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Online since: September 2011
Authors: Zhi Yun Wu, Rui Fang Ni
The micrographs revealed that CF and GF maintained their own tension behavior in the hybrid composite materials as well in the neat FRP materials.
It was confirmed that the tensile behavior of the hybrid composite materials matched the plus hybrid effect.
In the case of HFRP, CF and GF are maintained their own behavior in the hybrid composite materials.
[6] MANDERS P W, BANER M G, in: The strength of hybrid glass/carbon fiber composites, Part 1: Failure strain enhancement and failure mode [J], edited in Journal of Materials Science.
[7] MANDERS P W, BANERM G, in: The strength of hybrid glass/carbon fiber composites, Part2: A statistical model [J], edited in Journal of Materials Science Vol. 16(1981), p. 2246.
It was confirmed that the tensile behavior of the hybrid composite materials matched the plus hybrid effect.
In the case of HFRP, CF and GF are maintained their own behavior in the hybrid composite materials.
[6] MANDERS P W, BANER M G, in: The strength of hybrid glass/carbon fiber composites, Part 1: Failure strain enhancement and failure mode [J], edited in Journal of Materials Science.
[7] MANDERS P W, BANERM G, in: The strength of hybrid glass/carbon fiber composites, Part2: A statistical model [J], edited in Journal of Materials Science Vol. 16(1981), p. 2246.
Online since: June 2021
Authors: Guo Qi Liu, Zi Hao Chen, Qiang Gu, Wei Kui Ma
., Luoyang 471039, China
2School of Materials Science and Engineering, Zhengzhou University, Zhengzhou 450001, China
a635098742@qq.com, bliugq@lirrc.com
Keywords: Silicon nitride ceramics; additives; thermal conductivity
Abstract.
[10] Watari K, Hirao K, Brito M E, et al, Factors to enhance enhance thermal conducticity of beta-Si3N4 ceramics, Advances in Technology of Materials and Materials Processing Journal(ATM), 2005, 7(2): 191-202
[18] Matovic, B., et al, Thermal Conductivity of Pressureless Sintered Silicon Nitride Materials with LiYO2 Additive, Science of Sintering 36.1 (2004): 3-9
Jae-Woong, et al, Microstructure and thermal conductivity of sintered reaction-bonded silicon nitride: The particle size effects of MgO additive, Advances in Materials Science and Engineering, 2018, 2018:1-5
[26] Y.S.Duan , J.S.Zzhang , Rare earth oxides on property of pressureless sintered Si3N4 ceramics, Journal of Inorganic Materials , 2017, 32(12):1275-1279
[10] Watari K, Hirao K, Brito M E, et al, Factors to enhance enhance thermal conducticity of beta-Si3N4 ceramics, Advances in Technology of Materials and Materials Processing Journal(ATM), 2005, 7(2): 191-202
[18] Matovic, B., et al, Thermal Conductivity of Pressureless Sintered Silicon Nitride Materials with LiYO2 Additive, Science of Sintering 36.1 (2004): 3-9
Jae-Woong, et al, Microstructure and thermal conductivity of sintered reaction-bonded silicon nitride: The particle size effects of MgO additive, Advances in Materials Science and Engineering, 2018, 2018:1-5
[26] Y.S.Duan , J.S.Zzhang , Rare earth oxides on property of pressureless sintered Si3N4 ceramics, Journal of Inorganic Materials , 2017, 32(12):1275-1279
Online since: August 2014
Authors: Vladimír Ivančo, Martin Orečný
Introduction
Radioactive materials are widely used for many purposes in industries and in other areas.
The rules define the conditions for transport of shipment containing radioactive materials.
All three materials had the same density and bulk modulus equal to bulk modulus of water.
These materials were modelled by hex solid elements in FEM analyses.
Kalina, Simulation of 9 m drop test of the cask for transport of radioactive material, American Journal of Mechanical Engineering, 1 (2013), 198-203
The rules define the conditions for transport of shipment containing radioactive materials.
All three materials had the same density and bulk modulus equal to bulk modulus of water.
These materials were modelled by hex solid elements in FEM analyses.
