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Online since: January 2021
Authors: Roberto Montanari, Andrea Di Schino, Giuseppe Napoli, Claudio Testani, Orlando di Pietro, Giulia Stornelli, Luciano Pilloni
Pilloni, Effect of thermo-mechanical parameters on the mechanical properties of Eurofer97 steel for nuclear applications, Open Engineering 8 (2018) 349-353
[9] Michael Gorley, Eberhard Diegele, Sergei Dudarev, Gerald Pintsuk, Materials engineering and design for fusion—Towards DEMO design criteria, Fusion Engineering and Design 136 (2018) 298–303
Surrey, Influence of a 1.5 T magnetic field on the tensile properties of Eurofer-97 steel, Fusion Engineering and Design 141 (2019) 68-72
Zinkle, Advanced materials for fusion technology, Fusion Engineering and Design 74 (2005) 31–40
Dietz, Present development status of EUROFER and ODS-EUROFER for application in blanket concepts, Fusion Engineering and Design 75–79 (2005) 989–996
[9] Michael Gorley, Eberhard Diegele, Sergei Dudarev, Gerald Pintsuk, Materials engineering and design for fusion—Towards DEMO design criteria, Fusion Engineering and Design 136 (2018) 298–303
Surrey, Influence of a 1.5 T magnetic field on the tensile properties of Eurofer-97 steel, Fusion Engineering and Design 141 (2019) 68-72
Zinkle, Advanced materials for fusion technology, Fusion Engineering and Design 74 (2005) 31–40
Dietz, Present development status of EUROFER and ODS-EUROFER for application in blanket concepts, Fusion Engineering and Design 75–79 (2005) 989–996
Online since: February 2013
Authors: Hong Zhen Guo, Tao Wang, Zhang Long Zhao, Ze Kun Yao, Yong Zhang, Shu Hong Fu
Microstructural Evolutions of a High Temperature Titanium Alloy Processed by Thermal Mechanical Treatments
Tao Wang1, a, Hongzhen Guo2, b , Zekun Yao2, c, Zhanglong Zhao2, d,
Shuhong Fu1, e and Yong Zhang1, f
1Science and Technology on Advanced High Temperature Structural Materials Laboratory, Beijing Institute of Aeronautical Materials, Beijing 100095, PR China
2School of Material Science and Engineering, Northwestern Polytechnical University, Xi’an 710072, PR China
awangtao8206@163.com, bhzguo@nwpu.edu.cn, cyzekun@nwpu.edu.cn, dzhaozhanglong000@sohu.com, efshdora@163.com, fbiamzhang@163.com
Keywords: TG6 titanium alloy, Thermal mechanical treatment, Microstructure, Deformation mechanism.
Titanium alloys are more difficult to process in comparison to other engineering materials such as aluminum and steels due to their complicated transformation[2].
Yao, Influence of processing parameters on microstructure and tensile properties of TG6 titanium alloy, Materials Science and Engineering A. 528 (2010) 736-744
Nie, The high temperature deformation behavior and microstructure of TC21 titanium alloy, Materials Science and Engineering A. 527 (2010) 5360-5367
Khorev, Alloying and heat treatment of high-strength structural titanium β alloys, Russian Engineering Research. 30(2010) 781-788
Titanium alloys are more difficult to process in comparison to other engineering materials such as aluminum and steels due to their complicated transformation[2].
