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Online since: December 2012
Authors: Guo Tian He, Zhi Zeng, Li Song, Ying Chun Ran, Yan Ma, Song Wang, De Sheng Zhang, Ming Li
Magneto-rheological grease attracts the attention as a new kind of intelligent material.
For example, magneto-rheological grease is a new intelligent material; it has become an important branch of intelligent material field.
Many foreign experts have been carried out research using computer simulation technology for magneto-rheological smart materials, but it has great differentia between simulation results and the actual rheological properties, and mostly on the simulation of Bingham model and it’s improved.
Liao, “Study on MR semi-active suspension system and its road testing,” journal of intelligent material system and structures,Vol.17,p p801-803,2006 [2] B.F.
Journal of Zhejiang University Science,Vol.5:pp514-519,2003 [11] M.J.
For example, magneto-rheological grease is a new intelligent material; it has become an important branch of intelligent material field.
Many foreign experts have been carried out research using computer simulation technology for magneto-rheological smart materials, but it has great differentia between simulation results and the actual rheological properties, and mostly on the simulation of Bingham model and it’s improved.
Liao, “Study on MR semi-active suspension system and its road testing,” journal of intelligent material system and structures,Vol.17,p p801-803,2006 [2] B.F.
Journal of Zhejiang University Science,Vol.5:pp514-519,2003 [11] M.J.
Online since: November 2016
Authors: V.V. Praveen, K.M. Peethambaran, T.D. John
It also possesses good weld strength when welded with suitable filler materials.
Sometimes a filler material is added to the weld pool of molten material, which after solidification gives a strong bond between the materials.
With TIG welding process, welding of ‘difficult-to- weld’ materials such as aluminium and magnesium becomes easy.
P.B. (1999), Effect of welding parameters on the solidification microstructure of autogenous TIG welds in an Al– Cu–Mg–Mn alloy, Materials Science and Engineering: A, 259(1), 53-64
R.N. (2012), Effect of Pulsed Current Tig Welding Parameters on Mechanical Properties of J-Joint Strength of AA 6351, The International Journal of Engineering And Science (IJES), 1(1), 1-5
Sometimes a filler material is added to the weld pool of molten material, which after solidification gives a strong bond between the materials.
With TIG welding process, welding of ‘difficult-to- weld’ materials such as aluminium and magnesium becomes easy.
P.B. (1999), Effect of welding parameters on the solidification microstructure of autogenous TIG welds in an Al– Cu–Mg–Mn alloy, Materials Science and Engineering: A, 259(1), 53-64
R.N. (2012), Effect of Pulsed Current Tig Welding Parameters on Mechanical Properties of J-Joint Strength of AA 6351, The International Journal of Engineering And Science (IJES), 1(1), 1-5
Online since: November 2013
Authors: Michael Ferry, Olga Biletska, Mark Gibson, Kevin J. Laws
Laws,1,3 Mark Gibson,2,3 Michael Ferry1,2
1Australian Research Council Centre of Excellence for Design in Light Metals and
School of Materials Science and Engineering, University of New South Wales, Australia
2CSIRO, Process Science and Engineering, Bayview Av, Clayton, Victoria, Australia
3Advanced Manufacturing Cooperative Research Centre (AMCRC)
aCorresponding author email: olga.biletska@gmail.com
Keywords: Magnesium, Metallic glass composites, Microstructure
Abstract.
In contrast with Mg-based crystalline materials, Mg-based bulk metallic glasses (BMGs) are known for their low density and high strength, which translates into a high specific-strength material.
Kim, Journal of Materials Research 22 (2007) 334-338
Ma, Journal of Materials Research 22 (2007) 314-325
Zhang, Journal of Alloys and Compounds 478 (2009) 419-422
In contrast with Mg-based crystalline materials, Mg-based bulk metallic glasses (BMGs) are known for their low density and high strength, which translates into a high specific-strength material.
