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Online since: September 2013
Authors: Tao Chen, Li Guo Chen, Ming Qiang Pan, Yang Jun Wang
Lau: Journal of Materials Processing Technology, Vol. 102 (2000), pp.25
Monteiro Baptista: Journal of Materials Processing Technology, Vol. 103 (2000), pp.417
Davim: Journal of Materials Processing Technology, Vol. 128 (2002), pp.100
KilIçkap: Journal of Materials Processing Technology, Vol. 164-165 (2005), pp.862
Dabade: Journal of Materials Processing Technology, Vol. 192-193 (2007), pp.166
Monteiro Baptista: Journal of Materials Processing Technology, Vol. 103 (2000), pp.417
Davim: Journal of Materials Processing Technology, Vol. 128 (2002), pp.100
KilIçkap: Journal of Materials Processing Technology, Vol. 164-165 (2005), pp.862
Dabade: Journal of Materials Processing Technology, Vol. 192-193 (2007), pp.166
Online since: March 2010
Authors: Zhi Feng Liu, Qi Zhang, Wen Tong Yang, Jian Hua Wang, Yong Sheng Zhao
Finite element model is shown in Fig. 2; the model uses rigid materials for the
punch, die, binder, taking the United States No.36 DQSK steel material for blank.
Li: Journal of plasticity engineering, Vol. 16 (2009), p. 19-23 [6] H.Y.
Liu: Journal of Materials Processing Technology, (2007), p. 140-144 [7] Y.M.
Rolfe: Journal of Materials Processing Technology, Vol. 203 (2008), p. 129-136 [9] M.
Oudjene: Journal of Materials Processing Technology, Vol. 200 (2008), p. 71-76
Li: Journal of plasticity engineering, Vol. 16 (2009), p. 19-23 [6] H.Y.
Liu: Journal of Materials Processing Technology, (2007), p. 140-144 [7] Y.M.
Rolfe: Journal of Materials Processing Technology, Vol. 203 (2008), p. 129-136 [9] M.
Oudjene: Journal of Materials Processing Technology, Vol. 200 (2008), p. 71-76
Online since: October 2018
Authors: Akram Salehi, Ahmad Moloodi, Faezeh Barzegar, Jalal Mirabbasi
Liang, “Functional materials of porous metals made by P/M, electroplating and some other techniques”, Journal of Materilas Science 36, (2001), 5059 – 5072
Zwick, “Metal foams as compact high performance heat exchangers”, Mechanics of Materials 35, (2003), 1161–1176
[11] DIN 50134 Standard, “Testing of Metallic Materials-Compression Test of Metallic Cellular Materials”, (2008)
"Preparation and corresponding structure of nickel foam", Materials science and technology 16.5, (2000), 575-578
Materials Science and Engineering: A 638, (2015), 54-59.
Zwick, “Metal foams as compact high performance heat exchangers”, Mechanics of Materials 35, (2003), 1161–1176
[11] DIN 50134 Standard, “Testing of Metallic Materials-Compression Test of Metallic Cellular Materials”, (2008)
"Preparation and corresponding structure of nickel foam", Materials science and technology 16.5, (2000), 575-578
Materials Science and Engineering: A 638, (2015), 54-59.
Online since: May 2013
Authors: Xiao Nong Cheng, Ya Bo Li, Fu Ming Wang
For this evaluation, electrochemical measurements - polarization curves - were obtained for tested materials, and optical microscope was used to observe corrosive microstructure.
Experimental results shows: cerium reduces grain sizes and improves intergranular corrosion resistance of test materials.
Test materials were divided into two groups: the one group materials were sensitized at 950˚C for 30 minutes, then water-quenched; and the other without any retreatment.
Test materials were cut into smaller pieces (10×10×10 mm3), polished, and mounted in an epoxy resin, machined into such shape showed in Fig.1.
Hudson: Corrosion Science Vol. 52 (2010) p. 873 [6] Jeong Kil Kim, Yeong Ho Kim and Jong Sub Lee: Corrosion Science Vol. 52 (2010) p.1847 [7] Martin Matula, Ludmila Hyspecka and Milan Svoboda: Materials Characterization Vol. 46 (2001) p. 203 [8] YAN Hai-tao, BI Hong-yun and LI Xin: Materials Characterization Vol. 59(2008) p.1741 [9] Jeong Kil Kim, Yeong Ho Kim and Sang Ho Uhm: Corrosion Science Vol. 51 (2009) p.2716 [10] LI Ya-bo: Study on Application Fundamentals of Cerium in Cr12 Ferritic Stainless Steel (University of Science and Technology Beijing, Beijing 2009)
Experimental results shows: cerium reduces grain sizes and improves intergranular corrosion resistance of test materials.
