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Online since: July 2006
Authors: Krzysztof Jan Kurzydlowski, Bogusława Adamczyk-Cieślak, Jaroslaw Mizera
Ao: Journal of Materials Processing Technology 99
(2000), pp. 202 - 206
[2] H
[3] K.K.
Sasaki: Journal of Materials Processing Technology 151 (2004), pp. 232 - 236 [5] Y.
Lowe: Materials Science and Engineering A 291 (2000), pp. 46 - 53 [6] S.
Alford: Materials Science and Engineering A368 (2004), pp. 28-40 [7] S.
Bourke: Materials Science and Engineering A 394 (2005), pp. 66 - 77 [10] B.
Sasaki: Journal of Materials Processing Technology 151 (2004), pp. 232 - 236 [5] Y.
Lowe: Materials Science and Engineering A 291 (2000), pp. 46 - 53 [6] S.
Alford: Materials Science and Engineering A368 (2004), pp. 28-40 [7] S.
Bourke: Materials Science and Engineering A 394 (2005), pp. 66 - 77 [10] B.
Online since: September 2017
Authors: Sergey V. Konovalov, S.V. Voronin, K.K. Chaplygin, A.D. Litoshina
Semina, Evolution of Al-19.4Si alloy surface structure after electron beam treatment and high cycle fatigue, Materials Science and Technology (United Kingdom), 31 (2015) 1523-1529
Pierce, Topography and mechanical property mapping of International Simple Glass surfaces with atomic force microscopy, Procedia Materials Science, 7 (2014) 216-222
Bergman, Method to account for true contact area in soda-lime glass during nano-indentation with the Berkovich tip, Materials Science and Engineering, (2005) 1-8
Lawn, Vickers indentation curves of elasto-plastic materials, ASTM, (1986) 72-89
Karabasov, New Materials, MISIS, Moscow, 2002.
Pierce, Topography and mechanical property mapping of International Simple Glass surfaces with atomic force microscopy, Procedia Materials Science, 7 (2014) 216-222
Bergman, Method to account for true contact area in soda-lime glass during nano-indentation with the Berkovich tip, Materials Science and Engineering, (2005) 1-8
Lawn, Vickers indentation curves of elasto-plastic materials, ASTM, (1986) 72-89
Karabasov, New Materials, MISIS, Moscow, 2002.
Online since: September 2013
Authors: Jian Zhong Chen, Si Rong Zhu, Zhuo Qiu Li
Springer Science Business Media, 2011
Effects of moisture and temperature on the tensile strength of composite materials[J].
Journal of Composite Materials, 1977, 11(1): 2-16
Mechanics of Time-Dependent Materials, 2004, 8(1): 65-94
Journal of composite materials, 2009, 43(19): 2109-2124
Effects of moisture and temperature on the tensile strength of composite materials[J].
Journal of Composite Materials, 1977, 11(1): 2-16
Mechanics of Time-Dependent Materials, 2004, 8(1): 65-94
Journal of composite materials, 2009, 43(19): 2109-2124
Online since: September 2020
Authors: Khairum Bin Hamzah, Nik Mohd Asri Nik Long
These problems will affect the engineering structures which related to the stability and safety of the materials.
This observation indicate that the strength of the materials increases subjected to normal stress and decreases subject to shear stress.
This observation indicate that the strength of the materials decreases as increases for shear and mixed stresses.
However the strength of the materials increases as increases for all various stresses.
Eshkuvatov, Stress intensity factors for a crack in bonded dissimilar materials subjected to various stresses, Universal Journal of Mechanical Engineering. 7(4) (2019) 179-189
This observation indicate that the strength of the materials increases subjected to normal stress and decreases subject to shear stress.
This observation indicate that the strength of the materials decreases as increases for shear and mixed stresses.
However the strength of the materials increases as increases for all various stresses.
Eshkuvatov, Stress intensity factors for a crack in bonded dissimilar materials subjected to various stresses, Universal Journal of Mechanical Engineering. 7(4) (2019) 179-189
Online since: February 2013
Authors: Hua Jian Li, Ming Hui Wang, Wan Jiang
TiB2/TiN nano-composites were in-situ fabricated by spark plasma sintering (SPS) technique using Ti and BN powders as starting materials.
In recent years, Spark Plasma Sintering (SPS) has been widely used to produce fully dense bulk materials (such ceramics, metal, composites).
In this work, TiB2/TiN nano-composites were prepared by Spark Plasma Sintering (SPS) using Ti and BN powders as starting materials.
Conclusion In this work, the TiB2/TiN nano-composites were fabricated by SPS using Ti and BN powders as starting materials at 1450℃ for 3 min.
Journal of Refractory Metals and Hard Materials 35 (2012) 1-9
In recent years, Spark Plasma Sintering (SPS) has been widely used to produce fully dense bulk materials (such ceramics, metal, composites).
In this work, TiB2/TiN nano-composites were prepared by Spark Plasma Sintering (SPS) using Ti and BN powders as starting materials.
Conclusion In this work, the TiB2/TiN nano-composites were fabricated by SPS using Ti and BN powders as starting materials at 1450℃ for 3 min.
