Research article Topical Sections

Co-Sintering behaviour of zirconia-ferritic steel composites

  • Received: 11 May 2016 Accepted: 03 August 2016 Published: 11 August 2016
  • 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.

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

    Related Papers:

  • 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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