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Online since: October 2008
Authors: Ming Wei Wang, Liwen Zhang
Zhang
2,b
1
School of Mechanical Engineering and Automation, Dalian Polytechnic University, Dalian
116034,China
2
School of Material Science and Engineering, Dalian University of Technology, Dalian 116085,China
a
wangmw@dlpu.edu.cn, bcommat@student.dlut.edu.cn
Keywords: BT20 Ti-alloy, Vacuum hot bulge forming, FEM, Numerical simulation
Abstract.
Mechanical properties and thermal expansion coefficient of materials are measured by experiment.
Kang: Journal of Harbin Institute of Technology, Vol. 38 (2006) No.1, pp. 191
Li: Chinese Journal of Mechanical Engineering, Vol. 28 (1992) No.1, pp. 53 (In Chinese)
Dean: Journal of Materials Processing Technology, Vol. 153-154 (2004), pp. 122
Mechanical properties and thermal expansion coefficient of materials are measured by experiment.
Kang: Journal of Harbin Institute of Technology, Vol. 38 (2006) No.1, pp. 191
Li: Chinese Journal of Mechanical Engineering, Vol. 28 (1992) No.1, pp. 53 (In Chinese)
Dean: Journal of Materials Processing Technology, Vol. 153-154 (2004), pp. 122
Online since: June 2013
Authors: Xiong Chen, Chang Sheng Zhou, Rui Liu
Due to the different thermal resistance ability, steps are formed at the interface of two materials.
Several thermal protection materials have been successfully used in solid-propellant motors, such as carbon-based materials, reinforced-polymer composites, refractory metals and ceramics[3,4].
C is also the interface of two materials.
O.: AIAA Journal Vol. 3 (1965), p.1250-1257 [5] Evans B., Kuo K.
K.: AIAA Paper No.2007-5776 [6] Piyush Thakre, Vigor Yang: Journal of Propulsion and Power Vol. 24 (2008), p.822-833
Several thermal protection materials have been successfully used in solid-propellant motors, such as carbon-based materials, reinforced-polymer composites, refractory metals and ceramics[3,4].
C is also the interface of two materials.
O.: AIAA Journal Vol. 3 (1965), p.1250-1257 [5] Evans B., Kuo K.
K.: AIAA Paper No.2007-5776 [6] Piyush Thakre, Vigor Yang: Journal of Propulsion and Power Vol. 24 (2008), p.822-833
Online since: May 2023
Authors: Kernou Nassim, Benmammar Djilali, Lyacine Bennacer
Materials and Methods
2.1.
Materials Figure 1 demonstrates the schematic diagram of the experimental device used to study the transport and the deposition of SP in a saturated porous medium [11,24,27].
Cai, Influences of TiO2 Nanoparticles on the Transport of Hydrophobic Organic Contaminant in Soil, In Advanced Materials Research. 1010–1012 (2014) 55–68
Ayatollahi, Mitigation of Fine Particles Migration in Deep Bed Filters Treated by a Nanofluid Slug: An Experimental Study, Advanced Materials Research. 829 (2013) 841–845
Fogler, The Existence of a Critical Salt Concentration for Particle Release, Journal of Colloid and Interface Science. 101 (1984) 214-224
Materials Figure 1 demonstrates the schematic diagram of the experimental device used to study the transport and the deposition of SP in a saturated porous medium [11,24,27].
Cai, Influences of TiO2 Nanoparticles on the Transport of Hydrophobic Organic Contaminant in Soil, In Advanced Materials Research. 1010–1012 (2014) 55–68
Ayatollahi, Mitigation of Fine Particles Migration in Deep Bed Filters Treated by a Nanofluid Slug: An Experimental Study, Advanced Materials Research. 829 (2013) 841–845
Fogler, The Existence of a Critical Salt Concentration for Particle Release, Journal of Colloid and Interface Science. 101 (1984) 214-224
Online since: October 2014
Authors: Geng Zhi, Wei Yao Bi, Jia Jun Tang, Xue Kun Li, Yi Ming Rong
As the second hardest material, CBN (cubic boron nitride) is suitable for grinding hardened materials, e.g. hardened D2 mold and die steel [2].
Acknowledgements The research is supported by the National Science Foundation of China (NSFC: E 51305229), Beijing Municipal Science & Technology Commission (NO.
Journal of Machine Engineering. 10 (2010) 18-29
Advanced Materials Research. 76-78 (2009) 9-14
Materials and Design. 28 (2007) 101-111.
Acknowledgements The research is supported by the National Science Foundation of China (NSFC: E 51305229), Beijing Municipal Science & Technology Commission (NO.
Journal of Machine Engineering. 10 (2010) 18-29
Advanced Materials Research. 76-78 (2009) 9-14
Materials and Design. 28 (2007) 101-111.
Online since: December 2010
Authors: Hai Peng Yu, He Miao Guo, Bin Zhang
As one of emerging products in building materials market in recent years, wooden acoustic materials are unique from other acoustic materials and popular among customers, with characteristics such as excellent sound absorption effects, beautiful shapes, luxurious colors, strong three-dimensional sense, ease of processing and assembly.
Yu et al. have tested the sound absorption capacity of some wooden building materials and analyzed the main factors that affect the sound absorption of wooden building materials [6].
Sound Absorption of Wood-Based Materials.
Journal of Building Materials, 2008, 11(1): p. 71-75. in Chinese
Journal of Cleaner Production, 2009:17, p. 724–731
Yu et al. have tested the sound absorption capacity of some wooden building materials and analyzed the main factors that affect the sound absorption of wooden building materials [6].
Sound Absorption of Wood-Based Materials.
