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Online since: July 2024
Authors: Karla Lisette Lopez Pasapera, Sanchez Rosario Ronald Luis, Soto Noa Eder
For which, descriptions of the materials and instruments used for the necessary tests were made.
Materials and Tools/Equipment Materials.
The raw materials used were brick dust and alkaline solution.
Dosage in kilograms (Kg) of the materials to be used in the production of concrete.
The combination of these materials is carried out in the concrete mixer of the university laboratory.
Materials and Tools/Equipment Materials.
The raw materials used were brick dust and alkaline solution.
Dosage in kilograms (Kg) of the materials to be used in the production of concrete.
The combination of these materials is carried out in the concrete mixer of the university laboratory.
Online since: June 2013
Authors: Ding Hua Zhang, Kun Bu, Qiu Sheng Luo, Shi Feng Li
[2] COX D C, ROEBUCK B, RAE C M F: Materials Science and Technology Vol. 17-19 (2003), p. 444
[5] XIONG Jichun, LI Jiarong, LIU Shizhong: Journal of Materials Engineering Vol. 7-9 (2009), p. 112
[6] Jo C Y, Cho H Y, Kim H M: Material Science and Technology Vol. 12-19 (2003), p. 1675
[7] Bond S D,Martin J W: Journal of Materials ScienceVol. 17-19 (1984), p. 3869 [8] Seo D, Au P, Huang X: Processes,and Repair Techniques Vol. 41-42 (2006), p. 690
Han:Engineering Failure AnalysisVol. 18-19 (2011), p. 947 [14] WANG D L, JIN T, YANG S Q: Materials Science Forum Vol. 546-549 (2007), p. 1230 [15] Jo C Y, Cho H Y, Kim H M: Material Science and Technology Vol. 12-19 (2003), p. 1673 [16] Wei P, Li JR, Zhong ZG: J Mater Eng Vol. 10-12 (2001), p. 5.
[5] XIONG Jichun, LI Jiarong, LIU Shizhong: Journal of Materials Engineering Vol. 7-9 (2009), p. 112
[6] Jo C Y, Cho H Y, Kim H M: Material Science and Technology Vol. 12-19 (2003), p. 1675
[7] Bond S D,Martin J W: Journal of Materials ScienceVol. 17-19 (1984), p. 3869 [8] Seo D, Au P, Huang X: Processes,and Repair Techniques Vol. 41-42 (2006), p. 690
Han:Engineering Failure AnalysisVol. 18-19 (2011), p. 947 [14] WANG D L, JIN T, YANG S Q: Materials Science Forum Vol. 546-549 (2007), p. 1230 [15] Jo C Y, Cho H Y, Kim H M: Material Science and Technology Vol. 12-19 (2003), p. 1673 [16] Wei P, Li JR, Zhong ZG: J Mater Eng Vol. 10-12 (2001), p. 5.
Online since: September 2017
Authors: Igor A. Savin, A.V. Shaparev
Savin, Calculation of the Amount of the Reduction Required for the Formation of Compound Layers during Cold Rolling of Bimetals,Materials Science Forum, 870 (2016) 328-333
Gavarieva, Influence of multilayer coatings on the operational stability of molds for injection molding, IOP Conference Series: Materials Science and Engineering, 134(1) (2016) 012031
Parsa, Cladding of aluminum on AISI 304L stainless steel by cold roll bonding, Mechanism, microstructure, and mechanical properties, Materials Science and Engineering, 613 (2014) 232-239
Shlyakhova, Evolution of macro-scale plastic flow localization of tri-layered stainless steel, Low carbon steel, Stainless steel metal with digital image correlation method, Materials Science Forum, 870 (2016) 60-65
Zhu, Variations in the microstructure and mechanical properties of the oxide layer on high speed steel hot rolling work rolls, Journal of Materials Processing Technology, 212(12) (2012) 2597-2608
Gavarieva, Influence of multilayer coatings on the operational stability of molds for injection molding, IOP Conference Series: Materials Science and Engineering, 134(1) (2016) 012031
Parsa, Cladding of aluminum on AISI 304L stainless steel by cold roll bonding, Mechanism, microstructure, and mechanical properties, Materials Science and Engineering, 613 (2014) 232-239
Shlyakhova, Evolution of macro-scale plastic flow localization of tri-layered stainless steel, Low carbon steel, Stainless steel metal with digital image correlation method, Materials Science Forum, 870 (2016) 60-65
Zhu, Variations in the microstructure and mechanical properties of the oxide layer on high speed steel hot rolling work rolls, Journal of Materials Processing Technology, 212(12) (2012) 2597-2608
Online since: August 2013
Authors: Jun Xu, Zhi Feng Zhang, Bao Li, Zhi Gang Wang
The starting materials were 99.9%Al, 99.99%Cu, 99.92%Zn, 99.5%Mg, 99.5%Cu, Al-4%Zr and Al-2%Sc master alloys.
