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Online since: January 2016
Authors: Zhan Qiang Liu, Zhao Jun Kou, Yu Chao Li, Yu Kui Cai
The experimental results presented that the dimensions of burr could reduce greatly by the proposed PMMA coating method compared to materials without coating.
However, owing to its properties of poor heat conduction, high chemical reactivity and low elastic modulus, titanium alloy easily reacts to tool materials at high temperature caused by narrow cutting zone, which makes it be considered as typical difficult-to-machine materials.
Toropov et al[6] established a prediction model for burr formation in machining of ductile materials.
Journal of Engineering Materials and Technology, 1991, 113(1):75-87
A new burr formation model for orthogonal cutting of ductile materials[J].
However, owing to its properties of poor heat conduction, high chemical reactivity and low elastic modulus, titanium alloy easily reacts to tool materials at high temperature caused by narrow cutting zone, which makes it be considered as typical difficult-to-machine materials.
Toropov et al[6] established a prediction model for burr formation in machining of ductile materials.
Journal of Engineering Materials and Technology, 1991, 113(1):75-87
A new burr formation model for orthogonal cutting of ductile materials[J].
Online since: March 2017
Authors: Samya Dahbi, Latifa Ezzine, Haj El Moussami
Tarng, Design optimization of cutting parameters for turning operations based on the Taguchi method, Journal of Materials Processing Technology, 84 (1998) 122-129
Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems, fourth ed., John Wiley & Sons, New Jersey, 2010
Siddiqueed, RSM based study of cutting temperature during hard turning with Multilayer Coated Carbide Insert, Procedia Materials Science, 6 (2014) 1233-1242
Dolinsek, Tribology of coated tools in conventional and HSC machining, Journal of Materials Processing Technology, 118 (2001) 377-384
Melkote, Effect of cutting edge geometry and work piece hardness on surface generation in the finish hard turning of AISI 52100 steel, Journal of Materials Processing Technology, 94 (1999) 216-226
Groover, Fundamentals of Modern Manufacturing: Materials, Processes, and Systems, fourth ed., John Wiley & Sons, New Jersey, 2010
Siddiqueed, RSM based study of cutting temperature during hard turning with Multilayer Coated Carbide Insert, Procedia Materials Science, 6 (2014) 1233-1242
Dolinsek, Tribology of coated tools in conventional and HSC machining, Journal of Materials Processing Technology, 118 (2001) 377-384
Melkote, Effect of cutting edge geometry and work piece hardness on surface generation in the finish hard turning of AISI 52100 steel, Journal of Materials Processing Technology, 94 (1999) 216-226
Online since: April 2012
Authors: Shao Peng Wu, Jun Han, Jin Shan Wang, Xing Liu
Construction and Building Materials, 22 (2008) 1906~1913
Journal of Hazardous Materials 150 (2008) 424~432 [5] WEI Rong-mei, YU Jian-ying, WU Shao-peng, et al.
Journal of Zhengzhou University (Engineering Science), 2008, Vol.29, No.4, [8] YE Fen.
Function Materials. 2004,Vol.35,83~86 [20] XING Yin.
Journal of Chang-an University: Natural Science Edition, 2007, 27 (4):6~9.
Journal of Hazardous Materials 150 (2008) 424~432 [5] WEI Rong-mei, YU Jian-ying, WU Shao-peng, et al.
Journal of Zhengzhou University (Engineering Science), 2008, Vol.29, No.4, [8] YE Fen.
Function Materials. 2004,Vol.35,83~86 [20] XING Yin.
Journal of Chang-an University: Natural Science Edition, 2007, 27 (4):6~9.
Online since: April 2013
Authors: Mohd Amri Lajis, M.I. Daud, Mohamad Zaky Noh, N.K. Yusuf
Journal of Materials Processing Technology. (1996). 60: 719-722
Journal of Materials Processing Technology. (1997). 64:149-156
Journal of Materials Processing Technology. (2000).106:34-39
Materials Science Forum. (2007). 544-54
Materials Science and Engineering. (2003).
Journal of Materials Processing Technology. (1997). 64:149-156
Journal of Materials Processing Technology. (2000).106:34-39
Materials Science Forum. (2007). 544-54
Materials Science and Engineering. (2003).
Online since: November 2025
Authors: Viktoriya Pasternak, Artem Ruban, Dmitry Bazaliiev, Kyrylo Pasynchuk, Jerzy Telak
Materials.
Journal of Materials Processing Tech.. 299 (2022) 1–15
Materials Science Forum. 1038 (2021) 492–499 [33] Hai.
Materials Science Forum. 1038 (2021) 15–24
Materials Science Forum. 1038 (2021) 460–467.
Journal of Materials Processing Tech.. 299 (2022) 1–15
Materials Science Forum. 1038 (2021) 492–499 [33] Hai.
Materials Science Forum. 1038 (2021) 15–24
Materials Science Forum. 1038 (2021) 460–467.
Online since: February 2011
Authors: Taghi Tabarsa, Hossein Khanjanzadeh, Hamidreza Pirayesh
Introduction
Wood plastic composites (WPCs) are defined as composite materials containing wood (in various forms) and thermoplastic materials.