Kim, Journal of Materials Research 22 (2007) 334-338
Ma, Journal of Materials Research 22 (2007) 314-325
Zhang, Journal of Alloys and Compounds 478 (2009) 419-422
Online since: June 2014
Authors: Wei Gao, Zhong Jun Ding, Bao Hua Liu, Xiang Mei Meng
The resistivity characteristics of sediments are important to analyze marine sedimental environment and material source.
Beijing: Science Press. (1989) [3] Zheng Guangying.
Beijing: Science Press. (1991) [4] S.
Journal of Sedimentary Petrology, 5(3): 721-725. (1981) [5] S.
Chinese Journal of Soil Science, 32(90): 85-87. (2001) [9] Ding Zhongjun, Liu Baohua, Liu Zhongchen and Xin Haiying.
Beijing: Science Press. (1989) [3] Zheng Guangying.
Beijing: Science Press. (1991) [4] S.
Journal of Sedimentary Petrology, 5(3): 721-725. (1981) [5] S.
Chinese Journal of Soil Science, 32(90): 85-87. (2001) [9] Ding Zhongjun, Liu Baohua, Liu Zhongchen and Xin Haiying.
Online since: April 2011
Authors: Qing Wang, Zhao Yang Ding, Jing Da, Kun Ran, Zhi Tong Sui
Factors Influencing Bonding Strength of Geopolymer-Aggregate Interfacial Transition Zone
Qing Wang1,a , Zhaoyang Ding1,b, Jing Da1,c, Kun Ran1,d and Zhitong Sui2,e
1School of Materials Science and Engineering, Shenyang Jianzhu University, Shenyang 110168, China
2School of Materials & Metallurgy, Northeastern University , Shenyang 110004, China.
Experiment Raw materials.
Results may vary with the raw materials because that the raw materials are not pure crystal .
Journal of Hazardous Materials, 2007, 139, pp. 506–513
Supplementary Cementing Materials for Sustainable Development Inc, Ottawa, Canada (2008)
Experiment Raw materials.
Results may vary with the raw materials because that the raw materials are not pure crystal .
Journal of Hazardous Materials, 2007, 139, pp. 506–513
Supplementary Cementing Materials for Sustainable Development Inc, Ottawa, Canada (2008)
Online since: March 2015
Authors: De Long Wu, Ying Liang Tian, Shu Guang Guo
The Mechanism Research of Foam Glass under Surface Depression
DelongWu1, a, YingliangTian2,b , ShuGuangGuo3,c
1 Beijing University of Technology Material Science and Engineering College China
2 Beijing University of Technology Material Science and Engineering College China
3 Beijing University of Technology Material Science and Engineering College China
awudelongjay@126.com, bboli106@126.com, cdawulaixi@163.com
Keywords: foam glass, under surface depression, release agent, the flame heating temperature.
Introduction Foam glass is a good performance kind of heat insulation materials.
Materials Letters, 2006, 60(7): 929-934
Functional Materials, 2014, 2(45): 02114-02118.
Journal of Vacuum Science and Technology, 2012, 32(7): 599-604.
Introduction Foam glass is a good performance kind of heat insulation materials.
Materials Letters, 2006, 60(7): 929-934
Functional Materials, 2014, 2(45): 02114-02118.
Journal of Vacuum Science and Technology, 2012, 32(7): 599-604.
Online since: December 2010
Authors: Lu Feng Yang, Qiong Ming Jiang, Zheng Chen
The sources of randomness are related to material properties, parameters of mechanical model, and environmental conditions[8].
Acknowledgements The work described in this paper was supported by National Natural Science Foundation of China (NSFC, No: 50768001), Guangxi Program of Science and Technology (No: 0992028-7), the Project of Guangxi Natural Science Foundation (No: 0991020Z) References [1] Suryavanshi A K,Swamyr N,Cardew G E.
Journal of The Chinese Ceramic Society.
Construction and Building Materials.
Journal of Guangxi University of Technology.Vol.21(2010)
Acknowledgements The work described in this paper was supported by National Natural Science Foundation of China (NSFC, No: 50768001), Guangxi Program of Science and Technology (No: 0992028-7), the Project of Guangxi Natural Science Foundation (No: 0991020Z) References [1] Suryavanshi A K,Swamyr N,Cardew G E.
