Search results

Venkateswarlu3,c and Muralimohan Cheepu4,d* 1Department of Mechanical Engineering, Acharya Nagarjuna University, Andhra Pradesh 522510, India 2Department of Mechanical Engineering, RVR & JC College of Engineering, Andhra Pradesh 522019, India 3Department of Mechanical Engineering, Marri Laxman Reddy Institute of Technology and Management, Telangana 500043, India 4Department of Materials System Engineering, Pukyong National University, Busan 48510, Republic of Korea Email: anadella7779@gmail.com, *bvcdas@rvrjcce.ac.in, cdevuri.venky@gmail.com, *dmuralicheepu@gmail.com Keywords: TIG welding, High strength tensile steel, Inconel 718 super alloy, Microstructures, Mechanical properties, Fractography.
Seshabhattar (Eds.), Techno-Societal 2016, International Conference on Advanced Technologies for Societal Applications, ICATSA 2016, Springer, Cham, 2018, pp.709-717
(eds) Advanced Materials.
Forum. 710 (2012) 620-625
In Advances in Materials and Metallurgy, pp. 271-281.

Introduction The research based on fluid convection is highly in demand in many industrial and engineering applications.
The sudden failure of the device may cause a significant loss in engineering or scientific research, which cannot be appreciated.
Khandekar, Engineering applications of ferrofluids: A review.
Chemical Engineering Communications, 67(1) (1988) 1-18
Krakov, Magnetic fluids: engineering applications.

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

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

Goryunov, A compression mold for casting under pressure, Mechanical engineering, 1974
Gavarieva, Influence of multilayer coatings on the operational stability of molds for injection molding, IOP Conference Series: Materials Science and Engineering, 1(134) (2016) 012031
Haga, Advanced casting methodologies: inert environment vacuum casting and solidification, die casting, compocasting, and roll casting, casting, semi-solid forming and hot metal forming, Comprehensive Materials Processing, Elsevier Ltd., 5 (2014) 3-37
Engineering Journal" (with attachment), 5 (2014) 48-52
Dornfeld, Moving towards green and sustainable manufacturing, International Journal of Precision Engineering and Manufacturing - Green Technology, 1 (2014) 63-66

Modified Jiles-Atherton Model The phenomenological description advanced in the eighties of the last century has gained a considerable attention in the scientific and engineering community.
The corresponding values are obtained from the transformed constitutive relationship Extended Takács Model Takács has advanced an interesting description of hysteresis loops and related magnetization curves using a hyperbolic tangent transformation between the loop coordinates [7].
It should be remarked that this optimization routine is very attractive from the engineering point of view, as it yields optimal solutions in a reasonable time and it does not require many user settings.
In order to draw some meaningful conclusions about the obtained results, the final relationship erived for the modified JA the parameter b responsible for reversible magnetization effects has been set to zero, as the corresponding model advanced by Takács does not consider the reversibility.
Forum 727–728 (2012) 130–134

Synthesis and Characterization of Copper/Paraffin Nanocomposites for Thermal Actuation Bin Xu 1,a, Baiyang Lou 2,b 1,2Institute of Material and Surface Engineering, Zhejiang University of Technology, Hangzhou, 310014, China axub@zjut.edu.cn, blby00518@163.com Keywords: Nanocomposites, High energy ball milling, Thermal sensitivity, Microstructure Abstract.
It also can be used as thermo-sensitive and expansive materials for thermal actuation with a high sensitivity at the phase change temperature, which gives them great advantages in engineering applications[1-2].
Sharma: Advanced engineering materials, Vol.10 (2008) No.4, pp.366-370
Lu: Introduction to Powder Engineering (Shanghai: Tongji University Press, China 1993)
Maccormick: Materials Forum, Vol.16 (1992), pp.91-95

Materials Science and Engineering A ,1996, 207, 159- 169
Materials Science and Engineering R, 2009, 65, 39–104
High-nitrogen steels: the current state and development trends.Advanced Steels, 2011:367-370
Proceedings of the 8th Vacuum Metallurgy and Surface Engineering Conference.
Materials Science and Engineering A, 2006, 417, 307–314

Reed, Analysis of fatigue crack initiation and S–N response of model cast aluminium piston alloys, Materials Science and Engineering: A, Volume 528, Issue 24, 15 September 2011, Pages 7331-7340
Reed, Micromechanisms of short fatigue crack growth in an Al–Si piston alloy, Materials Science and Engineering: A, Volume 612, 26 August 2014, Pages 302-309, ISSN 0921-5093
London: Mechanical Engineering Publications: 1990. p. 147-62
Mater Sci Forum 2006;1083: 519-521
Moffat, Micromechanistic analysis of fatigue in aluminium silicon casting aloys (Ph.D. thesis), School of Engineering Sciences, University of Southampton, 2007

The Effect of Enhanced Solution Treatment on Microstructures and Properties of 6013 Type Aluminum Alloy Fubao ZHANG1, 2, a, Tongming TANG1,b, Yufeng ZHAO3, Xiaojing XU2, Zhilan JU1 and Guoran HUA1 1School of Mechanical Engineering, Nantong University, Nantong 226019, China 2Engineering Institute of Advanced Manufacturing and Modern Equipment Technology, Jiangsu University, Zhenjiang 212013, China 3Nantong Polytechnic College, Nantong 226002, China antuzfb@126.com, btomtang@ntu.edu.cn Keywords: 6013 type aluminum alloy; enhanced solution treatment; microstructure; mechanical properties; corrosion resistance Abstract.
Materials Forum. 2004(28): 832-837
Materials Science and Engineering A. 2006: 687-692
Rare Metal Materials and Engineering. 2007, 36(Suppl.3): 195-198
Material Science Engineering A. 1997, 238(2): 293-302.