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Online since: March 2020
Authors: Zi Yao Wei
China Soft Science, 2016 (01): 79-97
Science of The Total Environment, 2018, 634:1119-1125
New Building Materials, 2006 (7)
Journal of Anhui University of Technology (Natural Science), 2018, v.35; No.137 (01): 8-12
New building materials, 2017, 44 (03): 24-27
Science of The Total Environment, 2018, 634:1119-1125
New Building Materials, 2006 (7)
Journal of Anhui University of Technology (Natural Science), 2018, v.35; No.137 (01): 8-12
New building materials, 2017, 44 (03): 24-27
Online since: July 2016
Authors: Chang An Wang, Hao Ran Lu, Ze Ya Huang
Synthesis and Characterization of LaMgAl11O19 as Thermal Barrier Coatings Material
Zeya Huanga, Haoran Lub and Chang-An Wangc
The State Key Lab of New Ceramics and Fine Processing, School of Materials Science and Engineering, Tsinghua University, Beijing 100084, P.
LaMgAl11O19 was synthesized at 1550 °C using La2O3, MgO and Al2O3 as raw materials.
Jordan, Materials science - Thermal barrier coatings for gas-turbine engine applications, Science, 296 (2002) 280-284
Stoever, Ceramic materials for thermal barrier coatings, Journal Of the European Ceramic Society, 24 (2004) 1-10
Levi, Materials design for the next generation thermal barrier coatings, Annual Review Of Materials Research, 33 (2003) 383-417
LaMgAl11O19 was synthesized at 1550 °C using La2O3, MgO and Al2O3 as raw materials.
Jordan, Materials science - Thermal barrier coatings for gas-turbine engine applications, Science, 296 (2002) 280-284
Stoever, Ceramic materials for thermal barrier coatings, Journal Of the European Ceramic Society, 24 (2004) 1-10
Levi, Materials design for the next generation thermal barrier coatings, Annual Review Of Materials Research, 33 (2003) 383-417
Shock-Induced Reaction Characteristics of an Al/Ni Composite Processed via Accumulative Roll-Bonding
Online since: November 2016
Authors: Xian Feng Zhang, Cheng Ji, Xiang Liang Yang, Jie Zhou, Yuan He, Chuan Ting Wang, Wei Xiong, Yong He, Lei Gu, Xu Chao Pan
Introduction
Multifunctional energetic structural materials (MESMs) are special class of materials with dual functions of mechanical property and energetic characteristics.
Quasi-static compression tests was performed on the cylindrical speicemen by means of a CSS44100 Universal Materials Testing Machine.
Such deform pattern was widely observed during ARB processing of different materials [12, 13].
Ames, Reaction efficiencies for impact-initiated energetic materials, 32nd International Pyrotechnics Seminar, June 2005
Qiao, Experimental study on impact-initiated characters of multifunctional energetic structural materials, Journal of Applied Physics 113 (2013) 083508
Quasi-static compression tests was performed on the cylindrical speicemen by means of a CSS44100 Universal Materials Testing Machine.
Such deform pattern was widely observed during ARB processing of different materials [12, 13].
Ames, Reaction efficiencies for impact-initiated energetic materials, 32nd International Pyrotechnics Seminar, June 2005
Qiao, Experimental study on impact-initiated characters of multifunctional energetic structural materials, Journal of Applied Physics 113 (2013) 083508
Online since: September 2016
Authors: Daniele Barbera, Hao Feng Chen, Ying Hua Liu
This latter class of structures pose great challenges, for both material science and structure integrity.
Two thermal loading scenarios are studied; the first considers a cycling homogenous (i.e. identical) high temperature across the entire component, where the thermal stress is induced by the different coefficients of thermal expansion between dissimilar materials.
S., 2013, "Materials challenges in nuclear energy," Acta Materialia, 61(3), pp. 735-758
[9] Ure, J., Chen, H., and Tipping, D., 2013, "Calculation of a lower bound ratchet limit part 2 – Application to a pipe intersection with dissimilar material join," European Journal of Mechanics - A/Solids, 37, pp. 369-378
-Q., 2015, "Parameter correlation of high-temperature creep constitutive equation for RPV metallic materials," Journal of Nuclear Materials, 465, pp. 196-203.
Two thermal loading scenarios are studied; the first considers a cycling homogenous (i.e. identical) high temperature across the entire component, where the thermal stress is induced by the different coefficients of thermal expansion between dissimilar materials.
