Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: November 2012
Authors: Deng Wan Li, Feng Xiao, Yu Situ
Implementing Collaborative Innovation Accelerating Multi-cooperation for Vocational Colleges
Feng Xiaoa, Yu Situb, Deng Wan Lic
Sichuan Engineering Technical College, Sichuan Deyang, China
axiaofength@163.com, bsty@scetc.net, cldw@scetc.net
Keywords: Collaborative innovation, Vocational colleges, Multi-cooperation
Abstract.
Objectively speaking, it is obvious that vocational colleges must enter the social production and the main battlefield of economic construction for modern higher vocational education so that they understand the situation clearly in advance.
(In Chinese) [3] Research Group:Education Forum, Vol. 3 (2007), p12.
Zhong: Education Forum, Vol. 2 (2006), p23.
Objectively speaking, it is obvious that vocational colleges must enter the social production and the main battlefield of economic construction for modern higher vocational education so that they understand the situation clearly in advance.
(In Chinese) [3] Research Group:Education Forum, Vol. 3 (2007), p12.
Zhong: Education Forum, Vol. 2 (2006), p23.
Online since: February 2018
Authors: Muralimohan Cheepu, Devuri Venkateswarulu, Woo Seong Che, B. Srinivas, T. Ramachandraiah, Sangathoti Haribabu, Suresh Alapati, Sivaji Karna
Venkateswarulu5,e, Sivaji Karna6,f, Suresh Alapati1,g,
and Woo Seong Che1,h
1Department of Mechatronics Engineering, Kyungsung University, Busan 48434,
Republic of Korea
2Department of Mechanical Engineering, Sri Venkatesa Perumal College of Engineering
and Technology Puttur 517583, Andhra Pradesh, India
3Senior Engineer, Department of Research and Development, D&H Secheron Electrodes
Pvt.
Limited, Madhya Pradesh 452006, India 4Department of Mechanical Engineering, MVGR College of Engineering, Andhra Pradesh 535005, India 5Department of Mechanical Engineering, Marri Laxman Reddy Institute of Technology and Management, Telangana 500043, India 6Defence Research and Development Laboratory, Telangana 500058, India amuralicheepu@gmail.com, bharibab204513@gmail.com, cchandramech05@gmail.com, dbadari.srinivas@gmail.com, edvriitr@gmail.com, fkarnaauce@gmail.com, gsureshalapatimech@gmail.com, hwsche@ks.ac.kr Keywords: Accumulative roll bonding, magnesium, aluminum, mechanical properties, interface.
Most recently extensive studies and its usage on composed of magnesium rapidly increased in many advanced countries [3].
Forum. 710 (2012) 620–625
Seshabhattar (Eds.), Techno-Societal 2016, International Conference on Advanced Technologies for Societal Applications, ICATSA 2016, Springer, Cham, 2018, pp 709-717. https://doi.org/10.1007/978-3-319-53556-2_73 [17] J.A.D.
Limited, Madhya Pradesh 452006, India 4Department of Mechanical Engineering, MVGR College of Engineering, Andhra Pradesh 535005, India 5Department of Mechanical Engineering, Marri Laxman Reddy Institute of Technology and Management, Telangana 500043, India 6Defence Research and Development Laboratory, Telangana 500058, India amuralicheepu@gmail.com, bharibab204513@gmail.com, cchandramech05@gmail.com, dbadari.srinivas@gmail.com, edvriitr@gmail.com, fkarnaauce@gmail.com, gsureshalapatimech@gmail.com, hwsche@ks.ac.kr Keywords: Accumulative roll bonding, magnesium, aluminum, mechanical properties, interface.
Most recently extensive studies and its usage on composed of magnesium rapidly increased in many advanced countries [3].
Forum. 710 (2012) 620–625
Seshabhattar (Eds.), Techno-Societal 2016, International Conference on Advanced Technologies for Societal Applications, ICATSA 2016, Springer, Cham, 2018, pp 709-717. https://doi.org/10.1007/978-3-319-53556-2_73 [17] J.A.D.
Online since: December 2012
Authors: Donato Cancellara, Fabio de Angelis, Vittorio Pasquino
[3] Fajfar, P., Capacity spectrum method based on inelastic demand spectra, Earthquake Engineering & Structural Dynamics, Vol. 28, Issue 9, pp. 979-993, (1999)
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)
[17] De Angelis, F., Cancellara, D., Implications due to different loading programs in inelastic materials, Advanced Material Research, Vol. 422, pp. 726-733, (2012)
[18] De Angelis, F., Cancellara, D., Results of distinct modes of loading procedures in the nonlinear inelastic behavior of solids, Advanced Material Research, Vol. 482-484, pp.1004-1011, (2012)
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)
[17] De Angelis, F., Cancellara, D., Implications due to different loading programs in inelastic materials, Advanced Material Research, Vol. 422, pp. 726-733, (2012)
[18] De Angelis, F., Cancellara, D., Results of distinct modes of loading procedures in the nonlinear inelastic behavior of solids, Advanced Material Research, Vol. 482-484, pp.1004-1011, (2012)
Online since: April 2008
Authors: L.G. Guo, He Yang
Introduction
Radial-axial ring rolling has now become one of advanced hot-forming technologies used to
manufacture some key ring parts, such as aircraft turbine ring, press vessel ring, some large flanges,
bearing ring and gear ring, because of its technical superiorities as a result of its continuous and
local plastic deformation characteristic.