Properties of some waste plastics are similar to those made from virgin materials.
A.; Rowell, R.M. in: Materials Interactions Relevant to Recycling of Wood-Based Materials, Rowell, R.
K., Eds.; Materials Research Society: Pittsburg, PA, 1992; Vol. 266, p 3
Mechanical Properties of Composites from Sawdust and Recycled Plastics, Journal of Applied Polymer Science, Vol. 100, 3641–3645 (2006).
Properties of some waste plastics are similar to those made from virgin materials.
A.; Rowell, R.M. in: Materials Interactions Relevant to Recycling of Wood-Based Materials, Rowell, R.
K., Eds.; Materials Research Society: Pittsburg, PA, 1992; Vol. 266, p 3
Mechanical Properties of Composites from Sawdust and Recycled Plastics, Journal of Applied Polymer Science, Vol. 100, 3641–3645 (2006).
Online since: September 2014
Authors: Chun Fang Wang, Kai Kun Wang, Zhe Luo
The main aim of this paper is to simulate the flexible thixo-extrusion process of aluminum alloy A356 and investigate the control method of materials flow front.
Combining with the lack of the available data of high volume solid fraction semi-solid materials, it is difficult to obtain the flow stress of the material during the extrusion process.
International Journal of Minerals, Metallurgy and Materials, 2010, 17(1): 53-57
International Journal of Minerals, Metallurgy and Materials, 2009, 16(3): 309-313
Journal of Matetials Processing Technology, 2006:360-363
Combining with the lack of the available data of high volume solid fraction semi-solid materials, it is difficult to obtain the flow stress of the material during the extrusion process.
International Journal of Minerals, Metallurgy and Materials, 2010, 17(1): 53-57
International Journal of Minerals, Metallurgy and Materials, 2009, 16(3): 309-313
Journal of Matetials Processing Technology, 2006:360-363
Online since: December 2025
Authors: Manuel Jr. Cabiguen, Ismail Mohd Saaid, Lexyber Manalo, Jayson D. Santos
,Liu, F.; and Zhou, J., The synthesis of a novel magnetic demulsifier and its application for the demulsification of oil-charged industrial wastewaters, Journal of Materials Chemistry A (2014) 2(1), 94-99
E., Covalent functionalized magnetic nanoparticles for crude oil recovery, Materials Chemistry and Physics (2019) 238 121910
A., Magnetic polyester bis-MPA dendron nanohybrid demulsifier can effectively break water-in-crude oil emulsions, Journal of Materials Research and Technology (2020) 9(6), 13411-13424
[64] Liu, J., Li, X., Jia, W., Ding, M., Zhang, Y.; and Ren, S., Separation of Emulsified Oil from Oily Wastewater by Functionalized Multiwalled Carbon Nanotubes, Journal of Dispersion Science and Technology (2016) 37(9), 1294-1302 [65] Zhang, F., Liu, G., Ma, J., Ouyang, J., Yi, X.; and Su, H., Main challenges in demulsifier research and application, IOP Conference Series: Materials Science and Engineering (2017)
A. and Abdulkhabeer, A., Synthesis of novel demulsifier nano-materials and their application in the oil industry, Materials today: proceedings (2022) 49 2842-2850
E., Covalent functionalized magnetic nanoparticles for crude oil recovery, Materials Chemistry and Physics (2019) 238 121910
A., Magnetic polyester bis-MPA dendron nanohybrid demulsifier can effectively break water-in-crude oil emulsions, Journal of Materials Research and Technology (2020) 9(6), 13411-13424
[64] Liu, J., Li, X., Jia, W., Ding, M., Zhang, Y.; and Ren, S., Separation of Emulsified Oil from Oily Wastewater by Functionalized Multiwalled Carbon Nanotubes, Journal of Dispersion Science and Technology (2016) 37(9), 1294-1302 [65] Zhang, F., Liu, G., Ma, J., Ouyang, J., Yi, X.; and Su, H., Main challenges in demulsifier research and application, IOP Conference Series: Materials Science and Engineering (2017)
A. and Abdulkhabeer, A., Synthesis of novel demulsifier nano-materials and their application in the oil industry, Materials today: proceedings (2022) 49 2842-2850
Online since: February 2019
Authors: Olga Yu. Makovskaya, K.S. Kostromin
Castro, Leaching behaviour of a galvanic sludge in sulphuric acid and ammoniacal media, Journal of Hazardous Materials, B121 (2005) 195-202
Bernardes, Galvanic sludge metals recovery by pyrometallurgical and hydrometallurgical treatment, Journal of Hazardous Materials, 131 (2006) 210-216
Koutny, Stabilization/solidification of galvanic sludges by asphalt emulsions, Journal of Hazardous Materials, 122(1-2) (2005) 139-45
Castro, Solvent extraction applied to the recovery of heavy metals from galvanic sludge, Journal of Hazardous Materials B120 (2005) 113-118
Carneiro, A, Ribeiro, Development of a Process for Copper Recovering from Galvanic Sludges, Materials Science Forum 730-732 (2013) 575-580
Bernardes, Galvanic sludge metals recovery by pyrometallurgical and hydrometallurgical treatment, Journal of Hazardous Materials, 131 (2006) 210-216
Koutny, Stabilization/solidification of galvanic sludges by asphalt emulsions, Journal of Hazardous Materials, 122(1-2) (2005) 139-45
Castro, Solvent extraction applied to the recovery of heavy metals from galvanic sludge, Journal of Hazardous Materials B120 (2005) 113-118
Carneiro, A, Ribeiro, Development of a Process for Copper Recovering from Galvanic Sludges, Materials Science Forum 730-732 (2013) 575-580
Online since: November 2010
Authors: Hang Wu, Wei Guo, Zhen Zhong Zheng, Qing Chang Chen, Qing Guo Chu
They are: sintering time: 3 hours; sintering temperature: 1073.15 k; flux NaCl amount: 15% wt of the reaction raw materials; Fe / Sr molar ratio: 11.4; the sample magnetic properties: Ms = 63.39emu / g; Mr = 33.44emu / g; Hc = 5798Oe, Mr / Ms = 1 : 1.90 ≈ 1:2.