S., 2013, "Materials challenges in nuclear energy," Acta Materialia, 61(3), pp. 735-758
[9] Ure, J., Chen, H., and Tipping, D., 2013, "Calculation of a lower bound ratchet limit part 2 – Application to a pipe intersection with dissimilar material join," European Journal of Mechanics - A/Solids, 37, pp. 369-378
-Q., 2015, "Parameter correlation of high-temperature creep constitutive equation for RPV metallic materials," Journal of Nuclear Materials, 465, pp. 196-203.
Online since: January 2011
Authors: Ju Min Hao, Bo Wang, Chun Shui, Jiang Zheng
Microalgea is one of the most potential biomass materials for the renewable energy.
Materials and methods Microalgae, culture medium and culture condition.
On the other hand, microalgae is one of the most potential recycling energy materials, the successful production of the microalgae by the aquiculture wastewater would be helpful to the exploitation of the microalgae biomass energy.
Qingyu, “Renewable bio-energy from the production of microalgae pyrolysis: a review,” Journal of Liaoning University (Natural Science Edition), vol. 26, pp. 182-187, February 1999.
“Outdoor culture of Isochrysis galbana ALII-4 in a closed tubular photobioreactor”, Journal of Biotechnology, vol. 37, pp. 159-166, 1994.
Materials and methods Microalgae, culture medium and culture condition.
On the other hand, microalgae is one of the most potential recycling energy materials, the successful production of the microalgae by the aquiculture wastewater would be helpful to the exploitation of the microalgae biomass energy.
Qingyu, “Renewable bio-energy from the production of microalgae pyrolysis: a review,” Journal of Liaoning University (Natural Science Edition), vol. 26, pp. 182-187, February 1999.
“Outdoor culture of Isochrysis galbana ALII-4 in a closed tubular photobioreactor”, Journal of Biotechnology, vol. 37, pp. 159-166, 1994.
Online since: April 2014
Authors: Qi Hong Huang
Through machining experiment of the several major processed forms, it shows that the dual turntable five-axis machine system has high machining quality and could be used to machine the difficult-to-cut materials, spatial complicated curved surface parts and special requirements.
Five-axis CNC technology is one of the most difficult machine technical and is suitable for machining the difficult-to-cut materials, spatial complicated curved surface parts and special requirements, and has been widely used [3-4].
Through machining experiment of the several major processed forms, it shows that the dual turntable five-axis machine system has high machining quality and could be used to machine the difficult-to-cut materials, spatial complicated curved surface parts and special requirements.
Mechanical Science and Technology for Aerospace Engineering Vol. 27(2008), p. 119 [2] REN Fu-jun, CHINESE JOURNAL OF MECHANICAL ENGINEERING Vol. 43(2007), p. 214 [3] D.C.H.
Mechanical Science and Technology for Aerospace Engineering Vol. 29(2010), p. 936 [6] HU Fu-qiang, Journal of Harbin Institute of Technology Vol. 35(2003), p. 1172 [7] C.C.Lo, International Journal of Machine Tools & Manufacture Vol. 40(2000), p. 307 [8] Peternell M, Pottmann H, Ravani B.
Five-axis CNC technology is one of the most difficult machine technical and is suitable for machining the difficult-to-cut materials, spatial complicated curved surface parts and special requirements, and has been widely used [3-4].
Through machining experiment of the several major processed forms, it shows that the dual turntable five-axis machine system has high machining quality and could be used to machine the difficult-to-cut materials, spatial complicated curved surface parts and special requirements.
Mechanical Science and Technology for Aerospace Engineering Vol. 27(2008), p. 119 [2] REN Fu-jun, CHINESE JOURNAL OF MECHANICAL ENGINEERING Vol. 43(2007), p. 214 [3] D.C.H.
Mechanical Science and Technology for Aerospace Engineering Vol. 29(2010), p. 936 [6] HU Fu-qiang, Journal of Harbin Institute of Technology Vol. 35(2003), p. 1172 [7] C.C.Lo, International Journal of Machine Tools & Manufacture Vol. 40(2000), p. 307 [8] Peternell M, Pottmann H, Ravani B.
Online since: September 2024
Authors: Olena Nadon, Oleksandr Chernenko, Viktoriya Pasternak, Artem Ruban
Materials.
Romin, Software modeling environment for solving problems of structurally inhomogeneous materials, Materials Science Forum 1068 (2022) 215-222. https://doi.org/10.4028/p-h1c2rp [2] Jun-bao.
Ruban, Investigation of the properties of powder materials using computer modeling, Materials Science Forum 1038 (2021) 33-39. https://doi.org/10.4028/www.scientific.net/MSF.1038.33 [6] Sh.
