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Online since: April 2013
Authors: Ibrahim Deiab, Amir Rashid, Mihai Nicolescu, Salman Pervaiz, Basil Darras
Titanium alloys are labeled as difficult to materials because of their low machinability rating.
These alloys are termed as “Difficult-to-cut materials” because of their low machiability rating.
Wear mechanisms such as adhesion, abrasion and diffusion depends on the tool and workpiece materials and the cutting temperature.
[6] Zoya, Z.A., Krishnamurthy, R., 2000, The performance of CBN tools in the machining of titanium alloys, Journal of Materials Processing Technology. 100; 80–86
[18] Jawaid, A., Che-Haron, C.H. and Abdullah, A., “Tool wear characteristics in turning of Titanium Alloy Ti - 6246,” Journal of Materials Processing Technology, Vol. 92-93, pp. 329-334, 1999
These alloys are termed as “Difficult-to-cut materials” because of their low machiability rating.
Wear mechanisms such as adhesion, abrasion and diffusion depends on the tool and workpiece materials and the cutting temperature.
[6] Zoya, Z.A., Krishnamurthy, R., 2000, The performance of CBN tools in the machining of titanium alloys, Journal of Materials Processing Technology. 100; 80–86
[18] Jawaid, A., Che-Haron, C.H. and Abdullah, A., “Tool wear characteristics in turning of Titanium Alloy Ti - 6246,” Journal of Materials Processing Technology, Vol. 92-93, pp. 329-334, 1999
Online since: March 2014
Authors: Zhi Chen, He Li, Yu Huang, Zhen Zhang
Journal of materials processing technology 141.3 (2003): 295-301
Journal of materials processing technology 58.4 (1996): 385-389
Journal of Materials Processing Technology 94.2 (1999): 208-215
International Journal of Machine Tools and Manufacture 43.2(2003): 151-159
International Journal of Computer Integrated Manufacturing 19.7 (2006): 727-735
Journal of materials processing technology 58.4 (1996): 385-389
Journal of Materials Processing Technology 94.2 (1999): 208-215
International Journal of Machine Tools and Manufacture 43.2(2003): 151-159
International Journal of Computer Integrated Manufacturing 19.7 (2006): 727-735
Online since: December 2011
Authors: Hu Cai, Peng Zhang, Yuan Xun Wang
Surface coefficient of heat transfer of materials
temperature (°C)
20
100
200
300
400
500
600
700
800
900
1000
copper electrode (W/m2·°C)
0
11.16
15.31
19.96
25.62
32.57
41.02
51.20
63.29
77.50
94
DP600
(W/m2·°C)
25
Thermoelectric Properties of Materials.
Chicago, USA, 2004, 539~545 [3] Shi G, Westgate S.A, Resistance spot welding of high strength steels, International Journal for the Joining of Materials, 2004, 16 (1)9~14 [4] Agashe S, Zhang H, Selection of schedules based on heat balance in resistance spot welding, Welding Journal, 2003 (7)179~183 [5] Aslanlar S, The effect of nucleus size on mechanical properties in electrical resistance spot welding of sheets used in automotive industry.
Materials and Design, 2006, 27, 125~131 [6] Xu J.H, Jiang X.P, Zeng Q,et al, Optimization of resistance spot welding on the assembly of refractory alloy 50Mo-50Re thin sheet, Journal of Nuclear Materials, 2007, 366, 417~425 [7] Aslanlar S, Ogur A, Ozsarac U, et al, Effect of welding current on mechanical properties of galvanized chromided steel sheets in electrical resistance spot welding, Materials and Design, 2007, 28, 2~7 [8] Kahraman N, The influence of welding parameters on the joint strength of resistance spot-welded titanium sheets, Materials and Design, 2007, 28, 420~427 [9] Bouyousfi B, Sahraoui T, Guessasma S, et al, Effect of process parameters on the physical characteristics of spot weld joints.
Materials and Design, 2007, 28, 414~419 [10] Long X, Khanna S.K, Fatigue properties and failure characterization of spot welded high strength steel sheet, International Journal of Fatigue, 2007 29, 879~886 [11] Sun D.Q, Lang B, Sun D.X, et al, Microstructures and mechanical properties of resistance spot welded magnesium alloy joints, Materials Science and Engineering A, 2007, 460-461: 494 ~498 [12] Kearns W.H, Welding Processes, AWS Welding Handbook, 3. 7th ed.
