Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: May 2004
Authors: Giovanni Baldi, A. Barzanti, V. Faso
New Glass-Ceramic Materials for Ceramic Industry
G.
Glass ceramic pigments An innovative application of glass ceramic materials is the "in-situ" synthesis of pigments.
Strnad, Volume and surface crystallization during formation of glass ceramic materials, Glass Ceramics Materials, ed.
[3] G.Baldi, E.Generali, C.Leonelli,T.Manfredini, G.C.Pellacani, C.Siligardi, Journal of Material Science, 30 (1995), p.3251
Strnad, Glass Ceramic Materials, ed.
Glass ceramic pigments An innovative application of glass ceramic materials is the "in-situ" synthesis of pigments.
Strnad, Volume and surface crystallization during formation of glass ceramic materials, Glass Ceramics Materials, ed.
[3] G.Baldi, E.Generali, C.Leonelli,T.Manfredini, G.C.Pellacani, C.Siligardi, Journal of Material Science, 30 (1995), p.3251
Strnad, Glass Ceramic Materials, ed.
Online since: June 2017
Authors: Juraj Kralik
Kabelac, Study of a Nuclear Power Plant Containment Damage Caused by Impact of a Plane, International Refereed Journal of Engineering and Science (IRJES). 1(4) (2012) 48-53.
Brozovsky, Bearing capacity analysis of reinforced concrete beams, International Journal of Mechanics. 7 (3) (2013) 192-200
Krizma, Assessment of Concrete Damage, Building Research Journal. 54 (2006) 211-216
Advanced Materials Research. 859 (2013) 114-121.
Puklicky, Material and geometrical characteristics of structural steels based on statistical analysis of metallurgical products, Journal of Civil Engineering and Management. 15 (3) (2009) 299-307
Brozovsky, Bearing capacity analysis of reinforced concrete beams, International Journal of Mechanics. 7 (3) (2013) 192-200
Krizma, Assessment of Concrete Damage, Building Research Journal. 54 (2006) 211-216
Advanced Materials Research. 859 (2013) 114-121.
Puklicky, Material and geometrical characteristics of structural steels based on statistical analysis of metallurgical products, Journal of Civil Engineering and Management. 15 (3) (2009) 299-307
Online since: January 2012
Authors: W.J. Dan, W.G. Zhang
Takahashi et al., Effect of hardening exponent on tube bending, Journal of Materials Processing Technology, Vol. 201(2008), p.189
[2] S.
Murata, Effect of initial thickness on shear bending process of circular tubes, Journal of Materials Processing Technology, Vol.191(2007), p.136 [6] X.T.
Sun et al., Study on varying curvature push-bending technique of rectangular section tube, Journal of Materials Processing Technology, Vol.187-188(2007), p.476 [7] H.
Zhan et al., The interactive effects of wrinkling and other defects in thin-walled tube NC bending process, Journal of Materials Processing Technology, Vol.187-188 (2007), p.502 [8] H.
Huang et al., Springback analysis of numerical control bending of thin-walled tube using numerical-analytic method, Journal of Materials Processing Technology, Vol.177 (2006), p.197-201.
Murata, Effect of initial thickness on shear bending process of circular tubes, Journal of Materials Processing Technology, Vol.191(2007), p.136 [6] X.T.
Sun et al., Study on varying curvature push-bending technique of rectangular section tube, Journal of Materials Processing Technology, Vol.187-188(2007), p.476 [7] H.
Zhan et al., The interactive effects of wrinkling and other defects in thin-walled tube NC bending process, Journal of Materials Processing Technology, Vol.187-188 (2007), p.502 [8] H.
Huang et al., Springback analysis of numerical control bending of thin-walled tube using numerical-analytic method, Journal of Materials Processing Technology, Vol.177 (2006), p.197-201.