Test materials were divided into two groups: the one group materials were sensitized at 950˚C for 30 minutes, then water-quenched; and the other without any retreatment.
Test materials were cut into smaller pieces (10×10×10 mm3), polished, and mounted in an epoxy resin, machined into such shape showed in Fig.1.
Hudson: Corrosion Science Vol. 52 (2010) p. 873 [6] Jeong Kil Kim, Yeong Ho Kim and Jong Sub Lee: Corrosion Science Vol. 52 (2010) p.1847 [7] Martin Matula, Ludmila Hyspecka and Milan Svoboda: Materials Characterization Vol. 46 (2001) p. 203 [8] YAN Hai-tao, BI Hong-yun and LI Xin: Materials Characterization Vol. 59(2008) p.1741 [9] Jeong Kil Kim, Yeong Ho Kim and Sang Ho Uhm: Corrosion Science Vol. 51 (2009) p.2716 [10] LI Ya-bo: Study on Application Fundamentals of Cerium in Cr12 Ferritic Stainless Steel (University of Science and Technology Beijing, Beijing 2009)
Online since: September 2022
Authors: Jian Yu Chen, Xiao Zhang, Xian Shuai Chen, Jin Yang Zhang
Journal of Dental Sciences. (5) 2010 156-165
Dental Material. (28) 2012 e218-228
Journal of the Mechanical Behavior of Biomedical Materials. (88) 2018 488-496
Journal of the Mechanical Behavior of Biomedical Materials. (71) 2017 244-249
Dental Materials. (28) 2012 218-228.
Dental Material. (28) 2012 e218-228
Journal of the Mechanical Behavior of Biomedical Materials. (88) 2018 488-496
Journal of the Mechanical Behavior of Biomedical Materials. (71) 2017 244-249
Dental Materials. (28) 2012 218-228.
Online since: August 2018
Authors: Rui Zhang, Bing Bing Fan, Yong Qiang Chen, Sai Li, Wei Li, Ting Ting Su, Hong Xia Li
Microwave sintering promoted the density of materials by materials dielectric loss absorbing microwave[3].
Microwave is absorbed selectively by different materials at related temperature which leads to the phenomenon[15].
Hejazi, Processing of nanocrystalline 8mol% yttria-stabilized zirconia by conventional, microwave-assisted and two-step sintering, Materials Science & Engineering A, 492 (2008) 261-267
Ohji, Fabrication of porous Al2O3 by microwave sintering and its properties, Materials Letters, 48 (2001) 215-218
Stevens, Zirconia-toughened alumina (ZTA) ceramics, Journal of Materials Science, 24 (1989) 3421-3440
Microwave is absorbed selectively by different materials at related temperature which leads to the phenomenon[15].
Hejazi, Processing of nanocrystalline 8mol% yttria-stabilized zirconia by conventional, microwave-assisted and two-step sintering, Materials Science & Engineering A, 492 (2008) 261-267
Ohji, Fabrication of porous Al2O3 by microwave sintering and its properties, Materials Letters, 48 (2001) 215-218
Stevens, Zirconia-toughened alumina (ZTA) ceramics, Journal of Materials Science, 24 (1989) 3421-3440
Online since: October 2011
Authors: T.K. Sahoo, Barada Kanta Mishra, B.B. Jha, R.K. Sahoo, Olga I. Bylya, M.K. Sarangi
Langdon, “Seventy-five years of superplasticity: historic developments and new opportunities,” Journal of material sciences, Vol. 44, 2009, p.5998-6010
Lutjering, “Influence of processing on microstructure and mechanical properties of (α+β) titanium alloys,”Materials Science and Engineering A, vol.243, 1998, p. 32–45 [7] H.J.
Qazi, “Titanium alloys for biomedical applications,” Materials Science and Engineering C, Vol. 26, 2006, p. 1269 – 1277
Fraser , “Quantification of micro structural features in α/β titanium alloys,” Materials Science and Engineering A ,Vol .372 ,2004 P.191–198
[13] L.A.Xue, R.Raj, “Deformation-induced phase transformation in Zinc sulfide,” Journal of materials science letters, Vol.9, 1990, p.818-819.
Lutjering, “Influence of processing on microstructure and mechanical properties of (α+β) titanium alloys,”Materials Science and Engineering A, vol.243, 1998, p. 32–45 [7] H.J.
