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Co-Sintering behaviour of zirconia-ferritic steel composites

Fraunhofer IKTS, Winterbergstraße 28, 01277 Dresden, Germany

Topical Section: Metal ceramic (Cermets)

The combination of metallic and ceramic materials allows the combination of positive properties of both and can be applied in various industrial fields. At the moment, the deployment of these composites faces difficult and complex manufacturing. One attempt, which offers a short process route and a high degree of flexibility regarding design is a combined shaping (co-shaping) with a combined sintering (co-sintering). The article will show co-sintering results of different metal-ceramic symmetric and asymmetric multi-layered tapes, consisting of yttria stabilized zirconia combined with a ferritic iron chromium steel. Focus is on the densification and co-sintering behaviour of ceramic layers depending on the sintering behaviour of metallic layers. Co-sintered composites were characterized by field emission scanning electron microscopy, x-ray diffraction measurements and in terms of adhesive tensile strength.
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Keywords metal-ceramic composite; co-sintering; porous-dense combination; tensile strength

Citation: Tim Slawik, Anne Günther, Tassilo Moritz, Alexander Michaelis. Co-Sintering behaviour of zirconia-ferritic steel composites. AIMS Materials Science, 2016, 3(3): 1160-1176. doi: 10.3934/matersci.2016.3.1160

References

  • 1. Rooney M, Roberts JC, Murray GM, et al. (2000) Advanced Materials: Challenges and Oppertunities. John Hopkins APL Technical Digest 21: 516–527.
  • 2. Butterman WC, Gilette RG (1990) Markets for new materials. New materials society: Challenges and opportunities U. S. Department of the Interior. 2: 1–47.
  • 3. Dixon DG (1995) Ceramic matrix composite-metal brazed joints. J Mater Sci 30: 1539–1544.    
  • 4. Berger L-M, Barbosa MM, Martin H-P, et al. (2013) Potential of Thermal Spray Technologies for the Manufacture of TEG. Thermoelectrics Goes Automative II (Thermoelectrics III), expert Verlag, Renningen, 260–272.
  • 5. Cai PZ, Green DJ, Messing GL (1997) Constrained Densification of Alumina / Zirconia Hybrid Laminates, I: Experimental Observation of Processing Defects. J Am Ceram Soc 50: 1929–1939.
  • 6. Chang J, Guillon O, Rödel J, et al. (2008) Characterization of warpage behaviour of Gd-doped ceria/NiO-yttria stabilized zirconia bi-layer samples for solid oxide fuel cell. J Power Sources 185: 759–764.    
  • 7. Ravi D, Green DJ (2006) Sintering stresses and distortion produced by density differences in bi-layer structures. J Eur Ceram Soc 26: 17–25.    
  • 8. Reynier T, Bouvard D, Carry CP, et al. (2012) Co-sintering of an anode-supported SOFC based on scandia stabilized zirconia electrolyte. Advances in Science and Technology II: Ceramic Transaction 232: 91–99.
  • 9. Guillon O, Krauß S, Rödel J (2007) Influence of thickness on the constrained sintering of alumina films. J Eur Ceram Soc 27: 2623–2627.    
  • 10. Kim J-S, Rudkin RA, Wang X, et al. (2011) Constrained sintering kinetics of 3YSZ films. J Eur Ceram Soc 31: 2231–2239.    
  • 11. Muecke R, Menzler NH, Buchkremer H-P, et al. (2009) Cofiring of Thin Zirconia Films during SOFC Manufacturing. J Am Ceram Soc 92: 95–102.    
  • 12. Yamaguchi T, Suzuki T, Shimizu S, et al. (2007) Examination of wet coating and co-sintering technologies for micro-SOFCs fabrication. J Membrane Sci 300: 45–50.    
  • 13. Baumann A (2010) Powder injection moulding of metal-ceramic composites, PhD-thesis, Berg-akademie Freiberg.
  • 14. Yeo J-G, Jung Y-G, Choi S-C (1998) Zirconia-stainless steel fuctionally graded material by tape casting. J Eur Ceram Soc 18: 1281–1285.    
  • 15. Hage C (2013) Fundamental aspects of 2 component powder injection moulding, PhD-thesis, Karlsruher Institute of Technology.
  • 16. Shen Z, Zhu X, Le S, et al. (2012) Co-sintering anode and Y2O3 stabilized ZrO2 thin electrolyte film for solid oxide fuel cell fabricated by co-tape casting. Int J Hydrogen Energ 37: 10337–10345.    
  • 17. Wu K, Scheler S, Park H-S, et al. (2013) Pressureless sintering of ZrO2-ZrSiO4/NiCr functionally graded materials with a shrinkage matching process. J Eur Ceram Soc 33: 1111–1121.    
  • 18. Slawik T, Bergner A, Puschmann R, et al. (2014) Metal-Ceramic Layered and Composites Manufactured Using Powder Techniques. Adv Eng Mater 16: 1293–1302.
  • 19. Slawik T, Bergner A, Scheithauer U, et al. (2015) Adapting the co-sintering bahavior of metal-ceramic composites. Proceedings EuroPM2015.
  • 20. Mistler RE, Twiname ER (2000) Tape Casting–Theory and Practice. Wiley-American Ceramic Society. 1 edition.
  • 21. Scheithauer U, Slawik T, Schwarzer E, et al. (2015) Manufacturing of Metal-Ceramic-Composites by Thermoplastic 3D-Printing (3DTP). J Ceram Sci Techn 29: 125–132.
  • 22. Slawik T, Moritz T, Scholl R, et al. (2013) Multilayered metal-ceramic composites made by coating technologies Proceedings 8. Pacific Rim International Conference on Advanced Materials and Processing.
  • 23. Bergner A (2014) Steel-ceramic laminates made by tape casting - Processing and Interfaces. Singh JP, Bansal NP, Bhalla AS, et al. (Editors). Processing and Properties of Advanced Ceramics and Composites VI 249: 53–63.
  • 24. Hagy HE (1963) Experimental Evaluation of Beam-Bending Method of Determining Glass Viscosities in the Range 10 8to 10 15 Poises. J Am Ceram Soc 46: 93–97    
  • 25. Lee S-H, Messing GL, Green DJ (2003) Bending Creep Test to Measure the Viscosity of Porous Materials during Sintering. J Am Ceram Soc 86: 877–882.
  • 26. Lame O, Bouvard D, Wiedmann H (2002) Anisotropic shrinkage and gravity induced creep during sintering of steel powder compacts. Powder Metall 45: 181–185.    
  • 27. Blaine DC, Bollina R, Park S-J, et al. (2005) Critical use of video-imaging to rationalize computer sintering simulation models. Comput Ind 56: 867–875.    
  • 28. Jankowski AF (1987) Adhesion of physically vapor-dposited titanium coatins to beryllium substrates. Thin Solid Films 154: 183–198.    
  • 29. Dourandish M, Simchi A, Shabestary ET, et al. (2008) Pressureless Sintering of 3Y-TZP/Stainless-Steel Composite Layers. J Am Ceram Soc 91: 3493–3503.    
  • 30. Dourandish M, Simchi A (2009) Study the sintering behaviour of nano-crystalline 3Y-TZP/430L stainless-steel composite layers for co-powder injection molding. J Mater Sci 44: 1264–1274.

 

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