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Online since: February 2016
Authors: S.V. Kuz’min, V.I. Lysak, Valentin O. Kharlamov, Aleksandr Vasilevich Krokhalev
Materials and methods
Fig. 1.
a) b) 1 1 The dependence of the hardness (HV) of the explosion-fabricated materials on the maximal pressure is complex.
Gourdin, Dynamic consolidation of metal powders, Progress in Materials Science. 30 (1986) 39–80
Raabea, Hierarchical microstructure of explosive joints: Example of titanium to steel cladding, Materials Science and Engineering A. 528 (2011) 2641–2647
[12] A.G Mamalis, I.N Vottea, D.E Manolakos, On the modelling of the compaction mechanism of shock compacted powders, Journal of Materials Processing Technology. 108 (2001) 165-178
a) b) 1 1 The dependence of the hardness (HV) of the explosion-fabricated materials on the maximal pressure is complex.
Gourdin, Dynamic consolidation of metal powders, Progress in Materials Science. 30 (1986) 39–80
Raabea, Hierarchical microstructure of explosive joints: Example of titanium to steel cladding, Materials Science and Engineering A. 528 (2011) 2641–2647
[12] A.G Mamalis, I.N Vottea, D.E Manolakos, On the modelling of the compaction mechanism of shock compacted powders, Journal of Materials Processing Technology. 108 (2001) 165-178
Online since: April 2016
Authors: Yan Ni Tan, Liu Yong, Xiang He, Wen Wang, Dong Duan, Kai Yang Li, Hui Xia Li, Lan Lan Luo
References
[1] Oh SH, Choi SY, Lee YK, Kim KN: Journal of Biomedical Materials Research. 2002;62:593-9
[2] Oh SH, Choi SY, Lee YK, Kim KN, Choi SH: Journal of Biomedical Materials Research Part A. 2003;67A:104-11
[3] Tan Y, Yong L, Qing Z, Birdi G, Grover LM: Materials Science Forum: Trans Tech Publ; 2014. p. 387-94
[12] Canal C, Ginebra MP: Journal of the Mechanical Behavior of Biomedical Materials. 2011;4:1658-71
[20] Soboyejo WO, Nemetski B, Allameh S, Marcantonio N, Mercer C, Ricci J: Journal of Biomedical Materials Research. 2002;62:56-72
[2] Oh SH, Choi SY, Lee YK, Kim KN, Choi SH: Journal of Biomedical Materials Research Part A. 2003;67A:104-11
[3] Tan Y, Yong L, Qing Z, Birdi G, Grover LM: Materials Science Forum: Trans Tech Publ; 2014. p. 387-94
[12] Canal C, Ginebra MP: Journal of the Mechanical Behavior of Biomedical Materials. 2011;4:1658-71
[20] Soboyejo WO, Nemetski B, Allameh S, Marcantonio N, Mercer C, Ricci J: Journal of Biomedical Materials Research. 2002;62:56-72
Online since: September 2022
Authors: Rozana Aina Maulat Osman, Mohd Sobri Idris, Ku Noor Dhaniah Ku Muhsen, Nur Izzati Muhammad Nadzri, Domingo Arturo Ruiz León
Journal of Materials Science: Materials in Electronics, 1-13
Journal of Materials Science: Materials in Electronics, 30(23), 20673-20686
Solid state sciences, 14(10), 1520-1524
Journal of Materials Science: Materials in Electronics, 30(8), 7514-7523
Advanced materials, 2(3), 132-138
Journal of Materials Science: Materials in Electronics, 30(23), 20673-20686
Solid state sciences, 14(10), 1520-1524
Journal of Materials Science: Materials in Electronics, 30(8), 7514-7523
Advanced materials, 2(3), 132-138
Online since: July 2015
Authors: Klaus Drechsler, Jakob Wölling, Frank Manis
This reaction leads
to degradation of fibre materials shown in [9,10,12].
