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Online since: October 2010
Authors: Fa Yun Zhang, Jian Xiong Ye, Hong Yan
In a word, for the particle-reinforced composite materials, the size of structures during isothermal heat treatment is mainly affected by refining and hindering of SiC particles.
Zavaliangos: Materials Science and Engineering Vol. 289 (2000) , p.217 [2] D.B.
Liu:Journal of Alloys and Compounds Vol.416 (2006),p.143 [6] T.
Ha: Materials Science Technology Vol.16 (2000), p.887 [7]H.
Zhang: Materials Science Forum Vol.561-565(2007), p.945
Zavaliangos: Materials Science and Engineering Vol. 289 (2000) , p.217 [2] D.B.
Liu:Journal of Alloys and Compounds Vol.416 (2006),p.143 [6] T.
Ha: Materials Science Technology Vol.16 (2000), p.887 [7]H.
Zhang: Materials Science Forum Vol.561-565(2007), p.945
Online since: May 2011
Authors: Zheng Nong Li, Chuan Xiong Zhang, Wen Hai Shi
Acknowledgements
The work described in this paper was fully supported by grants from the National Science Foundation of China (Project No: 90815030, 51008237 and 50978094), the Science Plan Project of Ministry of Housing and Urban-Rural Development of the People's Republic of China (Project No: 2009K218 and 2010K343), and the Science Plan Project of Wenzhou Science and Technology (Project no: S20090009).
AIAA/ASME 9th Structures, Structural Dynamics and Materials Conference, AIAA, (1968), p. 68-288
Journal of Mechanical Design, Vol. 104, No. 4 (1982), p. 307-313
Journal of Wind Engineering and Industry Aerodynamics, Vol. 74-76 (1998), p. 741-750
Journal of Wuhan University of Technology, Vol. 32, No. 9 (2010), p. 56-59.
AIAA/ASME 9th Structures, Structural Dynamics and Materials Conference, AIAA, (1968), p. 68-288
Journal of Mechanical Design, Vol. 104, No. 4 (1982), p. 307-313
Journal of Wind Engineering and Industry Aerodynamics, Vol. 74-76 (1998), p. 741-750
Journal of Wuhan University of Technology, Vol. 32, No. 9 (2010), p. 56-59.
Online since: November 2011
Authors: Ling Ling Zhang, Da Qiang Cang, Li Xue Qin, Jian Feng Duan, Dong Xu
The material of the model is plexiglass, and the lance material is stainless steel.
Reference: [1]LIANG Fu-bin, GUO jing-jing and CHEN jian: Journal of Foundry Technology, Vol.29 (2008), p.877~879
[6]Liu Zhulin, Gao Zeping and He Zhihong: Journal of Special Steel, Vol. 28(2007), p.16~18
[7] M.MARTIN, M.RENDUELES and M.DIAZ: Chemical Engineering Science, Vol.60(2005), p.5781~5791
[9]Ping Tang, Yangyang Yu, Guanghua Wen: Journal of University of Science and Technology Beijing, Vol. 15(2008), p.5~9
Reference: [1]LIANG Fu-bin, GUO jing-jing and CHEN jian: Journal of Foundry Technology, Vol.29 (2008), p.877~879
[6]Liu Zhulin, Gao Zeping and He Zhihong: Journal of Special Steel, Vol. 28(2007), p.16~18
[7] M.MARTIN, M.RENDUELES and M.DIAZ: Chemical Engineering Science, Vol.60(2005), p.5781~5791
[9]Ping Tang, Yangyang Yu, Guanghua Wen: Journal of University of Science and Technology Beijing, Vol. 15(2008), p.5~9
Online since: June 2012
Authors: B.J. Shi, Wen Sheng Yuan, Zhong Lei Wang, Gang Cheng
Wedge rolling process, than the process in terms of cutting and forging, is of quality, high efficiency, materials-saving, energy saving, long mold life, and in the forming process no impact and noise etc. and thus has been widely used in the shaft parts production.
