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Online since: August 2013
Authors: Cheng Qian, Xing Yong Liu, Ting Ting Tang, Ya Jing Lan, Shuang Luo, Shi Xiong Hao
[2] Liquan Li and Xiaowei Liang: Journal of Flame Retardant Materials and Technology.
[3] Brown N: Journal of Crystal Growth.
James: Journal of Crystal Growth.
Veller, etc: Chemical Engineering Science.
[7] Brown N: Journal of Crystal Growth.
[3] Brown N: Journal of Crystal Growth.
James: Journal of Crystal Growth.
Veller, etc: Chemical Engineering Science.
[7] Brown N: Journal of Crystal Growth.
Online since: March 2017
Authors: S. Nallusamy, M.A. Adil Ahamed
Dighe S.B and Kakirde A, (2014), “Lean manufacturing implementation using value stream mapping: A case study of pumps manufacturing company”, International Journal of Science and Research, Vol. 3(6), pp. 2492-2498
[2].
Venkataraman K, Ramnath, Kumar and Elanchezhian, (2014), “Application of value stream mapping for reduction of cycle time in a machining process”, Procedia Material Science, Vol. 6, pp. 1187-1196 [5].
International Journal of Engineering Science and Innovative Technology, Vol. 4(3), pp. 156-163 [20].
Nallusamy S and Saravanan, (2016), “A Study on lean tools execution in a small scale manufacturing industry for productivity improvement”, Indian Journal of Science and Technology, Vol. 9(35), pp. 1-7 [21].
Paula D, Bholeb G.P and Chaudharic J.R, (2014), “A review on green manufacturing: it’s important, methodology and its application”, Procedia Materials Science, Vol. 6, pp. 1644-1649 [23].
Venkataraman K, Ramnath, Kumar and Elanchezhian, (2014), “Application of value stream mapping for reduction of cycle time in a machining process”, Procedia Material Science, Vol. 6, pp. 1187-1196 [5].
International Journal of Engineering Science and Innovative Technology, Vol. 4(3), pp. 156-163 [20].
Nallusamy S and Saravanan, (2016), “A Study on lean tools execution in a small scale manufacturing industry for productivity improvement”, Indian Journal of Science and Technology, Vol. 9(35), pp. 1-7 [21].
Paula D, Bholeb G.P and Chaudharic J.R, (2014), “A review on green manufacturing: it’s important, methodology and its application”, Procedia Materials Science, Vol. 6, pp. 1644-1649 [23].
Online since: July 2011
Authors: Dong Xu Li, Miao Miao Chen, Yun Wei Yu, Chun Hua Feng
Study on flue gas desulphurization gypsum plaster
Miaomiao Chen1,a, Yunwei Yu2,b , Chunhua Feng1,c and Dongxu Li1,d
1State Key Laboratory of Materials-Oriented Chemical Engineering, College of Material Science and Engineering, Nanjing University of Technology, Nanjing, 210009, China
2 Suzhou much new material limited company, Suzhou, 212151, China
achenmm88@sohu.com,bszmuchyyw@yahoo.cn,cfengchunhua@sohu.com,ddongxuli@njut.edu.cn
Correspondent author: Dongxu LI (1956–), male, Ph.D., professor.
Due to the very low price and large availability of FGD gypsum, the material has a good potential for applications in building materials, especially as raw materials in gypsum plaster [1-3].
[3] Zhao Hai-jun, Yan Yun, Hu Zhi-hua, He Liu-hong, Study on gypsum plastering, Journal of Materials Science & Engineering. 25(2007)229-233
[7] Dalmay P, Smith A, Chotard T, et al, Properties of cellulosic fibre reinforced plaster: influence of hemp or flax fibres on the properties of set gypsum, Journal of materials science.45(2010)793-803
[8] Bai Yang, Dongxu Li, Effect of activity admixture on FGD plastering gypsum, Journal of Materials Science & Engineering. 27(2009) 447-450
Due to the very low price and large availability of FGD gypsum, the material has a good potential for applications in building materials, especially as raw materials in gypsum plaster [1-3].
[3] Zhao Hai-jun, Yan Yun, Hu Zhi-hua, He Liu-hong, Study on gypsum plastering, Journal of Materials Science & Engineering. 25(2007)229-233
[7] Dalmay P, Smith A, Chotard T, et al, Properties of cellulosic fibre reinforced plaster: influence of hemp or flax fibres on the properties of set gypsum, Journal of materials science.45(2010)793-803
[8] Bai Yang, Dongxu Li, Effect of activity admixture on FGD plastering gypsum, Journal of Materials Science & Engineering. 27(2009) 447-450
Online since: July 2012
Authors: Zheng Kui Guo, Heng Zhi Chen, Jing Liu
It is appropriate approach to promote carbonation rate through adding materials with a low melting point to the sorbent.
