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Online since: April 2011
Authors: Wei Tang, He Xue, Dan Zhao
Supported by the China National Natural Science Foundation (No.50875207 and No.11072191)
FEM Simulation
Material Model.
Transactions of the ASME- Journal of Pressure Vessel and Technology, 2009, 131(1), 61-70 [6] D.
Standard test method for plane strain fracture toughness of metallic materials, Annual book of ASTM Standards, Vol. 03.01, ASTM International, 2002 [8] ABAQUS/Standard User’s Manual.
Nuclear Science and Technology, 2005, 42(2), 225-232 [11] Q.J.Peng, J.Kwon, T.Shoji.
Journal of Nuclear Materials, 2004, 324(1), 52-61
Transactions of the ASME- Journal of Pressure Vessel and Technology, 2009, 131(1), 61-70 [6] D.
Standard test method for plane strain fracture toughness of metallic materials, Annual book of ASTM Standards, Vol. 03.01, ASTM International, 2002 [8] ABAQUS/Standard User’s Manual.
Nuclear Science and Technology, 2005, 42(2), 225-232 [11] Q.J.Peng, J.Kwon, T.Shoji.
Journal of Nuclear Materials, 2004, 324(1), 52-61
Online since: February 2019
Authors: Denis A. Rogozhnikov, Oleg A. Dizer, Stanislav S. Naboichenko
It must be mentioned that each of these methods has advantages and disadvantages, and each technology is selected for specific raw materials.
Materials and Methods Investigation of materials The raw material being investigated was a persistent gold-sulphide flotation concentrate of the Uderey’s deposit with the size of 100% -0.074 mm.
Summary Based on the results of the analytical studies of the chemical and phase compositions of the materials studied.
Acknowledgements Results has been obtained under support of the Russian Science Foundation under grant № 18-19-00186.
Journal of Siberian Federal University, Chemistry, 11 (2018) 110-121
Materials and Methods Investigation of materials The raw material being investigated was a persistent gold-sulphide flotation concentrate of the Uderey’s deposit with the size of 100% -0.074 mm.
Summary Based on the results of the analytical studies of the chemical and phase compositions of the materials studied.
Acknowledgements Results has been obtained under support of the Russian Science Foundation under grant № 18-19-00186.
Journal of Siberian Federal University, Chemistry, 11 (2018) 110-121
Online since: May 2020
Authors: Bao Chang Liu, Shuai Zhang, Yue Zhu, Shu Jing Wang, Kun Bi, Wen Hao Dai
Materials. 9 (2016) 1006
Materials & Design. 31 (2010) 522–526
Materials & Design. 87 (2015) 482-487
Journal of Superhard Materials. 40 (2018) 110-117
International Journal of Refractory Metals& Hard Materials. 79 (2019) 115-122.
Materials & Design. 31 (2010) 522–526
Materials & Design. 87 (2015) 482-487
Journal of Superhard Materials. 40 (2018) 110-117
International Journal of Refractory Metals& Hard Materials. 79 (2019) 115-122.
Online since: May 2015
Authors: Yu Shun Cheng, Fang Sung Cheng
Journal of Materials Processing Technology 187-188, 649-652
Materials Science Forum. 704-705, 252-260
Journal of Materials Processing Technology 214, 97-105
Journal of Materials Processing Technology 149, 272-277
Journal of Materials Processing Technology 209, 3060-3068
Materials Science Forum. 704-705, 252-260
Journal of Materials Processing Technology 214, 97-105
Journal of Materials Processing Technology 149, 272-277
Journal of Materials Processing Technology 209, 3060-3068
Online since: September 2019
Authors: Alain Iost, Nouel Hezil, Fethia Bouaksa, Mohamed Zine Touhami, Alex Montagne, Aleksei Obrosov, Ridha Djellabi, Alberto Mejias, Mamoun Fellah
and novel materials, university of sciences and technology, BP-1505 El M’naouar, Oran, Algeria.
7Department of Physical Metallurgy and Materials Technology, Brandenburg Technical University, 03046 Cottbus, Germany.
Materials Letters, 155 (2015) 75-77
Materials Science & Engineering.
Construction and Building Materials, 175 (2018) 653-663
Journal of Membrane Science, 225 (1-2) (2003) 177–186
Materials Letters, 155 (2015) 75-77
Materials Science & Engineering.
Construction and Building Materials, 175 (2018) 653-663
Journal of Membrane Science, 225 (1-2) (2003) 177–186
Online since: September 2019
Authors: Mariamu K. Ali, A.A. Moneim
Journal of Materials Chemistry C 5, no. 18 (2017): 4350-4360
Journal of Electronic Materials 47, no. 1 (2018): 242-250
Progress in Materials Science 73 (2015): 44-126
Journal of Materials Chemistry A 4, no. 14 (2016): 5265-5273
Journal of Materials Science: Materials in Electronics 29, no. 20 (2018): 17445-17453
Journal of Electronic Materials 47, no. 1 (2018): 242-250
Progress in Materials Science 73 (2015): 44-126
Journal of Materials Chemistry A 4, no. 14 (2016): 5265-5273
Journal of Materials Science: Materials in Electronics 29, no. 20 (2018): 17445-17453
Online since: February 2011
Authors: Jing Liu, Bo Lin He, Ying Xia Yu
It is an effective way to surface strengthening of metallic materials.
