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Online since: October 2025
Authors: Vladimir Lebedev, Alina Lytvyn, Maksym Riabchenko, Dmytro Ivashchenko
Composites Part B: Engineering. 176 (2019) 107207
Composites Part B: Engineering. 96 (2016) 231–41
Composites Part B: Engineering. 134 (2018) 91–7
Composites Part B: Engineering. 91 (2016) 505–12
Journal of Engineering Sciences. 10(1) (2023) C1-C8
Composites Part B: Engineering. 96 (2016) 231–41
Composites Part B: Engineering. 134 (2018) 91–7
Composites Part B: Engineering. 91 (2016) 505–12
Journal of Engineering Sciences. 10(1) (2023) C1-C8
Online since: June 2011
Authors: Mevlut Turkoz, Murat Dilmec, Huseyin Selcuk Halkaci
Aluminum and aluminum alloys are widely used in engineering design mainly because of advantages of their light weight, high strength-to-weight ratio, corrosion resistance and relatively low cost [1,2].
Aluminum sheet forming is making rapid advances in technology [3].
Measurements usually are performed at 10, 15 and 20 % engineering strain [12,13].
Cantor et al., Automotive Engineering Lightweight, Functional, and Novel Materials, Taylor & Francis Group, USA (2008)
[12] Richard Gedney, Sheet Metal Formability, Advanced Materials & Processes, 2002, 33 36
Aluminum sheet forming is making rapid advances in technology [3].
Measurements usually are performed at 10, 15 and 20 % engineering strain [12,13].
Cantor et al., Automotive Engineering Lightweight, Functional, and Novel Materials, Taylor & Francis Group, USA (2008)
[12] Richard Gedney, Sheet Metal Formability, Advanced Materials & Processes, 2002, 33 36
Online since: April 2012
Authors: Anthony D. Rollett, R.M. Suter, Ulrich Lienert, S. F. Li, J. Lind, C. M. Hefferan
Suter1,3,f
1Department of Physics, Carnegie Mellon University, Pittsburgh, PA 15213 USA
2Advanced Photon Source, Argonne National Laboratory, Argonne, IL 60439 USA
3Department of Materials Science and Engineering, Carnegie Mellon University,
Pittsburgh, PA 15213 USA
acheffera@andrew.cmu.edu, bsfli@andrew.cmu.edu, cjlind@andrew.cmu.edu,
dlienert@aps.anl.gov, erollett@andrew.cmu.edu, fsuter@andrew.cmu.edu
Keywords: Grain growth, microstructure, x-ray diffraction, synchrotron radiation, orientation imaging
Abstract.
In-situ measurements were carried out at Sector 1 of the Advanced Photon Source.
Measurements were carried out at Advanced Photon Source (APS) beamline 1-ID. [22] Line focused 50 keV x-rays illuminated planar sections through the sample.
Use of the Advanced Photon Source was supported by the U.S.
Forum, 539-543, 2353-2358 (2007)
In-situ measurements were carried out at Sector 1 of the Advanced Photon Source.
Measurements were carried out at Advanced Photon Source (APS) beamline 1-ID. [22] Line focused 50 keV x-rays illuminated planar sections through the sample.
Use of the Advanced Photon Source was supported by the U.S.
Forum, 539-543, 2353-2358 (2007)
Online since: May 2020
Authors: Michail Bruyako, L. Grigoryeva
Georesource engineering. 327, 5 (2016) 93-94
Key Engineering Materials. 721 (2017) 111-116
Key Engineering Materials. 736 (2018) 183-186
Key Engineering Materials. 781 (2018) 143-148
Advanced Materials Research. 880 (2014) 233-236
Key Engineering Materials. 721 (2017) 111-116
Key Engineering Materials. 736 (2018) 183-186
Key Engineering Materials. 781 (2018) 143-148
Advanced Materials Research. 880 (2014) 233-236
Online since: January 2022
Authors: Ali H. Al-Marzouqi, Sidra Siraj, Waleed Ahmed
Processing Biodegradable Fused Filament Fabrication Waste with Micro-Silica Particles
Sidra Siraj1,a,*, Ali Al-Marzouqi2,b and Waleed Ahmed3,c
1,2Chemical Engineering Department, COE, United Arab Emirates University, Al Ain, UAE
3ERU and Mechanical Engineering, COE, United Arab Emirates University, Al Ain, UAE
a*sidra.siraj@uaeu.ac.ae, bhassana@uaeu.ac.ae, cw.ahmed@uaeu.ac.ae.