Online since: November 2012
Authors: Rui Zhang, Zi Li Kou, Shen Zhuo Liu, Cheng Liang Liu, Yu Li, Rong Qi Li, Xiao Zhi Yan
Journal of Materials Processing Technology 102 (2000) 25-29
Journal of Materials Processing Technology 128 (2002) 100–105
Barash, Experimental investigation on CBN turning of hardened AISI 52100 steel, Journal of Materials Processing Technology 124 (2002) 274-283 [12] R.
Advanced materials Reserch Vol 337 (2011) pp 728-734
Zhang ,Study on wear mechanisms and grain effects of PCD tool in machining laminated flooring, International Journal of Refractory Metals & Hard Materials 22 (2004) 111-115.
Journal of Materials Processing Technology 128 (2002) 100–105
Barash, Experimental investigation on CBN turning of hardened AISI 52100 steel, Journal of Materials Processing Technology 124 (2002) 274-283 [12] R.
Advanced materials Reserch Vol 337 (2011) pp 728-734
Zhang ,Study on wear mechanisms and grain effects of PCD tool in machining laminated flooring, International Journal of Refractory Metals & Hard Materials 22 (2004) 111-115.
Online since: January 2006
Authors: Chun Quan Zhai, Qu Dong Wang, Yongjun Chen, Jianguo Peng
Introduction
As a result of the high strength of fine grained materials and also the interest in work hardening
mechanisms associated with fine grain sizes, development in severe plastic deformation (SPD)
methods for fabricating sub-micron and nano-scale grained materials have attracted the growing
interest of specialists in materials science [1].
Cao, A.Godfrey, Q.Liu: Materials Science and Engineering A Vol.361 (2003), p. 9 [2] R Z Valiev, R.K.IsIamgaliev, I V Alexandrov: Progress in Materials Science.
R Lapovok, I G .Brodova, P.F Thomson: Materials Science and Engineering: A Vol.357 (2003), p. 159 [4] Q Wei, T Jiao, S.N Mathaudhu, E Ma, K.T Hartwig, K.T Ramesh: Materials Science and Engineering: A, Vol.358 (2003), p. 266 [5] Y Ivanisenko, R.Z Valiev, H J.Fecht :Materials Science and Engineering: A Vol.390 (2005), p.159 [6] H S Kim, S I Hong, Y S Lee, A A Dubravina, I V Alexandrov: Journal of Materials Processing Technology, Vol.142 (2003), p. 334 [7] M.T.
Ruano: Scripta Materialia, Vol.51 (2004), p. 1093 [8] N Kamikawa, N Tsuji, Y Minamino: Science and Technology of Advanced Materials, Vol.5 (2004), p. 163 [9] M Richert, H.P Stüwe; M.J Zehetbauer, J Richert, R Pippan, C Motz, E Schafler: Materials Science and Engineering:A Vol.355 (2003), p. 180 [10] H S Chu, K S Liu, J W Yeh: Materials Science and Engineering: A, Vol.277 (2000),p. 25 [11] Lin H K, Huang J C: MATERIALS TRANSACTIONS, Vol.43 (2002), p. 2424 [12] Y M Hwang, M T Yang: Key Engineering Materials, Vol.233 (2002), p. 311 [13] R.
[14] M Chandrasekaran, Y M S John: Materials Science and Engineering A Vol.381 (2004), p. 308 [15] Akihiro Yamashita, Zenji Horita, T G, Langdon: Materials Science and Engineering A, 300 (2001), p. 142 [16] Shi-Ying Yuan, Jien-Wei Yeh, Chun-Huei Tsau.
Cao, A.Godfrey, Q.Liu: Materials Science and Engineering A Vol.361 (2003), p. 9 [2] R Z Valiev, R.K.IsIamgaliev, I V Alexandrov: Progress in Materials Science.
R Lapovok, I G .Brodova, P.F Thomson: Materials Science and Engineering: A Vol.357 (2003), p. 159 [4] Q Wei, T Jiao, S.N Mathaudhu, E Ma, K.T Hartwig, K.T Ramesh: Materials Science and Engineering: A, Vol.358 (2003), p. 266 [5] Y Ivanisenko, R.Z Valiev, H J.Fecht :Materials Science and Engineering: A Vol.390 (2005), p.159 [6] H S Kim, S I Hong, Y S Lee, A A Dubravina, I V Alexandrov: Journal of Materials Processing Technology, Vol.142 (2003), p. 334 [7] M.T.