Journal of the Chemical Society, B, 1970, 158-163 [8] Xu J, Froment GF.
Mu, Materials Letters, 2010, 64, 1404–1406 [23] Olivares-Marín, M., T.C.
Eriksen, Separation Science and Technology, 2006, 41, 283–296, [25] Ida, J.I., R.T.
Gomes, International Journal of Hydrogen Energy, 2009, 34, 343–355
Journal of the Chemical Society, B, 1970, 158-163 [8] Xu J, Froment GF.
Mu, Materials Letters, 2010, 64, 1404–1406 [23] Olivares-Marín, M., T.C.
Eriksen, Separation Science and Technology, 2006, 41, 283–296, [25] Ida, J.I., R.T.
Gomes, International Journal of Hydrogen Energy, 2009, 34, 343–355
Online since: December 2014
Authors: Li Qun Han, Jian Zhao Zhou, Xin Min Shen
The material removal volume in the deterministic surfacing can be obtained by subtraction between original data and target data, as shown in Fig. 2(d).
(a) 3D shape of operation function (b) Original data with its expansion (c) Target data with its expansion (d) Material removal volume Fig. 2 Schematic diagram of modeling of terrain data Evaluation of residual error Supposing the expanded original data and expanded target data is O (x, y) and T (x, y), respectively, the ideal material removal volume IMRR (x, y) can be expressed by Eq. 2
(3) Therefore, the actual material removal volume AMRR (x, y) is the convolution of operation function and the optimized distribution of dwelling time, as shown in Eq. 4
Express Vol. 21 (2013), p. 26123-26135 [6] XM Shen, M Nagano, WQ Peng, YF Dai, and K Yamamura: Key Engineering Materials Vol. 523-524 (2012), p. 276-280 [7] XM Shen, YF Dai, WQ Peng, M Nagano, and K Yamamura: Key Engineering Materials Vol. 516 (2012), p. 504-509 [8] M Christen, J Kowalski, P Bartelt: Cold Regions Science and Technology Vol. 63 (2010), p. 1-14 [9] ZR Detweiler, JB Ferris: Journal of Terramechanics Vol. 47 (2010), p. 209-217 [10] J Jin, L Tang: Journal of Field Robotics Vol. 28 (2011), p. 424–440 [11] W Zhang, DR Montgomery: Water resources research Vol. 30 (1994), p. 1019-1028 [12] DM Wolock, CV Price: Water Resources Research Vol. 30 (1994), p. 3041-3052 [13] C Hladik, M Alber: Remote Sensing of Environment Vol. 121 (2012), p. 224-235 [14] F Pan, J Nichols: Hydrological Processes Vol. 27 (2012), p. 3596-3606 [15] JP Wilson: Geomorphology Vol. 137 (2012), p. 107-121 [16] D Lamsal, T Sawagaki, T Watanabe: Journal of Mountain Science Vol. 8 (2011),
p. 390-402 [17] C Hirt: Journal of Geodesy Vol. 84 (2012), p. 179-190 [18] S Roux, F Brun, D Wallach: European Journal of Agronomy Vol. 52 (2014), p. 191-197 [19] OP Ferreira, BF Svaiter: Journal of Complexity Vol. 28 (2012), p. 346-363
(a) 3D shape of operation function (b) Original data with its expansion (c) Target data with its expansion (d) Material removal volume Fig. 2 Schematic diagram of modeling of terrain data Evaluation of residual error Supposing the expanded original data and expanded target data is O (x, y) and T (x, y), respectively, the ideal material removal volume IMRR (x, y) can be expressed by Eq. 2
(3) Therefore, the actual material removal volume AMRR (x, y) is the convolution of operation function and the optimized distribution of dwelling time, as shown in Eq. 4
Express Vol. 21 (2013), p. 26123-26135 [6] XM Shen, M Nagano, WQ Peng, YF Dai, and K Yamamura: Key Engineering Materials Vol. 523-524 (2012), p. 276-280 [7] XM Shen, YF Dai, WQ Peng, M Nagano, and K Yamamura: Key Engineering Materials Vol. 516 (2012), p. 504-509 [8] M Christen, J Kowalski, P Bartelt: Cold Regions Science and Technology Vol. 63 (2010), p. 1-14 [9] ZR Detweiler, JB Ferris: Journal of Terramechanics Vol. 47 (2010), p. 209-217 [10] J Jin, L Tang: Journal of Field Robotics Vol. 28 (2011), p. 424–440 [11] W Zhang, DR Montgomery: Water resources research Vol. 30 (1994), p. 1019-1028 [12] DM Wolock, CV Price: Water Resources Research Vol. 30 (1994), p. 3041-3052 [13] C Hladik, M Alber: Remote Sensing of Environment Vol. 121 (2012), p. 224-235 [14] F Pan, J Nichols: Hydrological Processes Vol. 27 (2012), p. 3596-3606 [15] JP Wilson: Geomorphology Vol. 137 (2012), p. 107-121 [16] D Lamsal, T Sawagaki, T Watanabe: Journal of Mountain Science Vol. 8 (2011),
p. 390-402 [17] C Hirt: Journal of Geodesy Vol. 84 (2012), p. 179-190 [18] S Roux, F Brun, D Wallach: European Journal of Agronomy Vol. 52 (2014), p. 191-197 [19] OP Ferreira, BF Svaiter: Journal of Complexity Vol. 28 (2012), p. 346-363
Online since: August 2013
Authors: Hai Quan Su, Yan Qiu Lei
The morphology of the hydrochars changed with reaction time increased, the surface of the materials contained a large number of functional groups, showed higher adsorption capacity for Cr(VI) than activated carbon and the removal rates of Cr(VI) were 67% and 29% respectively(pH=1, 20℃).
