Challenges in Developing High Performance Al-Li Alloys

Pasang, Timotius; Lynch, S.P.; Moutsos, Stavroula

doi:10.5188/ijsmer.14.7

Cited by 6 publications

(4 citation statements)

References 16 publications

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“…11 e. This means that AA8090 displayed anisotropy in its tensile properties. Moreover, the degree of anisotropy in the tensile properties of AA8090 was higher than that in AA1420, the finding which is in line with those reported in previous investigations [97] , [98] , [99] . Anisotropic tensile properties (through-thickness anisotropy and in-plane anisotropy) are a pivotal issue that has received much attention in 2 nd generation Al-Li alloys, particularly anisotropy in the ductility, yield, ultimate strength and fracture toughness as depicted in previous figures.…”

Section: Anisotropic Behavior Of the Al-li Alloyssupporting

confidence: 92%

Strengthening mechanisms, deformation behavior, and anisotropic mechanical properties of Al-Li alloys: A review

El-Aty

Guo

et al. 2018

Journal of Advanced Research

500

124

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Section: Anisotropic Behavior Of the Al-li Alloyssupporting

confidence: 92%

Strengthening mechanisms, deformation behavior, and anisotropic mechanical properties of Al-Li alloys: A review

El-Aty

Guo

et al. 2018

Journal of Advanced Research

500

124

View full text Add to dashboard Cite

show abstract

“…The 2nd generation alloy's tensile properties depend upon the loading directions, where the Fs and UTS values are higher than for those 90°and 45°directions, which can be observed from figures 4(a) and (b). Which is conclude that anisotropy was higher in the 2nd generation than the 1st generation in tensile properties by different investigations [68][69][70]. These anisotropy properties were reported and highlighted more in the 2nd generation as they received particular attention, which dominates some of the properties like ductility, yield, ultimate, and fracture toughness [71][72][73].…”

Section: Tensile Properties Of 2nd Generation Alloysmentioning

confidence: 82%

Improving the properties of aluminum-lithium composites in aerospace applications: review

Polayya,

Rao,

Veeresh Kumar

2024

Eng. Res. Express

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Aluminium (Al)-Lithium (Li) alloys have found widespread applications in aerospace and military domains. Primarily, they are found to have low density, leading to weight savings and several economic considerations. The paper explores the historical development of Al-Li alloys across distinct generations, highlighting their evolution. It also delves into the diverse applications of Al-Li alloys in aerospace and military domains. A concise discussion of the mechanical behaviour and tensile strengths is presented across the first, second, and third generations of Al-Li alloys. This review includes a discussion on microstructural investigation, emphasizing metallurgical factors such as increased efficiency, various precipitate phases, and intergranular features. Weldability and tribological properties of Al-Li alloys, with a specific emphasis on the corrosion aspects of these alloys are discussed. Furthermore, the review assesses the future development and manufacturing flexibility of Al-Li Metal Matrix Composites. In summary, this comprehensive review consolidates insights into the utilization, evolution, and characteristics of Al-Li Metal Matrix Composites, providing valuable information for researchers and practitioners aiming to enhance the performance of these alloys in aerospace applications.

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“…High‐entropy alloys made by this method are significantly more robust and ductile than other casting methods, and the rupture strength can reach 1400 MPa, which is six times the strength of 304 stainless steel used in traditional engines. In 2021, Pasang et al [ 98 ] investigated the mechanical characteristics of Ti–6Al–4 V prepared by AM technologies and found that EBM samples have higher surface roughness than SLM samples. The development of new materials for EBM has also progressed.…”

Section: Powder‐based Methodsmentioning

confidence: 99%

“…However, due to the equipment's poor production speed, the shortcomings of powder performance, and the inefficient manufacturing industry chain, SLM still has the space for the following developments. [98,99] 1) Developing purer and more refined powders, optimizing their overall qualities such as particle size, thermophysical properties, and developing a suitable manufacturing method to eliminate spheroidization, warpage deformation, and fractures in treated components. [83] 2) Accelerating research on large-part SLM moulding.…”

Section: Research Focus and Prospects Of Slmmentioning

confidence: 99%

Powder‐Based Additive Manufacturing: A Critical Review of Materials, Methods, Opportunities, and Challenges

Shanthar,

Chen,

Abeykoon

2023

Adv Eng Mater

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As a 0‐dimensional moulding material, powder particles can realise the construction of most engineering parts and can further improve the precision moulding and high‐performance manufacturing capabilities of additive manufacturing (AM). Therefore, the powder‐based additive manufacturing methods provide an outstanding practical value and development for modern manufacturing world. However, powder materials that are utilised in additive manufacturing continue to face challenges such as a lack of accessible categories, temperature restrictions, and poor performance of moulded components. Therefore, researching for new additive manufacturing materials and procedures has become one of the important and influential ways to accelerate the progress of additive manufacturing technology and also to expand its application fields. For this purpose, it is invaluable to understand and update on the current state‐of‐the‐art of powder‐based additive manufacturing technologies. Hence, this work first reviews the research background of powder‐based 3D printing in details while systematically expounding on the technologies and equipment, material types, influencing factors, existing problems and development trends of powder‐based 3D printing. In addition, the basic principles of powder‐based 3D printing were also revealed, and the formation and optimization of metal, polymer, and ceramic powders in powder‐based 3D printing equipment were explored. Throughout the last decade, powder‐based AM has gradually emerged in the fields of biomedical and aerospace, such as the construction of tissue scaffolds and the construction of aero‐engine parts, respectively. However, powder materials may have insufficient comprehensive performance due some limitations, as the control of mechanical characteristics and dimensional accuracy of powder moulded parts are still challenging during manufacturing processes. Therefore, exploring the mechanism/s of additive manufacturing of powder‐based materials, improving the mechanical properties of powder‐based AM products, and the possible directions for improving the usability of powder materials are the main focus of this paper.This article is protected by copyright. All rights reserved.

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Challenges in Developing High Performance Al-Li Alloys

Cited by 6 publications

References 16 publications

Strengthening mechanisms, deformation behavior, and anisotropic mechanical properties of Al-Li alloys: A review

Strengthening mechanisms, deformation behavior, and anisotropic mechanical properties of Al-Li alloys: A review

Improving the properties of aluminum-lithium composites in aerospace applications: review

Powder‐Based Additive Manufacturing: A Critical Review of Materials, Methods, Opportunities, and Challenges

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