Qazi, “Titanium alloys for biomedical applications,” Materials Science and Engineering C, Vol. 26, 2006, p. 1269 – 1277
Fraser , “Quantification of micro structural features in α/β titanium alloys,” Materials Science and Engineering A ,Vol .372 ,2004 P.191–198
[13] L.A.Xue, R.Raj, “Deformation-induced phase transformation in Zinc sulfide,” Journal of materials science letters, Vol.9, 1990, p.818-819.
Online since: August 2016
Authors: Gabriela Marginean, Dragos Toader Pascal, Viorel Aurel Şerban
Optimization of Process Parameters for the Manufacturing of High Temperature Vacuum Brazed WC-NiCrBSi Coatings
PASCAL Dragos-Toader 1,2,a, SERBAN Viorel-Aurel 2,b,
MARGINEAN Gabriela 2,c
1 Department of Materials Science and Engineering, Politehnica University Timisoara, Piata Victoriei Nr.2, 300006 Timisoara, Timis, Romania
2 Department of Materials Science and Testing, University of Applied Sciences Gelsenkirchen, Neidenburger Str 43, 45877 Gelsenkirchen, Germany
adragos.pascal@w-hs.de, bviorel.serban@upt.ro, cgabriela.marginean@w-hs.de
Keywords: vacuum brazing; tungsten carbide; brazing alloy; hardfacing; process optimization
Abstract.
The chemical composition of the powder materials and the amounts used to make the brazing tapes are presented in Table 1.
Journal of Refractory Metals & Hard Materials, 28 (2010) 95-105
Journal of Refractory Metals and Hard Materials, 35 (2012) 246-250
Bao, Wear-resistant WC composite hard coatings by brazing, Journal of Materials Engineering and Performance, 13 (2004) 385-388
The chemical composition of the powder materials and the amounts used to make the brazing tapes are presented in Table 1.
Journal of Refractory Metals & Hard Materials, 28 (2010) 95-105
Journal of Refractory Metals and Hard Materials, 35 (2012) 246-250
Bao, Wear-resistant WC composite hard coatings by brazing, Journal of Materials Engineering and Performance, 13 (2004) 385-388
Online since: June 2015
Authors: Yan Xia Lin, Chang Min Wu, Shou Xiang Sheng
Destruction of toxic materials.
Journal of Hazardous Materials, 176(2010)1101-1105 [17] V.Birke,et.al,.
Journal of materials science 39(2004)511105116 [18] Kunlun Zhang, Jun Huang, Gang Yu,et.al.
Journal of materials science 39(2004)5497-5501 [24] In Wook Nah, Kyung-Yub Hwang,et.al,.
Journal of Hazardous Materials 147(2007)652-65
Journal of Hazardous Materials, 176(2010)1101-1105 [17] V.Birke,et.al,.
Journal of materials science 39(2004)511105116 [18] Kunlun Zhang, Jun Huang, Gang Yu,et.al.
Journal of materials science 39(2004)5497-5501 [24] In Wook Nah, Kyung-Yub Hwang,et.al,.
Journal of Hazardous Materials 147(2007)652-65
Online since: August 2013
Authors: San Min Wang, Su Chen, Ru Yuan
Definition of the pole for the flexible body, the rod materials were selected to the following three material:
(1) 45 steel, elastic modulus 210 GPa, density 7800 kg/m3;
(2)Aluminum, elastic modulus 70 GPa, density 2700 kg/m3;
(3)Carbon fiber composite materials, elastic modulus 588 GPa, density1940 kg/m3;
Eq. 1 and Eq. 6 are non-linear second-order differential equations.
Conclusion The model of different materials and elastic deformation are different, the smaller the density of the material, the shorter institutions fully extended the time required will be; the greater the elastic modulus of the material, the smaller the elastic deformation will be; and flexible model will commence significantly beating when the expansion completes, and smaller the elastic modulus is, the greater the beat will be.
Fluctuation range of flexible models of different materials, and the greater the density, the smaller the fluctuation range; the greater the elastic modulus, the smaller the fluctuation range will be.
Acknowledgments This research is supported by the National Natural Science Foundation of China (Grant No. 51175422 ).
Mechanical Science and Technology, Vol.07 (2004) [7].
Conclusion The model of different materials and elastic deformation are different, the smaller the density of the material, the shorter institutions fully extended the time required will be; the greater the elastic modulus of the material, the smaller the elastic deformation will be; and flexible model will commence significantly beating when the expansion completes, and smaller the elastic modulus is, the greater the beat will be.
Fluctuation range of flexible models of different materials, and the greater the density, the smaller the fluctuation range; the greater the elastic modulus, the smaller the fluctuation range will be.
Acknowledgments This research is supported by the National Natural Science Foundation of China (Grant No. 51175422 ).
Mechanical Science and Technology, Vol.07 (2004) [7].