Yao, Influence of processing parameters on microstructure and tensile properties of TG6 titanium alloy, Materials Science and Engineering A. 528 (2010) 736-744
Nie, The high temperature deformation behavior and microstructure of TC21 titanium alloy, Materials Science and Engineering A. 527 (2010) 5360-5367
Khorev, Alloying and heat treatment of high-strength structural titanium β alloys, Russian Engineering Research. 30(2010) 781-788
Online since: January 2022
Authors: Ahmad Zahirani Ahmad Azhar, Afifah Ali, Hanisah Manshor
Effect of Pressure Load on the Physical Properties of ZTA-TiO2-Cr2O3
HANISAH Manshor1,a*, AFIFAH Mohd Ali2,b
and AHMAD Zahirani Ahmad Azhar2,c
1Department of Science in Engineering, Faculty of Engineering, International Islamic University Malaysia, 53100 Gombak, Selangor, Malaysia
2Department of Manufacturing and Materials Engineering, Faculty of Engineering, International Islamic University Malaysia, 53100 Gombak, Selangor, Malaysia
ahanisahmanshor@iium.edu.my, bafifahali@iium.edu.my, czahirani@iium.edu.my
Keywords: ZTA-TiO2-Cr2O3, pressure load, density, Vickers hardness.
The phase composition and crystalline structure of the sintered samples were analysed by XRD (Bruker D8 Advance) with CuKα radiation operating at 40kV and 30mA.
Xiang, Size effect in compression fracture: Splitting crack band propagation bazant, Journal of Engineering Mechanics-asce 123 (1997) 162–172
Abed, Simulation of cold die compaction alumina powder, Trends in Mechanical Engineering and Technology 1.1 (2011) 1–21
Rashid, Effect of compaction pressure on mechanical properties of aluminium particle sizes AA6061Al alloy through powder metallurgical process, ARPN Journal of Engineering and Applied Sciences 11.8 (2016) 5155–5160
The phase composition and crystalline structure of the sintered samples were analysed by XRD (Bruker D8 Advance) with CuKα radiation operating at 40kV and 30mA.
Xiang, Size effect in compression fracture: Splitting crack band propagation bazant, Journal of Engineering Mechanics-asce 123 (1997) 162–172
Abed, Simulation of cold die compaction alumina powder, Trends in Mechanical Engineering and Technology 1.1 (2011) 1–21
Rashid, Effect of compaction pressure on mechanical properties of aluminium particle sizes AA6061Al alloy through powder metallurgical process, ARPN Journal of Engineering and Applied Sciences 11.8 (2016) 5155–5160
Online since: November 2010
Authors: Luboš Náhlík, Pavel Hutař, Zdeněk Knésl, Lucie Šestáková
Knésl: Key Engineering Materials Vols. 385-387 (2008), p. 317-320
[5] J.
Tuan: Materials Science and Engineering A 393 (2005), p. 133-139 [11] B.N.
Kim: Engineering Fracture Mechanics Vol. 59, No. 3 (1998), p. 289-303 [12] W.
Lissenden: Materials Science and Engineering A 338 (2002), p. 271-281 [15] N.
Keršner: Structural Engineering, Mechanics and Computation, edited by A.
Tuan: Materials Science and Engineering A 393 (2005), p. 133-139 [11] B.N.
Kim: Engineering Fracture Mechanics Vol. 59, No. 3 (1998), p. 289-303 [12] W.
Lissenden: Materials Science and Engineering A 338 (2002), p. 271-281 [15] N.
Keršner: Structural Engineering, Mechanics and Computation, edited by A.
Online since: October 2006
Authors: M. Ossowski, T. Wierzchon
Ossowski 1b
1Faculty of Materials Science and Engineering.
The rapid progress in engineering enhances the demands set on materials requiring better mechanical properties, resistance to frictional wear, resistance to corrosion and erosion etc.
These demands can be satisfied by e.g. applying various surface engineering techniques which permit modifying the microstructure, phase and chemical composition of the surface layers of the treated parts.
Forum., Vols. 475-479 (2005), p.3887, [10] G.
Czyrska-Filemonowicz: Proc. 2 nd International Conference Heat Treatment and Surface Engineering in Automotive Applications, , Riva del Garda , Italy (2005), CD-rom
The rapid progress in engineering enhances the demands set on materials requiring better mechanical properties, resistance to frictional wear, resistance to corrosion and erosion etc.
These demands can be satisfied by e.g. applying various surface engineering techniques which permit modifying the microstructure, phase and chemical composition of the surface layers of the treated parts.
