Crack Repair of Single Crystal Turbine Blades Using Laser Cladding Technology

Rottwinkel, Boris; Nölke, Christian; Kaierle, Stefan; Wesling, Volker

doi:10.1016/j.procir.2014.06.151

Cited by 56 publications

(19 citation statements)

References 5 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Turbine blades are made of heat-resistant steel or nickel/cobalt-based superalloys. Because of the harsh environment and relatively short lifespan of the blades, any opportunity to regenerate damaged element is very attractive [6,7,8,9]. …”

Section: Introductionmentioning

confidence: 99%

Grain-Boundary Interaction between Inconel 625 and WC during Laser Metal Deposition

et al. 2018

View full text Add to dashboard Cite

In this study, the laser metal deposition (LMD) of the Inconel 625–tungsten carbide (WC) metal matrix composite was investigated. The composite coating was deposited on Inconel 625 substrate by powder method. A powder mixture containing 10 wt% of WC (5 µm) was prepared by wet mixing with dextrin binder. Coating samples obtained by low-power LMD were pore- and crack-free. Ceramic reinforcement was distributed homogenously in the whole volume of the material. Topologically close-packed (TCP) phases were formed at grain boundaries between WC and Inconel 625 matrix as a result of partial dissolution of WC in a nickel-based alloy. Line analysis of the elements revealed very small interference of the coating in the substrate material when compared to conventional coating methods. The average Vickers hardness of the coating was about 25% higher than the hardness of pure Inconel 625 reference samples.

show abstract

Section: Introductionmentioning

confidence: 99%

Grain-Boundary Interaction between Inconel 625 and WC during Laser Metal Deposition

et al. 2018

View full text Add to dashboard Cite

show abstract

“…High-pressure single-crystal turbine blades made of Ni-based superalloys have superior creep and fatigue properties with respect to the polycrystalline ones and, accordingly, they can sustain temperatures up to 1100 °C. However, as a consequence of the extreme conditions in the engine of High-pressure single-crystal turbine blades made of Ni-based superalloys have superior creep and fatigue properties with respect to the polycrystalline ones and, accordingly, they can sustain temperatures up to 1100 • C. However, as a consequence of the extreme conditions in the engine of commercial airplanes, they undergo erosion and cracking [90,99,100]. Kaierle et al demonstrated that the DED process had promising results in the building-up of a single crystal or directionally solidified structures, while laser remelting could be used to extend this monocrystalline height [99].…”

Section: Repaired By Thermal Spraymentioning

confidence: 99%

Application of Directed Energy Deposition-Based Additive Manufacturing in Repair

et al. 2019

View full text Add to dashboard Cite

In the circular economy, products, components, and materials are aimed to be kept at the utility and value all the lifetime. For this purpose, repair and remanufacturing are highly considered as proper techniques to return the value of the product during its life. Directed Energy Deposition (DED) is a very flexible type of additive manufacturing (AM), and among the AM techniques, it is most suitable for repairing and remanufacturing automotive and aerospace components. Its application allows damaged component to be repaired, and material lost in service to be replaced to restore the part to its original shape. In the past, tungsten inert gas welding was used as the main repair method. However, its heat affected zone is larger, and the quality is inferior. In comparison with the conventional welding processes, repair via DED has more advantages, including lower heat input, warpage and distortion, higher cooling rate, lower dilution rate, excellent metallurgical bonding between the deposited layers, high precision, and suitability for full automation. Hence, the proposed repairing method based on DED appears to be a capable method of repairing. Therefore, the focus of this study was to present an overview of the DED process and its role in the repairing of metallic components. The outcomes of this study confirm the significant capability of DED process as a repair and remanufacturing technology.

show abstract

“…Results of metallographic studies showed the existence of clear boundary between the base and built-up material, absence of defects and fine-needled structure of built-up layer indicating high cooling speeds. In respect to the advantages of used methods the authors also mentioned its adaptivity, тельным результатом стало наличие системы контроля геометрии наплавленных валиков с целью обеспечения минимального припу-ска на последующую механическую обработку, а так же оценки технологической возможно-сти "лечения" поверхностных трещин лопаток из никелевых сплавов при лазерной наплавке [21][22][23].…”

Section: Fig 4 Cracks and Porosity In Built-up Layer On The Blade Ounclassified

“…Also, authors mention the advantages of fiber laser in comparison with СО 2 laser. The positive result consisted in the presence of control system of weld bead geometry for the purpose of provision of minimum allowance for the further mechanical treatment; also the evaluations of technological capacity of "treatment" of surface cracks of the blades of nickel alloys during the laser cladding were mentioned in the papers [21][22][23].…”

Section: рис6 макет адаптивного автоматизированного ком-плекса лазеmentioning

confidence: 99%

Prospects of Use of Laser Cladding Technology for Restoration of Compressor Blades of Gas Turbine Engines

Zemlyakov¹,

Babkin²,

Korsmik³

et al. 2016

FRos

View full text Add to dashboard Cite

Laser cladding as technology of repair operations is in demand for the restoration of the parts, which were operated in aggressive media and subjected to surface wear. It is applicable to the machines and mechanisms, which are used in engine building, nuclear power engineering, petrochemical production, mineral resource and metal-working industries. Analysis of technologies and equipment for the restoration of compressor blades of gas turbine engines and steam generators applied in the world practice is given. The domestic complex of laser cladding is suggested. Against the background of domestic complexes it is distinguished by the presence of cassette accessories, which allows easy transition from single-piece cladding to automated cladding of the set of one-type blades.

show abstract

Crack Repair of Single Crystal Turbine Blades Using Laser Cladding Technology

Cited by 56 publications

References 5 publications

Grain-Boundary Interaction between Inconel 625 and WC during Laser Metal Deposition

Grain-Boundary Interaction between Inconel 625 and WC during Laser Metal Deposition

Application of Directed Energy Deposition-Based Additive Manufacturing in Repair

Prospects of Use of Laser Cladding Technology for Restoration of Compressor Blades of Gas Turbine Engines

Contact Info

Product

Resources

About