Reclamation of intermetallic titanium aluminide aero-engine components using directed energy deposition technology

IF 1.9 Q3 ENGINEERING, MANUFACTURING
Balichakra Mallikarjuna, E. Reutzel
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引用次数: 1

Abstract

Titanium Aluminide (TiAl) alloys are intermetallics that offer low density, high melting point, good oxidation and corrosion resistance compared to Ni-based superalloys. As a result, these alloys are used in aero-engine parts such as turbine blades, fuel injectors, radial diffusers, divergent flaps, and more. During operation, aero-engine components are subjected to high thermal loading in an oxidizing and corrosive environment, which results in wear and other material damage. Replacement of the entire component may not be desirable due to long lead time and expense. In such cases, repair and refurbishing may be the best option for the reclamation of TiAl parts. Unfortunately, approved repair technology is not currently available for TiAl based components. Additive Manufacturing (AM) based Directed Energy Deposition (DED) may serve as an option to help repair and restore expensive aero-engine parts. In this work, a review of efforts to utilize the DED technique to repair damaged TiAl-based aerospace parts locally is conducted. Replacing the entire TiAl part is not advisable as it is expensive. DED is a promising technique used to produce, repair, rework, and overhaul (MRO) damaged parts. Considering the high-quality standard of the aircraft industry, DED repaired TiAl parts to be certified for their future use in the aircraft is very important. However, there are no standards for the certification of TiAl repaired parts is reported. Case studies reveal that DED is under consideration for repair of TiAl parts. Hybrid technology comprising machining, repair and finishing capability in a single machine is an attractive implementation strategy to improve repair efficacies. The review shows that the investigations into development and applications of DED-based repairing techniques are limited, which suggests that further investigations are very much needed.
利用定向能沉积技术回收金属间钛铝化物航空发动机部件
与镍基高温合金相比,钛铝(TiAl)合金是一种金属间化合物,具有密度低、熔点高、抗氧化性和耐腐蚀性好等优点。因此,这些合金被用于航空发动机部件,如涡轮叶片、燃油喷射器、径向扩散器、发散襟翼等。在运行过程中,航空发动机部件在氧化和腐蚀环境中承受高热负荷,导致磨损和其他材料损坏。由于交货期和费用较长,可能不希望更换整个部件。在这种情况下,维修和翻新可能是回收TiAl零件的最佳选择。不幸的是,目前批准的修复技术还不能用于基于TiAl的组件。基于增材制造(AM)的定向能量沉积(DED)可以作为一种选择,帮助修复和恢复昂贵的航空发动机部件。在这项工作中,回顾了利用DED技术在局部修复受损钛基航空航天部件的努力。更换整个TiAl部分是不可取的,因为它是昂贵的。DED是一种很有前途的技术,用于生产、修理、返工和大修(MRO)损坏的零件。考虑到飞机工业的高质量标准,DED修复的TiAl零件获得认证对于其未来在飞机上的使用非常重要。但是,目前还没有关于TiAl修复件认证的标准报道。案例研究表明,人们正在考虑将DED用于TiAl零件的修复。将加工、修理和精加工能力集成在一台机器上的混合技术是提高修理效率的一种有吸引力的实施策略。综述表明,基于d的修复技术的开发和应用的研究是有限的,这表明进一步的研究是非常必要的。
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来源期刊
Manufacturing Review
Manufacturing Review ENGINEERING, MANUFACTURING-
CiteScore
5.40
自引率
12.00%
发文量
20
审稿时长
8 weeks
期刊介绍: The aim of the journal is to stimulate and record an international forum for disseminating knowledge on the advances, developments and applications of manufacturing engineering, technology and applied sciences with a focus on critical reviews of developments in manufacturing and emerging trends in this field. The journal intends to establish a specific focus on reviews of developments of key core topics and on the emerging technologies concerning manufacturing engineering, technology and applied sciences, the aim of which is to provide readers with rapid and easy access to definitive and authoritative knowledge and research-backed opinions on future developments. The scope includes, but is not limited to critical reviews and outstanding original research papers on the advances, developments and applications of: Materials for advanced manufacturing (Metals, Polymers, Glass, Ceramics, Composites, Nano-materials, etc.) and recycling, Material processing methods and technology (Machining, Forming/Shaping, Casting, Powder Metallurgy, Laser technology, Joining, etc.), Additive/rapid manufacturing methods and technology, Tooling and surface-engineering technology (fabrication, coating, heat treatment, etc.), Micro-manufacturing methods and technology, Nano-manufacturing methods and technology, Advanced metrology, instrumentation, quality assurance, testing and inspection, Mechatronics for manufacturing automation, Manufacturing machinery and manufacturing systems, Process chain integration and manufacturing platforms, Sustainable manufacturing and Life-cycle analysis, Industry case studies involving applications of the state-of-the-art manufacturing methods, technology and systems. Content will include invited reviews, original research articles, and invited special topic contributions.
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