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Online since: March 2007
Authors: G. Matula, José Manuel Torralba, Leszek Adam Dobrzański, A. Kloc
Torralba
2
1, Division of Materials Processing Technology and Computer Techniques in Materials Science,
Institute of Engineering Materials and Biomaterials, Silesian University of Technology,
Konarskiego St. 18a, 44-100 Gliwice, Poland
2, Universidad Carlos III de Madrid, Avda.
Functionally gradient materials (FGM) are materials whose properties change in their volume.
Higher high-speed steel density in pressurelessly formed materials, in comparison with the high-speed steel density in compacted and sintered materials, is caused by higher carbon concentration.
Hence the sintering temperature corresponding to the maximum density of the pressurelessly formed materials is lower in comparison with the materials made using traditional powder metallurgy methods.
Matula, Struktura i własności spiekanej stali szybkotnącej HS6-5-2 formowanej wtryskowo, Proceedings of the third scientific conference M3E'2005, Gliwice - Wisła [7] Miyamoto Z., Kaysser W.M., Rabin B.H., Kawasaki A., Ford R.G., Functionally Graded Materials, Kluwer Academic Publisher, Boston, 1999 [8] Kieback B., Neubrand A., Riedel H., Processing techniques for functionally graded materials, Materials Science and Engineering: A Volume:362, Issue: 1-2, Grudzień 5, 2003, p.81-106 [9] Lengauer W., Dreyer K., Functionally graded hardmetals, Journal of Alloys and Compounds, 338, 2002, p. 194-212 [10] Bever M.B., Duwez P.F., Mater.
Functionally gradient materials (FGM) are materials whose properties change in their volume.
Higher high-speed steel density in pressurelessly formed materials, in comparison with the high-speed steel density in compacted and sintered materials, is caused by higher carbon concentration.
Hence the sintering temperature corresponding to the maximum density of the pressurelessly formed materials is lower in comparison with the materials made using traditional powder metallurgy methods.
Matula, Struktura i własności spiekanej stali szybkotnącej HS6-5-2 formowanej wtryskowo, Proceedings of the third scientific conference M3E'2005, Gliwice - Wisła [7] Miyamoto Z., Kaysser W.M., Rabin B.H., Kawasaki A., Ford R.G., Functionally Graded Materials, Kluwer Academic Publisher, Boston, 1999 [8] Kieback B., Neubrand A., Riedel H., Processing techniques for functionally graded materials, Materials Science and Engineering: A Volume:362, Issue: 1-2, Grudzień 5, 2003, p.81-106 [9] Lengauer W., Dreyer K., Functionally graded hardmetals, Journal of Alloys and Compounds, 338, 2002, p. 194-212 [10] Bever M.B., Duwez P.F., Mater.
Online since: September 2013
Authors: En Ze Wang, Li Ge Wang, Fu Te Lv
The preparation of phosphate bonding agent and its application
in ceramic coating
Fute Lva, Lige Wangb, Enze Wangc
Key Laboratory for Advanced Building Materials of Sichuan Province State, Southwest University of Science and Technology, Mianyang 621010, China
a261507951@qq.com, bwanglige@swust.edu.cn, cwangenze@swust.edu.cn
Keywords: Phosphate bonding agent, CuO, ceramic coating
Abstract.
A kind of phosphate bonding agent was prepared with H3PO4 and Al(OH)3 as the main raw materials in this paper.
Experimental Experimental materials. 85%H3PO4(AR);Al(OH)3(AR);CuO(AR);SiC(AR) Preparation of phosphate bonding agent.
Jouranl of Materials Science, 2001, (36):5079-5085 [5] Preparation of aluminum phosphate adhesive and mechanical properties of [D].
Journal of theAmerican Ceramic Society,2003,86(11):1838—1844
A kind of phosphate bonding agent was prepared with H3PO4 and Al(OH)3 as the main raw materials in this paper.
Experimental Experimental materials. 85%H3PO4(AR);Al(OH)3(AR);CuO(AR);SiC(AR) Preparation of phosphate bonding agent.
