Search results

School of Materials Science and Engineering, Wuhan University of Technology, Wuhan, China 2.
It was used for reactive salic cementitious materials.
Acknowledgements The authors gratefully acknowledge the project supported by the National Major Fundamental Research Program of China (Grant No. 2009CB23201) and the facilities provided by the school of materials science and engineering at Wuhan University of Technology, Hubei, China.
[3]NanruYang: Journal of The Chinese Ceramic Society, 24(4)(1999):209–215.
(in Chinese) [5]Davidovits J: Journal of Thermal Analysis,35(2)(1989):429-41

Introduction: Functionally Graded Materials (FGMs) are an emerging class of materials with great scope for engineering via tailoring of properties.
The concept of FGM was first proposed in the 1980s for heat-resistant applications as an alternative to traditional composite materials made up of two dissimilar materials. [1,2].
FGMs are advanced composite materials with the ability to tailor material for a specific application [1].
In multi-material depositions, inadequate compatibility between the depositing materials also leads to cracks and mechanical property degradation.
Pietrzak, Metal-ceramic functionally graded materials - Manufacturing, characterization, application, Bulletin of the Polish Academy of Sciences: Technical Sciences. 64 (2016) 151–160. https://doi.org/10.1515/bpasts-2016-0017

Mechanical Properties of Self-Healing System in Cementitious Material with Microcapsule Peng Liang1,a, Qianjin Mao1,b*, Ziming Wang1,c and Suping Cui1,d 1College of Materials Science and Engineering, Beijing University of Technology, Beijing, China aS201509050@emails.bjut.edu.cn, bmaoqj@bjut.edu.cn, cwangziming@bjut.edu.cn, dcuisuping@bjut.edu.cn Keywords: cementitious materials; microcapsule; self-healing materials; mechanical property Abstract.
Experiments Materials.
Journal of Advanced Concrete Technology. 10(6) (2012) 207-218
Progress in Polymer Science. 49-50 (2015) 175-220
New building materials, 5 (2014) 40-42

Journal of Materials Science, 29:294-323, 1994
Materials Science and Engineering A, 175:183-199, 1994
Journal of Polymer Science: Part B: Polymer Physics, 42:2983-2994, 2004
Journal of Computer-Aided Materials Design, 4:75-98, 1997
Mechanics of Materials, 7:15-33, 1988

While grinding hard and brittle materials the structure quality and accuracy depends on the material removal mechanism.
Li, Investigation of grinding modes in horizontal surface grinding of optical glass BK7, Journal of Materials Processing Technology 211 (2011) 1629–1636
Scattergood, Ductile-Regime Grinding: A New Technology for Machining Brittle Materials, J.
Evans, A model for crack initiation in elastic/plastic indentation fields, Journal of Materials Science 12 (1977) 2195–2199
Bifano, Ductile-regime grinding of brittle materials, Dissertation, 1988

A review of some of the various fatigue models introduced over the years for both metallic materials, in particular aluminium alloys followed by fatigue and durability concerns associated with composite materials.
Among the most commonly used materials laid Aluminium.
Hence the fatigue damage evolution is non-linear in composite materials.
Repair of Composite Materials.
Reissner, “The Stresses in Cemented Joints,” Journal of Applied Mechanics , vol. 11, pp.

Work on the current topic of hybrid titanium-polymer composite materials (TPCM) is continuing.
Filatov, IOP Conference Series: Materials Science and Engineering 971 (2020) 022062 doi:10.1088/1757-899X/971/2/022062
Deyev, Mechanics of composite materials 2 (1994) 136 – 145 [4] G.P.
Out, Applied Composite Materials Vol.10 4 – 5 (2003) 257 – 276
Plotnikova, Advanced materials and technologies 1 (2017) 44 – 55

This paper chronicles the inextricable link between materials and design.
These designs broke through the 10 OPR barrier, placing higher demands on materials and motivating the need for dedicated high temperature materials research.
Their slightly higher OPR of 35 demanded similar materials advances.
Another class of high temperature materials is the intermetallics.
Callopy, Technology for Jet Engines: Case Study in Science and Technology Development, Journal of Propulsion and Power Vol. 21(5) (2005), p.769

There are presented aspects regarding the welding of ferrous metal materials (DD13), couples of non-ferrous metallic materials (Al Cu range) and steels with aluminum.
For welding tools, the optimal materials, sizes and geometries are adapted for each couple of materials to be welded and for each developed FSW welding technology.
Hirsch – Automotive Trends in Aluminium – The European Perspective, Materials Froum Vol. 28, Institute of Materials Engineering Australasia Ltd, 2004 [2] T.
Ionescu – „Innovative solutions for ultrasonic joining“, Welding and Material Testing Journal, Year XXVI, No. 1, pp. 3-5, 2017, ISSN 1453-0392, 2017
Ciucă – Application of Thermography in Materials Science and Engineering, Chapter in the book: Raghu Prakash “Infrared Thermography”, pp.27-52, available at http://www.intechopen.com/books/infrared-thermography, ISBN: 978-953-51-0242-7, Publisher InTech, March, 2012

Analyses of Influencing Factors of Pore Formation during Resistance Spot Welding of Magnesium Alloy Yimin Tu1, 2, a, Ranfeng Qiu1, 2, b, Hongxin Shi1, c, Hua Yu1, d and Keke Zhang1, e 1School of Materials Science and Engineering, Henan University of Science and Technology, Luoyang, 471003, China 2 Henan Key Laboratory of Advanced Non-ferrous Metals, Henan University of Science and Technology, Luoyang 471003, China a yimin@mail.haust.edu.cn, b xdqrf@yahoo.com.cn, c hyhx66@163.com, d kedayuhua@126.com, e zhkeke@mail.haust.edu.cn Keywords: Resistance spot welding, Magneisum alloy, Pore, Mechanism Abstract.
[4] Ranfeng Qiu, Hongxin Shi, Hua Yu, Keke Zhang, Yimin Tu and Shinobu Satonaka: Materials and Manufacturing Processes 25-11(2010), p. 1304-1308
Wesley: Welding Journal 54-3(1975), 95s-98s
Wu: Welding Journal 56-8 (1977), p. 238s-244s
Hu: Welding Journal 83-4 (2004), p. 123s-132s.