References [1] WU Y L, FROES F H, ALVARFZ A, LI C G, LIU J.: Microstructure and properties of a new super-high-strength Al-Zn-Mg-Cu alloy C912 [J] Materials and Design, 1997,18(4): 211-215
Materials Science and Engineering 2000, A285: 62-68
Materials Science and Engineering, 1995, A191(12): 143-150
Journal of Materials Science, 1997, 32(11): 2883-2894
References [1] WU Y L, FROES F H, ALVARFZ A, LI C G, LIU J.: Microstructure and properties of a new super-high-strength Al-Zn-Mg-Cu alloy C912 [J] Materials and Design, 1997,18(4): 211-215
Materials Science and Engineering 2000, A285: 62-68
Materials Science and Engineering, 1995, A191(12): 143-150
Journal of Materials Science, 1997, 32(11): 2883-2894
Online since: August 2014
Authors: Shi Feng Huang, Xin Chun Xie, Xiao Jing Guo, Dong Yu Xu, Jin Sen Zhang, Fei Sha
Experimental Setup
The 1-3 type piezo-damping composite materials were fabricated by cutting-filling technique.
Wang, Research progress in Piezoelectric Ceramic/polymer Advanced Damping Materials.
Materials Review, 2008. 22(1):41-52 [2] Forward.
International Journal of High Technology Ceramics, 1988, 4(1):91
Mechanism in damping of mechanical vibration by piezoelectric ceramic-polymer composite materials. journal of materials science, 1995, 2648-2655.doi: 10.1007/BF00362148 [8] Petrovic Z, Stojalovic N.
Wang, Research progress in Piezoelectric Ceramic/polymer Advanced Damping Materials.
Materials Review, 2008. 22(1):41-52 [2] Forward.
International Journal of High Technology Ceramics, 1988, 4(1):91
Mechanism in damping of mechanical vibration by piezoelectric ceramic-polymer composite materials. journal of materials science, 1995, 2648-2655.doi: 10.1007/BF00362148 [8] Petrovic Z, Stojalovic N.
Online since: January 2006
Authors: Peter Orban, Millan K. Yeung
References
[1] Ratchev S., Liu S., Huang W. and Becker A.A., "A flexible force model for end milling of
low-rigidity parts", Journal of Materials Processing Technology, Vol. 153-154, No. 1-3,
November 10 2004, pp.134-138.
[3] Dong H.Y. and Ke Y.L., "Finite element simulation for optimal clamping scheme of thinwalled work piece in milling process", Zhejiang Daxue Xuebao (Gongxue Ban) Journal of Zhejiang University (Engineering Science), Vol. 38 No. 1, January 2004, pp. 17-21.
[6] Ratchev S., Govender E., Nikov S., Phuah K. and Tsiklos G., "Force and deflection modelling in milling of low-rigidity complex parts", Journal of Materials Processing Technology, Vol. 143-144 No. 1, Dec 20 2003, pp. 796-801.
[7] Ning H., Zhigang W., Chengyu J. and Bing Z., "Finite element method analysis and control stratagem for machining deformation of thin-walled components", Journal of Materials Processing Technology, Vol. 139 No. 1-3 SPEC, August 20, 2003, pp. 332-336.
S. and Liao C.L., "Finite-element modeling of static surface errors in the peripheral milling of thin-walled work pieces", Journal of Materials Processing Technology, Vol. 94 No. 2, September 1999, pp. 235-246.
[3] Dong H.Y. and Ke Y.L., "Finite element simulation for optimal clamping scheme of thinwalled work piece in milling process", Zhejiang Daxue Xuebao (Gongxue Ban) Journal of Zhejiang University (Engineering Science), Vol. 38 No. 1, January 2004, pp. 17-21.
[6] Ratchev S., Govender E., Nikov S., Phuah K. and Tsiklos G., "Force and deflection modelling in milling of low-rigidity complex parts", Journal of Materials Processing Technology, Vol. 143-144 No. 1, Dec 20 2003, pp. 796-801.
[7] Ning H., Zhigang W., Chengyu J. and Bing Z., "Finite element method analysis and control stratagem for machining deformation of thin-walled components", Journal of Materials Processing Technology, Vol. 139 No. 1-3 SPEC, August 20, 2003, pp. 332-336.
S. and Liao C.L., "Finite-element modeling of static surface errors in the peripheral milling of thin-walled work pieces", Journal of Materials Processing Technology, Vol. 94 No. 2, September 1999, pp. 235-246.
Online since: July 2011
Authors: Zun Jie Wei, Fei Wang, Yan Pei Song, Hui Gai Wang
Wei 4,d
1School of Material Science and Engineering.