In Beijing University of Science and Technology Shu xuedao and others take physical experiments and numerical simulation of effects of various process parameters on multi-wedge cross wedge rolling metal flow law, stress field and strain field, rolling pressure and torque and obtains relative conclusions; From Southwest Institute of Technology and Engineering, Ni Zeming [7] through a combination of theoretical analysis and experimental verification, investigates the causes of part of the rolling parts defects, and gives relevant solutions; From Shandong Architecture University, Yuan Wensheng [8] by the experimental studies parts rolling defects that may arise using multi-wedge plate cross wedge rolling in the rolling process of "the crank axis" parts of bike, and comes to the relative solution; From Beijing University of Science and Technology Zhao Jing [9] by the second development of PRO / E software, achieves computer-aided design of vehicle semi axle cross wedge rolling multi-wedge
Zhao: Metallurgical equipment Vol.(3)(2005),p.1 [2] X.D.Xing,X.D.Shu,Z.H.Hu: Journal of Beijing University of Science and Technology Vol.26(5)(2004), p.548 [3] J.Zhao, X.D.Shu,Z.H.Hu: Heavy machinery Vol.(6)(2005),p.31 [4] X.D.Shu,X.D.Xing,Z.H.Hu: RollingVol.21(6)(2004), p.40 [5] X.D.Shu,X.D.Xing,Z.H.Hu: Heavy machinery Vol.(6)(2004),p.19 [6] X.D.Shu,X.D.Xing,Z.H.Hu: Journal of Beijing University of Science and Technology Vol.27(2)(2005), p.222 [7]Z.M.Ni, D.J.
Journal of Shandong Architecture University Vol.22(5)(2007), p.454
In Beijing University of Science and Technology Shu xuedao and others take physical experiments and numerical simulation of effects of various process parameters on multi-wedge cross wedge rolling metal flow law, stress field and strain field, rolling pressure and torque and obtains relative conclusions; From Southwest Institute of Technology and Engineering, Ni Zeming [7] through a combination of theoretical analysis and experimental verification, investigates the causes of part of the rolling parts defects, and gives relevant solutions; From Shandong Architecture University, Yuan Wensheng [8] by the experimental studies parts rolling defects that may arise using multi-wedge plate cross wedge rolling in the rolling process of "the crank axis" parts of bike, and comes to the relative solution; From Beijing University of Science and Technology Zhao Jing [9] by the second development of PRO / E software, achieves computer-aided design of vehicle semi axle cross wedge rolling multi-wedge
Zhao: Metallurgical equipment Vol.(3)(2005),p.1 [2] X.D.Xing,X.D.Shu,Z.H.Hu: Journal of Beijing University of Science and Technology Vol.26(5)(2004), p.548 [3] J.Zhao, X.D.Shu,Z.H.Hu: Heavy machinery Vol.(6)(2005),p.31 [4] X.D.Shu,X.D.Xing,Z.H.Hu: RollingVol.21(6)(2004), p.40 [5] X.D.Shu,X.D.Xing,Z.H.Hu: Heavy machinery Vol.(6)(2004),p.19 [6] X.D.Shu,X.D.Xing,Z.H.Hu: Journal of Beijing University of Science and Technology Vol.27(2)(2005), p.222 [7]Z.M.Ni, D.J.
Journal of Shandong Architecture University Vol.22(5)(2007), p.454
Online since: September 2023
Authors: Oihane Murua De la Mata, Gaizka Gómez Escudero, Eneko Ukar, Jon Iñaki Arrizubieta Arrate, Aitzol Lamikiz Mentxaka
Moridi, “State of the art in directed energy deposition: From additive manufacturing to materials design,” Coatings, vol. 9, no. 7.
Lamikiz, “Latest developments in industrial hybrid machine tools that combine additive and subtractive operations,” Materials, vol. 11, no. 12.
