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Preparation and Properties of Asymmetric Porous Aluminium-Oxide Ceramic HollowFibre Membranes Haibo Mu, Guizeng Hao, Xiaowei Li and Bo Meng School of Chemical Engineering, Shandong University of Technology, Zibo 255049, PR China muhaibo111@126.com, mb1963@sdut.edu.cn Keywords: hollow fibre membrane; Al2O3; phase inversion; non-solvent Abstract.
Characterization and performance of high-flux PdAu/ceramic composite membranes, Chinese Journal of Catalysis, 2010, 31(6): 711-715 [9] G L Chen, H Qi, W B Peng,et al.
Porous ceramic support of coated alumina prepared by low-temperature sintering, Journal of the Chinese Ceramic Society, 2009,37(11): 1818-1822
Preparation of porous aluminium oxide (Al2O3) hollow fibre membranes by a combined phase-inversion and sintering method, Ceramics International 2003, 29: 875–881
Towards single step production of multi-layer inorganic hollow fibers, Journal of Membrane Science, 2004, 239: 265–269.

Eco‐Friendly Innovation of Non-Fired Ceramic Tiles from Rice Husk Ash and Recycled Glass Cullet Purinut Maingam1,a*, Ubolrat Wangrakdiskul1,b and Natthakitta Piyarat1,c 1Department of Production Engineering, Faculty of Engineering, King Mongkut’s University of Technology North Bangkok, 1518 Pracharat 1 Rd., Wongsawang, Bangsue, Bangkok 10800, Thailand as6201021910047@email.kmutnb.ac.th, bubolrat.w@eng.kmutnb.ac.th, cs6201021910021@email.kmutnb.ac.th Keywords: Non-firing, Non-fired ceramic tiles, Energy conservation, Rice husk ash, Glass cullet Abstract.
They all consumed energy for firing ceramic bodies.
Acknowledgement The authors are grateful for all necessary resources by the Production Engineering Department, Faculty of Engineering, King Mongkut’s University of Technology North Bangkok, Thailand.
Abadir: HBRC journal Vol. 14 (2018), p. 309-315 [12] J.
Wongchareonsin: International Journal of Advanced Culture Technology Vol. 3 (2015), p. 15-24 [14] D.

Heat Cutting for Remanufacture Hardness Deposited Materials Zhiyuan Wu1,a, Xiaojun Shi1,b, Xinli Tian1,c, Xiujian Tang1 and Shu Zhang1 1National Key Laboratory for Equipment Remanufacturing, Academy of Armored Force Engineering, China, 100072 aWu_zhiyuan20021@163.com, bshixiaojun01@sina.com, ctianxli719251@sohu.com Keywords: Heat cutting, High hardness materials, Remanufacture, Impact cutting Abstract.
Heat Cutting by Si3N4 Ceramic Tools Orthogonal Experiment for Cutting Parameters.
So the Si3N4 ceramic tool is not suitable for heat cutting hardness materials.
Brozek: Journal of Materials Processing Technology, Vol. 168 (2005), pp. 488-495
Nouari: International Journal of Machine Tools & Manufacture, Vol. 47 (2007), pp. 1715-1727

Proceedings of the SPIE - The International Society for Optical Engineering 2014, 8987, 89871B (7 pp.)-89871B (7 pp
M.; Bernik, S., Journal of the European Ceramic Society 2013, 33 (2), 335-344
Longo, Journal of the European Ceramic Society, vol.28, no.3, pp.505–529, 2008
Zecca, Journal of Alloys and Compounds. 386 (2005) 103–106
[15] Deng, W.; Zhu, Y.; Zhou, Y.; Huang, Y.; Cao, M.; Xiong, L., Rare Metal Materials and Engineering 2006, 35 (3), 348-51

Yang 2,b 1 School of Materials Science and Engineering, Harbin Institute of Technology, Harbin 150001, China 2 School of Mechanical and Electrical Engineering, Harbin Engineering University, Harbin 150001, China a hitzhangjie@hit.edu.cn, b zhulingbin@126.com Keywords: Silicon Nitride ceramic; 40CrMo steel; braze; microstructure Abstract.
Introduction Ceramic has many outstanding properties such as wearing and thermal oxidation resistances, however, the natural brittleness of ceramics greatly limits their applications.
Advantages of both ceramics and metals can be achieved through bonding between ceramics and metals by modern joining technologies.
Thus, developements and applications of the joining techniques for ceramics and metals have became an important technique in ceramic applications.
Drew: International Journal of Refractory Metals and Materials Vol. 22 (2004), p. 95 [3] J.