Henan University of Science and Technology, Luoyang, 471003, China 2Henan Key Lab. of Advanced Non-Ferrous Materials, Luoyang 471003, China 3Luoyang Ship Material Research Institute, Luoyang 471039, China 4National Key Lab. for Precision Hot Processing of Metal.
Chinese Journal of Rare Metals, Vol. 32 (2008), p. 518
Materials Letters, Vol. 57 (2003), p. 3234
Materials Letters, Vol. 57 (2003), p. 1970
Henan University of Science and Technology, Luoyang, 471003, China 2Henan Key Lab. of Advanced Non-Ferrous Materials, Luoyang 471003, China 3Luoyang Ship Material Research Institute, Luoyang 471039, China 4National Key Lab. for Precision Hot Processing of Metal.
Chinese Journal of Rare Metals, Vol. 32 (2008), p. 518
Materials Letters, Vol. 57 (2003), p. 3234
Materials Letters, Vol. 57 (2003), p. 1970
Online since: June 2014
Authors: Nabipour Afrouzi Hadi, Zulkurnain Abdul-Malek, Saeed Vahabi-Mashak, Nabipour-Afrouzi Hadi, Amir Hesam Khavari
A cavity within a dielectric material is a highly stressed area and the ideal place for starting partial discharge and breakdown.
The model is made of a homogenous solid dielectric material of 3mm thickness and 9mm diameter.
From Fig. 2a, the electric field inside the cavity is higher than the surrounding material due to lower permittivity compared to the insulator material.
Vahabi-Mashak, Study on Effect of Size and Location of Void on Electric Field and Potential Distributions in Stator Bar Insulation with finite-element-model, Life Science Journal, 2013, vol. 10, no. 4, pp. 2036-2041
Vahabi-Mashak, Three-Dimensional Potential and Electric Field Distributions in HV Cable Insulation Containing Multiple Cavities, Advanced Materials Research, 2014, vol. 845, pp. 372-377
The model is made of a homogenous solid dielectric material of 3mm thickness and 9mm diameter.
From Fig. 2a, the electric field inside the cavity is higher than the surrounding material due to lower permittivity compared to the insulator material.
Vahabi-Mashak, Study on Effect of Size and Location of Void on Electric Field and Potential Distributions in Stator Bar Insulation with finite-element-model, Life Science Journal, 2013, vol. 10, no. 4, pp. 2036-2041
Vahabi-Mashak, Three-Dimensional Potential and Electric Field Distributions in HV Cable Insulation Containing Multiple Cavities, Advanced Materials Research, 2014, vol. 845, pp. 372-377
Online since: January 2016
Authors: Yong Jie Bao, Hang Gao, Yi Ni Zhang, Xue Shu Liu
Composites Science and Technology. 58(1998) 267-283
MATERIALS & DESIGN. 40(2012) 263–268
Advanced Materials Research. 565(2012) 436–441
Composites Part A: Applied Science and Manufacturing . 33(2001)577-581
Journal of Manufacturing Science and Engineering. 124(2002)773-777.
MATERIALS & DESIGN. 40(2012) 263–268
Advanced Materials Research. 565(2012) 436–441
Composites Part A: Applied Science and Manufacturing . 33(2001)577-581
Journal of Manufacturing Science and Engineering. 124(2002)773-777.
Online since: July 2014
Authors: Xu Guang Yang
By summing up it, the teachers should integrate the enterprise practice results into the professional development, talent training scheme, teaching material construction, teaching reform and so on.
Acknowledgements This work was financially supported by the Philosophy and Social Science Fund Project of Education Department of Jiangsu Province(2013sjb880035) References [1] F.
Gu, Virtual unit network technology application in the network experimental teaching, Journal of The Information Science and Technology of China. 13(2011)133-134
Xu, Research on the Ways of Enterprise Practice by Professional Teachers in Higher Vocational Colleges, Journal of Beijing Polytechnic College.11(2012)40-44
Wang, Research on the Method of University-enterprise Cooperation in Higher Vocational Colleges, Journal of Changchun University of Science and Technology.12( 2011)25-26
Acknowledgements This work was financially supported by the Philosophy and Social Science Fund Project of Education Department of Jiangsu Province(2013sjb880035) References [1] F.
Gu, Virtual unit network technology application in the network experimental teaching, Journal of The Information Science and Technology of China. 13(2011)133-134
Xu, Research on the Ways of Enterprise Practice by Professional Teachers in Higher Vocational Colleges, Journal of Beijing Polytechnic College.11(2012)40-44
Wang, Research on the Method of University-enterprise Cooperation in Higher Vocational Colleges, Journal of Changchun University of Science and Technology.12( 2011)25-26