Kalina, Simulation of 9 m drop test of the cask for transport of radioactive material, American Journal of Mechanical Engineering, 1 (2013), 198-203
Online since: September 2011
Authors: H.W. Zoch, B. Striewe, D. Bormann, M. Hunkel, F.W. Bach, N. Grittner, Axel von Hehl
Journal of Materials Science 27 (1992) 6797
[16] Wrzesinski, W.
Materials Science and Technology 6 (1990) 187 [19] Rawers, J.
Journal of Materials Science 27 (1992) 2877 [20] Wang, G.
Journal of Materials Science 23 (1988) 1301 [23] Uenishi, K.; Sugimoto, A.; Kobayashi, K.
Journal of Materials Science 27 (1992) 4201 [25] Abdel-Hamid, A.
Materials Science and Technology 6 (1990) 187 [19] Rawers, J.
Journal of Materials Science 27 (1992) 2877 [20] Wang, G.
Journal of Materials Science 23 (1988) 1301 [23] Uenishi, K.; Sugimoto, A.; Kobayashi, K.
Journal of Materials Science 27 (1992) 4201 [25] Abdel-Hamid, A.
Online since: August 2014
Authors: Nur Ain Jaya, Romisuhani Ahmad, Mohd Mustafa Al Bakri Abdullah
Australian Journal of Basic and Applied Sciences 2013; 7: 182-186
Journal of Materials Processing Technology 2007; 190: 243-250
Progress in Materials Science 1990; 34: 261-366
Materials Processing and Manufacturing Science 2006; 167-245
Materials Science and Engineering 1980; 44: 1-66
Journal of Materials Processing Technology 2007; 190: 243-250
Progress in Materials Science 1990; 34: 261-366
Materials Processing and Manufacturing Science 2006; 167-245
Materials Science and Engineering 1980; 44: 1-66
Online since: September 2011
Authors: Bing Jun Wang, Hong Tian Xiao
Introduction
Most brittle rock materials often contain some imperfections, such as flaws or cracks in their internal regions.
Especially anisotropy rocks are often modeled as transversely isotropic materials from the standpoint of practical considerations in engineering.
DBEM for cracks in transversely isotropic bi-materials Yue [4] presented the closed-form fundamental solution for the elastic field of two joined transversely isotropic solids.
Wang: Journal of Zhejiang University. 2008,42:1106-1110.
Yue: International Journal of Engineering Science. 1995, 33:351-69
Especially anisotropy rocks are often modeled as transversely isotropic materials from the standpoint of practical considerations in engineering.
DBEM for cracks in transversely isotropic bi-materials Yue [4] presented the closed-form fundamental solution for the elastic field of two joined transversely isotropic solids.
Wang: Journal of Zhejiang University. 2008,42:1106-1110.
Yue: International Journal of Engineering Science. 1995, 33:351-69
Online since: January 2015
Authors: Gang Wu, Qing Zhi Zhang, Zhen Ping Zhang, Yan Fei Li, Qiao Lian Feng, Zhi Yin Tang
Thermal conductivity is one of the basic thermal physical parameters of solid materials.
Introduction Thermal conductivity is one of the basic thermal physical parameters of the solid materials.
Thermal conductivity measurements of solid materials at low temperature.
Ordnance Material Science and Engineering.2008.11:1~4.
Journal of Astronautics.
Introduction Thermal conductivity is one of the basic thermal physical parameters of the solid materials.
Thermal conductivity measurements of solid materials at low temperature.
Ordnance Material Science and Engineering.2008.11:1~4.
Journal of Astronautics.
Online since: September 2013
Ten
supporting journals, including Journal of Inorganic and Organometallic Polymers
and Materials (JIOPM; Springer), Monatshefte für Chemie - Chemical Monthly (CM;
Springer) Journal of the Chinese Advanced Materials Society (JCAMS; Taylor
Francis), Journal of Energetic Materials (JEM; Taylor & Francis), Journal of Nano
Research (JNanoR; Trans Tech), Polymers & Polymer Composites (PPC; Smithers
Rapra), Current Organic Chemistry (COC; Bentham Science), Key Engineering
Materials (KEM; Trans Tech), The Open Electrochemistry Journal (TOEJ; Bentham
Science), and American Journal of Environmental Science (AJES; Science
publications), have included ca. 700 full manuscripts contributed and 315 abstracts.
