Research of Different Processes for Forming Fiber Metal Laminates

Chernikov, D. G.; Erisov, Yaroslav; Petrov, Ilia; Alexandrov, Sergei; Lang, Lihui

doi:10.1007/s12239-019-0131-7

Cited by 8 publications

(3 citation statements)

References 11 publications

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“…[121] Al 5005 [122] Al 6061 [123] glass fibre reinforced/epoxy [114,124] carbon fibre reinforced/epoxy [125] [126] commercial aluminium [127] Al Figures 2 and 3 can be derived from Table 1, showing that aluminium alloy is the most frequently used base material in the fabrication of FMLs, with a percentage use of 62%, as indicated in Figure 2. Figure 3 shows that glass is the reinforcement most commonly used in FMLs, with a percentage use of 36.89%.…”

Section: Materials Alloy Fibre Reinforced Referencesmentioning

confidence: 99%

“…The EMF process influences such properties as residual stresses, impact toughness, and durability, and its major advantage is that it increases the formability of materials [380,402]. Chernikov et al [127] compared the electromagnetic forming of five-layer fibre reinforced metal polymer laminates with forming using a rubber pad. The formation of rifts (Figure 39) eliminates the high-velocity impact of the material with the die and the resulting delamination of the blank.…”

Section: Electromagnetic Formingmentioning

confidence: 99%

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New Advances and Future Possibilities in Forming Technology of Hybrid Metal–Polymer Composites Used in Aerospace Applications

et al. 2021

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Fibre metal laminates, hybrid composite materials built up from interlaced layers of thin metals and fibre reinforced adhesives, are future-proof materials used in the production of passenger aircraft, yachts, sailplanes, racing cars, and sports equipment. The most commercially available fibre–metal laminates are carbon reinforced aluminium laminates, aramid reinforced aluminium laminates, and glass reinforced aluminium laminates. This review emphasises the developing technologies for forming hybrid metal–polymer composites (HMPC). New advances and future possibilities in the forming technology for this group of materials is discussed. A brief classification of the currently available types of FMLs and details of their methods of fabrication are also presented. Particular emphasis was placed on the methods of shaping FMLs using plastic working techniques, i.e., incremental sheet forming, shot peening forming, press brake bending, electro-magnetic forming, hydroforming, and stamping. Current progress and the future directions of research on HMPCs are summarised and presented.

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Section: Materials Alloy Fibre Reinforced Referencesmentioning

confidence: 99%

Section: Electromagnetic Formingmentioning

confidence: 99%

New Advances and Future Possibilities in Forming Technology of Hybrid Metal–Polymer Composites Used in Aerospace Applications

et al. 2021

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“…They concluded that the BHG smaller than the initial thickness of FML can improve the quality and depth of forming of FML hydroformed specimens. Chernikov et al [13] compared the electromagnetic formed FMLs with the rubber pad forming process and proved that the formability was increased in the electromagnetic forming process. In a parametric study, Werner et al [14] concluded that the tension-compression behavior of the fibers has an important effect in the forming of FMLs.…”

Section: Introductionmentioning

confidence: 99%

Creep Age Forming of Fiber Metal Laminates: Effects of Process Time and Temperature and Stacking Sequence of Core Material

et al. 2021

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Fiber metal laminates (FMLs) are a type of hybrid materials interlacing composites and metals. In the present work, FMLs with aluminum alloy 6061 as the skin and E-glass fiber-reinforced polypropylene (PP) as the core material are fabricated and formed by the creep age forming (CAF) process. The effects of time and temperature as the process parameters and thickness and stacking sequences of composites layers as the FML parameters are evaluated on the springback of glass-reinforced aluminum laminates (GLARE) FMLs. After the CAF process, the springback of creep age-formed FMLs is calculated. The results show that the FMLs can be successfully formed with the CAF process by considering appropriate time and temperature. In addition, the stacking sequence of composite layers can affect the springback behavior of FMLs significantly.

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Forming challenges of small and complex fiber metal laminate parts in aerospace applications—a review

Blala

Lang

Khan

et al. 2023

Int J Adv Manuf Technol

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Research of Different Processes for Forming Fiber Metal Laminates

Cited by 8 publications

References 11 publications

New Advances and Future Possibilities in Forming Technology of Hybrid Metal–Polymer Composites Used in Aerospace Applications

New Advances and Future Possibilities in Forming Technology of Hybrid Metal–Polymer Composites Used in Aerospace Applications

Creep Age Forming of Fiber Metal Laminates: Effects of Process Time and Temperature and Stacking Sequence of Core Material

Forming challenges of small and complex fiber metal laminate parts in aerospace applications—a review

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