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Online since: December 2011
Authors: Jun Chen, Wen Wen Zhang, Xiao Ming Chen, Shi Ping Liu, Hua Zheng, Hong Zhang, Lian Song Yu, Ying Feng
Many types of materials are involved in the drying process.
Generally they can be divided into the following types according to the water absorption features of the materials [11]: non-hygroscopic pore material, absorbent pore material, strict absorbent material and colloidal material.
The microwave drying, if applied under a vacuum environment, can not only avoid the oxidation of the dried materials [15], but also can reduce the external pressure of the materials and increased the mass transfer driving force.
Journal of Northeast Forestry University, Vol.32(2004)No.6, p. 58-63
Journal of Beijing Forestry University, Vol.24(2004)No.6, p. 98-101
Generally they can be divided into the following types according to the water absorption features of the materials [11]: non-hygroscopic pore material, absorbent pore material, strict absorbent material and colloidal material.
The microwave drying, if applied under a vacuum environment, can not only avoid the oxidation of the dried materials [15], but also can reduce the external pressure of the materials and increased the mass transfer driving force.
Journal of Northeast Forestry University, Vol.32(2004)No.6, p. 58-63
Journal of Beijing Forestry University, Vol.24(2004)No.6, p. 98-101
Online since: October 2012
Authors: Muhammad Riza, Muataz H.F. Al Hazza, Erry Yulian Triblas Adesta, M.Y. Suprianto
International Journal of Engineering and Applied Sciences 6:3 2010
[2] M.H AlHazza and Adesta E.
Advanced Materials Research. 264-265 (2011) 1003-1008
Journal of materials processing technology, 203 (2008)147–153
Advanced Materials Research Vols. 264-265, (2011) pp 1097-1101
Journal of Applied Sciences, 11 (2011) 2578-2584
Advanced Materials Research. 264-265 (2011) 1003-1008
Journal of materials processing technology, 203 (2008)147–153
Advanced Materials Research Vols. 264-265, (2011) pp 1097-1101
Journal of Applied Sciences, 11 (2011) 2578-2584
Online since: December 2013
Authors: S. Sharif, Denni Kurniawan, M.Y. Noordin, P.Y.M. Wibowo Ndaruhadi
Low cutting force is also important in bone machining considering that bone is a brittle material.
Occurrence of brittle fracture when machining brittle materials should be suppressed as it deteriorate the quality of surface finish [7,8].
Temperature changes near the drilling face, The Journal of Bone and Joint Surgery. 78 (1996), p.357-62
[2] G Augustin, S Davila, K Mihoci, T Udiljak, DS Vedrina, A Antabak, Thermal osteonecrosis and bone drilling parameters revisited, Arch Orthop Trauma Surg. 128 (2008), p.71–77 [3] SC Isler, E Cansiz, CTanyel, M Soluk, F Selvi, Z Cebi, The effect of irrigation temperature on bone healing, International Journal of Medical Sciences. 8 (2011), p.704-708 [4] SRH Davidson, DF James, Drilling in bone: modeling heat generation and temperature distribution, Journal of Biomechanical Engineering. 125 (2003), p.305-314 [5] D Kurniawan, N Jiawkok, MY Noordin, Machining conditions effect to machining temperature and forces in orthogonal machining of bone, Advanced Materials Research. 658 (2013), p.223-226 [6] S Sharif, EA Rahim, H Sasahara, Machinability of titanium alloys in drilling.