Jouranl of Materials Science, 2001, (36):5079-5085 [5] Preparation of aluminum phosphate adhesive and mechanical properties of [D].
Journal of theAmerican Ceramic Society,2003,86(11):1838—1844
Online since: October 2009
Authors: Monika Willert-Porada, M. Knoll
REFERENCES
1Riley, F.L., Silicon �itride and Related Materials.
Materials Science and Engineering A, 2002. 335(1-2): p. 26-31. 7Yang, J.
Material Science and Engineering, 2003.
Materials Chemistry and Physics, 2002. 73: p. 123-128. 19 Jinhui, D., L.
Materials Chemistry and Physics, 2003. 80: p. 356-359. 20Toropov, N.A. and I.A.
Materials Science and Engineering A, 2002. 335(1-2): p. 26-31. 7Yang, J.
Material Science and Engineering, 2003.
Materials Chemistry and Physics, 2002. 73: p. 123-128. 19 Jinhui, D., L.
Materials Chemistry and Physics, 2003. 80: p. 356-359. 20Toropov, N.A. and I.A.
Online since: April 2021
Authors: A.V. Smirnova, Lyudmila G. Kolyada, Elena V. Tarasyuk
Development of New Composite Materials from Tetra Pak Packaging Waste
L.G.
Karaboyaci, Process design for the recycling of Tetra Pak components, European Journal of Engineering and Natural Sciences. 2 (2017) 126-129
Journal of Thermoplastic Composite Materials. 29 (2016) 1601-1610
Science progress. 101 (2018) 161-170
Derkach, Processing of combined materials containers and packages, Container and packing. 1 (2004) 25-26
Karaboyaci, Process design for the recycling of Tetra Pak components, European Journal of Engineering and Natural Sciences. 2 (2017) 126-129
Journal of Thermoplastic Composite Materials. 29 (2016) 1601-1610
Science progress. 101 (2018) 161-170
Derkach, Processing of combined materials containers and packages, Container and packing. 1 (2004) 25-26
Online since: July 2014
Authors: Chinnakurli Suryanarayana Ramesh, Harsha R. Gudi, A.C. Vijetha, Nirupama Mohan
These problems are addressed by developing materials which are harder and possessing excellent corrosion resistance in sea water.
Keshavamurthy, “Slurry erosive wear behavior of Ni–P coated Si3N4 reinforced Al6061 com-posites”, Materials and Design, Vol 32, (2011), pp1833–1843
S.Asthana, Reinforced cast metal, Part II evaluation of interface, “Material Science,(1998),35, 1959-80
RAL,”Preparation of nickel coated powder as precursor to reinforce metal matrix composite”, Journal Material Science, (2000), Vol 35, p. 4763-4768
[14] V.Ganesh, C.K.Lee, M.Gupta, “Enhancing the tensile modulus and strength of Aluminium alloy using Inter-connected reinforcement methodology”, Materials Science& Engineering A, Vol 333, p. 193-198, (2002).
Keshavamurthy, “Slurry erosive wear behavior of Ni–P coated Si3N4 reinforced Al6061 com-posites”, Materials and Design, Vol 32, (2011), pp1833–1843
S.Asthana, Reinforced cast metal, Part II evaluation of interface, “Material Science,(1998),35, 1959-80
RAL,”Preparation of nickel coated powder as precursor to reinforce metal matrix composite”, Journal Material Science, (2000), Vol 35, p. 4763-4768
[14] V.Ganesh, C.K.Lee, M.Gupta, “Enhancing the tensile modulus and strength of Aluminium alloy using Inter-connected reinforcement methodology”, Materials Science& Engineering A, Vol 333, p. 193-198, (2002).
Online since: October 2014
Authors: Abdul Hadi, Jagannathan Krishnan, Elvana Nerissa
Materials and Method
Synthesis of photocatalyst by solgel method.