Experimental Materials.
Roberts, The Carbon Fibre Industry Worldwide 2008-2014, Materials Technology Publications (2008), 297-302
Grove-Nielsen, CFRP-Recycling Following a Pyrolysis Route: Process Optimization and Potentials, Journal of Composite Materials 43 (2009), 1121-1132
Cross, The oxidation behaviour of carbon fibres, Journal of Material Science 29 (1994), 2250-2254.
Experimental Materials.
Roberts, The Carbon Fibre Industry Worldwide 2008-2014, Materials Technology Publications (2008), 297-302
Grove-Nielsen, CFRP-Recycling Following a Pyrolysis Route: Process Optimization and Potentials, Journal of Composite Materials 43 (2009), 1121-1132
Cross, The oxidation behaviour of carbon fibres, Journal of Material Science 29 (1994), 2250-2254.
Online since: June 2014
Authors: Bo Yang
Such these spoil material and waste slag used to stack at discretion in place along with gradient.
Chinese Journal of Soil Science,2007,06:93-97
Journal of China Agricultural University,1998,02: 41-45
Soil Science Society of America Journal, 1993, 57: 1586-1594
Journal of Hydrology, 2000, 231/232: 265-276.
Chinese Journal of Soil Science,2007,06:93-97
Journal of China Agricultural University,1998,02: 41-45
Soil Science Society of America Journal, 1993, 57: 1586-1594
Journal of Hydrology, 2000, 231/232: 265-276.
Online since: October 2014
Authors: Sheng Jiang Wu, Hui Ping Shao, Tao Lin, Zi Fen Zhao
Advanced Materials, 2004, 16(13): 1071-1074
Journal of University of Science and Techno logy Beijing, 2011, 33(9): 1122-1126
Journal of Materials Science: Materials in Medicine, 2009, 20(12): 2401-2411
Journal of Materials Science: Materials in Medicine, 2010, 21(7): 2035-2047
Journal of Materials Science: Materials in Medicine, 1998, 9(3): 121-128.
Journal of University of Science and Techno logy Beijing, 2011, 33(9): 1122-1126
Journal of Materials Science: Materials in Medicine, 2009, 20(12): 2401-2411
Journal of Materials Science: Materials in Medicine, 2010, 21(7): 2035-2047
Journal of Materials Science: Materials in Medicine, 1998, 9(3): 121-128.
Online since: June 2013
Authors: Anne Marie Habraken, Carlos Felipe Guzmán
Cao, “Mechanics of fracture in single point incremental forming,” Journal of Materials Processing Technology, vol. 212, no. 7, pp. 1573–1590, Jul. 2012
H. van den Boogaard, “An overview of stabilizing deformation mechanisms in incremental sheet forming,” Journal of Materials Processing Technology, vol. 209, no. 8, pp. 3688–3695, Apr. 2009
H. van den Boogaard, “Strain in Shear, and Material Behaviour in Incremental Forming,” Key Engineering Materials, vol. 344, pp. 519–526, 2007
Allwood, “The mechanics of incremental sheet forming,” Journal of Materials Processing Technology, vol. 209, no. 3, pp. 1158–1174, Feb. 2009
Bai, “Calibration and evaluation of seven fracture models,” International Journal of Mechanical Sciences, vol. 47, no. 4–5, pp. 719–743, Apr. 2005
H. van den Boogaard, “An overview of stabilizing deformation mechanisms in incremental sheet forming,” Journal of Materials Processing Technology, vol. 209, no. 8, pp. 3688–3695, Apr. 2009
H. van den Boogaard, “Strain in Shear, and Material Behaviour in Incremental Forming,” Key Engineering Materials, vol. 344, pp. 519–526, 2007
Allwood, “The mechanics of incremental sheet forming,” Journal of Materials Processing Technology, vol. 209, no. 3, pp. 1158–1174, Feb. 2009
Bai, “Calibration and evaluation of seven fracture models,” International Journal of Mechanical Sciences, vol. 47, no. 4–5, pp. 719–743, Apr. 2005
Online since: May 2012
Authors: Jiang Zhu, Rong Bing Fu, Xin Xing Liu, Fang Liu, Jin Ma, Yu Mei Ma, Chang Bo Zhang
In this study, based on changing the structure and composition of electrode material, the surfaces of graphite electrodes were attached by different active materials to form different permeable reactive composite electrodes.