Ruano: Scripta Materialia, Vol.51 (2004), p. 1093 [8] N Kamikawa, N Tsuji, Y Minamino: Science and Technology of Advanced Materials, Vol.5 (2004), p. 163 [9] M Richert, H.P Stüwe; M.J Zehetbauer, J Richert, R Pippan, C Motz, E Schafler: Materials Science and Engineering:A Vol.355 (2003), p. 180 [10] H S Chu, K S Liu, J W Yeh: Materials Science and Engineering: A, Vol.277 (2000),p. 25 [11] Lin H K, Huang J C: MATERIALS TRANSACTIONS, Vol.43 (2002), p. 2424 [12] Y M Hwang, M T Yang: Key Engineering Materials, Vol.233 (2002), p. 311 [13] R.
[14] M Chandrasekaran, Y M S John: Materials Science and Engineering A Vol.381 (2004), p. 308 [15] Akihiro Yamashita, Zenji Horita, T G, Langdon: Materials Science and Engineering A, 300 (2001), p. 142 [16] Shi-Ying Yuan, Jien-Wei Yeh, Chun-Huei Tsau.
Online since: August 2011
Authors: Lian Min Ji, Li Juan Li, Zhi Qi Liu, Bo Zhang, Feng Nie, Zhong Min Zeng, Fu Gen Song, Yan Hui Zhang, Xu Hong Jia
Such magnesium hydroxide materials were found to give an enhanced powder filtration.
Introduction Magnesium hydroxide(Mg(OH)2), a very popular, environmental friendly and thermally stable flame-retardant filler in composite materials [1-4], has shown many excellent functions in modern technology, which has been widely used in the fields such as polymers, electric cables, building and decoration materials, as well as a precursor for the preparation of magnesium oxide[5].
Such magnesium hydroxide materials were found to give an enhanced powder filtration.
Acknowledgements This work was financially supported by the Programs of QingHai Science & Technology Department (2005-G-165).
Opperhauser, Effect of pH on the growth of Mg(OH)2 crystals in an aqueous environment at 60°C, Journal of Crystal Growth. 41 (1977) 228-234
Introduction Magnesium hydroxide(Mg(OH)2), a very popular, environmental friendly and thermally stable flame-retardant filler in composite materials [1-4], has shown many excellent functions in modern technology, which has been widely used in the fields such as polymers, electric cables, building and decoration materials, as well as a precursor for the preparation of magnesium oxide[5].
Such magnesium hydroxide materials were found to give an enhanced powder filtration.
Acknowledgements This work was financially supported by the Programs of QingHai Science & Technology Department (2005-G-165).
Opperhauser, Effect of pH on the growth of Mg(OH)2 crystals in an aqueous environment at 60°C, Journal of Crystal Growth. 41 (1977) 228-234
Online since: November 2010
Authors: Hui Ai, Chuan Qing Zhang, Li Zhang, Ju Tian
Relative to the materials research, the research of structures is backward, especially the research on bearing capacity of prestressed concrete structure under high temperature.
Then the capability of various materials should be found out by the indicative temperature.
First, the temperature of various materials that correspond to different combustion duration is found out, and then the material strength at specific temperature is calculated.
[6] Wu Bo, Liang Yuehuan: Journal of South China University of Technology(Natural Science Edition), Vol. 36 (2008)
[7] Li Wei, Guo Zhenhai: Journal Of Building Structures, Vol. 14(1993)
Then the capability of various materials should be found out by the indicative temperature.
First, the temperature of various materials that correspond to different combustion duration is found out, and then the material strength at specific temperature is calculated.