Journal of Materials Processing Technology, 2008, 327~335 [14] Marashi P, Pouranvari M., Amirabdollahian S, et al, Microstructure and failure behavior of dissimilar resistance spot welds between low carbon galvanized and austenitic stainless steels, Materials Science and Engineering A, 2008, 480 (1-2)175~180 [15] Wang L, Wang M., Lu F.G, Dynamic simulation of resistance spot welding of zinc-coated steels, China Welding, 2006, 15(4)39~42 [16] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅠ-modeling studies, Welding Journal, 1994, 73(4)67~74 [17] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅡ-experimental studies, Welding Journal, 1994, 73(5)91~100
Chicago, USA, 2004, 539~545 [3] Shi G, Westgate S.A, Resistance spot welding of high strength steels, International Journal for the Joining of Materials, 2004, 16 (1)9~14 [4] Agashe S, Zhang H, Selection of schedules based on heat balance in resistance spot welding, Welding Journal, 2003 (7)179~183 [5] Aslanlar S, The effect of nucleus size on mechanical properties in electrical resistance spot welding of sheets used in automotive industry.
Materials and Design, 2006, 27, 125~131 [6] Xu J.H, Jiang X.P, Zeng Q,et al, Optimization of resistance spot welding on the assembly of refractory alloy 50Mo-50Re thin sheet, Journal of Nuclear Materials, 2007, 366, 417~425 [7] Aslanlar S, Ogur A, Ozsarac U, et al, Effect of welding current on mechanical properties of galvanized chromided steel sheets in electrical resistance spot welding, Materials and Design, 2007, 28, 2~7 [8] Kahraman N, The influence of welding parameters on the joint strength of resistance spot-welded titanium sheets, Materials and Design, 2007, 28, 420~427 [9] Bouyousfi B, Sahraoui T, Guessasma S, et al, Effect of process parameters on the physical characteristics of spot weld joints.
Materials and Design, 2007, 28, 414~419 [10] Long X, Khanna S.K, Fatigue properties and failure characterization of spot welded high strength steel sheet, International Journal of Fatigue, 2007 29, 879~886 [11] Sun D.Q, Lang B, Sun D.X, et al, Microstructures and mechanical properties of resistance spot welded magnesium alloy joints, Materials Science and Engineering A, 2007, 460-461: 494 ~498 [12] Kearns W.H, Welding Processes, AWS Welding Handbook, 3. 7th ed.
Journal of Materials Processing Technology, 2008, 327~335 [14] Marashi P, Pouranvari M., Amirabdollahian S, et al, Microstructure and failure behavior of dissimilar resistance spot welds between low carbon galvanized and austenitic stainless steels, Materials Science and Engineering A, 2008, 480 (1-2)175~180 [15] Wang L, Wang M., Lu F.G, Dynamic simulation of resistance spot welding of zinc-coated steels, China Welding, 2006, 15(4)39~42 [16] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅠ-modeling studies, Welding Journal, 1994, 73(4)67~74 [17] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅡ-experimental studies, Welding Journal, 1994, 73(5)91~100
Online since: April 2012
Authors: Ya Dong Bian, Ran Hai
Journal of Tongji University(Natural Science), 34(2006) 786-789
Journal of Building Materials, 12(2009) 88-91
Journal of Building Materials, 9(2006) 593-597
New Building Materials, 6(2005) 12-14
Inorganic materials science, Henan Science and Technology Press, Zhengzhou, 1998.
Journal of Building Materials, 12(2009) 88-91
Journal of Building Materials, 9(2006) 593-597
New Building Materials, 6(2005) 12-14
Inorganic materials science, Henan Science and Technology Press, Zhengzhou, 1998.
Online since: June 2017
Authors: Y. Zhao, S.J. Chen, Jian Xiao
Journal of Materials Processing Technology,2008, 439–448
Journal of Materials Processing Technology, 2008, 203(1-3):439-448
Journal of Materials Processing Technology,2013,213:1782-1791
Journal of Materials Processing Technology,2004,148,93-102 [13] J.J.
Materials and Design,2016,102:30-40
Journal of Materials Processing Technology, 2008, 203(1-3):439-448
Journal of Materials Processing Technology,2013,213:1782-1791
Journal of Materials Processing Technology,2004,148,93-102 [13] J.J.
Materials and Design,2016,102:30-40
Online since: March 2012
Authors: Xin Min Huang, Yong Qiang Qin, Jun Li Cao, Yu Cheng Wu, He Bing Han
Microstructure and Properties of a Bismuth-Brass
Hebing Han 1, 2, 3, Xinmin Huang 1, 2, 3, a, Yucheng Wu 1, 2, 3, b,
Yongqiang Qin 1, 2, 3, Junli Cao 1, 2, 3
1School of Materials Science and Engineering, Hefei University of Technology, Hefei 230009, China
2Laboratory of Nonferrous Metal Materials and Processing Engineering of Anhui province, Hefei 230009, China
3Engineering Technology Research Institute of Hefei University of Technology-Tongling, Tongling 244000, China
axmhuang808@163.com, bycwu@hfut.edu.cn
Keywords: Bismuth-brass; Microstructure; Mechanical properties; Free-cutting.