Hou: submitted to Chinese Journal of Chemical Engineering (2007) [2] Arman Sikirman, Jagannathan Krishan, Faraziehan Senusi and Junaidah Jai: submitted to Advance Material Research (2014) [3] Q.
Gohar: submitted to Journal of Hazardous Material (2009) [5] J.
Kim: submitted to Journal of Hazardous Material (2009) [10] G.
Ren: submitted to Applied Surface Science (2010)
Hou: submitted to Chinese Journal of Chemical Engineering (2007) [2] Arman Sikirman, Jagannathan Krishan, Faraziehan Senusi and Junaidah Jai: submitted to Advance Material Research (2014) [3] Q.
Gohar: submitted to Journal of Hazardous Material (2009) [5] J.
Kim: submitted to Journal of Hazardous Material (2009) [10] G.
Ren: submitted to Applied Surface Science (2010)
Online since: February 2011
Authors: Xiu Hui Wang, Guo Quan Zhao, Hong Gao, Jin Long Yang, Yan Min Zhao
The Effect of Mineralizers on Synthesis of Perovskite-Phase Lanthanum Aluminate Powders
Wang Xiu-hui1,2,a, Zhao Guo-quan2,b, Zhao Yan-min2,c, Gao Hong2,d and Yang Jin-long1,e
1Department of Materials Science and Engineering, State Key Lab of New Ceramics and Fine Processing, Tsinghua University, Beijing 10084, China;
2Liaoning Key Lab for fabrication and Application of Super-fine Inorganic Powders, Jiaotong University, Dalian, Liaoning 116028, China
adl_wangxh@djtu.edu.cn,breddevils.utd@gmail.com,czhao.1@hotmail.com,dtaoci@djtu.edu.cn,ejlyang@mail.tsinghua.edu.cn1
Keywords: perovskite-phase lanthanum aluminate; solid-reaction; mineralizer; additive; synthesize.
Abstract: The solid-reaction was applied to synthesize perovskite-phase Lanthanum Aluminate powders by using AlOOH and La2(C2O4)3 as raw materials, mineralizer AlCl3 and AlF3 as the additives, graund and mixed, then calcined at 800℃ and 1200℃ for 3 h.
Introduction The perovskite-phase lanthanum aluminate crystal (LaAlO3 ) possess of low dielectric constants and dielectric loss, and it is lattice-matched to many perovskite structure materials.
Physics, 2001, 30(7) 392-397 [2] National Key Basic Research Program Network, Research of the perovskite functional crystals, http://www.973.gov.cn:80/show/stuff6-3.html [3] Mao Shaoyu, Cai Yu and Liu Yao, et al in: Application of Oxalyl Dihydrazide in The Combustion Synthesis of LaAlO3, Functional Materials, 1998, 29(1):110-111 [4] Xu Chaofen, Xu Yebin, in: Synthesis of Lanthanum Aluminate by Ethylene Diamine Tetraacetic Acid Gel Route, Journal of Huazhong University of Science and Technology (Natural Science), 2005, 33(1):78-80 [5] Huang Guohua, Zhou Dongxiang and Xu Jianmei, et al in: Synthesis of Lanthanum Aluminate by the Liquid Mixing Method, Journal of Huazhong University of Science and Technology (Natural Science).2004 32(02):52-53 [6] Wang Xiuhui, Wu Xiaolin and Zhai Yuchun et al, in: The Synthesis of Lanthanum Aluminate Powders by Alkoxide-hydrolysis, Rare Metal Materials and Engineering. 2007.8, 36(S1): 62-64 [7] Feng Duan, Shi Changxu et al, in: Introduction to Materials
and Science [M], Beijing: Chemical Industry Press, 2002
Abstract: The solid-reaction was applied to synthesize perovskite-phase Lanthanum Aluminate powders by using AlOOH and La2(C2O4)3 as raw materials, mineralizer AlCl3 and AlF3 as the additives, graund and mixed, then calcined at 800℃ and 1200℃ for 3 h.