Besides, he built up The deformation and diffusion model of the nanocrystalline material was built up by the auther.The friction damage and the sliding contact fatigue damage under sliding contact load were analyzed by using the nanocrystalline material with the average grain size smaller than 100nm, micro nanocrystalline materials with 100nm~1000nm and micron materials[18].
The results show that the nanocrystalline materials not only can perfectly resist the friction damage and sliding contact fatigue damage, but also reduced the friction coefficient obviously comparing with the micro nanocrystalline materials and the micron materials.
The nanocrystalline microstructure obtained can enhance the strength of the materials in certain degree.
Ovid’ko: International Materials Reviews, Vol.50(2005), p.65 [18]T.
Besides, he built up The deformation and diffusion model of the nanocrystalline material was built up by the auther.The friction damage and the sliding contact fatigue damage under sliding contact load were analyzed by using the nanocrystalline material with the average grain size smaller than 100nm, micro nanocrystalline materials with 100nm~1000nm and micron materials[18].
The results show that the nanocrystalline materials not only can perfectly resist the friction damage and sliding contact fatigue damage, but also reduced the friction coefficient obviously comparing with the micro nanocrystalline materials and the micron materials.
The nanocrystalline microstructure obtained can enhance the strength of the materials in certain degree.
Ovid’ko: International Materials Reviews, Vol.50(2005), p.65 [18]T.
Online since: July 2015
Authors: Daria Pelevina, Vladimir Turkov, Sergey Kalmykov, Vera Naletova
The influence of a rotating magnetic field on the sample with
magnetizable materials near the vessel bottom
Daria Pelevina1,a∗, Vladimir Turkov1,b, Sergey Kalmykov1,c
and Vera Naletova1,d
Lomonosov Moscow State University, Leninskiye gory, 119992, Moscow, Russia
apelevina.daria@gmail.com, bturkov@imec.msu.ru, ckalmykov.sergei@gmail.com,
dnaletova@imec.msu.ru
Keywords: Magnetic fluid drop, body with magnetizable polymer, rotating magnetic field, translational
motion.
All results of this paper is presented for the field rotated clockwise.Table 1: Properties of magnetizable materials Material Carrier medium Material of Density Saturation Initial particles [kg/m3] magnetization, [kA/m] susceptibility MF EFH1 light hydrocarbon magnetite 1210 31.8 1.89 MP silicone rubber nickel 3600 394 4.39 The motion of the MF drop In the experiments the MF drop with volume V0 = 14.2 mm3 is placed in the vessel, filled with a mixture of glycerol and water in equal proportions by volume.
Morozov, Rotation of a droplet in a viscous fluid, Journal of Experimental and Theoretical Physics 85 (4) (1997) 728-733
Richter, Rolling ferrofluid drop on the surface of a liquid, New Journal of Physics 10 (2008) 063029
Dikansky, Motion of a deformable drop of magnetic fluid on a solid surface in a rotating magnetic field, Experimental Thermal and Fluid Science. 39 (2012), 265-268.
All results of this paper is presented for the field rotated clockwise.Table 1: Properties of magnetizable materials Material Carrier medium Material of Density Saturation Initial particles [kg/m3] magnetization, [kA/m] susceptibility MF EFH1 light hydrocarbon magnetite 1210 31.8 1.89 MP silicone rubber nickel 3600 394 4.39 The motion of the MF drop In the experiments the MF drop with volume V0 = 14.2 mm3 is placed in the vessel, filled with a mixture of glycerol and water in equal proportions by volume.
Morozov, Rotation of a droplet in a viscous fluid, Journal of Experimental and Theoretical Physics 85 (4) (1997) 728-733
Richter, Rolling ferrofluid drop on the surface of a liquid, New Journal of Physics 10 (2008) 063029
Dikansky, Motion of a deformable drop of magnetic fluid on a solid surface in a rotating magnetic field, Experimental Thermal and Fluid Science. 39 (2012), 265-268.
Online since: December 2024
Authors: Muhammad Hammad Rasool, Maqsood Ahmad, Husnain Ali, Nimra Tariq Bajwa, Numair Ahmed Siddiqui
Materials and Methods
2.1.
Materials Ascorbic Acid 99%> and Glycerine (99USP) have been procured from EvaChem, Selangor, Malaysia. 2.2.
This information holds significance as it can impact the chemical reactivity and stability of NADES, as well as their compatibility with other materials or processes.
Prandi, Promising technological and industrial applications of deep eutectic systems, Materials, 14 (2021) 2494
Jadhav, Novel curcumin ascorbic acid cocrystal for improved solubility, Journal of Drug Delivery Science and Technology, 61 (2021) 102233
Materials Ascorbic Acid 99%> and Glycerine (99USP) have been procured from EvaChem, Selangor, Malaysia. 2.2.
This information holds significance as it can impact the chemical reactivity and stability of NADES, as well as their compatibility with other materials or processes.
Prandi, Promising technological and industrial applications of deep eutectic systems, Materials, 14 (2021) 2494
Jadhav, Novel curcumin ascorbic acid cocrystal for improved solubility, Journal of Drug Delivery Science and Technology, 61 (2021) 102233