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Research on Load-carrying Performances of Magnetic-fluid Lubrication for Mill Oil-film Bearing Jianmei Wang 1, a, Qingxue Huang 1,b, Jianzhao Sun1,a, Xunjie Huang1,c, Jianfeng Kang1,d 1Taiyuan University of Science and Technology, People’s Republic of China awjmhdb@163.com, bhqx@tyust.edu.cn, chxjxs@sohu.com, dkangjianfeng163@163.com Keywords: Oil-film bearing.
Moreover, foreign scholar N.C.Das[3] has done some optimization analysis on load-carrying capacity of journal bearing under magnetic-fluid lubrication.
Shah[4] analyzed the squeeze film of journal bearing under magnetic fluid based on three models, etc..
The geometry and material parameters of oil-film bearing are given in Table 1.
Acknowledgements The authors would like to thank the support of the National Youth Science Foundation of China (51205269) and Shanxi Provincial Natural Science Foundation of China (2012011018-2).

The present contribution hopes to stimulate and lead the development of a theoretical basis for the science of automobile modeling evaluations and to formulate a methodology for this discipline.
Methods And Materials Subjects.
Acknowledgments This study was supported by the National Science Foundation of China (50435040) and Foundation of State Key Laboratory of Automobile Dynamic Stimulation, China, (20071105).
Safety Science, no. 47, pp.115-124, 2009
[3] MA Schier, "Changing in EEG alpha power during simulated driving: a demonstration," International Journal of Psychophysiology, no. 37, pp. 155-162, 2000

Conventional metal, concrete and fiber-reinforced polymer are usually used as the materials for the roadside structure.
It can be seen from Fig. 2 (b) that under the force, non-crystalline materials [8] distorted and oriented along the force direction, while the deformation was restricted by the crystalline regions around.
The porous UHMWPE was a promising roadside safety material.
Acknowledgment The financial support for this work from the National Natural Science foundation of China (No.10772024) and the Scientific Research Fund of University of Science and Technology (grant No.06108032) is gratefully acknowledged.
Eskandarian: International Journal of Crashworthiness Vol.10 (2005), p. 5

Another possible solution is using adhesive bonded materials which resist to corrosion.
International Journal of Adhesion & Adhesive 29 (2009) 77-90
Kinloch, Adhesion and adhesives – science and technology, 1st ed.
Messler, Joining of materials and structures from pragmatic process to enabling technology.
Žarnovský, Impact of atmosphere to improvement of the mechanical properties of metal materials (Vplyv plynných atmosfér na zlepšenie mechanických vlastností kovových materiálov).

Introduction In recent days lighter and stronger materials are evolved in order to satisfy the need of advance technology.
Design and fabrication of these materials is continuously evolving to make even stronger and lighter structures.
In terms of structure, materials can be divided into four basic categories: metals, polymers, ceramics, and composite materials.
A composite material is a combination of two or more materials in right proportions to get single entity and improved qualities from the single material.
Sandwich structures represent special type of composite materials.

Cui, et al., Journal of Materials Processing Technology, 2001, 113(1): 482-485
Xie P, et al., Materials Letters, 2016, 169: 86-89
Fan, et al., Journal of Materials Chemistry C, 2014, 2(33): 6752-6757
Gao, et al., Journal of Magnetism and Magnetic Materials, 2015, 381: 105-108
Zhang et al., Materials & Design, 2016, 97: 454-458

Composition – property relations in shear thickening fluids Łukasz Wierzbicki1a*and Marcin Leonowicz1 1Faculty of Materials Science and Engineering, Warsaw University of Technology, Wołoska 141, 02-507 Warsaw, Poland alwierzbicki@inmat.pw.edu.pl Keywords: shear thickening fluid, fumed silica, storage modulus, loss modulus Abstract.
STFs have the ability of predictable response to the external stimuli, which includes them into the group of smart materials, which combine functions of a sensor, processor and actuator.
Acknowledgment The project “Smart materials for energy absorption and protection of human body” is financed by the National Centre for Research and Development within the scheme of Applied Research Programme, within years 2013-2015, agreement PBSl/A5/19/2012 PBSl/A5/19/2012.
Wierzbicki, Rheological Fluids for Energy Absorbing Systems, Applied Mechanics and Materials, (2013), 440, 13 [3] Lee Y S, Wetzel E D, Wagner N J.
The ballistic impact characteristics of Kevlar woven fabrics impregnated with a colloidal shear thickening fluid, Journal of Materials Science, (2003), 38: 2825 [4] R.G.

Acknowledgement The authors would like to express their gratitude to the Ministry of Science and Technology, Malaysia (MOSTI) and Ministry of Higher Education, Malaysia (MOHE) for the financial support given to this work.
Bonner.Journal of Material Processing Tech, vol 173 (2006) p.269–274 [6] A.R.
Journal of Alloys and Compounds, vol 470 (2009) p.323–327 [7] M.C.
Materials Science and Engineering, A vol. 487 (2008) p.171–179
Journal of Materials Processing Technology vol.74 (1998) p. 183–189

Using adaptive materials, dynamical characteristics of structures could be controlled in a predictable manner to avoid the dynamical instabilities such as structural resonances [1].
The active vibration control is introduced by using piezoelectric materials where the layers are symmetrically embedded in the host structure spread over the entire beam span.
Synergistic Implications of Tailoring and Adaptive Materials Technology on Vibration Control of Anisotropic Thin-Walled Beams, International Journal of Engineering Science, 39(1), 71-94
Control of Cantilever Vibration via Structural Tailoring and Adaptive Materials, AIAA Journal, 35(8), 1309-1315
Oscillation Control of Cantilevers via Smart Materials Technology and Optimal Feedback Control: Actuator Location and Power Consumption Issues, International Journal of Engineering Science, 7(6), 833-842

Introduction Unlike ductile materials, (quasi)brittle materials often undergo sudden failures without any prior warning.
The numerical modeling of the onset of such catastrophic failures is further complicated by the presence of a strong size dependence in the mechanical response of such materials [1, 2, 3].
A numerical model must capture the multiscale nature of the damage phenomena in order to reproduce the experimentally observed size effect in quasibrittle materials.
Ostoja-Starzewski in: Handbook of Damage Mechanics: Nano to Macro Scale for Materials and Structures, edited by G.Z.
Ostoja-Starzewski: Microstructural randomness and scaling in mechanics of materials (CRC Press, Boca Raton, FL, 2008)