A Review on Inertia and Linear Friction Welding of Ni-Based Superalloys
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  • 作者:Ahmad Chamanfar (1)
    Mohammad Jahazi (1)
    Jonathan Cormier (2)

    1. Dpartement de Gnie Mcanique     ; 脡cole de Technologie Suprieure ; 1100 rue Notre-Dame Ouest ; Montreal ; QC ; H3C 1K3 ; Canada
    2. Dpartement de Physique et Mcanique des Matriaux     ; Institut Pprime ; CNRS-ENSMA-Universit de Poitiers ; UPR CNRS 3346 ; BP 40109 ; ENSMA-Tlport 2 ; 1 avenue Cl茅ment Ader ; 86961 ; Futuroscope-Chasseneuil Cedex ; France
  • 刊名:Metallurgical and Materials Transactions A
  • 出版年:2015
  • 出版时间:April 2015
  • 年:2015
  • 卷:46
  • 期:4
  • 页码:1639-1669
  • 全文大小:4,766 KB
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  • 刊物类别:Chemistry and Materials Science
  • 刊物主题:Chemistry
    Materials Science
    Metallic Materials
    Structural Materials
    Physical Chemistry
    Ceramics,Glass,Composites,Natural Materials
  • 出版者:Springer Boston
  • ISSN:1543-1940
文摘
Inertia and linear friction welding are being increasingly used for near-net-shape manufacturing of high-value materials in aerospace and power generation gas turbines because of providing a better quality joint and offering many advantages over conventional fusion welding and mechanical joining techniques. In this paper, the published works up-to-date on inertia and linear friction welding of Ni-based superalloys are reviewed with the objective to make clarifications on discrepancies and uncertainties reported in literature regarding issues related to these two friction welding processes as well as microstructure, texture, and mechanical properties of the Ni-based superalloy weldments. Initially, the chemical composition and microstructure of Ni-based superalloys that contribute to the quality of the joint are reviewed briefly. Then, problems related to fusion welding of these alloys are addressed with due consideration of inertia and linear friction welding as alternative techniques. The fundamentals of inertia and linear friction welding processes are analyzed next with emphasis on the bonding mechanisms and evolution of temperature and strain rate across the weld interface. Microstructural features, texture development, residual stresses, and mechanical properties of similar and dissimilar polycrystalline and single crystal Ni-based superalloy weldments are discussed next. Then, application of inertia and linear friction welding for joining Ni-based superalloys and related advantages over fusion welding, mechanical joining, and machining are explained briefly. Finally, present scientific and technological challenges facing inertia and linear friction welding of Ni-based superalloys including those related to modeling of these processes are addressed.

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