Wang, “Microstructure and mechanical properties of forging-additive hybrid manufactured Ti–6Al–4V alloys,” Materials Science and Engineering A, vol. 811, Apr. 2021, doi: 10.1016/j.msea.2021.140984
Liu, “Microstructure and mechanical properties of hybrid fabricated Ti-6.5Al-3.5Mo-1.5Zr-0.3Si titanium alloy by laser additive manufacturing,” Materials Science and Engineering A, vol. 607, pp. 427–434, 2014, doi: 10.1016/j.msea.2014.04.019
Hakeem et al., “Comparative evaluation of thermal and mechanical properties of nickel alloy 718 prepared using selective laser melting, spark plasma sintering, and casting methods,” Journal of Materials Research and Technology, vol. 12, pp. 870–881, 2021, doi: 10.1016/j.jmrt.2021.03.043
Lamikiz, “Latest developments in industrial hybrid machine tools that combine additive and subtractive operations,” Materials, vol. 11, no. 12.
Wang, “Microstructure and mechanical properties of forging-additive hybrid manufactured Ti–6Al–4V alloys,” Materials Science and Engineering A, vol. 811, Apr. 2021, doi: 10.1016/j.msea.2021.140984
Liu, “Microstructure and mechanical properties of hybrid fabricated Ti-6.5Al-3.5Mo-1.5Zr-0.3Si titanium alloy by laser additive manufacturing,” Materials Science and Engineering A, vol. 607, pp. 427–434, 2014, doi: 10.1016/j.msea.2014.04.019
Hakeem et al., “Comparative evaluation of thermal and mechanical properties of nickel alloy 718 prepared using selective laser melting, spark plasma sintering, and casting methods,” Journal of Materials Research and Technology, vol. 12, pp. 870–881, 2021, doi: 10.1016/j.jmrt.2021.03.043
Online since: July 2017
Authors: Florina Daniela Ivan, Maria Butnaru, Liliana Verestiuc, Ionel Marcel Popa, Vera Balan
Various materials have been tested in the aim to substitute the natural bone.
Materials and methods 2.1.
The quantity of simulated body fluid included into composite materials has two components: water retained into materials porosity - as higher with material porosity increasing, and water interacted by hydrogen bonds with hydrophilic groups of the biopolymers.
Ma, Biomimetic materials for tissue engineering, Adv.
Amaral, Chitosan, Materials of Biological Origin, Elsevier Ltd (2011), 221-237
Materials and methods 2.1.
The quantity of simulated body fluid included into composite materials has two components: water retained into materials porosity - as higher with material porosity increasing, and water interacted by hydrogen bonds with hydrophilic groups of the biopolymers.
Ma, Biomimetic materials for tissue engineering, Adv.
Amaral, Chitosan, Materials of Biological Origin, Elsevier Ltd (2011), 221-237
Online since: January 2022
Authors: Rida Gallyamova, Fanil F. Musin, Rustam Safiullin, Vladimir Dokichev
Titanium oxide (TiO2) coatings obtained by the sol-gel technique are widely used in industry as reflective and anti-reflective coatings in optics, as well as protective, catalytic, modified, and functional coatings in material science, microelectronics, and biotechnology [1, 3].