Processing and Characterization of an Al2O3 /TiCN Micro- Nano- Composite Graded Ceramic Tool Material Z.J.
Zheng 1,c 1Key Laboratory of High Efficiency and Clean Mechanical Manufacture of MOE, School of Mechanical Engineering, Shandong University, 17923 Jingshi Road, Jinan 250061, PR China 2Shandong Polytechnic, 23000 Jingshidong Road, Jinan 250104, PR China ajnrp-gzj@163.com, b zhaojun@sdu.edu.cn, c zgm03010805@163.com Keywords: Micro-nano-composite graded ceramics, Mechanical properties, Microstructure, Strengthening mechanisms, Toughening mechanisms Abstract.
Ai et al. [6] proposed the FGM’s design model of the symmetric composition distribution, and fabricated Al2O3/TiC and Al2O3/(W, Ti)C functionally graded ceramic tool materials, which have higher toughness and thermal shock resistance compare to the homogeneous ceramics.
Liu: Proceedings of the Fifth International Conference on High Speed Machining, (Metz, France, University of Metz, 2006)
Qiu et al.: Journal of Rare Earths 25 (2007) p. 291.

The split Hopkinson pressure bar has been widely used and modified to determine the dynamic properties of a variety of engineering materials, such as metals [4-7], concrete[8-10], ceramics[11-13].
Yang, Constitutive equation for Ti-6Al-4V at high temperatures measured using the SHPB technique, International Journal of Impact Engineering. 31(2005) 735-754
Zhou, Dynamic behavior of concrete at high strain rates and pressures: I. experimental characterization, International Journal of Impact Engineering. 25(2001) 869-886
Subhash, Critical appraisal of limiting strain rates for compression testing of ceramics in a split Hopkinson pressure bar, Journal of the American Ceramic Society. 77(1994) 263-267
Tan, Specimen Stress Equilibrium in Split Hopkinson Pressure Bar Tests of Ceramics at High Strain Rate, Mechanical Properties and Performance of Engineering Ceramics and Composites VI. 2011) 53-66

Guoa* College of Mechanical and Energy Engineering, Jimei University, Xiamen 361021, China achjmu@163.com Keywords: plasma; spray; ceramic coating; wear; remanufacture Abstract: Microscopic observation and testing were carried out on the structure & texture, bonding form and performances of different plasma-sprayed ceramic coatings on the wear surface of Cr12MoV dies by KYKY-2800B SEM.
XU, Remanufacture Engineering and Its Development in China, China Surface Engineering, 23 (2012):1-6 [2] H.K.
Wang, et al, Laser remanufacturing technology and its applications, Proceedings of SPIE−The International Society for Optical Engineering. 68(2008)25
Chen, S.Ni, et al, Phase formation regularites of ultrafine TiAl NiAl and FeAl 5intermetallic compound powers during solid-liquid reaction milling, Journal of Alloys and Compounds. 457(2008)292-295 [6] X.L.
Fan, et al, Friction and Wear Properties of a Magnetron Spyttered TiB2-TiN Films on Cr12MoV Steels, Lubrication Engineering, 36(2011)35-38 [9] C.R.Brooks, Failure Analysis of Engineering Materials, McGraw-Hill Companies, Inc, 2002 [10] K.

Influence of Ceramic Fibers on Mechanical Characteristics of Refractory Composites HOLČAPEK Ondřej1,a *, REITERMAN Pavel1,b and KONVALINKA Petr1,c 1CTU in Prague, Faculty of Civil Engineering, Experimental Centre, Thákurova 7, 166 29, Prague 6, Czech Republic aondrej.holcapek@fsv.cvut.cz, bpavel.reiterman@fsv.cvut.cz, cpetr.konvalinka@fsv.cvut.cz Keywords: Compressive strength, tensile strength in bending, dynamic modulus of elasticity, aluminous cement, crushed basalt aggregates, high temperature influence, ceramic fibers.
The composite´s matrix was supplemented by various amounts of ceramic fibers.
Ceramic Fibers.
References [1] Máca, P., Sovják, R., Konvalinka, P., Mix design of UHPFRC and its response to projectile impact, International Journal of Impact Engineering, 2014, pp. 158-163
[6] Holčapek, O., Reiterman, P., Vogel, F., Vejmelková, E., Konvalinka, P., Mechanical Properties of Aluminous Paste at High Temperature, Research and Applications in Structure Engineering, Mechanics and Computation 2013, Cape Town, ISBN 978-1-138-00061-2, (2013), pp. 635-636

Inclusion engineering and the metallurgy of calcium treatment.
Ceramics International 2015;41:2089-98
Advanced Engineering Materials 2017;19(9):1700199-1-12
Advanced Engineering Materials 2017;18
Ceramics International 2012;38(2):919-27