materials, 2017.
Experimental Materials.
Engineering Science and Technology, an International Journal, 21(3) (2018) 399-407.
Journal of Composite Materials, 45(7) (2011) 803-814.
Canadian International Conference on Composite Materials, 2017.
Online since: September 2019
Authors: Ye Gu, Cai Qi Zhao, Yong Yang, Wei Ran Zhao
Progress in Research Work of Light Materials, J.
Journal of Southeast University (Natural Science). 2014, 44(3): 626-630
Journal of Materials Processing Technology. 2014, 214(1):81-86
Construction & Building Materials. 1999, 13(3):109-116
Journal of Space Science. 2002(10), 142-148
Journal of Southeast University (Natural Science). 2014, 44(3): 626-630
Journal of Materials Processing Technology. 2014, 214(1):81-86
Construction & Building Materials. 1999, 13(3):109-116
Journal of Space Science. 2002(10), 142-148
Online since: January 2014
Authors: Xian Yan Chen, Xing Liu, Long Fang Ye, Xue Yi Li, Fen Xiao, Qing H. Liu
Therefore, by using this measurement system, the electromagnetic parameters of microwave absorbing materials can be accurately characterized.
Thus, the test of electromagnetic parameters for a mixture of absorbing materials and permeable materials can be achieved easily.
Also it can be used to measure the electromagnetic parameters of absorbing materials.
Also it can be used to measure the electromagnetic parameters of absorbing materials.
Therefore, by using this testing system, the electromagnetic parameters of microwave absorbing materials can be accurately measured.
Thus, the test of electromagnetic parameters for a mixture of absorbing materials and permeable materials can be achieved easily.
Also it can be used to measure the electromagnetic parameters of absorbing materials.
Also it can be used to measure the electromagnetic parameters of absorbing materials.
Therefore, by using this testing system, the electromagnetic parameters of microwave absorbing materials can be accurately measured.
Online since: September 2016
Authors: Pi Hua Wen, Perry Hinneh
Wen1, b
1School of Engineering and Materials Science, Queen Mary University of London, E1 4NS, UK
ap.hinneh@qmul.ac.uk, bp.h.wen@qmul.ac.uk
Keywords: Interface crack, stress intensity factor, bi-material, FEM, quarter point method.
This is followed by numerical examples of different crack configurations for several E1/E2 material combinations.
International journal for numerical methods in engineering 10.1 (1976): 25-37
SIAM Journal on Applied Mathematics 58.2 (1998): 428-455
Inter Journal of Solids and Structures.
This is followed by numerical examples of different crack configurations for several E1/E2 material combinations.
International journal for numerical methods in engineering 10.1 (1976): 25-37
SIAM Journal on Applied Mathematics 58.2 (1998): 428-455
Inter Journal of Solids and Structures.
Online since: August 2024
Authors: Firas Basim Ismail, Miqdam T. Chaichan, Muhammad Idzmir Fahmy, Hussein A. Kazem, Muhammad Aqil Afham Rahmat, Azher M. Abed
Durability and infrastructure compatibility are considered when selecting materials.
Materials and Methods Data collection begins with identifying the target building power consumption and the area of study rain precipitation, both of which will affect the overall design of the system.
Thermal science and Engineering progress, 7, pp.45-53
Sakarya University Journal of Science (SAUJS)/Sakarya Üniversitesi Fen Bilimleri Enstitüsü Dergisi, 27(2)
Asian Journal of Research in Computer Science, 8(1), pp.46-61
Materials and Methods Data collection begins with identifying the target building power consumption and the area of study rain precipitation, both of which will affect the overall design of the system.
Thermal science and Engineering progress, 7, pp.45-53
Sakarya University Journal of Science (SAUJS)/Sakarya Üniversitesi Fen Bilimleri Enstitüsü Dergisi, 27(2)
Asian Journal of Research in Computer Science, 8(1), pp.46-61
Online since: September 2013
Authors: Jamaluddin Mahmud, Nur Hanis Arzami, Nor Fazli Adull Manan, Muhammad Hussain Ismail
Preparing materials and samples compulsory in experiment based research.
Available at Strength of Materials laboratory in Faculty of Mechanical Engineering UiTM Shah Alam.
Gilchrist, Mélanie Otténio, Characterization of the anisotropic mechanical properties of excised human skin, Journal of the Mechanical Behavior of the Biomedical Materials. 5 (2012) 139-148 [2] Langer, K.
The Imperial Academy of Science, Vienna.
Evans, An anisotropic, hyperelastic model for skin: Experimental measurements, finite element modelling and identification of parameters for human and murine skin, Journal of the Mechanical Behavior of the Biomedical Materials. 18 (2013) 167-180 [4] Guozheng Kang and Xinfeng W, Ratchetting of porcine skin under uniaxial cyclic loading, Journal of the Mechanical Behavior of the Biomedical Materials. 4 (2011) 498-506 [5] Jansen, L., Rottier, P., Some mechanical properties of human abdominal skin measured on excised strips.
Available at Strength of Materials laboratory in Faculty of Mechanical Engineering UiTM Shah Alam.
Gilchrist, Mélanie Otténio, Characterization of the anisotropic mechanical properties of excised human skin, Journal of the Mechanical Behavior of the Biomedical Materials. 5 (2012) 139-148 [2] Langer, K.
The Imperial Academy of Science, Vienna.
Evans, An anisotropic, hyperelastic model for skin: Experimental measurements, finite element modelling and identification of parameters for human and murine skin, Journal of the Mechanical Behavior of the Biomedical Materials. 18 (2013) 167-180 [4] Guozheng Kang and Xinfeng W, Ratchetting of porcine skin under uniaxial cyclic loading, Journal of the Mechanical Behavior of the Biomedical Materials. 4 (2011) 498-506 [5] Jansen, L., Rottier, P., Some mechanical properties of human abdominal skin measured on excised strips.