Search results

Numerical Solution of Bending Problem of A FGM Cantilever Beam With Large Deformation Qing-Lu LI 1, a, Shi-Rong LI 2,b 1 Department of Engineering Mechanics, Lanzhou university of technology, P.R.China 2 Department of Engineering Mechanics, Lanzhou university of technology, P.R.China 3List all alqu2008@163.com, blisr@yahoo.com.cn Keywords: FGM, shooting method, extensible beam , large deformation, numerical solution.
Assuming the FGM is composed with two materials, such as metal and ceramic.
The Young’s modulus, Poisson’s ratio for ceramic are ,.
International Journal of Non-linear Mechanics 35, 997. (2000) [6] Li, S.
-H..Journal of Sound and Vibration 248,379.(2001)

Zhang, Facile biphasic synthesis of TiO2–MnO2 nanocomposites for photocatalysis, Ceramics International, 42 (2016) 19425-19428
Teo, Low-temperature synthesis of TiO2 nanocrystals for high performance electrochemical supercapacitors, Ceramics International, 45 (2018) 4990-5000
Yisong, Advanced Electrode Materials for Electrochemical Supercapacitors in: Materials Science & Engineering, McMaster University, 2015, pp. 254
Herrmann, Field-Assisted Sintering Technology/Spark Plasma Sintering: Mechanisms, Materials, and Technology Developments, Advanced Engineering Materials, 16 (2014) 830-849
Yan, Synthesis of manganese titanate MnTiO3 powders by a sol–gel–hydrothermal method, Materials Science and Engineering: B, 113 (2004) 121-124

Research on the treatment of oily sludge Ping Chen1,2,a, Lianbao Kan1,2 1 Heilongjiang Key Laboratory of Disaster Prevention, Mitigation and Protection Engineering; Daqing, Heilongjiang, 163318, China 2 College of Civil and Architecture Engineering, Northeast Petroleum University; Daqing, Heilongjiang, 163318, China; aemail:shenjiangong22@126.com Keywords: Oily sludge; Ultrasound; Biodegradation; Sludge dewatering Abstract: The oily sludge was more serious polluted to the environment, it is necessary to harmless treatment.
The results showed that practically no change occurred in the main technological properties required to specify porous red ceramic products.
Stefanescu: Journal of Petroleum Science and Engineering Vol. 22 (1999) , p.151–160 [11] C.
Tahhan, Rouba Youssef Abu-Ateih: International Biodeterioration & Biodegradation Vol. 63 (2009) , p.1054–1060 [14] Vanessa S.
Holanda: Ceramics International Vol.39 (2013) , p. 57–63 [20] Patricia Fernanda Andrade, Thiago Figueiredo Azevedo, Iara F.

The subject of ecological environment functional materials (EEFMS) is the certain combination of materials science and engineering and environment science and engineering, which mainly concerns on the research and development of environment pollution and control functional materials and micro-environment control functional materials [1-2].
The environment mineral materials is the interaction, infiltration and amalgamation of quite many of subjects involved in environment science, mineral science, materials science, engineering science, physics and chemistry.
College of Marine Science and Engineering 13 Nanjing University Research Center of Ecomaterial and Renewable Energy 14 Beihang University Research Center of Materials Physics and Chemistry 15 Dalian University of Technology Department of Materials Engineering 16 Wuhan University of Technology School of Materials Science and Engineering 17 China University of Geosciences School of Materials 18 Southwest University of Science and Technology Analytical and Testing Center 19 Shanghai Second Polytechnic University Department of Environment Engineering 20 Yantai University School of Environment and Materials Engineering 21 Zhe Jiang Forestry University Institute of Ecological Environment Materials 22 Xi'an University of Architecture and Technology Institute of Ecological Environment Materials Table 2 Primary Laboratory Engaged in EEFMS Research NO.
By far, a integrate university education system with undergraduate, master, doctor has come into being in universities depending on the subjects of material science and engineering, and so on.
:Journal of Rare Earths, Vol. 24(2006) p.248 [10] Junping Meng, Jinsheng Liang, Xiuqin Ou, et al.: Journal of Nanoscience and Nanotechnology, Vol. 8(2008) p.1279 [11] Dongbin Zhu, Jinsheng Liang, Yan Ding, et al.: Journal of the American Ceramic Society, Vol. 91(2008) p.2588 [12] Jinsheng Liang, Junping Meng, Dongbin Zhu, et al.: J.