Journal of The Chinese Ceramic Society.
Construction and Building Materials.
Journal of Guangxi University of Technology.Vol.21(2010)
Online since: February 2012
Authors: Jian Jun Li, Qian Liu, Xiu Juan Fu
Friction Behavior under Different Forming Speed for Sheet Metal Forming
Xiu juan Fu1,2, a, Jian jun Li1,b, Qian Liu1,c
1 State Key Laboratory of Materials Processing and Die & Mould Technology, Huazhong University of Science and Technology, Wuhan, 430074, China
2 School of Materials Science and Engineering, Wuhan Institute of Technology, Wuhan,430073, China
afuxiujuan2010@163.com, bljj@263.net.cn,cliuwb79@sohu.com
Keywords: sheet metal forming.
Experimental conditions and materials Experimental device.
Bech: submitted to Journal of Tribology of the ASME( 2001)
[5] M.Andrzej: submitted to Journal of Materials Processing Technology (2000)
L.Valvo: submitted to Journal of Materials Processing Technology (2006)
Experimental conditions and materials Experimental device.
Bech: submitted to Journal of Tribology of the ASME( 2001)
[5] M.Andrzej: submitted to Journal of Materials Processing Technology (2000)
L.Valvo: submitted to Journal of Materials Processing Technology (2006)
Online since: November 2010
Authors: Yan Yan Yan, Bo Zhao, Pei Lin Xu
Liu: Key Engineering Materials, Vol. 416 (2009), pp. 619
[4] Gadow, R., Kern, F. and Killinger, A.: International Journal of Materials and Product Technology, Vol. 35 (2009), No.3-4, pp.334
[5] Zhao Bo,Tong Jing Lin, Wu Yan and Gao, Guo Fu: Key Engineering Materials, Vol. 364-366 II (2008), pp.909
Zhao and Y.Wu: Materials Science Forum, Vol. 532-533 (2006), pp.532
[7] Zhao B., Yan Y.Y.and Wu Y.: Key Engineering Materials, Vol. 315-316 (2006), pp.314.
[4] Gadow, R., Kern, F. and Killinger, A.: International Journal of Materials and Product Technology, Vol. 35 (2009), No.3-4, pp.334
[5] Zhao Bo,Tong Jing Lin, Wu Yan and Gao, Guo Fu: Key Engineering Materials, Vol. 364-366 II (2008), pp.909
Zhao and Y.Wu: Materials Science Forum, Vol. 532-533 (2006), pp.532
[7] Zhao B., Yan Y.Y.and Wu Y.: Key Engineering Materials, Vol. 315-316 (2006), pp.314.
Online since: January 2021
Authors: Hiroyuki Miyamoto, Mayu Asano, Motohiro Yuasa
Langdon, Influence of stacking fault energy on microstructural development in equal-channel angular pressing, Journal of Materials Research 14 (1999) 4044-4050
Zhang, Influence of stacking-fault energy on the accommodation of severe shear strain in Cu-Al alloys during equal-channel angular pressing, Journal of Materials Research 24 (2009) 3636-3646
Varyukhin, Nanostructured Materials by High-Pressure Severe Plastic Deformation, NATO science series, 2006
Adams, Electron Back scatter Diffraction in Materials Science, Kluwer Academic/Plenum Publishers, New York, 2000
Langdon, Microstructure and properties of a CoCrFeNiMn high-entropy alloy processed by equal-channel angular pressing, Materials Science & Engineering A (2017) 411-419
Zhang, Influence of stacking-fault energy on the accommodation of severe shear strain in Cu-Al alloys during equal-channel angular pressing, Journal of Materials Research 24 (2009) 3636-3646
Varyukhin, Nanostructured Materials by High-Pressure Severe Plastic Deformation, NATO science series, 2006
Adams, Electron Back scatter Diffraction in Materials Science, Kluwer Academic/Plenum Publishers, New York, 2000
Langdon, Microstructure and properties of a CoCrFeNiMn high-entropy alloy processed by equal-channel angular pressing, Materials Science & Engineering A (2017) 411-419