Physical properties of hydrochar materials Reaction time(h) Yield[%]a pH N(%) C(%) H(%) 0 / / 0.14 44.24 5.79 3 0.53 4.00 0.2 47.90 6.07 6 0.3 3.73 0.74 48.92 5.84 8 0.3 3.66 0.86 51.94 5.76 10 0.32 3.72 0.88 52.10 5.35 14 0.39 3.80 0.91 54.11 5.44 18 0.41 3.68 0.68 52.40 5.83 22 0.45 3.68 0.56 55.30 6.07 26 0.44 3.64 1.10 56.71 5.50 28 0.37 3.66 1.11 56.50 5.62 32 0.38 3.64 0.89 56.62 5.74 38 0.38 3.6 0.93 56.43 5.70 40 0.38 3.67 1.13 56.97 5.56 44 0.38 3.65 0.94 56.96 5.89 a Yield expressed as (g product/100 g raw material).
Acknowledgements This work was financially supported by National Natural Science Foundation of China (No.21166014) References [1] S.
Wan, H.Amirhossein et al., A review on surface modification of activated carbon for carbon dioxide adsorption, Journal of Analytical and Applied Pyrolysis,89, 143–151.(2010) [3] M.
Prakash, Removal of Cr(VI) from aqueous solutions using agricultural waste ‘maize bran’, Journal of Hazardous Materials,152 ,356–365.(2008)
Physical properties of hydrochar materials Reaction time(h) Yield[%]a pH N(%) C(%) H(%) 0 / / 0.14 44.24 5.79 3 0.53 4.00 0.2 47.90 6.07 6 0.3 3.73 0.74 48.92 5.84 8 0.3 3.66 0.86 51.94 5.76 10 0.32 3.72 0.88 52.10 5.35 14 0.39 3.80 0.91 54.11 5.44 18 0.41 3.68 0.68 52.40 5.83 22 0.45 3.68 0.56 55.30 6.07 26 0.44 3.64 1.10 56.71 5.50 28 0.37 3.66 1.11 56.50 5.62 32 0.38 3.64 0.89 56.62 5.74 38 0.38 3.6 0.93 56.43 5.70 40 0.38 3.67 1.13 56.97 5.56 44 0.38 3.65 0.94 56.96 5.89 a Yield expressed as (g product/100 g raw material).
Acknowledgements This work was financially supported by National Natural Science Foundation of China (No.21166014) References [1] S.
Wan, H.Amirhossein et al., A review on surface modification of activated carbon for carbon dioxide adsorption, Journal of Analytical and Applied Pyrolysis,89, 143–151.(2010) [3] M.
Prakash, Removal of Cr(VI) from aqueous solutions using agricultural waste ‘maize bran’, Journal of Hazardous Materials,152 ,356–365.(2008)
Online since: September 2014
Authors: Tsutao Katayama, Kazuto Tanaka, Shunsuke Maehata, Masahiro Shinohara
However polyamide 6 is highly hygroscopic and the mechanical properties of materials are reported to be degraded by water absorption.
However polyamide 6 is highly hygroscopic and the mechanical properties of materials are reported to be degraded by water absorption[2].
Experimental procedure Materials and molding method.
Beckwith: Thermoplastic composites resins matrices, Sampe Journal, Vol. 44, No.1 (2008), p. 70-71
Enoki: Effect of Water Absorption on the Mechanical Properties of Carbon Fiber/Polyamide composites, Journal of Solid Mechanics and Materials Engineering, Vol. 7, No.5 (2013), p. 520-529
However polyamide 6 is highly hygroscopic and the mechanical properties of materials are reported to be degraded by water absorption[2].