Journal of Manufacturing Processes. 13 (2011), p.50-59 [8] DP Yu, YS Wong, GS Hong, A novel method for determination of the subsurface damage depth in diamond turning of brittle materials, International Journal of Machine Tools and Manufacture. 51 (2011), p. 918-927 [9] H Ohashi, M Therin, A Meunier, P Christel, The effect of drilling parameters on bone- Part I General healing response, Journal of Materials Science: Materials in Medicine. 5 (1994), p.225- 231 [10] MY Noordin, D Kurniawan, S Sharif, Feasibility of mild hard turning of stainless steel using coated carbide tool, International Journal of Advanced Manufacturing Technology. 60 (2012), p.853-863 [11] D Kurniawan, NM Yusof, S Sharif, Hard machining of stainless steel using wiper coated carbide: tool life and surface integrity, Materials and Manufacturing Processes. 25 (2010), p.370-377 [12] C Yeager, A Nazari, D Arola, Machining of cortical bone: Surface texture, surface integrity and cutting forces, Mach Sci Technol. 12
Occurrence of brittle fracture when machining brittle materials should be suppressed as it deteriorate the quality of surface finish [7,8].
Temperature changes near the drilling face, The Journal of Bone and Joint Surgery. 78 (1996), p.357-62
[2] G Augustin, S Davila, K Mihoci, T Udiljak, DS Vedrina, A Antabak, Thermal osteonecrosis and bone drilling parameters revisited, Arch Orthop Trauma Surg. 128 (2008), p.71–77 [3] SC Isler, E Cansiz, CTanyel, M Soluk, F Selvi, Z Cebi, The effect of irrigation temperature on bone healing, International Journal of Medical Sciences. 8 (2011), p.704-708 [4] SRH Davidson, DF James, Drilling in bone: modeling heat generation and temperature distribution, Journal of Biomechanical Engineering. 125 (2003), p.305-314 [5] D Kurniawan, N Jiawkok, MY Noordin, Machining conditions effect to machining temperature and forces in orthogonal machining of bone, Advanced Materials Research. 658 (2013), p.223-226 [6] S Sharif, EA Rahim, H Sasahara, Machinability of titanium alloys in drilling.
Journal of Manufacturing Processes. 13 (2011), p.50-59 [8] DP Yu, YS Wong, GS Hong, A novel method for determination of the subsurface damage depth in diamond turning of brittle materials, International Journal of Machine Tools and Manufacture. 51 (2011), p. 918-927 [9] H Ohashi, M Therin, A Meunier, P Christel, The effect of drilling parameters on bone- Part I General healing response, Journal of Materials Science: Materials in Medicine. 5 (1994), p.225- 231 [10] MY Noordin, D Kurniawan, S Sharif, Feasibility of mild hard turning of stainless steel using coated carbide tool, International Journal of Advanced Manufacturing Technology. 60 (2012), p.853-863 [11] D Kurniawan, NM Yusof, S Sharif, Hard machining of stainless steel using wiper coated carbide: tool life and surface integrity, Materials and Manufacturing Processes. 25 (2010), p.370-377 [12] C Yeager, A Nazari, D Arola, Machining of cortical bone: Surface texture, surface integrity and cutting forces, Mach Sci Technol. 12
Online since: October 2012
Authors: Bin Meng, Jin Hui Peng
In microwave metallurgy process, the refractory materials are exposed both to microwave energy and the reaction materials.
These complex stringent requirements restrict the candidate range of refractory materials for microwave metallurgy, so that the refractory material only with single component hardly meets the demands for microwave metallurgy process.
Therefore, the composite refractory materials, such as corundum-mullite, were explored to be applied in microwave metallurgy.
Bulletin of Materials Science, 2009, 32, (1):1-13 [2]MacKenzie, J.
Journal of Hazardous Materials, 2009, 166: 1535-1539
These complex stringent requirements restrict the candidate range of refractory materials for microwave metallurgy, so that the refractory material only with single component hardly meets the demands for microwave metallurgy process.
Therefore, the composite refractory materials, such as corundum-mullite, were explored to be applied in microwave metallurgy.
Bulletin of Materials Science, 2009, 32, (1):1-13 [2]MacKenzie, J.
Journal of Hazardous Materials, 2009, 166: 1535-1539
Online since: January 2012
Authors: Jian Zhong Li, Yan Fu Cao, Ya Jun Qing
Luchao: Simulation on Triaxial Compression Creep Deformation of Reticulate Red Clay, Advanced Materials Research, Vols. 261-263, 1414-1418(2011)
[6] X.