Materials and Methods Experimental materials.
During the remediation process, replacing materials in time according to the saturation of them could help to control the pH of cathode lower than 7.0.
References [1] Qiguo Zhao, Yongming Luo and Ying Teng: Acta Pedologica Snica Vol. 46 (2009), p. 1140-1145 (in Chinese) [2] Guanlin Guo, Qixing Zhou and Xiuying Li: Chinese Journal of Applied Ecology Vol. 16 (2005), p. 1990-1996 (in Chinese) [3] Yongming Luo: Progress in Chemistry Vol. 21 (2009), p. 558-565 (in Chinese) [4] Page M M, Page C L: Journal of Environmental Engineering Vol. 128 (2002), p. 208-219 [5] Hui Wang, Jianwei Ma and Xiangyu Fan, et al: Ecology and Environment Vol. 16 (2007), p. 223-227 (in Chinese) [6] Virkutyte J, Sillanpaa M, Latostenmaa P: Science Total Environment Vol. 289 (2002), p. 97-121 [7] Ho S V, Sheridan P W and Hughes B M, et al: Environmental Science and Technology Vol. 33 (1999), p. 1086-1091 [8] Kim D H, Ryu B G and Park S W, et al: Journal of Hazardous Material Vol. 165 (2009), p. 501-505 [9] Puppala S K, Alshawabkeh A N and Acar Y B, et al: Journal of Hazardous Material Vol. 55(1997), p. 203-220 [10] Ramamurthy A S, Vo D and Li X J, et al: Water
(Environmental Protection Agency, Washington DC 1996) [21] Xuejun Chen, Zhemin Shen and Bingxin Ju, et al: Environmental Chemistry Vol.24 (2005), p. 666-668 (in Chinese) [22] Kim S O, Kim K W: Journal of Hazardous Materials Vol. 85 (2001), p. 195-211 [23] Alloway B J: Heavy metals in soils (Blackie Academic & Professional, Glasgow, Scotland 1995) [24] Ottosen L M, Hansen H K and, Ribeiro A B, et al: Journal of Hazardous Materials Vol.85 (2001), p. 291-299
Materials and Methods Experimental materials.
During the remediation process, replacing materials in time according to the saturation of them could help to control the pH of cathode lower than 7.0.