Forum., Vols. 475-479 (2005), p.3887, [10] G.
Czyrska-Filemonowicz: Proc. 2 nd International Conference Heat Treatment and Surface Engineering in Automotive Applications, , Riva del Garda , Italy (2005), CD-rom
Online since: December 2010
Authors: Jing Ji, Wen Fu Zhang, Hai Yan Sui, Zong Wang
Buckling Analysis of Two-Span Continuous Beams with Lateral Elastic Brace under Uniform Load
Wenfu Zhanga, Haiyan Suib , Zong Wangc and Jing Jid
Provincial key Lab of Disaster Prevention and Reduction Engineering and Protective Engineering, Northeast Petroleum University, Daqing, Heilongjiang,163318, China
azwfdqpi@126.com, bsuihaiyan2010@126.com, czgandlan@163.com, djijing1977@163.com
Keywords: Lateral Brace; Lateral Torsional Buckling; Continuou Beam; Energy Variation Method
Abstract.
Despite the stability of single-span beam is quite sound, and its formula for calculating the buckling load has been widely used, but due to complexity of LTB for continuous beam, at present there is no simple way to calculate the buckling loads for continuous beam, great difficulties exist in engineering applications.
But a set of simple bending moment formula of the continuous beam with lateral brace were not given; therefore, this research has important theoretical and engineering significance.
References [1] Ji Chen: Steel Stability Theory and Design (the 4th edition) (Science Press, China 2008) [2] Genshu Tong: Plane Stability of Steel Structures (China Building Industry Press, China 2006) [3] Wenfu Zhang and Haiyan Sui: the 3rd International Forum on Advances in Structural Engineering.
Yura: Engineering Journal .Vol. 38(2001), p. 11 [5] Nguyen, Canh Tuan, Moon, Jiho, Le and Van Nam: Journal of Constructional Steel Research.
Despite the stability of single-span beam is quite sound, and its formula for calculating the buckling load has been widely used, but due to complexity of LTB for continuous beam, at present there is no simple way to calculate the buckling loads for continuous beam, great difficulties exist in engineering applications.
But a set of simple bending moment formula of the continuous beam with lateral brace were not given; therefore, this research has important theoretical and engineering significance.
References [1] Ji Chen: Steel Stability Theory and Design (the 4th edition) (Science Press, China 2008) [2] Genshu Tong: Plane Stability of Steel Structures (China Building Industry Press, China 2006) [3] Wenfu Zhang and Haiyan Sui: the 3rd International Forum on Advances in Structural Engineering.
Yura: Engineering Journal .Vol. 38(2001), p. 11 [5] Nguyen, Canh Tuan, Moon, Jiho, Le and Van Nam: Journal of Constructional Steel Research.
Online since: March 2019
Authors: Olaitan Lukman Akanji, Olawale S. Fatoba, Esther Titilayo Akinlabi
AKINLABI2
1Department of Chemical, Metallurgical and Materials Engineering,
Tshwane University of Technology, Pretoria, South Africa.
2Department of Mechanical Engineering Science,
University of Johannesburg,
Johannesburg, South Africa.
The International Journal of Advanced Manufacturing Technology. http://dx.doi.org/10.1007/s00170-018-2106-7
International Journal of Advanced Manufacturing Technology 94 (1-4), 773-787
Lasers in Engineering, 39(3-6), 292-312
International Journal of Surface Science and Engineering. 12 (1), 40-59.
The International Journal of Advanced Manufacturing Technology. http://dx.doi.org/10.1007/s00170-018-2106-7
International Journal of Advanced Manufacturing Technology 94 (1-4), 773-787
Lasers in Engineering, 39(3-6), 292-312
International Journal of Surface Science and Engineering. 12 (1), 40-59.
Online since: July 2015
Authors: Oliver Lott, Alwin Nagel, Maren Klement
Advanced preform design, further HTSC-development and materials characterization will be the focus of continued work.
