| MATERIALS AND SUSTAINABLE DEVELOPMENT:GREEN MANUFACTURING AND PROCESSING OF MATERIALS |
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| Research Progress of Layered Ceramics and Layered Refractories |
| CHEN Yongqiang1, LI Hongxia1,2, LIU Guoqi2
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1 School of Materials Science and Engineering, Zhengzhou University, Zhengzhou 450001
2 Sinosteel Luoyang Institute of Refractories Research Co., Ltd., Luoyang 471039 |
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Abstract The development of modern industrial technology has put forward to higher requirementson steel strength, toughness and processing perfor-mance for steel materials. In particular, iron and steel products gradually realize functionalization as excellent structural materials. Refractories are important supporting materials for high-temperature metallurgical industry, especially for the efficiency and quality of high quality steel smelting. The basic properties of refractories, such as thermal conductivity, corrosion resistance, thermal shock resistance and erosion wear resistance, are interacted with each other. The traditional preparation process of refractories can't realize the best performance of each property for refractory products. The low thermal conductivity refractories can prevent decreasing rapidly of the molten steel temperature, thus, reducing heat loss, so as to reduce energy consumption. However, the thermal stress in the high-temperature zone and the low-temperature zone is quite diffe-rent, and the shear stress between the two zones can easily lead to the cracking and damage of the refractory. The high thermal conductivity refractories can alleviate the damage of temperature difference stress to refractory products. The temperature reduction of thermal surface of refractory materials can also form slag-skin attachments to protect refractory products. Meanwhile, the chemical erosion rate of alkali metals will be significantly reduced. Especially for traditional carbon-containing refractories, although the presence of carbon components improves the thermal shock resistance of the refractories, the oxidation of carbon in high-temperature smelting leads to the formation of porous structure in the refractories reducing the strength of the material. Then, the refractories are eroded and permeated by molten slag effecting the content of carbon in steel.
The researchers mainly optimized the performance of refractories by improving the composition and structure of refractories and adding or in situ generating ceramic protection phase. However, the optimization effect is still single, which can't achieve good unity of structure and function.Therefore, it is necessary to develop new type refractories with well-matched of structure and function, such as thermal shock resistance, anti-erosion and non-pollution. As a kind of bionic design, the fine structure of laminated composites ensures its excellent comprehensive perfor-mance.Although there are many methods to prepare laminated composites, there are some technical limitations. The technology of powder compaction and sequential casting cannot guarantee the uniformity of interface or interface layer, and the design of interlayer interface is limited. Centrifugal deposition and electrophoretic deposition are highly dependent on the characteristics of raw materials, which is not conducive to the structural design of refractories. Although 3D printing has been widely concerned, it has high requirements for equipment, especially for rapid prototyping of raw materials, and it has a lot shortcomings for ceramic materials. By contrast, the tape casting has flexible operation, good adaptable for raw material and convenient post processing for green tapes. Therefore, the researches on layered ceramics and refractories are often based on this.
This paper reviews the preparation technology of layered ceramic composites and the influence of different preparation methods and layered structures on their fracture strength and fracture toughness. The application of layered structure in the study of refractories and its influence on the thermal shock resistance and corrosion resistance of refractories are introduced.The key problems and the future development direction of layered refractories are proposed.
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Published: 23 July 2019
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| Fund:This work was financially supported by the National Natural Science Foundation of China (51772277,51372231),National Key R & D Program of China (2017YFB0304000). |
About author:: Yongqiang Chen received his B.S. degree and Master degree in School of Materials Science and Engineering, Zhengzhou University in 2014 and 2016 respectively. He is currently pursuing his Ph.D. at the same university. He is carrying out his research subject in State Key laboratory of Advanced Refractories, Sinosteel Luoyang Institute of Refractories Research under the guidance of professor Hongxia Li. His research has focused on integration of structure and function of oxides refractories.
Guoqi Liu, professor of engineering, master supervisors. In 1997, he graduated from Hebei Polytechnic University with a bachelor's degree in inorganic nonme-tal. He gained his master degree from Sinosteel Luoyang Institute of Refractories Research in June, 2000. He finished Ph.D. program and gained materials science Ph.D. degree from University of Science & Technology Beijing in May, 2006. He mainly engaged in gradient function refractories and containing-carbon refractory for basic and applied research. He has published more than 50 articles in domestic and foreign scientific journals, among which more than 20 have been included in EI or SCI. He has applied for 25 patents and obtained 20 authorized patents.