Zhongli: The Weathering Sequence of the Red Earth over Southern China, Journal of mountain science, 18(1): 7-12(2000)(in Chinese) [7] Z.
Jiancheng: On the Southern Vermicular Red Soil and Its Forming Environment, Journal of Jiaying university(natural science), 23(3): 79-83(2005)(in Chinese) [8] G.
Zejun: Research Advance of Red Earth in South China, Journal of east China normal university(natural science), 1: 69-75(2002) (in Chinese) [9] W.
Xiqing: Study on Shear Rate Effects of Reticulate Red Clay, Advanced Materials Research, Vols. 261-263, 1410-1413(2011)
Zhongli: The Weathering Sequence of the Red Earth over Southern China, Journal of mountain science, 18(1): 7-12(2000)(in Chinese) [7] Z.
Jiancheng: On the Southern Vermicular Red Soil and Its Forming Environment, Journal of Jiaying university(natural science), 23(3): 79-83(2005)(in Chinese) [8] G.
Zejun: Research Advance of Red Earth in South China, Journal of east China normal university(natural science), 1: 69-75(2002) (in Chinese) [9] W.
Xiqing: Study on Shear Rate Effects of Reticulate Red Clay, Advanced Materials Research, Vols. 261-263, 1410-1413(2011)
Online since: December 2024
Authors: Woei Jye Lau, Norhaniza Binti Yusof, Ahmad Fauzi Ismail, Teshini A/P Hari Ram, Farhana Aziz
This makes it an interesting area for researchers interested in developing new materials and technologies.
Besides cellulose, lignocellulosic materials are also made up of hemicellulose and lignin [6].
Materials and Methods Materials and Equipment The OPEFB was obtained from Sedenak Palm Oil Mill Reception, Sedenak, Johor, Malaysia.
Other materials used were C2H5OH, H2O2, NaOH, and distilled water.
Chieng, The Effect of Fiber Bleaching Treatment on the Properties of Poly(lactic acid)/Oil Palm Empty Fruit Bunch Fiber Composites, International journal of molecular sciences 15 (2014) 14728-14742.
Besides cellulose, lignocellulosic materials are also made up of hemicellulose and lignin [6].
Materials and Methods Materials and Equipment The OPEFB was obtained from Sedenak Palm Oil Mill Reception, Sedenak, Johor, Malaysia.
Other materials used were C2H5OH, H2O2, NaOH, and distilled water.
Chieng, The Effect of Fiber Bleaching Treatment on the Properties of Poly(lactic acid)/Oil Palm Empty Fruit Bunch Fiber Composites, International journal of molecular sciences 15 (2014) 14728-14742.
Online since: September 2013
Authors: Shao Jie Liu, Feng Qing Zhao, Xiao Meng Chu, Hui Jiao Yang
Therefore, surface-initiated ARGET ATRP polymerization has become an effective method for modifying the surface of materials.
Therefore, surface-initiated ARGET ATRP polymerization has become an effective method for modifying the surface of materials.
Zhou, New Chemical Materials, 2012,40(7), pp. 21-24 [11] A.
Milena, Journal of Membrane Science, 2011, 385-386, pp. 30-39 [18] Jonsson M., D.
Nordin, European Polymer Journal, 2009, 45, pp. 2374-2382
Therefore, surface-initiated ARGET ATRP polymerization has become an effective method for modifying the surface of materials.
Zhou, New Chemical Materials, 2012,40(7), pp. 21-24 [11] A.
Milena, Journal of Membrane Science, 2011, 385-386, pp. 30-39 [18] Jonsson M., D.
