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Evaluation of Mechanical Properties of Teak Wood Saw Dust – Cashew Nut Shell Liquid Resin Composites
Online since: June 2015
Authors: S. Sekar, T.N. Valarmathi, M. Ganesan
For mixing the raw materials additive materials such as methyl ethyl ketone peroxide, cobalt naphtha nate; poly vinyl acetate and wax are used.
[2] Michael Ikpi Ofem, Muneer Umar, Friday Aje Ovat, Mechanical properties of rice husk filled cashew nut shell liquid resin composites, Journal of Material Science Research, 1 (2012) 89-97
[6] Jeong-Hun lee, JisooJeon, Sumin Kim, Green adhesives using tannin and cashew nut shell liquid for environment-friendly furniture materials, Journal of the Korean Furniture Society, 22 (2011) 219-229
Kanmani, Cashew nutshell liquid resin, International Journal of Research Review in Engineering Science and Technology, 2 (2013) 60-65
Srivastava, Evaluation of properties of propylene-pine wood plastic composite, Journal of Material Environment Science, 3 (2012) 605-612
[2] Michael Ikpi Ofem, Muneer Umar, Friday Aje Ovat, Mechanical properties of rice husk filled cashew nut shell liquid resin composites, Journal of Material Science Research, 1 (2012) 89-97
[6] Jeong-Hun lee, JisooJeon, Sumin Kim, Green adhesives using tannin and cashew nut shell liquid for environment-friendly furniture materials, Journal of the Korean Furniture Society, 22 (2011) 219-229
Kanmani, Cashew nutshell liquid resin, International Journal of Research Review in Engineering Science and Technology, 2 (2013) 60-65
Srivastava, Evaluation of properties of propylene-pine wood plastic composite, Journal of Material Environment Science, 3 (2012) 605-612
Online since: April 2014
Authors: Xin Zhong Liu, Yong Jie Huang, Ze Ran Cheng, Wei Liao
Research on Environment Materials with Progress on Regeneration of Active Carbon
XinZhong Liu 1, a, YongJie Huang 2,b, ZeRan Cheng3,c and Wei Liao4,d
1 College of Ecological Environment and Urban Construction, Fujian University of Technology, Fuzhou, China
2 College of Environment and Resources, Fuzhou University, Fuzhou, China
3 College of Ecological Environment and Urban Construction, Fujian University of Technology, Fuzhou, China
4 College of Ecological Environment and Urban Construction, Fujian University of Technology, Fuzhou, China
aliuxinzh01@163.com, b35995563@qq.com, c 327782572@qq.com, d 1196421328@qq.com
Keywords: activated carbon; adsorption; regeneration technology
Abstract.
References [1] J H Yun, D K Choi, H Moon: Chemical engineering science Vol. 55 (2000), p. 5857 [2] X Liu, R Chen, R Weng, et al. : Functional Materials Letters Vol. 5 (2012) [3] P M Alvarez, F J Beltran, V Gomez-Serrano, et al. : Water research Vol. 38 (2004), p. 2155 [4] C Moreno-Castilla, J Rivera-Utrilla, J P Joly, et al. : Carbon Vol. 33 (1995), p. 1417 [5] S Román, B Ledesma, J F González, et al. : Journal of Analytical and Applied Pyrolysis Vol. 103 (2013), p. 201 [6] M Goto, N Hayashi, S Goto: Environmental science & technology Vol. 20 (1986), p. 463 [7] P Canizares, J Lobato, J Garcia-Gomez, et al. : Journal of applied electrochemistry Vol. 34 (2004), p. 111 [8] X Liu, R Weng, Z Chen: Acta Scientiarum Naturalium Universitatis Sunyatseni Vol.48 (2009), p.2 [9] H Zhang, L Ye, H Zhong: Journal of Chemical Technology and Biotechnology Vol. 77 (2002), p.1246 [10] R Berenguer, J P Marco-Lozar, C Quijada, et al. : Carbon Vol. 48 (2010), p. 2734 [11] J F González, J M Encinar
[14] C S Tan, D C Liou: Separation Science and Technology Vol. 24 (1989), p. 111 [15] A Dehdashti, A Khavanin, A Rezaee, et al. : Turkish J.
Advanced Materials Research Vol.675 (2013), p.289 [19] J A Menéndez, A Arenillas, B Fidalgo, et al. : Fuel Processing Technology Vol. 91 (2010), p. 1 [20] K E Haque, P D Kondos, R J C MacDonal: U.