Journal of Building Materials, 2008, 11(1): p. 71-75. in Chinese
Journal of Cleaner Production, 2009:17, p. 724–731
Online since: June 2013
Authors: M. Amuei, R. Khorshidi, Masoud Emamy
Ji: Materials Science and Engineering A Vol. 412 (2005), pp 298–306
Higginson: Materials Science and Engineering A Vol. 392 (2005), pp 73–80
Rassizadehghani: Materials Science and Engineering A Vol. 528 (2011), pp 4482–4490
Jin Park: Journal of Materials Processing Technology Vol. 82 (1998), pp 107–116
Kim: Materials Science and Engineering A Vol. 420 (2006), pp 165–170
Higginson: Materials Science and Engineering A Vol. 392 (2005), pp 73–80
Rassizadehghani: Materials Science and Engineering A Vol. 528 (2011), pp 4482–4490
Jin Park: Journal of Materials Processing Technology Vol. 82 (1998), pp 107–116
Kim: Materials Science and Engineering A Vol. 420 (2006), pp 165–170
Online since: August 2018
Authors: Cheng Liu, Du Xiong Wang, Rui Zhou, Guo Wang Ding
Kenny, Effect of grain size on the corrosion resistance of a high nitrogen-low nickel austenitic stainless steel, Journal of Materials Science Letters. 24 (2002) 1969-1971
Zhang, Intergranular corrosion behavior of high nitrogen austenitic stainless steel, International Journal of Minerals, Metallurgy and Materials. 16 (2009) 654-660
Kim, Effect of phase transformation on wear of high-nitrogen austenitic 18Cr18Mn2Mo0.9N steel, Materials Science and Engineering A. 449-451 (2007) 1075-1078
Brauer, Mechanical, chemical and tribological properties of the nickel-free high-nitrogen steel X13CrMnMoN18-14-3, Materials Science and Engineering Technology. 33 (2002) 705-803
Rawers, Effect of nitrogen alloying on the microstructure and abrasive wear of stainless steels, Journal of Materials Engineering and Performance. 3 (1994) 260-272
Zhang, Intergranular corrosion behavior of high nitrogen austenitic stainless steel, International Journal of Minerals, Metallurgy and Materials. 16 (2009) 654-660
Kim, Effect of phase transformation on wear of high-nitrogen austenitic 18Cr18Mn2Mo0.9N steel, Materials Science and Engineering A. 449-451 (2007) 1075-1078
Brauer, Mechanical, chemical and tribological properties of the nickel-free high-nitrogen steel X13CrMnMoN18-14-3, Materials Science and Engineering Technology. 33 (2002) 705-803
Rawers, Effect of nitrogen alloying on the microstructure and abrasive wear of stainless steels, Journal of Materials Engineering and Performance. 3 (1994) 260-272
Online since: April 2015
Authors: Rinlee Butch M. Cervera, Emie Salamangkit Mirasol
Experimental
Material and Method.
Oyawale: International Journal of Science and Technology Vol.2 No.4 (2012), pp. 210-213 [5] I.B.
Mamat: Maejo International Journal of Science and Technology 6(03) (2012), pp. 430-448 [6] Y.
Persegil: Materials Research Vol.5 No.4 (2002), pp. 467-474 [8] N.
Zainal: International Journal of Basic & Applied Sciences IJBAS-IJENS Vol. 09 No. 09 (2009), pp. 22-24 [10] A.
Oyawale: International Journal of Science and Technology Vol.2 No.4 (2012), pp. 210-213 [5] I.B.
Mamat: Maejo International Journal of Science and Technology 6(03) (2012), pp. 430-448 [6] Y.
Persegil: Materials Research Vol.5 No.4 (2002), pp. 467-474 [8] N.
Zainal: International Journal of Basic & Applied Sciences IJBAS-IJENS Vol. 09 No. 09 (2009), pp. 22-24 [10] A.
Online since: February 2012
Authors: Rui Guo, Li Ming Zhang
Journal of Materials Science, 1976, 11: 1393 ~ 1418
Materials Science and Engineering A, 1991, 131A (2) :265-272
Journal of Materials Science, 1991, 26:2173-2183
Materials Science and Engineering A. 1992, 151 (2): 255-262
Materials Science and Technology, 2002, 18 (3): 237-242
Materials Science and Engineering A, 1991, 131A (2) :265-272
Journal of Materials Science, 1991, 26:2173-2183
Materials Science and Engineering A. 1992, 151 (2): 255-262
Materials Science and Technology, 2002, 18 (3): 237-242
Online since: February 2015
Authors: Jing Yang, Han Zhou Sun, Wen Jie Ma, Jin Hua Zhou, Ni Li
Choi, et al: Journal of Applied Polymer Science, Vol. 111 (4) (2009), p. 1828
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Zhang, et al: Journal of Colloid and Interface Science, Vol. 361 (2) (2011), p. 483 [7] N.G.
Can, et al: Journal of Applied Polymer Science, Vol. 82 (3) (2001), p. 703 [23] C.
Wu, et al: Advanced Materials Research, Vol. 418-420 (2012) p. 693 [25] X.F.
Zhou, et al: Advanced Materials Research, Vol. 554-556 (2012), p. 191
Zhang, et al: Journal of Colloid and Interface Science, Vol. 361 (2) (2011), p. 483 [7] N.G.
Can, et al: Journal of Applied Polymer Science, Vol. 82 (3) (2001), p. 703 [23] C.
Wu, et al: Advanced Materials Research, Vol. 418-420 (2012) p. 693 [25] X.F.
Zhou, et al: Advanced Materials Research, Vol. 554-556 (2012), p. 191