Tendero, Stable hydrosols for TiO2 coatings, J. of Sol-Gel Science and Technology 56 (2010) 250-263
Trapalis, Sol-gel processing of titanium-containing thin coatings, J. of Materials Science 28 (1993) 2353-2360
Juoi, Effect of titanium (IV) isopropoxide molarity on the crystallinity and photocatalytic activity of titanium dioxide thin film deposited via green sol-gel route, J. of Materials Research and Technology 8 (2019) 1434-1439
Gulyaev, Preparation of carbon fiber for the application of interphase coating for composite materials with a ceramic matrix, Proceedings of VIAM 10 (2017) 79-89
Tendero, Stable hydrosols for TiO2 coatings, J. of Sol-Gel Science and Technology 56 (2010) 250-263
Trapalis, Sol-gel processing of titanium-containing thin coatings, J. of Materials Science 28 (1993) 2353-2360
Juoi, Effect of titanium (IV) isopropoxide molarity on the crystallinity and photocatalytic activity of titanium dioxide thin film deposited via green sol-gel route, J. of Materials Research and Technology 8 (2019) 1434-1439
Gulyaev, Preparation of carbon fiber for the application of interphase coating for composite materials with a ceramic matrix, Proceedings of VIAM 10 (2017) 79-89
Online since: December 2012
Authors: Yong Zuo, Yang Li, Hui Xie, Li Ping Liu, Feng Qi, Chang Qing Zhao, Jing Zhang
Now, the main anthocyanin extraction method is as follows: mulberry or fresh mulberry juice is first used as materials, and then traditional solvent is used for extraction; after concentrated the filtrate, the raw paste product is formed.
In this paper, waste lees from mulberry wine enterprise were used as materials and microwave as auxiliary technology was used to extract anthocyanin [8,9], and then solvent used for extracting, extraction time and ratio of solid to liquid were researched.
Materials and Methods Materials.
Journal of Agricultural and Food Chemistry, 2003, 51: 4539-4548
Science of sericulture, 2006, 32(1):90 - 94.
In this paper, waste lees from mulberry wine enterprise were used as materials and microwave as auxiliary technology was used to extract anthocyanin [8,9], and then solvent used for extracting, extraction time and ratio of solid to liquid were researched.
Materials and Methods Materials.
Journal of Agricultural and Food Chemistry, 2003, 51: 4539-4548
Science of sericulture, 2006, 32(1):90 - 94.
Online since: January 2006
Authors: Yu.R. Kolobov, Konstantin V. Ivanov
Lipnitskiy: Russian Physics Journal Vol.
47 (2004), in press
[9] K.I.
Ivanov: Interface Science Vol. 10, No.1 (2002), p. 31 [21] S.X.
Fedoseev: J. of Nuclear Materials Vol. 307-311 (2002), p. 532: J. of Nuclear Materials Vol. 307-311 (2002), p. 532 [24] M.V.
Ivanov: Problems of Materials Science No.1(37) (2004), p.56 [30] RF Patent is pending of 09.11.2004 for the invention "Method for production of ultrafine grain titanium billets" by Yu.R.
Zhu: in Ultrafine Grained Materials III.
Ivanov: Interface Science Vol. 10, No.1 (2002), p. 31 [21] S.X.
Fedoseev: J. of Nuclear Materials Vol. 307-311 (2002), p. 532: J. of Nuclear Materials Vol. 307-311 (2002), p. 532 [24] M.V.
Ivanov: Problems of Materials Science No.1(37) (2004), p.56 [30] RF Patent is pending of 09.11.2004 for the invention "Method for production of ultrafine grain titanium billets" by Yu.R.
Zhu: in Ultrafine Grained Materials III.
Online since: December 2010
Authors: Xie Quan Liu, Xin Hua Ni, Tao Sun, Qing Hua Gu, Xiang Feng Meng
Echigoya: Journal of the European Ceramic Society, Vol. 25( 2005) p. 1381
[3] Z.
Bai: Key Engineering Materials, Vol. 280-283(2005),p. 1053 [4] H.
Wang: Key Engineering Materials, Vol.336-338(2007),p. 2432 [6] X.
Zhao: Rare Metal Materials and Engineering(in Chines), Vol.34(2005), p. 597 [7] J.
Dai: Key Engineering Materials, Vol. 368-375 (2008), p.1648
Bai: Key Engineering Materials, Vol. 280-283(2005),p. 1053 [4] H.
Wang: Key Engineering Materials, Vol.336-338(2007),p. 2432 [6] X.
Zhao: Rare Metal Materials and Engineering(in Chines), Vol.34(2005), p. 597 [7] J.
Dai: Key Engineering Materials, Vol. 368-375 (2008), p.1648