Patent CA Vol. 242 (2008), p. 4 [21] C Y Cha , C T Carlisle: Journal of the Air & Waste Management Association Vol. 51 (2001), p. 1628
References [1] J H Yun, D K Choi, H Moon: Chemical engineering science Vol. 55 (2000), p. 5857 [2] X Liu, R Chen, R Weng, et al. : Functional Materials Letters Vol. 5 (2012) [3] P M Alvarez, F J Beltran, V Gomez-Serrano, et al. : Water research Vol. 38 (2004), p. 2155 [4] C Moreno-Castilla, J Rivera-Utrilla, J P Joly, et al. : Carbon Vol. 33 (1995), p. 1417 [5] S Román, B Ledesma, J F González, et al. : Journal of Analytical and Applied Pyrolysis Vol. 103 (2013), p. 201 [6] M Goto, N Hayashi, S Goto: Environmental science & technology Vol. 20 (1986), p. 463 [7] P Canizares, J Lobato, J Garcia-Gomez, et al. : Journal of applied electrochemistry Vol. 34 (2004), p. 111 [8] X Liu, R Weng, Z Chen: Acta Scientiarum Naturalium Universitatis Sunyatseni Vol.48 (2009), p.2 [9] H Zhang, L Ye, H Zhong: Journal of Chemical Technology and Biotechnology Vol. 77 (2002), p.1246 [10] R Berenguer, J P Marco-Lozar, C Quijada, et al. : Carbon Vol. 48 (2010), p. 2734 [11] J F González, J M Encinar
[14] C S Tan, D C Liou: Separation Science and Technology Vol. 24 (1989), p. 111 [15] A Dehdashti, A Khavanin, A Rezaee, et al. : Turkish J.
Advanced Materials Research Vol.675 (2013), p.289 [19] J A Menéndez, A Arenillas, B Fidalgo, et al. : Fuel Processing Technology Vol. 91 (2010), p. 1 [20] K E Haque, P D Kondos, R J C MacDonal: U.
Patent CA Vol. 242 (2008), p. 4 [21] C Y Cha , C T Carlisle: Journal of the Air & Waste Management Association Vol. 51 (2001), p. 1628
Online since: November 2011
Authors: Martin Veidt, Meng Hou, Michael T. Heitzmann, Luigi Jules Vandi, Rowan Paton
Introduction
Adhesive interfaces between two materials are generally perceived as having well defined borders.
Materials HexPly M18/1 supplied by Hexcel was used in this study.
Schubert, "Interfaces between incompatible polymers," Annual Review of Materials Science, vol. 25, pp. 325-356, 1995
Régnier, "Study of epoxy and epoxy-cyanate networks thermal degradation to predict materials lifetime in use conditions," Journal of Applied Polymer Science, vol. 77, pp. 3142-3153, 2000
Eibl, "Observing inhomogeneity of plastic components in carbon fiber reinforced polymer materials by ATR-FTIR spectroscopy in the micrometer Scale," Journal of Composite Materials, vol. 42, pp. 1231-1246, 2008.
Materials HexPly M18/1 supplied by Hexcel was used in this study.
Schubert, "Interfaces between incompatible polymers," Annual Review of Materials Science, vol. 25, pp. 325-356, 1995
Régnier, "Study of epoxy and epoxy-cyanate networks thermal degradation to predict materials lifetime in use conditions," Journal of Applied Polymer Science, vol. 77, pp. 3142-3153, 2000
Eibl, "Observing inhomogeneity of plastic components in carbon fiber reinforced polymer materials by ATR-FTIR spectroscopy in the micrometer Scale," Journal of Composite Materials, vol. 42, pp. 1231-1246, 2008.
Online since: September 2017
Authors: Adam Skrobak, Martin Bednarik, Vaclav Janostik
For all examined materials were also observed changes in elongation.
Experimental Materials.
The basic properties of used materials are shown in Table 2.
Satapathy et al., Studies on the effect of electron beam irradiation on waste polyethylene and its blends with virgin polyethylene, Journal of Applied Polymer Science 101 (2006) 715-726
Bednarik, Cross-linked low density polyethylene mechanical properties after temperature load at 110, 180 and 220 °C, MM Science Journal 2016 (2016) 1105-1109
Experimental Materials.
The basic properties of used materials are shown in Table 2.