Therefore, in this study we first summarize the complicated forming characteristics of radial-axial ring rolling process, and then focus on some key technologies for developing a 3D-FE model of the process, attempting to establish an advanced platform for the research and development of the forming technology and theory of radial-axial ring rolling.
Therefore, the model provides an advanced R&D platform for guiding the design and optimization of radial-axial ring rolling process.
Huang: Hand Book of Mechanical Engineering Materials, Volume I (2006), p. 745 (in Chinese) [6] L.
Forum Vol. 471-472 (2004), p. 760 [7] L.
Therefore, in this study we first summarize the complicated forming characteristics of radial-axial ring rolling process, and then focus on some key technologies for developing a 3D-FE model of the process, attempting to establish an advanced platform for the research and development of the forming technology and theory of radial-axial ring rolling.
Therefore, the model provides an advanced R&D platform for guiding the design and optimization of radial-axial ring rolling process.
Huang: Hand Book of Mechanical Engineering Materials, Volume I (2006), p. 745 (in Chinese) [6] L.
Forum Vol. 471-472 (2004), p. 760 [7] L.
Online since: May 2022
Authors: S.V. Akhonin, V.Yu. Belous, R.V. Selin
Advanced Engineering Materials, 22(5), 1901258
Advanced Engineering Materials, 21(8), 1801359
In Materials Science Forum (Vol. 618, pp. 165-168).
Materials Science and Engineering: C, 25(3), 304-311
In IOP Conference Series: Materials Science and Engineering (Vol. 582, No. 1, p. 012050).
Advanced Engineering Materials, 21(8), 1801359
In Materials Science Forum (Vol. 618, pp. 165-168).
Materials Science and Engineering: C, 25(3), 304-311
In IOP Conference Series: Materials Science and Engineering (Vol. 582, No. 1, p. 012050).
Online since: August 2012
Authors: Brian Gabbitas, De Liang Zhang, Fei Yang, Hui Yang Lu
Preparation, Microstructure and Properties of Ti-6Al-4V Rods by Powder Compact Extrusion of Powder Mixture
Fei Yanga, Deliang Zhangb, Huiyang Lu and Brian Gabbitas
Waikato Centre for Advanced Materials, School of Engineering, The University of Waikato, Private Bag 3105, Hamilton 3240, New Zealand
afyang@waikato.ac.nz, fyang0204@hotmail.com, bdlzhang@waikato.ac.nz
Keywords: Titanium alloy, extrusion, microstructure, mechanical properties
Abstract.
The typical engineering stress-strain curves of tensile test specimens cut from the Ti-6Al-4V alloy rods extruded at different temperatures are shown in Fig. 5.
Łojkowski, Strengthening of a Ti–6Al–4V titanium alloy by means of hydrostatic extrusion and other methods, Materials Science and Engineering: A, 515 (2009) 43-48 [3] R.
Bressiani, Production of Titanium Alloys for Advanced Aerospace Systems by Powder Metallurgy, Materials Research, 8 (2005) 443-446 [6] Y.
Dong, et. al., Microstructure and Mechanical Properties of Highly deformed Ti-6Al-4V, Materials Science and Engineering.
The typical engineering stress-strain curves of tensile test specimens cut from the Ti-6Al-4V alloy rods extruded at different temperatures are shown in Fig. 5.
Łojkowski, Strengthening of a Ti–6Al–4V titanium alloy by means of hydrostatic extrusion and other methods, Materials Science and Engineering: A, 515 (2009) 43-48 [3] R.
Bressiani, Production of Titanium Alloys for Advanced Aerospace Systems by Powder Metallurgy, Materials Research, 8 (2005) 443-446 [6] Y.
Dong, et. al., Microstructure and Mechanical Properties of Highly deformed Ti-6Al-4V, Materials Science and Engineering.
Online since: September 2019
Authors: A.G. Barbosa de Lima, J.M. Freitas de Oliveira, Vansostenes Antonio Machado de Miranda, A. Santos Pereira, R. Moura da Silva
Unsteady state heat transfer in packed-bed elliptic cylindrical reactor: theory, advanced modeling and applications. in: João M.P.Q.