Introduction The perovskite-phase lanthanum aluminate crystal (LaAlO3 ) possess of low dielectric constants and dielectric loss, and it is lattice-matched to many perovskite structure materials.
Physics, 2001, 30(7) 392-397 [2] National Key Basic Research Program Network, Research of the perovskite functional crystals, http://www.973.gov.cn:80/show/stuff6-3.html [3] Mao Shaoyu, Cai Yu and Liu Yao, et al in: Application of Oxalyl Dihydrazide in The Combustion Synthesis of LaAlO3, Functional Materials, 1998, 29(1):110-111 [4] Xu Chaofen, Xu Yebin, in: Synthesis of Lanthanum Aluminate by Ethylene Diamine Tetraacetic Acid Gel Route, Journal of Huazhong University of Science and Technology (Natural Science), 2005, 33(1):78-80 [5] Huang Guohua, Zhou Dongxiang and Xu Jianmei, et al in: Synthesis of Lanthanum Aluminate by the Liquid Mixing Method, Journal of Huazhong University of Science and Technology (Natural Science).2004 32(02):52-53 [6] Wang Xiuhui, Wu Xiaolin and Zhai Yuchun et al, in: The Synthesis of Lanthanum Aluminate Powders by Alkoxide-hydrolysis, Rare Metal Materials and Engineering. 2007.8, 36(S1): 62-64 [7] Feng Duan, Shi Changxu et al, in: Introduction to Materials
and Science [M], Beijing: Chemical Industry Press, 2002
Online since: December 2012
Authors: Subhash Chandra Panja, Sunil Hansda, Haradhan Soren, Simul Banerjee
The delamination is a major problem associated with the drilling of fiber reinforced composite materials.
Journal of material science.
Journal of material processing Technology.
Journal of Material Processing Technology.
Journal of Material Processing Technology.
Journal of material science.
Journal of material processing Technology.
Journal of Material Processing Technology.
Journal of Material Processing Technology.
Online since: September 2011
Authors: Quan Yi Huang, Hong Yong Yuan, Jin Jun Yuan
Emergency response and safeguard resources mainly include emergency institution, emergency human resources, emergency materials and equipment, emergency telecommunications, emergency health service, emergency shelters and emergency financial support, etc.
Lu: Journal of Xinyang Teachers College (Natural Science Edition), 2 Vol. 14 (2001) No. 3, p. 314-318
Zhang: Journal of Geospatial Information, Vol. 5 (2007) No. 1, p. 105-106
Chen: Journal of Modern Business, Vol. 20 (2008) , p. 141
Chen: Journal o f Geomatics World, (2006) No. 4, p. 53-58
Lu: Journal of Xinyang Teachers College (Natural Science Edition), 2 Vol. 14 (2001) No. 3, p. 314-318
Zhang: Journal of Geospatial Information, Vol. 5 (2007) No. 1, p. 105-106
Chen: Journal of Modern Business, Vol. 20 (2008) , p. 141
Chen: Journal o f Geomatics World, (2006) No. 4, p. 53-58
Online since: February 2011
Authors: Yin Fang Jiang, Lei Fang, Zhi Fei Li, Zhen Zhou Tang
Laser shock processing is a technique similar to shot peening that imparts compressive residual stresses in materials for improved fatigue resistance.
LSP is a process similar to traditional shot peening and designed to improve the mechanical properties and fatigue performance of materials [1].
Acknowledgements This research is financed by Natural Science Fund (51075193) References [1] William.Braisted and Robert.
Brockman: International Journal of Fatigue Vol.21 (1999), P.719–724
Yang: Chinese Journal of Lasers Vol. 33 (2006), pp. 1282-1287
LSP is a process similar to traditional shot peening and designed to improve the mechanical properties and fatigue performance of materials [1].
Acknowledgements This research is financed by Natural Science Fund (51075193) References [1] William.Braisted and Robert.
Brockman: International Journal of Fatigue Vol.21 (1999), P.719–724
Yang: Chinese Journal of Lasers Vol. 33 (2006), pp. 1282-1287