This contributes to advanced development and extension of information in several areas, which is of substantial worth, leading to increased waste associated with 3D printing On the other hand, 3D printing can efficiently incorporate raw materials to decrease left-over waste and save consumption of energy.
[14] Lu, B., Li, D., and Tian, X., 2015, “Development Trends in Additive Manufacturing and 3D Printing,” Engineering, 1(1), pp. 085–089
[17] Al Khawaja, H., Alabdouli, H., Alqaydi, H., Mansour, A., Ahmed, W., and Al Jassmi, H., 2020, “Investigating the Mechanical Properties of 3D Printed Components,” 2020 Advances in Science and Engineering Technology International Conferences (ASET), Dubai, pp. 1–7
Applications of 3d Printing in Biomedical Engineering.
This contributes to advanced development and extension of information in several areas, which is of substantial worth, leading to increased waste associated with 3D printing On the other hand, 3D printing can efficiently incorporate raw materials to decrease left-over waste and save consumption of energy.
[14] Lu, B., Li, D., and Tian, X., 2015, “Development Trends in Additive Manufacturing and 3D Printing,” Engineering, 1(1), pp. 085–089
[17] Al Khawaja, H., Alabdouli, H., Alqaydi, H., Mansour, A., Ahmed, W., and Al Jassmi, H., 2020, “Investigating the Mechanical Properties of 3D Printed Components,” 2020 Advances in Science and Engineering Technology International Conferences (ASET), Dubai, pp. 1–7
Applications of 3d Printing in Biomedical Engineering.
Online since: March 2009
Authors: František Lofaj, Vladimír Ivančo, Péter Pál Varga
Fracture of thin walled translucent polycrystalline alumina
(PCA) tubes
František Lofaj1,a, Vladimír Ivančo
2,b
and Péter Pál Varga3,c
1
Institute of Materials Research of SAS, Watsonova 47, 040 01 Košice, Slovakia
2
Faculty of Mechanical Engineering, Dept.
Summary of the mechanical and thermal properties of the advanced commercial PCA (Sapphal). [14].
Forum Inter.
Lynch: Engineering property data on selected ceramics, vol.III, single oxides, part 5.4.1, Aluminium oxide (Batelle Columbus Lab., Ohio, USA, 1981)
Morrell: Handbook of Properties of Technical and Engineering Ceramics.
Summary of the mechanical and thermal properties of the advanced commercial PCA (Sapphal). [14].
Forum Inter.
Lynch: Engineering property data on selected ceramics, vol.III, single oxides, part 5.4.1, Aluminium oxide (Batelle Columbus Lab., Ohio, USA, 1981)
Morrell: Handbook of Properties of Technical and Engineering Ceramics.
Online since: December 2012
Authors: Donato Cancellara, Fabio de Angelis
Part II: infilled structures, Journal of Earthquake Engineering, vol.1, n.3, pp. 475-503, (1997)
Journal for Multiscale Computational Engineering, Vol. 5, n. 2, pp. 105-116, (2007)
[14] De Angelis, F., On constitutive relations in non-smooth elasto/viscoplasticity, Advanced Materials Research, Vol. 566, pp. 691-698, (2012)
[17] De Angelis, F., Computational issues in rate dependent plasticity models, Advanced Materials Research, Vol. 566, pp. 70-77, (2012)
[19] De Angelis, F., Numerical algorithms for J2 viscoplastic models, Advanced Materials Research, Vol. 567, pp. 267-274, (2012)
Journal for Multiscale Computational Engineering, Vol. 5, n. 2, pp. 105-116, (2007)
[14] De Angelis, F., On constitutive relations in non-smooth elasto/viscoplasticity, Advanced Materials Research, Vol. 566, pp. 691-698, (2012)
[17] De Angelis, F., Computational issues in rate dependent plasticity models, Advanced Materials Research, Vol. 566, pp. 70-77, (2012)
[19] De Angelis, F., Numerical algorithms for J2 viscoplastic models, Advanced Materials Research, Vol. 567, pp. 267-274, (2012)
Online since: September 2020
Authors: P. Gunasekaran, K.T. Thilagham, D. Noorullah
College of Engineering, Salem,
Tamil Nadu, India
2Assistant Professor, Dept. of Metallurgical Engineering, Govt.