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|
| 1 |
Karambelas G, Santhanam S, Wing Z N. <i>Ceramics International</i>, 2013,39(2),1315.<br />
|
| 2 |
Wegst U G, Bai H, Saiz E, et al. <i>Nature Materials</i>, 2015, 14,23.<br />
|
| 3 |
Meyers M A, Chen P Y. <i>Science</i>, 2013 ,339(6121), 773.<br />
|
| 4 |
Bouville F, Maire E, Meille S,et al. <i>Nature Materials</i>, 2014 ,13(5),508.<br />
|
| 5 |
Liu Z, Liu M, NieL, et al.<i>International Journal of Hydrogen Energy</i>, 2013, 38(2), 1082.<br />
|
| 6 |
Largiller G, Bouvard D, Carry C P, et al.<i>Mechanics of Materials</i>, 2012 ,53, 123.<br />
|
| 7 |
Schaff ner S, Freitag L, Hubálková J, et al. <i>Journal of the European Ceramic Society</i>, 2016,36(8), 2109.<br />
|
| 8 |
Chang J C, Velamakanni B V, Lange F F, et al.<i>Journal of the American Ceramic Society</i>, 1991 ,74(9),2201.<br />
|
| 9 |
Chumanov I V, Anikeev A N, Chumanov V I.<i>Procedia Engineering</i>, 2015 ,129, 816.<br />
|
| 10 |
Ferrari B,Sánchez-Herencia A J,Moreno R. <i>Materials Letters</i>, 1998, 35(5-6),370.<br />
|
| 11 |
Scheithauer U, Bergner A, Schwarzer E, et al.<i>Journal of Materials Research</i>, 2014 ,29(17),1931.<br />
|
| 12 |
Moya J S, Sánchez-Herencia A J, Requena J, et al.<i>Materials Letters</i>, 1992 ,14(5-6), 333.<br />
|
| 13 |
Hadraba H, Drdlik D, Chlup Z, et al. <i>Journal of the European Ceramic Society</i>, 2013, 33(12), 2305.<br />
|
| 14 |
Moon R J, Bowman K P, Trumble K P, et al.<i>Acta Materialia</i>, 2001 ,49(6), 995.<br />
|
| 15 |
Yeo J G, Jung Y G, Choi S C.<i>Materials Letters</i>, 1998 ,37, 304.<br />
|
| 16 |
Zhang G J, Yue X M, Watanabe T. <i>Journal of the European Ceramic Society</i>, 1999 ,19(12), 2111.<br />
|
| 17 |
Roosen A.<i>Advances in Science and Technology,</i> 2006,45, 397.<br />
|
| 18 |
Balakrishnan J A, Krishnan B, Panicker R P N, et al.<i>Advances in Applied Ceramics</i>, 2013 ,106(3), 128.<br />
|
| 19 |
Bulatova R, Jabbari M, Kaiser A, et al. <i>Journal of the European Ceramic Society</i>, 2014, 34(16), 4285.<br />
|
| 20 |
Gurauskis J, Sánchez-Herencia A J.<i>Journal of the European Ceramic Society</i>, 2007, 27(2-3), 1389.<br />
|
| 21 |
Manu K, Sebastian M T. <i>Ceramics International</i>, 2016, 42(1),1210.<br />
|
| 22 |
Piwonski M A, Roosen A. <i>Journal of the European Ceramic Society</i>, 1999, 19(2), 263.<br />
|
| 23 |
Gurauskis J, Sanchez-Herencia A J, Baud N C.<i>Key Engineering Mate-rials</i>, 2007, 333, 219.<br />
|
| 24 |
G tschel I, Gutbrod B, Travitzky N, et al.<i>Advances in Applied Ceramics</i>, 2013,112(6), 358.<br />
|
| 25 |
Jurkow D, Roguszczak H, Golonka L.<i>Journal of the European Ceramic Society</i>, 2009, 29(4),703.<br />
|
| 26 |
Medri V, Pinasco P, Sanson A, et al.<i>International Journal of Applied Ceramic Technology</i>, 2012, 9(2), 349.<br />
|
| 27 |
Bermejo R, Torres Y, Sanchezherencia A, et al. Residual stresses. <i>Acta Materialia</i>, 2006 ,54(18), 4745.<br />
|
| 28 |
Kiefer T, Moon H, Lange F F.<i>Journal of the American Ceramic Society</i>, 2005, 88(10), 2855.<br />
|
| 29 |
Lugovy M, Orlovskaya N, Slyunyayev V, et al.<i>Composites Science & Technology</i>, 2002, 62(6), 819.<br />
|
| 30 |
Quinn G D, Melandri C, de Portu G, et al. <i>Journal of the American Ceramic Society</i>, 2013, 96(7), 2283.<br />
|
| 31 |
Salahi E, Esfahani H, Mobasherpour I, et al.<i>Ceramics International</i>, 2014, 40(2), 2717.<br />
|
| 32 |
Chang Y, Bermejo R, Messing G L, et al.<i>Journal of the American Cera-mic Society</i>, 2014, 97(11),3643.<br />
|