Journal of Materials Science, 1994, 29(9): 1692-1699
Environmental Protection Science, 2005, 31(4): 41-42
Journal of the Japan Institute of Metals, 2005, 69(2): 198-201
Materials Characterization, 2006, 57:424-429
Journal of Materials Science, 1994, 29(9): 1692-1699
Environmental Protection Science, 2005, 31(4): 41-42
Journal of the Japan Institute of Metals, 2005, 69(2): 198-201
Materials Characterization, 2006, 57:424-429
Online since: August 2015
Authors: Stefanie Reese, Marek Fassin, Stephan Wulfinghoff
Finite element analysis of composite materials.
On the coupling of anisotropic damage and plasticity models for ductile materials.
International journal of engineering science, 41(13):1535-1551, 2003.[11] S.
Computational Materials Science, 45(3):756-761, 2009
International Journal of Nonlinear Sciences and Numerical Simulation, 3(1):1-34, 2002
On the coupling of anisotropic damage and plasticity models for ductile materials.
International journal of engineering science, 41(13):1535-1551, 2003.[11] S.
Computational Materials Science, 45(3):756-761, 2009
International Journal of Nonlinear Sciences and Numerical Simulation, 3(1):1-34, 2002
Online since: July 2011
Authors: Yong Chen Song, Yong Shen, Wei Wei Jian, Yang Chun Zhan, Yi Zhang, Ying Hua Guan
Shen: Journal of Thermal Science and Technology, Vol. 2 (2003) No.4, P.358.
Ohshima: Polymer Engineering And Science, Vol.44 (2004) No.10, p.1915
Sayari: Chemical Engineering Science, Vol.64 (2009), p3721
Staudt: Microporous and Mesoporous Materials, Vol. 138 (2011), p.140
Ohshima: Polymer Engineering and Science, Vol. 42 (2002), p. 2234
Ohshima: Polymer Engineering And Science, Vol.44 (2004) No.10, p.1915
Sayari: Chemical Engineering Science, Vol.64 (2009), p3721
Staudt: Microporous and Mesoporous Materials, Vol. 138 (2011), p.140
Ohshima: Polymer Engineering and Science, Vol. 42 (2002), p. 2234
Online since: September 2013
Authors: Xue Mei Wang, Xue Xin Huang
ABCD classification of materials is the more commonly used method.
Use AHP to determine the weight of each factor, sort the classification of materials treat classified materials and get two index values (Wa, Wb)(refer with: Tab. 1).
Tab. 1 Material classification table Material classification Wa Wb Strategic materials Wa>Wa* Wbmaterials
Wa>Wa*
Wb>Wb*
Bottlenecks materials
Wamaterials
WaWb*
The principle of TOPSIS
TOPSIS (Technique for order preference by similarity to ideal solution) also known as the ideal solution is developed by CL Hwang in 1981 [4].
Without the need for cooperation in the case, is now on the four materials supplier evaluation.
Journal of Harbin Institute of Technology” Journal of Harbin Institute of Technology, China, 260-263 April 2009
Use AHP to determine the weight of each factor, sort the classification of materials treat classified materials and get two index values (Wa, Wb)(refer with: Tab. 1).
Tab. 1 Material classification table Material classification Wa Wb Strategic materials Wa>Wa* Wb
Without the need for cooperation in the case, is now on the four materials supplier evaluation.
Journal of Harbin Institute of Technology” Journal of Harbin Institute of Technology, China, 260-263 April 2009
Online since: August 2015
Authors: Didik Aryanto, Putut Marwoto, Edy Wibowo, Sugianto Sugianto, Sulhadi Sulhadi, Yanti Yanti
It is because sputtering can be used to produce thin films from materials that have high melting points [1,4].
Experimental A mixture of ZnO (99.999%) and Al2O3 (99.999%) was employed as pellet made-materials then used as a sputtered target.
Wahyuningsih, Room-temperature deposition of zno thin films by using dc magnetron sputtering, Advanced Materials Research 896 (2014) 237-240
Karppinen, Electron doping of ALD-grown ZnO thin films through Al and P substitutions, Journal of Materials Science 48 (2013) 2806-2811
Rezig, Effect of the substrate temperature on the Properties of ZnO films grown by RF magnetron sputtering, Materials Science and Engineering B 109 (2004) 236–240.
Experimental A mixture of ZnO (99.999%) and Al2O3 (99.999%) was employed as pellet made-materials then used as a sputtered target.
Wahyuningsih, Room-temperature deposition of zno thin films by using dc magnetron sputtering, Advanced Materials Research 896 (2014) 237-240
Karppinen, Electron doping of ALD-grown ZnO thin films through Al and P substitutions, Journal of Materials Science 48 (2013) 2806-2811
Rezig, Effect of the substrate temperature on the Properties of ZnO films grown by RF magnetron sputtering, Materials Science and Engineering B 109 (2004) 236–240.