Nordin, European Polymer Journal, 2009, 45, pp. 2374-2382
Online since: April 2014
Authors: Peng Pan, Hao Wen Chen, Yu Sakurai, Jun Cai Liu, Nobuo Murota, Masahiro Nakamura
Journal of sound and vibration, 1996, 193(1): 49-63
Journal of sound and vibration, 2006, 293(3): 865-872
Journal of Sound and Vibration, 2006, 294(4): 706-736
Journal of sound and vibration, 1996, 193(1): 175-184
Journal of Railway Science and Engineering, 2006, 3(2):1-5 (in Chinese)
Journal of sound and vibration, 2006, 293(3): 865-872
Journal of Sound and Vibration, 2006, 294(4): 706-736
Journal of sound and vibration, 1996, 193(1): 175-184
Journal of Railway Science and Engineering, 2006, 3(2):1-5 (in Chinese)
Online since: December 2012
Authors: Xiakeer Saitaer
Brief Analysis of Traditional Uyghur Felt
Xiakeer Saitaer 1, 2, a
1 College of Textile and Fashion, Xinjiang University, Urumqi, 830046, China
2 College of Textiles, Donghua University, Shanghai,201620, China
Corresponding e-mail: axaker2@163.com
Keywords:Traditional felt materials,The classification of traditional Uyghur felt
Abstract.
This paper discusses the raw material in traditional Uyghur felt handicraft and the classification of traditional Uyghur felt.
Raw Material Used in Handicraft of Felt Making Among all livestock fur, sheep wool has a wide range of applications and is the only raw material used in felt making.
Moreover, all ethnic groups in Xinjiang also have traditions to use felt, a proof of abundant supply of raw material and big market.
Acknowledgements This work was financially supported by the Science and Research Division of Xinjiang University of China in 2009, Subject No.: XY080243 References [1] XU Hong, Senewer (SaiNaWaEr),Mahire (MaYiLa) Xinjiang Folk/Traditional Felt Making The Eighth Edition of the Wool Textile Journal 2005 [2] Memetimin Sabir (MaimaiTiMing ShaBiEr) Felt Making (Uyghur) Xinjiang People’s Press August 2007 [3] Memetimin Sabir (MaimaiTiMing ShaBiEr) Uyghur Handicrafts (Uyghur) Kashgar Uyghur Press September 2002
This paper discusses the raw material in traditional Uyghur felt handicraft and the classification of traditional Uyghur felt.
Raw Material Used in Handicraft of Felt Making Among all livestock fur, sheep wool has a wide range of applications and is the only raw material used in felt making.
Moreover, all ethnic groups in Xinjiang also have traditions to use felt, a proof of abundant supply of raw material and big market.
Acknowledgements This work was financially supported by the Science and Research Division of Xinjiang University of China in 2009, Subject No.: XY080243 References [1] XU Hong, Senewer (SaiNaWaEr),Mahire (MaYiLa) Xinjiang Folk/Traditional Felt Making The Eighth Edition of the Wool Textile Journal 2005 [2] Memetimin Sabir (MaimaiTiMing ShaBiEr) Felt Making (Uyghur) Xinjiang People’s Press August 2007 [3] Memetimin Sabir (MaimaiTiMing ShaBiEr) Uyghur Handicrafts (Uyghur) Kashgar Uyghur Press September 2002
Online since: April 2015
Authors: Sanya Kumjing
Gonz´alez, “Analysis of factors affecting the high-speed side milling of hardened die steels”, Journal of Materials Processing Technology.Vol.162–163,200, pp. 696–701
Journal of Materials Processing Technology 102 (2000) 1-8
Journal of Materials Processing Technology 215 (2015) 159–170
Journal of Materials Processing Technology 214 (2014) 1638–1646
Journal of Materials Processing Technology 147 (2004) 321–327
Journal of Materials Processing Technology 102 (2000) 1-8
Journal of Materials Processing Technology 215 (2015) 159–170
Journal of Materials Processing Technology 214 (2014) 1638–1646
Journal of Materials Processing Technology 147 (2004) 321–327