Ceramics International, 2014, 40(5): 7539-7544
Materials engineering, 2019, 47 (04): 160-166
Ceramics International, 2020,46(1):1232-1235
Materials engineering, 2018, 46 (07): 19-28
Composites Part B: Engineering, 2017, 125

In the present study modeling of permeability of open-porosity ceramic materials used in non-polarizing electrodes is addressed.
The structure of the material filling the electrode determines the infiltration of its ceramic structure by electrolyte.
Brebbia, , Book Series: WIT Transactions on Engineering Sciences, Series Volume: 74, UK, ISBN: 978-1-84564-600-4
Wejrzanowski, Pressure drop in flow across ceramic foams – A numerical and experimental study, Chemical Engineering Science, Volume 137 (2015) Pages 320-337 [10] J.
Kurzydlowski, Image based analysis of complex microstructures of engineering materials, International Journal of Applied Mathematics and Computer Science, Vol. 18, No. 1 (2008), p. 33-39

[2] R X Xu, T H Topper, and J C Thompson, Fatigue Fracture Engineering and Materials Structure 20(9) 1351-1361 1997
[3] J Schijive, Fatigue Fracture Engineering and Materials Structure 5 77-90,1982 [4] Y Murakami, Stress Intensity Factor Handbook, Pergamon Press,1980 [5] R A Smith and K J Miller, International Journal of Mechanical Science 19 11-22 1977
[6] A Karlsson and J Backlund , International Journal of Fracture 14,585-596 1978 [7] D P Rooke, International Journal of Fatigue 2 69-75 1980
[8] P Lukas, M Klesnil, Materials Science and Engineering 34(1978)61-66
[9] T Fett, International Journal of Fracture 54 R57-64 1992

Composites Part B Engineering. 60.2(2014):597–602 [5] Y.X.
Composites Part B Engineering. 47.3(2013):320–325
Journal of Astm International. 4.7(2007):100516-100523
Materials Science and Engineering A. 425.1(2006):7-14
Materials Science and Engineering A. 398.1(2005):180–187

Introduction With the requirement of friction and wear materials increasing rapidly in engineering technology area, the research on structural ceramics have been focused on because of its feature of high temperature resistance, corrosion resistance, abrasion resistance, high intensity, low thermal conductivity and low density [1-4].
Therefore, the research on friction parts made of the ceramics of SiC and Si3N4 has been one of the frontier topics in current international friction research area[2].
The equipment is shown in follows in Fig.1.The experimental apparatus of ceramics friction ring is shown in Fig. 2.
It is the ring contact friction test of ceramic materials.
Jahamir (ed.), Friction and Wear of Ceramic, New York: Marcel Dekker, 1994, 3~12 [5] Xingsheng Tong,The Research on wear principle of ceramics friction pairs,The South China Science and Technology University Journal, 2001-04,29(4):94~97 (In Chinese) [6] T,Senda., Drennan,J., McPherson,R., Sliding wear of oxide ceramics at elevated temperatures, Journal of the American Ceramic Society,78(11):3018~3024 [7]Andersson, P., Blomberg, A., Instability in the tribochemical wear of silicon carbide in unlubricated sliding contacts, Wear, 1994,174(1–2):1~7

Scientific or engineering explanations for the observed patterns gradually were developed.
Engineering compilations are available which show tables or equations for KI for a variety of cracks and specimen shapes.
This is a classic engineering problem.
Some of the more systematic studies were done by laboratories and engineering firms that were refining ceramics for use in structural applications such as heat engines.
Richerson: Modern Ceramic Engineering, Marcel Dekker Inc., NY, 1982