Satapathy et al., Studies on the effect of electron beam irradiation on waste polyethylene and its blends with virgin polyethylene, Journal of Applied Polymer Science 101 (2006) 715-726
Bednarik, Cross-linked low density polyethylene mechanical properties after temperature load at 110, 180 and 220 °C, MM Science Journal 2016 (2016) 1105-1109
Online since: July 2013
Authors: Chang Hee Lee, Seong Lee, See Jo Kim, Sang Ho Mun, Kee Ahn Lee
Pure Al powders are widely known as energetic materials.
Accordingly, in order to increase the penetration depth and destructiveness, other materials or combinations of materials have been used[3-5].
Therefore, highly reactive materials (e.g., Al, Mg, and self-propagating high temperature synthesis materials) have been considered.
It was confirmed to be possible to manufacture metal bulk materials using kinetic spray process, having higher strength than the existing severe plastic processed materials.
Johnson-Cook models parameters for three different materials.
Accordingly, in order to increase the penetration depth and destructiveness, other materials or combinations of materials have been used[3-5].
Therefore, highly reactive materials (e.g., Al, Mg, and self-propagating high temperature synthesis materials) have been considered.
It was confirmed to be possible to manufacture metal bulk materials using kinetic spray process, having higher strength than the existing severe plastic processed materials.
Johnson-Cook models parameters for three different materials.
Innovative Sustainable Materials – Structural Stability Check of Various Waste Mix Concrete Material
Online since: October 2015
Authors: Abhinandan R. Gupta, S.K. Deshmukh
Innovative Sustainable Materials –
Structural Stability Check of Various Waste Mix Concrete Material
Abhinandan R.Gupta 1, Dr.
Materials like cement, steel, bricks are highly energy intensive materials.
· Out of various such waste materials some of them are selected as percentage replacement materials for concrete
Implication By carrying out strength check for various waste mix concrete materials, the basic properties of such materials are discovered.
Science, Vol1, Issue 3, pp 259-267
Materials like cement, steel, bricks are highly energy intensive materials.
· Out of various such waste materials some of them are selected as percentage replacement materials for concrete
Implication By carrying out strength check for various waste mix concrete materials, the basic properties of such materials are discovered.
Science, Vol1, Issue 3, pp 259-267
Online since: February 2026
Authors: Ige Samuel Ayeni, Oluniyi Oyedeji Popoola, John Femi Ekundayo
The materials used were shown in Figures 1 (a, b, and c).
Series Material Science Engineering, vol. 342, no. 1, 2018, doi: 10.1088/1757-899X/342/1/012104
Materials, vol. 263, p. 121007, 2020, doi: 10.1016/j.conbuildmat.2020.121007
Mohan, “Behaviour of Fibre Reinforced Concrete Using Basalt Fibre in Beam Column Joint under Cyclic Loading,” ARPN Journal of Engineering and Applied Science, vol. 14, no. 8, pp. 1463–1470, 2019
Asim et al., “Comparative Experimental Investigation of Natural Fibers Reinforced Light Weight Concrete as Thermally Efficient Building Materials,” Journal of Building Engineering, vol. 31, no.
Series Material Science Engineering, vol. 342, no. 1, 2018, doi: 10.1088/1757-899X/342/1/012104
Materials, vol. 263, p. 121007, 2020, doi: 10.1016/j.conbuildmat.2020.121007
Mohan, “Behaviour of Fibre Reinforced Concrete Using Basalt Fibre in Beam Column Joint under Cyclic Loading,” ARPN Journal of Engineering and Applied Science, vol. 14, no. 8, pp. 1463–1470, 2019
Asim et al., “Comparative Experimental Investigation of Natural Fibers Reinforced Light Weight Concrete as Thermally Efficient Building Materials,” Journal of Building Engineering, vol. 31, no.
Online since: February 2013
Authors: Yun Cheng Xie
Nano Fe3O4/Polymerization Ferric Chloride Composite Materials in the Application of Hydroxybenzene Wastewater
Yuncheng XIE1, 2
1College of Materials and Chemical Engineering, Chongqing University of Arts and Sciences, 402160, China
2Key Laboratory of Water Environmental Restoration, Chongqing University of Arts and Sciences, 402160, China
email:dyxieyuncheng@sina.com
Keywords: Nano Fe3O4.Polymerization ferric chloride.Composite materials.Phenolic wastewater
Abstract: Fenton’s reagent method optimizes conventional wastewater oxidization treatment technologies to remove biodegradable organic matter that cannot be removed.