References [1] Qiguo Zhao, Yongming Luo and Ying Teng: Acta Pedologica Snica Vol. 46 (2009), p. 1140-1145 (in Chinese) [2] Guanlin Guo, Qixing Zhou and Xiuying Li: Chinese Journal of Applied Ecology Vol. 16 (2005), p. 1990-1996 (in Chinese) [3] Yongming Luo: Progress in Chemistry Vol. 21 (2009), p. 558-565 (in Chinese) [4] Page M M, Page C L: Journal of Environmental Engineering Vol. 128 (2002), p. 208-219 [5] Hui Wang, Jianwei Ma and Xiangyu Fan, et al: Ecology and Environment Vol. 16 (2007), p. 223-227 (in Chinese) [6] Virkutyte J, Sillanpaa M, Latostenmaa P: Science Total Environment Vol. 289 (2002), p. 97-121 [7] Ho S V, Sheridan P W and Hughes B M, et al: Environmental Science and Technology Vol. 33 (1999), p. 1086-1091 [8] Kim D H, Ryu B G and Park S W, et al: Journal of Hazardous Material Vol. 165 (2009), p. 501-505 [9] Puppala S K, Alshawabkeh A N and Acar Y B, et al: Journal of Hazardous Material Vol. 55(1997), p. 203-220 [10] Ramamurthy A S, Vo D and Li X J, et al: Water
(Environmental Protection Agency, Washington DC 1996) [21] Xuejun Chen, Zhemin Shen and Bingxin Ju, et al: Environmental Chemistry Vol.24 (2005), p. 666-668 (in Chinese) [22] Kim S O, Kim K W: Journal of Hazardous Materials Vol. 85 (2001), p. 195-211 [23] Alloway B J: Heavy metals in soils (Blackie Academic & Professional, Glasgow, Scotland 1995) [24] Ottosen L M, Hansen H K and, Ribeiro A B, et al: Journal of Hazardous Materials Vol.85 (2001), p. 291-299
Online since: August 2013
Authors: Wei Xiang Liu
Modeling of Engineering Ceramics Grinding Surface Residual Stress
Weixiang Liu 1,a
1 Hunan Institute Of Science And Technology, Yueyang ,Hunan, China
alwxhnyy@126.com
Keywords: Engineering ceramics, Surface residual stress, Grinding, Modeling.
Because of hard and brittle properties of ceramic materials, grinding and polishing the surface is the main processing methods, after grinded and polished, ceramics surface appear residual stresses and resulting in the cracks.
Introduction Engineering ceramic materials have been widely used in electronics, machinery, chemical industry, communications and other fields.Because of hard and brittle properties of ceramic materials, grinding and polishing the surface are their main processing methods, and after grinded, polished the surface , surface cracks are the main problems affecting the quality of the machined surface, and the residual stress is an important cause of crack.
International Journal of Advanced Manufacturing Technology.
International Journal of Machine Tools & Manufacture, May2012, Vol. 56.
Because of hard and brittle properties of ceramic materials, grinding and polishing the surface is the main processing methods, after grinded and polished, ceramics surface appear residual stresses and resulting in the cracks.
Introduction Engineering ceramic materials have been widely used in electronics, machinery, chemical industry, communications and other fields.Because of hard and brittle properties of ceramic materials, grinding and polishing the surface are their main processing methods, and after grinded, polished the surface , surface cracks are the main problems affecting the quality of the machined surface, and the residual stress is an important cause of crack.
International Journal of Advanced Manufacturing Technology.
International Journal of Machine Tools & Manufacture, May2012, Vol. 56.
Online since: October 2012
Authors: Dong Ouyang, Yuan Ping Li, Jia Chu Xu
Introductions
Steel and Aluminum alloy are common materials used in long-span structures.
Moreover, with the development of modern material industry and vibration control technology, kinds of polymer damping materials of high energy dissipation characteristics and smart materials are widely used in long-span space structures.
Acknowledgment This work has been supported by Guangdong Province Science and Technology Plan Project (2010B010800004; 2011A080802010) and the Opening Fund of Laboratory for Mechanical Behaviors and Design of Materials, Chinese Academy of Sciences (LMBD-2011-2).
Journal of Vibration and Shock 24 (2005): 59-61 (In Chinese) [4] Li Yuanping.
Journal of Non-Newtonian Fluid Mechanics, 2010. 165(3-4):88-97
Moreover, with the development of modern material industry and vibration control technology, kinds of polymer damping materials of high energy dissipation characteristics and smart materials are widely used in long-span space structures.
Acknowledgment This work has been supported by Guangdong Province Science and Technology Plan Project (2010B010800004; 2011A080802010) and the Opening Fund of Laboratory for Mechanical Behaviors and Design of Materials, Chinese Academy of Sciences (LMBD-2011-2).
Journal of Vibration and Shock 24 (2005): 59-61 (In Chinese) [4] Li Yuanping.
Journal of Non-Newtonian Fluid Mechanics, 2010. 165(3-4):88-97