Strontium ferrite sintered magnetic material is the extremely important permanent magnet because of it’s lower processing cost and wide availability of raw materials great anti-oxidation, high coercivity and energy product, uniaxial magnetic anisotropy, Strontium ferrite plastic magnet (SrFe12O19) is widely used as permanent magnetic materials[4].
All data showed the optimum SrFe12O19 conditions were: 3 hours sintering time, at 1073.15 k, flux NaCl of 15% raw materials w.t., 11.4 Fe / Sr molar ratio.
of Magnetic Materials and Devices, Vol. 37 (2006), p. 17 [5] J.I.Kraschwitz, Mary Howe-grant: Encyclopedia of Chemical Technology, Vol. 10 (1993), p. 381 [6] N.Dishovske, A.Petkov, Iv.Nedkov: IEEE Trans.Magn, Vol. 30 (1994), p. 969 [7] Y.W.Dou, Ferrite, Jiangsu Science and Technology Press, Nanjing, 1996
[8] H.Su, H.W.Zhang, X.L.Tang, Y.L.Jing, Y.L.Liu: J.Magn.Magn.Mater, Vol. 310 (2007), p. 17 [9] N.Rezlescu, L.Sachelarie, E.Rezlescu, C.L.Sava, P.Popa: Ceram.Int, Vol. 29 (2003), p. 107 [10] B.P.Rao,C.O.Kim,C.G.Kim,Mater.Lett, Vol. 16 (2007), p. 1601 [11] Jotania R B,Khomane R B,Chatelon JP, et al: J.Magn.Magn.Mater, Vol. 320 (2008), p.1095 [12] Radwan M, Rashad M M: Journal of Materials Processing Technology, Vol. 181 (2007), p. 106 [13] Pablo Hernandez-Gomez, Carlos Torres, et al: Magnet Magnet Mater, Vol. 304 (2006), p. 766 [14] WANG Xiaorui, JIN Minglin, et: Materials Review, Vol. 22 (2008), p. 105
Strontium ferrite sintered magnetic material is the extremely important permanent magnet because of it’s lower processing cost and wide availability of raw materials great anti-oxidation, high coercivity and energy product, uniaxial magnetic anisotropy, Strontium ferrite plastic magnet (SrFe12O19) is widely used as permanent magnetic materials[4].
All data showed the optimum SrFe12O19 conditions were: 3 hours sintering time, at 1073.15 k, flux NaCl of 15% raw materials w.t., 11.4 Fe / Sr molar ratio.
of Magnetic Materials and Devices, Vol. 37 (2006), p. 17 [5] J.I.Kraschwitz, Mary Howe-grant: Encyclopedia of Chemical Technology, Vol. 10 (1993), p. 381 [6] N.Dishovske, A.Petkov, Iv.Nedkov: IEEE Trans.Magn, Vol. 30 (1994), p. 969 [7] Y.W.Dou, Ferrite, Jiangsu Science and Technology Press, Nanjing, 1996
[8] H.Su, H.W.Zhang, X.L.Tang, Y.L.Jing, Y.L.Liu: J.Magn.Magn.Mater, Vol. 310 (2007), p. 17 [9] N.Rezlescu, L.Sachelarie, E.Rezlescu, C.L.Sava, P.Popa: Ceram.Int, Vol. 29 (2003), p. 107 [10] B.P.Rao,C.O.Kim,C.G.Kim,Mater.Lett, Vol. 16 (2007), p. 1601 [11] Jotania R B,Khomane R B,Chatelon JP, et al: J.Magn.Magn.Mater, Vol. 320 (2008), p.1095 [12] Radwan M, Rashad M M: Journal of Materials Processing Technology, Vol. 181 (2007), p. 106 [13] Pablo Hernandez-Gomez, Carlos Torres, et al: Magnet Magnet Mater, Vol. 304 (2006), p. 766 [14] WANG Xiaorui, JIN Minglin, et: Materials Review, Vol. 22 (2008), p. 105