| 33 |
Lugovy M, Slyunyayev V, Subbotin V, et al.<i>Composites Science and Technology,</i> 2004,64(13-14), 1947.<br />
|
| 34 |
Parente P, Ortega Y, Savoini B, et al.<i>Journal of the European Ceramic Society</i>, 2012 ,32(16), 3989.<br />
|
| 35 |
Zhou P, Hu P, Zhang X, et al. <i>International Journal of Refractory Metals and Hard Materials</i>, 2015, 52,12.<br />
|
| 36 |
Wang C A, Yong H, Zan Q, et al.<i>Journal of the American Ceramic Society</i>, 2002, 85(10), 2457.<br />
|
| 37 |
Bermejo R, Danzer R.<i>Engineering Fracture Mechanics</i>, 2010, 77(11), 2126.<br />
|
| 38 |
Chang Y, Bermejo R, eveek O, et al. <i>Journal of the European Ceramic Society</i>, 2015, 35(2),631.<br />
|
| 39 |
Grigoriev O N,Karoteev A V, Maiboroda E N, et al.<i>Composites Part B: Engineering</i>, 2006, 37(6), 530.<br />
|
| 40 |
Hbaieb K, Mcmeeking R M, Lange F F.<i>International Journal of Solids and Structures</i>, 2007, 44(10), 3328.<br />
|
| 41 |
Kotoul M, Sevecek O, Vyslouzil T.<i>Theoretical and Applied Fracture Mechanics</i>, 2012, 61,40.<br />
|
| 42 |
Lugovy M,Slyunyayev V, Orlovskaya N, et al.<i>Acta Materialia</i>, 2005 ,53(2), 289.<br />
|
| 43 |
Robert M, Keith B, Kevin T, et al.<i>Journal of the American Ceramic Society</i>, 2010, 83(2), 445.<br />
|
| 44 |
Cui K, Li Y.<i>International Journal of Refractory Metals and Hard Mate-rials</i>, 2016, 54, 148.<br />
|
| 45 |
Vandeperre L J, Kristofferson A, Carlstrm E, et al.<i>Journal of the American Ceramic Society</i>, 2001, 84(1), 104.<br />
|
| 46 |
Wei C, Ye C.<i>International Journal of Refractory Metals and Hard Materials</i>, 2015, 51, 233.<br />
|
| 47 |
Shevchenko A V, Dudnik E V, Ruban A K, et al.<i>Powder Metallurgy & Metal Ceramics</i>, 2003, 42(3),145.<br />
|
| 48 |
Udupa G, Rao S S,Gangadharan K V.<i>Procedia Materials Science</i>, 2014, 5, 1291.<br />
|
| 49 |
Wang Q, Li Y, Sang S, et al.<i>Journal of Alloys & Compounds</i>, 2015, 645(5), 388.<br />
|
| 50 |
Chen J, Li N, Yan W.<i>Journal of the European Ceramic Society</i>, 2016 ,36(12),1505.<br />
|
| 51 |
Scheithauer U, Slawik T, Haderk K, et al. In:Proceedings of the Unified International Technical Conference on Refractories (UNITECR 2013). Victoria,BC, 2014, pp.267.<br />
|
| 52 |
Jakobsen D, Rauch H, Dudczig S, et al.<i>Journal of Materials Processing Technology</i>, 2016, 229, 623.<br />
|
| 53 |
Gtschel I, Hayashi Y, Kakimoto K I, et al. <i>International Journal of Applied Ceramic Technology</i>, 2012, 9(2), 329.<br />
|
| 54 |
Jakobsen D, Gtschel I, Roosen A. <i>Refractories Worldforum</i>, 2016,8(2),86.<br />
|
| 55 |
Jakobsen D, Hammerbacher R, Dudczig S, et al. <i>Journal of Ceramic Science & Technology</i>, 2014, 5(2), 137.<br />
|
| 56 |
Jakobsen D, Zhang W, Doynov N, et al. <i>Ceramics International</i>, 2016, 42(12), 13562.<br />
|
| 57 |
Geigenmüller A, Spindler H, Lenk K, et al.<i>Journal of Ceramic Science & Technology</i>, 2014, 5(2), 71.<br />
|
| 58 |
Hein J, Khatib O E, Kuna M, et al.<i>Journal of Ceramic Science & Technology</i>, 2016, 7(2),203.<br />
|
| 59 |
Pelissari P I B G B, Bouville F, et al.<i>Journal of the European Ceramic Society</i>, 2017,38(4), 2186.<br />
|
| 60 |
Naebe M, Shirvanimoghaddam K. <i>Applied Materials Today</i>, 2016, 5, 223.<br />
|
| 61 |
Scheithauer U, Schwarzer E, Michaelis A. <i>Refractories Worldforum</i>, 2016,8(2),95.<br />
|
| 62 |
Minatto F D, Milak P, Noni A D, et al.<i>Materials Science Forum</i>, 2015, 114(3), 393.
|
|
|
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2019, Vol. 33 
