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Proceedings of the International Conference on Joining of Materials, Denmark, 1999: 277-283
International Journal for Joining of Materials, 1998, 10(1): 3-23
Welding Journal, 1999, 78(9):322s-328s
Welding Journal 2001, 80(1): 33s-38s
Science and Technology of Welding and Joining, 2000, 5(5): 324-328

Materials of Construction, 1997,17(1): pp59-64 [5] TAN TENG HOOI.
ACI Materials Journal, 1993,90(5): pp435-440 [7] BYUNG HWAN OH.
ACI Materials Journal, 1991,88(2): pp122-128 [8] KRZYSZTOF DYDUCH.
Materials and Structures, 1994, 24: pp505-509 [9] Li Yongqiang, Che Huimin.
Shanghai: Shanghai Science and Technology Press, 1989

Honeycomb is two-dimensional, prismatic cellular materials with a regular and periodic microstructure [3].
A finite element method (FEM) technique developed for the study of spatially periodic materials is applied to the analysis of the linear elastic responses of regular and re-entrant honeycomb structure [4].
Natural Science Foundation, 1 to 4
Journal of Engineering Science and Technology Review, 62
Journal Of Material Science, 1.

Table 1 Specifications of experimental samples Fabric materials Weave Pattern Coating materials Density [warps*wefts，roots/10cm] Thickness[mm] Cotton Plain Polyurethane 200*200 0.95 Electrical strength tester, named INSTRON, was used in the experiment.
Journal of Donghua University (Natural Science), we, Vol.32 (2006), p. 119, in Chinese [2] R.Dhingra, R.Postle, Cai-yuan Chu.
Journal of China Textile University (Eng.
Donghua University (Natural Science).
The Science of Textile Materials.

Material 1 is air while material 2 and material 3 are both permanent magnet.
Journal of Magnetism and Magnetic Materials, (2009), p.1635-1638
Technology Magnetism[M]. beijing:Science Press,(2009)
BEIJING: Science Press, (2009)
Journal of Northwest Agriculture University,(2000).

Manufacturing Design of the Novel Multi-layer Blending Machine Jia Horng Lin1,2*, Wen Hao Hsing3, Ching Wen Lin4, Chien Teng Hsieh5, Wen Tai Cho1 and Ching Wen Lou6* 1Laboratory of Fiber Application and Manufacturing, Department of Fiber and Composite Materials, Feng Chia University, Taichung City 407, Taiwan (R.O.C.) 2School of Chinese Medicine, China Medical University, Taichung City 404, Taiwan, R.O.C. 3The Department of Textile Engineering, Chinese Culture University, Taipei City 111, Taiwan (R.O.C.) 4Department of Fashion Design, Asia University, Taichung City 413, Taiwan (R.O.C.) 5Department of Fashion Design and Merchandising, Shih Chien University Kaohsiung Campus, Kaohsiung City 845, Taiwan (R.O.C.) 6Institute of Biomedical Engineering and Material Science, Central Taiwan University of Science and Technology, Taichung City 406, Taiwan (R.O.C.)
Yao: International Nonwovens Journal vol.14 (2005), p.39-50
Lin: Textile Research Journal Vol.80 (2010), p.325-33
Lou: Advanced Materials Research Vol. 123-125 (2010), p. 359-362
Lin: Advanced Materials Research Vol. 55-57 (2008), p.397-400

Materials and methods The tested material is AAC (produced by Hebel) with lime-cement binder and sand filler.
Journal of Advanced Concrete Technology 2 (2004) 121-129
Plagge, Interlaboratory Comparison of Hygric Properties of Porous Building Materials.
Aligizaki, Pore Structure of Cement-Based Materials, Taylor& Francis, London and New York, 2006
Journal of ASTM International, 4 (2007) No.8.

Cutter Engagement Region (CER) is the part of tool that contacts with stock, where a series of energy exchange and material transportation take place.
Acknowledgments This work was financially supported by the Program for Zhejiang Leading Team of S&T Innovation (No.2009R50008), National Nature Science Foundation of China (No. 51105335).
Altintas, Prediction of ball-end milling forces from orthogonal cutting data, International Journal of Machine Tools & Manufacture, 36 (1996) 1059-1072
Lazoglu, Sculpture surface machining: a generalized model of ball-end milling force system, International Journal of Machine Tools & Manufacture, 43 (2003) 453-462
Salgado, Cutting force estimation in sculptured surface milling, International Journal of Machine Tools & Manufacture, 44 (2004) 1511-1526

Kwun 1, d 1 Division of Materials Science and Engineering, Korea University, Seoul, 136-701, Korea a ki-ho@korea.ac.kr, bchs2865@korea.ac.kr, cjyc6464@hanmail.net, dsookkwun@korea.ac.kr Keywords: Fatigue crack growth, Buttering, Alloy 82, SA 508 Cl.3, AISI 316L stainless steel Abstract.
The chemical compositions of the test materials are given in Table 1.
Chemical composition of test materials (wt. %).
Crack length vs. number of cycles in individual materials.
Pelloux: Welding Journal. 54 (1975), p.144 [6] D.A.

This study is included in a major project where other related phenomena and materials’ properties have been studied.
Both materials present a pearlitic microstructure.
Chemical composition of wheel and rail materials [% weight].
Anderson, A Study of Residual Stress Induced During Rolling, Journal of Tribology. 91, 2 (1969) 314-318
Mittemeijer, State of residual stress induced by cyclic rolling contact loading, Materials Science and Technology. 13, 5 (1997) 430-438