Luedtke, Thermal management materials for high-performance applications, Advanced Engineering Materials 6/3 (2004) 132-144
Kieback, Interfacial design of Cu-based composites prepared by powder metallurgy for heat sink applications, Materials Science and Engineering A 475 (2008) 39-44 [8] V.
Bolt, Synthesis and analysis of the thermal behavior of SiC-fibre reinforced copper matrix composites as heat sink material, Advanced Materials Research 59 (2009) 153-157
Lott, Interface Design of Copper/Alumina Composites with Interpenetrating Phase Structure, PhD thesis, School of Materials Science and Engineering University of New South Wales, Sydney, Australia, 2012
Luedtke, Thermal management materials for high-performance applications, Advanced Engineering Materials 6/3 (2004) 132-144
Kieback, Interfacial design of Cu-based composites prepared by powder metallurgy for heat sink applications, Materials Science and Engineering A 475 (2008) 39-44 [8] V.
Bolt, Synthesis and analysis of the thermal behavior of SiC-fibre reinforced copper matrix composites as heat sink material, Advanced Materials Research 59 (2009) 153-157
Lott, Interface Design of Copper/Alumina Composites with Interpenetrating Phase Structure, PhD thesis, School of Materials Science and Engineering University of New South Wales, Sydney, Australia, 2012
Online since: November 2015
Authors: Valery V. Kuzin, Predrag Dašić, Mike Portnoy, Sergey Fedorov
There are several publications investigating different behaviors of Si3N4 ceramics in engineering [4-8].
Lawrence, Surface characterization and compositional evaluation of a fibre laser processed silicon nitride (Si3N4) engineering ceramic, Lasers in Engineering 20 (5-6) (2010) 359-380
Lawrence, Investigation of temperature distribution during CO2 laser and fibre laser processing of a Si3N4 engineering ceramic by means of a computational and experimental approach, Lasers in Engineering 27 (3-4) (2014) 135-160
Kern, Chapter 2.06 - Advanced manufacturing of hard ceramics, in: Comprehensive Hard Materials, Vol. 2: Ceramics, Elsevier, Oxford, 2014, pp. 207-230
Lawrence, The influence of brightness during laser surface treatment of Si3N4 engineering ceramics, Optics and Lasers in Engineering 50 (12) (2012) 1746-1751
Lawrence, Surface characterization and compositional evaluation of a fibre laser processed silicon nitride (Si3N4) engineering ceramic, Lasers in Engineering 20 (5-6) (2010) 359-380
Lawrence, Investigation of temperature distribution during CO2 laser and fibre laser processing of a Si3N4 engineering ceramic by means of a computational and experimental approach, Lasers in Engineering 27 (3-4) (2014) 135-160
Kern, Chapter 2.06 - Advanced manufacturing of hard ceramics, in: Comprehensive Hard Materials, Vol. 2: Ceramics, Elsevier, Oxford, 2014, pp. 207-230
Lawrence, The influence of brightness during laser surface treatment of Si3N4 engineering ceramics, Optics and Lasers in Engineering 50 (12) (2012) 1746-1751
Online since: May 2019
Authors: Teik Cheng Lim
Suh: Materials Science and Engineering, vol. 95 (1987) p. 303-308
Lim: Proceedings of the Institution of Civil Engineers-Engineering and Computational Mechanics, vol. 170 (2017) p. 167-173
Lim: Journal of Engineering Materials and Technology, vol. 138 (2016) p. 014501
Lim: Journal of Engineering Materials and Technology, vol. 138 (2016) p. 041011
Lim: Mechanics of Advanced Materials and Structures, vol. 22 (2015) p. 205-212
Lim: Proceedings of the Institution of Civil Engineers-Engineering and Computational Mechanics, vol. 170 (2017) p. 167-173
Lim: Journal of Engineering Materials and Technology, vol. 138 (2016) p. 014501
Lim: Journal of Engineering Materials and Technology, vol. 138 (2016) p. 041011
Lim: Mechanics of Advanced Materials and Structures, vol. 22 (2015) p. 205-212