Bezuhla, Improvement of fire resistance of polymeric materials at their filling with aluminosilicates, Materials Science Forum 1006 (2020) 55-61
Computational Materials Science 160 (2019) 53-61
Romin, Software modeling environment for solving problems of structurally inhomogeneous materials, Materials Science Forum 1068 (2022) 215-222. https://doi.org/10.4028/p-h1c2rp [2] Jun-bao.
Ruban, Investigation of the properties of powder materials using computer modeling, Materials Science Forum 1038 (2021) 33-39. https://doi.org/10.4028/www.scientific.net/MSF.1038.33 [6] Sh.
Bezuhla, Improvement of fire resistance of polymeric materials at their filling with aluminosilicates, Materials Science Forum 1006 (2020) 55-61
Computational Materials Science 160 (2019) 53-61
Online since: January 2022
Authors: Jayaprakash Murugesan, Hemant Borkar, Arindom Baruah
[18] Mandal S, Rice J, Elmustafa AA, Experimental and numerical investigation of the plunge stage in friction stir welding, 2008, Journal of Materials Processing Technology,203, 411-19
[20] Schmidt H, Hattel JH and Wert J, An analytical model for the heat generation in friction stir welding, 2003, Modelling and Simulation in Materials Science and Engineering ,12 , 143
[25] Mirzae MH, Asadi P, Fazli A, Effect of Tool Pin Profile on Material Flow in Double Shoulder Friction Stir Welding of AZ91 Magnesium Alloy, 2020, International Journal of Mechanical Sciences,183
[29] Darras BM, Khraisheh MK, Abu Farha FK and Omar MA, Friction stir processing of commercial AZ31 magnesium alloy, 2007, Journal of Materials Processing Technology ,191, 77-81
[32] Safari M and Jalal J, Coupled Eulerian-Lagrangian (CEL) Modeling of Material Flow in Dissimilar Friction Stir Welding of Aluminum Alloys, oct 2019, Iranian Journal of Materials Forming, 6, 10-9
[20] Schmidt H, Hattel JH and Wert J, An analytical model for the heat generation in friction stir welding, 2003, Modelling and Simulation in Materials Science and Engineering ,12 , 143
[25] Mirzae MH, Asadi P, Fazli A, Effect of Tool Pin Profile on Material Flow in Double Shoulder Friction Stir Welding of AZ91 Magnesium Alloy, 2020, International Journal of Mechanical Sciences,183
[29] Darras BM, Khraisheh MK, Abu Farha FK and Omar MA, Friction stir processing of commercial AZ31 magnesium alloy, 2007, Journal of Materials Processing Technology ,191, 77-81
[32] Safari M and Jalal J, Coupled Eulerian-Lagrangian (CEL) Modeling of Material Flow in Dissimilar Friction Stir Welding of Aluminum Alloys, oct 2019, Iranian Journal of Materials Forming, 6, 10-9
Online since: November 2017
Authors: Sathyashankara Sharma, P.K. Jayashree, Shetty Raviraj
Babu: International journal of metals and materials, Vol.13, (2007), p.345-351
Idris and S.Farahany: Journal of composite materials, Vol. 47(10), (2012), p.1283-1291
[4] B.Roebuck: Journal of materials science letters, 6(10), (1987), p.1138-1140
[5] Sharma SS, Jagannath K, Prabhu PR, Gowri Shankar and Harisha SR: Materials Science Forum, Vol. 880, (2016) p. 140-143
Prabhukhot: International journal of material science and engineering, (2015), Vol.3 (4), p.287-294
Idris and S.Farahany: Journal of composite materials, Vol. 47(10), (2012), p.1283-1291
[4] B.Roebuck: Journal of materials science letters, 6(10), (1987), p.1138-1140
[5] Sharma SS, Jagannath K, Prabhu PR, Gowri Shankar and Harisha SR: Materials Science Forum, Vol. 880, (2016) p. 140-143
Prabhukhot: International journal of material science and engineering, (2015), Vol.3 (4), p.287-294
Online since: April 2012
Authors: Wang Bao Zhou, Li Zhong Jiang, Zhi Huang
Materials can be used effectively to reduce construction problems and achieve the purpose to save steel.
Beijing: Science Press, 2003, 1-28
Journal of Xi'an University of Architecture and Technology,1998,(3):205-208
Journal of Xi'an University of Architecture and Technology, 1998,(3):209-212
Journal of Structural Engineering, 127(1): 3-11, 2001
Beijing: Science Press, 2003, 1-28
Journal of Xi'an University of Architecture and Technology,1998,(3):205-208
Journal of Xi'an University of Architecture and Technology, 1998,(3):209-212
Journal of Structural Engineering, 127(1): 3-11, 2001