Doctoral Thesis in Process Engineering, Federal University of Campina Grande, Campina Grande, Brazil, 2018
Kreyszig, Advanced engineering mathematics. 9th. ed., New York, John Wiley & Sons, 2006
Levenspiel., Chemical Reaction Engineering (American 3rd ed translation).
Forum, 391 (2019) 54-59.
Doctoral Thesis in Process Engineering, Federal University of Campina Grande, Campina Grande, Brazil, 2018
Kreyszig, Advanced engineering mathematics. 9th. ed., New York, John Wiley & Sons, 2006
Levenspiel., Chemical Reaction Engineering (American 3rd ed translation).
Forum, 391 (2019) 54-59.
Online since: February 2020
Authors: Daniele Twardowski, Diego Alves de Miranda
Reverse Engineering of Turbine Blades Kaplan’s type for Small Hydroelectric Power Station. 75 Procedia CIRP, 379–384. (2018)
Engineering Failure Analysis. 27(1), 690–700. (2019)
Engineering Failure Analysis, 17(1), 192–199. (2010)
Advanced Engineering Forum, v.32, 41–51. (2019)
IOSR Journal of Mechanical and Civil Engineering. 15, 38-44. (2018)
Engineering Failure Analysis. 27(1), 690–700. (2019)
Engineering Failure Analysis, 17(1), 192–199. (2010)
Advanced Engineering Forum, v.32, 41–51. (2019)
IOSR Journal of Mechanical and Civil Engineering. 15, 38-44. (2018)
Online since: July 2019
Authors: Michael Schneider, Jens P. Konrath, Laura Stöber, Florian Patocka, Ulrich Schmid
Introduction
Due to outstanding material properties, silicon carbide (SiC) is a perfect candidate for high power, high temperature and high frequency electronics [1] and therefore an often selected material for advanced Schottky diodes.
Similar trends have been reported before, which were explained by using an advanced approach compared to Eq. 1, which models the diode current taking locally varying barrier heights into account [18].
References [1] Levinshtein, M.E., et al., Properties of Advanced Semiconductor Materials: GaN, AIN, InN, BN, SiC, SiGe, Wiley, New York, 2001
[4] Stöber, L., et al., Impact of contact material deposition technique on the properties of Ti/4H-SiC Schottky structures, in Materials Science Forum. 2016. p. 569-572
[17] Tung, R.T., Materials Science and Engineering: R: Reports 35 (2001) 1-138
Similar trends have been reported before, which were explained by using an advanced approach compared to Eq. 1, which models the diode current taking locally varying barrier heights into account [18].
References [1] Levinshtein, M.E., et al., Properties of Advanced Semiconductor Materials: GaN, AIN, InN, BN, SiC, SiGe, Wiley, New York, 2001
[4] Stöber, L., et al., Impact of contact material deposition technique on the properties of Ti/4H-SiC Schottky structures, in Materials Science Forum. 2016. p. 569-572
[17] Tung, R.T., Materials Science and Engineering: R: Reports 35 (2001) 1-138
Online since: January 2021
Authors: Carlos Roberto Grandini, Pedro Akira Bazaglia Kuroda, Fernanda de Freitas Quadros, Mycaela Vieira Nascimento
Chen, A Review on Biomedical Titanium Alloys: Recent Progress and Prospect, Advanced Engineering Materials 21 (2019) 1801215
Singh, Review on titanium and titanium based alloys as biomaterials for orthopaedic applications, Materials Science and Engineering: C 102 (2019) 844-862
Yang, A Review on High-Strength Titanium Alloys: Microstructure, Strengthening, and Properties, Advanced Engineering Materials 21 (2019) 1801359
Kobayashi, Effects of [omega]-phase precipitation on [beta]-->[alpha], [alpha]'' transformations in a metastable [beta] titanium alloy, Materials Science and Engineering A 312 (2001) 182-188
Ho, Effect of Omega Phase on Mechanical Properties of Ti-Mo Alloys for Biomedical Applications, Journal of Medical and Biological Engineering 28 (2008) 47-51
Singh, Review on titanium and titanium based alloys as biomaterials for orthopaedic applications, Materials Science and Engineering: C 102 (2019) 844-862
Yang, A Review on High-Strength Titanium Alloys: Microstructure, Strengthening, and Properties, Advanced Engineering Materials 21 (2019) 1801359
Kobayashi, Effects of [omega]-phase precipitation on [beta]-->[alpha], [alpha]'' transformations in a metastable [beta] titanium alloy, Materials Science and Engineering A 312 (2001) 182-188
Ho, Effect of Omega Phase on Mechanical Properties of Ti-Mo Alloys for Biomedical Applications, Journal of Medical and Biological Engineering 28 (2008) 47-51