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Online since: September 2021
Authors: Andrii Sudakov, Olesia Maksymovych, Aleksandr Lazorko, Oleksandr Hnatiuk, Andriy Mazurak, Oleh Dmitriiev
Such plates made of carbon materials are used as mounts to engines, machines, etc.
Science Publ
Materials Science, 37(6), 857-865. https://doi.org/10.1023/A:1015632905424 [7] Kharchenko, Ye.V., & Maksymovych M.O. (2020).
Journal of Mathematical Sciences, 174(3). 387-399. https://doi.org/10.1007/s10958-011-0306-x [10] Vasylev, V.V. (1988).
Mechanics of Composite Materials second edition,Taylor & Francis, 519
Science Publ
Materials Science, 37(6), 857-865. https://doi.org/10.1023/A:1015632905424 [7] Kharchenko, Ye.V., & Maksymovych M.O. (2020).
Journal of Mathematical Sciences, 174(3). 387-399. https://doi.org/10.1007/s10958-011-0306-x [10] Vasylev, V.V. (1988).
Mechanics of Composite Materials second edition,Taylor & Francis, 519
Online since: March 2014
Authors: Sten Johansson, Maqsood Ahmad, Taina Vuoristo, Daniel Bäckström, Ru Lin Peng, Mattias Lundberg
These advantages outweigh the relatively poor mechanical performance when compared to other common materials.
Johansson, Influence of Shot Peening Parameters on Residual Stresses in Flake and Vermicular Cast Irons, Materials Science Forum Vols. 768-769 (2013) 534-541
Johansson, Graphite Morphology's Influence on Shot Peening Results in Cast Irons, Materials Science Forum Vols. 768-769 (2013) 542-549
Davis, ASM SPECIALTY HANDBOOK - Cast Irons, ASM International, Materials Park, USA, 1996
Zambelli, The stiffness and modulus of elasticity of grey cast irons, Journal of Materials Science Letters. 2 (1983) 239-242
Johansson, Influence of Shot Peening Parameters on Residual Stresses in Flake and Vermicular Cast Irons, Materials Science Forum Vols. 768-769 (2013) 534-541
Johansson, Graphite Morphology's Influence on Shot Peening Results in Cast Irons, Materials Science Forum Vols. 768-769 (2013) 542-549
Davis, ASM SPECIALTY HANDBOOK - Cast Irons, ASM International, Materials Park, USA, 1996
Zambelli, The stiffness and modulus of elasticity of grey cast irons, Journal of Materials Science Letters. 2 (1983) 239-242
Online since: June 2014
Authors: Hector Torres, Dieter Horwatitsch, Markus Varga, Karl Adam, Manel Rodríguez Ripoll
[ 6 ] Özel, T.: Computational modelling of 3D turning: Influence of edge micro-geometry on forces, stresses, friction and tool wear in PcBN tooling, Journal of Materials Processing Technology, 2009, 209, pp. 5167-5177
-C.; Jain, A.; Altan, T.: A finite element analysis of orthogonal machining using different tool edge geometries, Journal of Materials Processing Technology, 2004, 146, pp. 72-81
[ 9 ] Dogra, M.; Sharma, V.S.; Dureja, J.: Effect of tool geometry variation on finish turning – A Review, Journal of Engineering Science and Technology Review, 2011, 4, pp. 1-13
[ 20 ] Bäker, M.: Finite element simulation of high-speed cutting forces, Journal of Materials Processing Technology, 2006, 176, pp. 117-126
[ 23 ] Petersen, S.B.; Martins, P.A.F.; Bay, N.: Friction in bulk metal forming: a general friction model vs. the law of constant friction, Journal of Materials Processing Technology, 1997, 66, pp. 186-194
-C.; Jain, A.; Altan, T.: A finite element analysis of orthogonal machining using different tool edge geometries, Journal of Materials Processing Technology, 2004, 146, pp. 72-81
[ 9 ] Dogra, M.; Sharma, V.S.; Dureja, J.: Effect of tool geometry variation on finish turning – A Review, Journal of Engineering Science and Technology Review, 2011, 4, pp. 1-13
[ 20 ] Bäker, M.: Finite element simulation of high-speed cutting forces, Journal of Materials Processing Technology, 2006, 176, pp. 117-126
[ 23 ] Petersen, S.B.; Martins, P.A.F.; Bay, N.: Friction in bulk metal forming: a general friction model vs. the law of constant friction, Journal of Materials Processing Technology, 1997, 66, pp. 186-194
Online since: July 2013
Authors: Peng Wan Chen, Kai Da Dai, Jian Rui Feng, Yuan Yuan, Er Feng An
Journal of the Mechanics and Physics of Solids. 53 (2005) 2501-2528
Science and Technology of Welding and Joining. 17 (2012) 36-41
Journal of Materials Processing Technology. 209 (2009) 445-454
Journal of Materials Science. 39 (2004) 6457-6466
Materials and Design. 35 (2012) 210-219
Science and Technology of Welding and Joining. 17 (2012) 36-41
Journal of Materials Processing Technology. 209 (2009) 445-454
Journal of Materials Science. 39 (2004) 6457-6466
Materials and Design. 35 (2012) 210-219
Online since: December 2024
Authors: Long Li
Introduction
Advances in materials science and manufacturing engineering have led to the design and application of numerous complex structures across various engineering fields.