College of Engineering, Salem, Tamil Nadu, India 3Head of the Department, Dept. of Metallurgical Engineering, Govt.
Ma, Friction stir welding and processing, Materials Science and Engineering: R: Reports, Volume 50, Issues 1–2, 2005, Pages 1-78
Materials Science and Engineering, 2018, 330
Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 224(12), 1854–1864
College of Engineering, Salem, Tamil Nadu, India 3Head of the Department, Dept. of Metallurgical Engineering, Govt.
Ma, Friction stir welding and processing, Materials Science and Engineering: R: Reports, Volume 50, Issues 1–2, 2005, Pages 1-78
Materials Science and Engineering, 2018, 330
Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 224(12), 1854–1864
Online since: May 2014
Authors: Henry Hu, Meng Wang, Yan Da Zou, Gary Meng, Yeou Li Chu, Patrick Cheng
V-HPDC as an emerging technology minimizes the entrapment of porosity, which could improve mechanical properties and engineering performance of welded die cast aluminum alloys [3,4,7].
The typical engineering stress-strain curves of the T6 heat treated A356 and the welded T6 A356/6061 are shown in Figure 2.
The authors would like to thank the Natural Sciences and Engineering Research Council of Canada (NSERC), AGS Agreatsun Welding Ltd, Ryobi Die Casting (USA) Inc, and University of Windsor for supporting this work.
Hu, Influence of aging temperatures and times on mechanical properties of vacuum high pressure die cast aluminum alloy A356, Advanced Materials Research, 445 (2012) 277-282
Nakata, Three defect types in friction stir welding of aluminum die casting alloy, Materials Science and Engineering A, 145 (2006) 250-254
The typical engineering stress-strain curves of the T6 heat treated A356 and the welded T6 A356/6061 are shown in Figure 2.
The authors would like to thank the Natural Sciences and Engineering Research Council of Canada (NSERC), AGS Agreatsun Welding Ltd, Ryobi Die Casting (USA) Inc, and University of Windsor for supporting this work.
Hu, Influence of aging temperatures and times on mechanical properties of vacuum high pressure die cast aluminum alloy A356, Advanced Materials Research, 445 (2012) 277-282
Nakata, Three defect types in friction stir welding of aluminum die casting alloy, Materials Science and Engineering A, 145 (2006) 250-254
Online since: May 2014
Authors: Ernst Kozeschnik, Georg Stechauner
Forum 500-501 631.
].
In the present paper, the conventional treatment is advanced by consideration of the following effects: (i) nucleation with variable precipitate composition according to minimum G*, (ii) size correction for the interfacial energy due to curvature as proposed in ref. [[] Sonderegger B, Kozeschnik E, 2009 Scr.
Conference Solid-Solid Phase Transformations in Inorganic Materials, PTM 2005, Phoenix, AZ, USA, 2005, 301-310. ,[] “Computational Materials Engineering - An Introduction to Computational Microstructure Evolution of Polycrystalline Materials”, K.G.
Summary An advanced simulation approach is developed for the numerical simulation of Cu-precipitation in ferritic steel, taking into account the major mechanisms affecting the precipitation kinetics in Cu-alloyed ferritic steels.
In the present paper, the conventional treatment is advanced by consideration of the following effects: (i) nucleation with variable precipitate composition according to minimum G*, (ii) size correction for the interfacial energy due to curvature as proposed in ref. [[] Sonderegger B, Kozeschnik E, 2009 Scr.
Conference Solid-Solid Phase Transformations in Inorganic Materials, PTM 2005, Phoenix, AZ, USA, 2005, 301-310. ,[] “Computational Materials Engineering - An Introduction to Computational Microstructure Evolution of Polycrystalline Materials”, K.G.
Summary An advanced simulation approach is developed for the numerical simulation of Cu-precipitation in ferritic steel, taking into account the major mechanisms affecting the precipitation kinetics in Cu-alloyed ferritic steels.