Journal of Refractory Metals and Hard Materials 35 (2012) 1-9
Online since: November 2015
Authors: L. Zahid, A.D.T. Hussain, E.M. Cheng, Wei Wen Liu, F. Malek, F.H. Wee, Mohd Asri Jusoh, Gomesh Nair Shasidharan, Yeng Seng Lee, Kok Yeow You
The dielectric properties of materials are very important for the absorption performance of materials.
The materials properties performance of MWCNTs/PE composites are potential use as microwave absorber and EMI shielding materials.
Ghasemi: Journal of Magnetism and Magnetic Materials, Vol. 323 (2011), p. 3133-3137 [4] S.
Detrembleur: Materials Science and Engineering: R: Reports, Vol. 74 (2013), p. 211-232 [6] T.
Ghasemi: Journal of Magnetism and Magnetic Materials, Vol. 330 (2013), p. 163-168 [12] M.
The materials properties performance of MWCNTs/PE composites are potential use as microwave absorber and EMI shielding materials.
Ghasemi: Journal of Magnetism and Magnetic Materials, Vol. 323 (2011), p. 3133-3137 [4] S.
Detrembleur: Materials Science and Engineering: R: Reports, Vol. 74 (2013), p. 211-232 [6] T.
Ghasemi: Journal of Magnetism and Magnetic Materials, Vol. 330 (2013), p. 163-168 [12] M.
Online since: June 2025
Authors: Arman Ray N. Nisay, Dan Erick P. Dominguez, Brian Jumaquio Tuazon, John Ryan C. Dizon, Madelene Velasco Villablanca
Yodo: A Review on Filament Materials for Fused Filament Fabrication, Journal of Manufacturing and Materials Processing Vol. 5(3), pp. 69
[15] A.
Milella: Composite materials: A Vision for the Future 1st Ed., Springer Science & Business Media (2011), p. 218 [17] F.
Schwartz: Composite materials handbook Ed.
Akessa: Strength analysis of 3D printed carbon fibre reinforced thermoplastic using experimental and numerical methods, IOP Conference Series: Materials Science and Engineering (2019) 700 012024 [22] M.
Fidan: Tensile Performance of 3D-Printed Continuous Fiber-Reinforced Nylon Composites, Journal of Manufacturing and Materials Processing Vol. 5 (3) (2021), p. 68 [23] Z.
Milella: Composite materials: A Vision for the Future 1st Ed., Springer Science & Business Media (2011), p. 218 [17] F.
Schwartz: Composite materials handbook Ed.
Akessa: Strength analysis of 3D printed carbon fibre reinforced thermoplastic using experimental and numerical methods, IOP Conference Series: Materials Science and Engineering (2019) 700 012024 [22] M.
Fidan: Tensile Performance of 3D-Printed Continuous Fiber-Reinforced Nylon Composites, Journal of Manufacturing and Materials Processing Vol. 5 (3) (2021), p. 68 [23] Z.
Online since: September 2013
Authors: Chuan Zhen Huang, Hong Mei Cheng
The model was extended by Fang [4] and applied for simulating sintering process of two-phase ceramic materials.
These fabrication conditions will be used in sintering experiment of nanocomposite ceramic tool materials in order to compare with the simulation results.
The microstructure of nanocomposite ceramic tool materials at different sintering pressure is shown in Fig. 1.
Microstructure of nanocomposite ceramic tool materials Fig. 2 is the fracture surface of A12O3/nano-SiC nanocomposite ceramic tool materials, which is fabricated at 1600℃, sintering pressure of 0Mpa, 20MPa and 32MPa, respectively, grain size of SiC is 60nm.
Journal of Physics D: Applied Physics.
These fabrication conditions will be used in sintering experiment of nanocomposite ceramic tool materials in order to compare with the simulation results.
The microstructure of nanocomposite ceramic tool materials at different sintering pressure is shown in Fig. 1.
Microstructure of nanocomposite ceramic tool materials Fig. 2 is the fracture surface of A12O3/nano-SiC nanocomposite ceramic tool materials, which is fabricated at 1600℃, sintering pressure of 0Mpa, 20MPa and 32MPa, respectively, grain size of SiC is 60nm.
Journal of Physics D: Applied Physics.
Online since: August 2011
Authors: Yu Sheng Li, Gui Bao Guo, Sheng Li An
China;
2School of Materials and Metallurgy, Inner Mongolia University of Science & Technology, Baotou 014010, China
ali8012@163.com, bguogb@imust.cn, cshengli_an@126.com
*Prof., to whom correspondence should be addressed.
Uyama: Journal Membrane Science, Vol. 55(1991), p. 119 [7] M.
Moel: Journal Polymer Science: Part B: Polymer.
Kang: Journal Membrane Science, Vol. 195 (2002), p. 103 [15] K.
Jokela, Materials Science Forum, (2002), p. 481 [16] M.
Uyama: Journal Membrane Science, Vol. 55(1991), p. 119 [7] M.
Moel: Journal Polymer Science: Part B: Polymer.
Kang: Journal Membrane Science, Vol. 195 (2002), p. 103 [15] K.
Jokela, Materials Science Forum, (2002), p. 481 [16] M.