These structures encompass porous configurations made from metals, non-metallic inorganic materials, polymers, or other complex materials, often characterized by a certain degree of porosity.
Due to their complex geometry and unique properties, TPMS structures have significant applications in fields including material science, physics, chemistry, and biology.
Journal of Materials Research and Technology, 2024, 30: 4950-4960
Experimental and numerical studies on mechanical properties of TPMS structures, International Journal of Mechanical Sciences [J], Volume 261, 2024, 108657
These structures encompass porous configurations made from metals, non-metallic inorganic materials, polymers, or other complex materials, often characterized by a certain degree of porosity.
Due to their complex geometry and unique properties, TPMS structures have significant applications in fields including material science, physics, chemistry, and biology.
Journal of Materials Research and Technology, 2024, 30: 4950-4960
Experimental and numerical studies on mechanical properties of TPMS structures, International Journal of Mechanical Sciences [J], Volume 261, 2024, 108657
Online since: November 2013
Authors: Ji Zhi Huang, Hui Wang, Xiang Gang Yin, Feng Wei
Journal of Colloid and interface Science, 263 (2003)1-7
Materials and Design, 32 (2003) 941-946
Journal of Materials Processing Technology,194 (2007) 89-92
Journal of Colloid and Interface Science, 330 (2009) 237–242
Materials Science & Technology, 2007, 15 (6): 851-857.
Materials and Design, 32 (2003) 941-946
Journal of Materials Processing Technology,194 (2007) 89-92
Journal of Colloid and Interface Science, 330 (2009) 237–242
Materials Science & Technology, 2007, 15 (6): 851-857.
Online since: October 2007
Authors: J.C. Huang, M.C. Kuo, M. Chen, Y.H. Lai
Chen a
a
Institute of Materials Science and Engineering; Center for Nanoscience and Nanotechnology,
National Sun Yat-Sen University, Kaohsiung, Taiwan 804, R.
Ishikawa: Journal of Macromolecular Science, Physics Vol.
Chen: Materials Chemistry and Physics Vol. 90 (2005), p. 185
Chen: Materials Chemistry and Physics Vol. 100 (2006), on line. [12] S.
Lee: Journal of Applied Polymer Science Vol. 94 (2004), p. 812
Ishikawa: Journal of Macromolecular Science, Physics Vol.
Chen: Materials Chemistry and Physics Vol. 90 (2005), p. 185
Chen: Materials Chemistry and Physics Vol. 100 (2006), on line. [12] S.
Lee: Journal of Applied Polymer Science Vol. 94 (2004), p. 812
Online since: October 2012
Authors: Xiu Ling Huang, Ya Feng Ding, Erwin Pasbrig, Zhi Wei Wang, Mei Hong Li
If such materials are used, IR scans or DSC is necessary for the analytic.
Plastic materials with density lower 1g·cm-3 swim on the water (PE, PP and ionomer).
All other materials (not filled or foamed) have a density > 1g·cm-3.
These elements are in additives to reduce/avoid the burning of plastic materials.
Bugusu: Journal of Food Science, Vol. 72 (2007) No.3, pp. 39-55
Plastic materials with density lower 1g·cm-3 swim on the water (PE, PP and ionomer).
All other materials (not filled or foamed) have a density > 1g·cm-3.
These elements are in additives to reduce/avoid the burning of plastic materials.
Bugusu: Journal of Food Science, Vol. 72 (2007) No.3, pp. 39-55
Online since: August 2009
Authors: Ming Zhou, P. Jia, M. Li
Liu: Journal of Manufacturing Processes, Vol. 7(2) (2005),
p. 95-101
[2] C.H.
Huang: Journal of Materials Processing Technology, Vol. 198(1-3) (2008), p. 350-358 [3] M.B.
Wang: Journal of Materials Processing Technology, Vol. 174(1-3) (2006), p. 29-33 [7] T.P.
Lu: Journal of Materials Processing Technology, Vol. 73(1-3) (1998), p. 42-48 [8] T.
Ono: Journal of Materials Processing Technology, Vol. 200(1-3) (2008), p. 356-363 [9] T.
Huang: Journal of Materials Processing Technology, Vol. 198(1-3) (2008), p. 350-358 [3] M.B.
Wang: Journal of Materials Processing Technology, Vol. 174(1-3) (2006), p. 29-33 [7] T.P.
Lu: Journal of Materials Processing Technology, Vol. 73(1-3) (1998), p. 42-48 [8] T.
Ono: Journal of Materials Processing Technology, Vol. 200(1-3) (2008), p. 356-363 [9] T.
Online since: June 2020
Authors: Avinash Parashar, Divya Singh
Computational materials science,131, 48-54
Computational materials science, 131, 108-119
Computational materials science, 143, 126-132
Materials Chemistry and Physics, 235, 121729
Journal of Nuclear Materials, 526, 151739 [15] Plimpton, S., 1995.
Computational materials science, 131, 108-119
Computational materials science, 143, 126-132
Materials Chemistry and Physics, 235, 121729
Journal of Nuclear Materials, 526, 151739 [15] Plimpton, S., 1995.