Experimental procedure Materials and molding method.
Beckwith: Thermoplastic composites resins matrices, Sampe Journal, Vol. 44, No.1 (2008), p. 70-71
Enoki: Effect of Water Absorption on the Mechanical Properties of Carbon Fiber/Polyamide composites, Journal of Solid Mechanics and Materials Engineering, Vol. 7, No.5 (2013), p. 520-529
Online since: September 2013
Authors: Mi Yan, Kun Ming Qian, Song Ji, Jie Hao, Yan Song Zhang, Ming Li Li, Jing Hui Huang, Ang Ding
Hadjipanayis: Journal of Magnetism and Magnetic Materials Vol. 238 (2002), p. 226
[5] T.
Machida: Journal of Magnetism and Magnetic Materials Vol. 271 (2004), p. 369 [6] M.
Schultz: Journal of Magnetism and Magnetic Materials Vol. 242-245 (2002), p. 1277 [15] G.L.
Wang: Journal of Magnetism and Magnetic Materials Vol 308 (2007), p. 20 [19] H.
Wen: Journal of Magnetism and Magnetic Materials Vol. 301 (2006), p. 1
Machida: Journal of Magnetism and Magnetic Materials Vol. 271 (2004), p. 369 [6] M.
Schultz: Journal of Magnetism and Magnetic Materials Vol. 242-245 (2002), p. 1277 [15] G.L.
Wang: Journal of Magnetism and Magnetic Materials Vol 308 (2007), p. 20 [19] H.
Wen: Journal of Magnetism and Magnetic Materials Vol. 301 (2006), p. 1
Online since: June 2015
Authors: Anna Zelenaya, V.I. Lutsyk, V.P. Vorob'eva
Zelenaya1
1Institute of Physical Materials Science SB RAS, 6, Sakhyanova st., Ulan-Ude, 670047 Russia
2Buryat State University, 24a, Smolina st., Ulan-Ude, 670000, Russia
vluts@ipms.bscnet.ru
Keywords: 3D simulation, phase diagrams, ternary oxide systems, materials CAD, microstructure, crystallization stages, micro-constituent
Abstract.
Introduction As it was rightly noted, “phase diagrams are guide for constructing of new oxide materials” [1].
Space 3-dimension (3D) computer model of phase diagram is a main tool of materials science.
Lutsyk, 3D Model of T-x-y Diagram as a Tool of Materials Science, Proceedings (2012) 131-133 [Intern.
Zelenaya, Crystallization Paths in SiO2-Al2O3-CaO System as a Genotype of Silicate Materials, Journal of Silicate Based and Composite Materials, 2 (2013) 34-38.
Introduction As it was rightly noted, “phase diagrams are guide for constructing of new oxide materials” [1].
Space 3-dimension (3D) computer model of phase diagram is a main tool of materials science.
Lutsyk, 3D Model of T-x-y Diagram as a Tool of Materials Science, Proceedings (2012) 131-133 [Intern.
Zelenaya, Crystallization Paths in SiO2-Al2O3-CaO System as a Genotype of Silicate Materials, Journal of Silicate Based and Composite Materials, 2 (2013) 34-38.
Online since: September 2007
Authors: Ming Zhi Wang, Yu Cheng Zhao, Jin Feng Sun, Xiao Pu Li, Zhan Wen He
Metals and Materials Society, Warren dale, PA, (1990), p. 21
Jiang, et al.: Materials Science and Engineering A242 (1998), pp. 268-277 [3] K.
Lu, et al: Journal of Materials Processing Technology Vol.67 (1997), pp. 100-104 [7] X.K.
Zhu, et al: Journal of Powder Metallurgy Technology Vol.4 (1999), pp. 291-296 [8] Baek-Hee Lee, et al: Journal of Materials Letters Vol.57 (2003), pp. 1103-1107 [9] I.F.
Zhang: Journal of Materials Processing Technology Vol. 67(1997), pp. 100-104
Jiang, et al.: Materials Science and Engineering A242 (1998), pp. 268-277 [3] K.
Lu, et al: Journal of Materials Processing Technology Vol.67 (1997), pp. 100-104 [7] X.K.
Zhu, et al: Journal of Powder Metallurgy Technology Vol.4 (1999), pp. 291-296 [8] Baek-Hee Lee, et al: Journal of Materials Letters Vol.57 (2003), pp. 1103-1107 [9] I.F.
Zhang: Journal of Materials Processing Technology Vol. 67(1997), pp. 100-104