[6] Wu Bo, Liang Yuehuan: Journal of South China University of Technology(Natural Science Edition), Vol. 36 (2008)
[7] Li Wei, Guo Zhenhai: Journal Of Building Structures, Vol. 14(1993)
Online since: July 2014
Authors: Wen Cheng Ma, Hong Jun Han, Ji Hua Huang, Shi Yi Zheng, Ling Yue Chen, Xiao Liu, Sheng Yong Jia, Jin Ming Mu
In the past, the pharmaceutical enterprises treated the residues as the raw materials of fertilizer and feedstuff to sell.
Absorption materials.
Journal of Hazardous Materials B77 (2000), p. 149-159
Journal of Henan Institute of Science and Technology.
Journal of Hebei University of Science and Technology.
Absorption materials.
Journal of Hazardous Materials B77 (2000), p. 149-159
Journal of Henan Institute of Science and Technology.
Journal of Hebei University of Science and Technology.
Online since: September 2013
Authors: Wen Hui Li, Sheng Qiang Yang, Jin Yu Guo, Hong Ling Chen
Introduction
Permanent magnetic material is a kind of important functional materials and applied widely in almost all the science and technology and military fields.
(a) i=0 Contour of air gap (b) i=0 along the L path (c) i=-4.125A Contour of air gap (d) i=-4.125A along the L path Fig. 4 Distribution of air gap magnetic induction intensity in different current for magnetic materials Finishing of Non-magnetic Materials (the same permeability as air).
Song: Lecture of basis knowledge of commonly used permanent magnet materials and its application of the Magnetic Materials and Devices, (2007) No.6, pp.65-68 (In Chinese)
Yang: Research of Magnetic induction intensity Intensity on Magnetic Abrasive of the Key Engineering Materials, (2011) No.455, pp.174-180
Wang: Internal Magnetic Abrasive Particles Surface Finishing Based on Permanent Magnetic Field of the Advanced Materials Research, (2008), pp.53-54;65-68
(a) i=0 Contour of air gap (b) i=0 along the L path (c) i=-4.125A Contour of air gap (d) i=-4.125A along the L path Fig. 4 Distribution of air gap magnetic induction intensity in different current for magnetic materials Finishing of Non-magnetic Materials (the same permeability as air).
Song: Lecture of basis knowledge of commonly used permanent magnet materials and its application of the Magnetic Materials and Devices, (2007) No.6, pp.65-68 (In Chinese)
Yang: Research of Magnetic induction intensity Intensity on Magnetic Abrasive of the Key Engineering Materials, (2011) No.455, pp.174-180
Wang: Internal Magnetic Abrasive Particles Surface Finishing Based on Permanent Magnetic Field of the Advanced Materials Research, (2008), pp.53-54;65-68
Online since: September 2013
Authors: Michael A. Gharghouri, Michael Bach, Ali Merati, Ronald Rogge, Robert Bell, Xin Wang
The process uses a rotating tool to mix the joining materials together.
Table 1: Material properties of stringer and flat sheet materials.
Williams, Residual stresses in friction stir welded Al sheets, Applied Physics A Materials Science & Processing 74 (2002) 1161-1165
Reynolds, A Study of Residual Stresses and Microstructure in 2024-T3 Aluminum Friction Stir Butt Welds, Journal of Engineering Materials and Technology 124 (2002) 215-221
Reynolds, A Study of Residual Stresses and Microstructure in 2024-T3 Aluminum Friction Stir Butt Welds, Journal of Engineering Materials and Technology 124 (2002) 215-221
Table 1: Material properties of stringer and flat sheet materials.
Williams, Residual stresses in friction stir welded Al sheets, Applied Physics A Materials Science & Processing 74 (2002) 1161-1165
Reynolds, A Study of Residual Stresses and Microstructure in 2024-T3 Aluminum Friction Stir Butt Welds, Journal of Engineering Materials and Technology 124 (2002) 215-221
Reynolds, A Study of Residual Stresses and Microstructure in 2024-T3 Aluminum Friction Stir Butt Welds, Journal of Engineering Materials and Technology 124 (2002) 215-221