H Fujii (National Institute for Materials Science, Japan) Dr.
Kumakura (National Institute for Materials Science, Japan) Dr.
K Togano (National Institute for Materials Science, Japan) Dr.
Korea) Sponsors Jiangsu University University of Jinan State Key Laboratory of Bioreactor Engineering (East China University of Science and Technology) Hengyang Normal University Journal of Inorganic and Organometallic Polymers and Materials (JIOPM; Springer), Monatshefte für Chemie - Chemical Monthly (CM; Springer) Journal of the Chinese Advanced Materials Society (JCAMS; Taylor Francis) Journal of Energetic Materials (JEM; Taylor & Francis) Journal of Nano Research (JNanoR; Trans Tech) Polymers & Polymer Composites (PPC; Smithers Rapra) Current Organic Chemistry (COC; Bentham Science) Key Engineering Materials (KEM; Trans Tech) The Open Electrochemistry Journal (TOEJ; Bentham Science) American Journal of Environmental Science (AJES; Science publications).
H Fujii (National Institute for Materials Science, Japan) Dr.
Kumakura (National Institute for Materials Science, Japan) Dr.
K Togano (National Institute for Materials Science, Japan) Dr.
Korea) Sponsors Jiangsu University University of Jinan State Key Laboratory of Bioreactor Engineering (East China University of Science and Technology) Hengyang Normal University Journal of Inorganic and Organometallic Polymers and Materials (JIOPM; Springer), Monatshefte für Chemie - Chemical Monthly (CM; Springer) Journal of the Chinese Advanced Materials Society (JCAMS; Taylor Francis) Journal of Energetic Materials (JEM; Taylor & Francis) Journal of Nano Research (JNanoR; Trans Tech) Polymers & Polymer Composites (PPC; Smithers Rapra) Current Organic Chemistry (COC; Bentham Science) Key Engineering Materials (KEM; Trans Tech) The Open Electrochemistry Journal (TOEJ; Bentham Science) American Journal of Environmental Science (AJES; Science publications).
Online since: August 2019
Authors: Jana Sobotová, Martin Kuřík, Nikola Moravcová
Materials Science and Engineering: A. 2010, 528(2), 589-603.
Materials Science and Engineering: A. 2014, 598, 413-419.
Materials Science and Engineering: A. 2016, 662, 356-362.
Journal of Materials Science and Chemical Engineering. 2015, 03(09), 37-46.
Materials Science and Engineering: A. 2016, 652, 192-204.
Materials Science and Engineering: A. 2014, 598, 413-419.
Materials Science and Engineering: A. 2016, 662, 356-362.
Journal of Materials Science and Chemical Engineering. 2015, 03(09), 37-46.
Materials Science and Engineering: A. 2016, 652, 192-204.
Online since: December 2013
Authors: A. Mimi Mazira, M.T. Ramlah, A. Sharifah, Nor Munirah Abdullah
Normally, ultrafiltration membranes are made from polymeric materials and some type may be prepared by using an inorganic materials [3].
In this study, cellulose acetate will be used as one of the materials in membrane fabrication.
Cellulose acetate hollow fiber ultrafiltration membranes made from CA/PVP 360 K/NMP/water, Journal of Membrane Science, 218, 173-183
Preparation characterization and performance studies of ultrafiltration membranes with polymeric additive, Journal of Membrane Science, 350, 130-138
Preparation, morphologies and properties for flat sheet PPESK ultrafiltration membranes, Journal of Membrane Science, 270, 146-153
In this study, cellulose acetate will be used as one of the materials in membrane fabrication.
Cellulose acetate hollow fiber ultrafiltration membranes made from CA/PVP 360 K/NMP/water, Journal of Membrane Science, 218, 173-183
Preparation characterization and performance studies of ultrafiltration membranes with polymeric additive, Journal of Membrane Science, 350, 130-138
Preparation, morphologies and properties for flat sheet PPESK ultrafiltration membranes, Journal of Membrane Science, 270, 146-153