In this paper, ferric chloride hexahydrate, iron (II) chloride tetra hydrate, and ammonia act as raw materials in preparing the nano-iron oxide / polymer composite material ferric chloride.
Materials & Methods Selected materials.
Science and technology information.2008 (29):76
Journal o f Mater ials Science & Eng ineering.2009, 3 (6):353-354
In this paper, ferric chloride hexahydrate, iron (II) chloride tetra hydrate, and ammonia act as raw materials in preparing the nano-iron oxide / polymer composite material ferric chloride.
Materials & Methods Selected materials.
Science and technology information.2008 (29):76
Journal o f Mater ials Science & Eng ineering.2009, 3 (6):353-354
Online since: October 2010
Authors: Yan Jiang, Juan Cong, Xiao Juan Yan, Hai Yue Zhang
Infrared spectroscopy (IR) results showed that this membrane belong to bio-cellulose materials.
Experiments Materials Acetobacter xylinum (A. xylinum) 1.1812, Escherichia coli (E.
Conclusion BC materials were produced in the surface film by static culture of A. xylinum.
BC can provide a facile approach toward manufacturing of metallic nanocomposites, antimicrobial materials, low-temperature catalysts and other useful materials.
W, Newton E: Journal of Hospital Infection Vol. 62 (2006), p. 58-63 [25] Zhao L; Song J X: Journal of Tropical Medicine Vol. 10(7) 2007 (), p. 965-968 [26] Ma X, Wang RM, Guan FM: Industrial Microbiology Vol. 35(3) (2005), p. 23-26 "In Chinese" [27] Iguchi M, Yamanaka S, Budhiono A: Journal of Materials Science Vol. 35(2) (2000), p. 261-270 [28] Liu SX, Li CF: Bacterial cellulose (Beijing: China agricultural university press) 2007, P. 28“In Chinese” [29] Feng QL, Wu J, Chen GQ, Cui FZ, Kim TN, Kim JO: Journal of Biomedical Material Research Vol. 52(4) (2000), p. 662-668
Experiments Materials Acetobacter xylinum (A. xylinum) 1.1812, Escherichia coli (E.
Conclusion BC materials were produced in the surface film by static culture of A. xylinum.
BC can provide a facile approach toward manufacturing of metallic nanocomposites, antimicrobial materials, low-temperature catalysts and other useful materials.
W, Newton E: Journal of Hospital Infection Vol. 62 (2006), p. 58-63 [25] Zhao L; Song J X: Journal of Tropical Medicine Vol. 10(7) 2007 (), p. 965-968 [26] Ma X, Wang RM, Guan FM: Industrial Microbiology Vol. 35(3) (2005), p. 23-26 "In Chinese" [27] Iguchi M, Yamanaka S, Budhiono A: Journal of Materials Science Vol. 35(2) (2000), p. 261-270 [28] Liu SX, Li CF: Bacterial cellulose (Beijing: China agricultural university press) 2007, P. 28“In Chinese” [29] Feng QL, Wu J, Chen GQ, Cui FZ, Kim TN, Kim JO: Journal of Biomedical Material Research Vol. 52(4) (2000), p. 662-668
Online since: March 2016
Authors: Abdullah Abdul Samat, Abdul Mutalib Md Jani, Nafisah Osman, Ismariza Ismail
This paper reports on the reactivity study of composite cathode materials that comprises different weight percent of La0.6Sr0.4Co0.2Fe0.8O3-α (LSCF) and BaCe0.54Zr0.36Y0.1O3-α (BCZY).
One of the materials issues governing the development of IT-SOFC that has been highlighted is the compatibility between cathode and electrolyte materials.
At calcination temperature of 1000 oC, we suggest that there were no observable chemical reactions among these two materials.
We also thank Science officer of Center for Research and Instrumentation Management (CRIM) UKM, Mr.
Zhou, in: Department of Chemical and Materials Engineering (University of Alberta, Master Abstract International, 2012).
One of the materials issues governing the development of IT-SOFC that has been highlighted is the compatibility between cathode and electrolyte materials.
At calcination temperature of 1000 oC, we suggest that there were no observable chemical reactions among these two materials.
We also thank Science officer of Center for Research and Instrumentation Management (CRIM) UKM, Mr.
Zhou, in: Department of Chemical and Materials Engineering (University of Alberta, Master Abstract International, 2012).