2022-Sustainable Industrial Processing Summit
SIPS2022 Volume 18 Intl. Symp on Advanced Materials, Polymers, Composite, Nanomaterials, Nanotechnologies and Manufacturing

Editors:F. Kongoli, F. Marquis, N. Chikhradze, T. Prikhna, M. De Campos, S. Lewis, S. Miller, S. Thomas.
Publisher:Flogen Star OUTREACH
Publication Year:2022
Pages:290 pages
ISBN:978-1-989820-68-1(CD)
ISSN:2291-1227 (Metals and Materials Processing in a Clean Environment Series)
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    Mechanical Response of Lightweight Graphene Reinforced Aluminum Foams at High Strain Rates and High Temperature

    Sanjeev Khanna1; Akhouri Sinha1;
    1UNIVERSITY OF MISSOURI, Columbia, United States;
    Type of Paper: Keynote
    Id Paper: 366
    Topic: 43

    Abstract:

    Closed-cell aluminum foam is a particular type of lightweight metal that can sustain considerable deformation under approximate constant stress, which is known as plateau stress. Therefore, under quasi-static and dynamic loading, aluminum foams can be used for absorbing energy during loading. In addition, the light weight can potentially reduce the weight of the components and reduce overall energy consumption, such as in automobiles and aircraft. In this investigation, aluminum foams reinforced with graphene of concentration varying between 0.2 – 0.6 wt.% was manufactured using the liquid metallurgy route. The compressive dynamic behavior of Aluminum foam reinforced with graphene platelets has been studied over a range of strain rates between 1000 to 2200 s-1 using the Split Hopkinson Pressure Bar (SHPB) apparatus. The mechanical response has been studied at room temperature and at high temperatures of 473 oK and 623 oK. Amongst the four different graphene concentrations studied, 0.6 wt.% displayed the maximum value of peak stress, plateau stress, and energy absorption. The experimental data obtained in the present studies are validated using a theoretical model. The high strain rate response of the 0.6 wt.% graphene foam at 623 oK is nearly 50% better than the unreinforced foam at room temperature for all strain rates studied.

    Keywords:

    Nanomaterials; New and advanced materials;

    References:

    1. Dannemann, K. A., & Lankford, J. (2000). High strain rate compression of closed-cell
    aluminum foams. Materials Science and Engineering A, 293(1), 157–164.
    2. Hakamada, M., Nomura, T., Yamada, Y., Chino, Y., Chen, Y., Kusuda, H., & Mabuchi,
    M. (2005). Compressive deformation behavior at elevated temperatures in a closed-cell
    aluminum foam. Materials Transactions, 46(7), 1677–1680.
    3. Cady, C. M., Gray, G. T., Liu, C., Lovato, M. L., & Mukai, T. (2009). Compressive
    properties of a closed-cell aluminum foam as a function of strain rate and
    temperature. Materials Science and Engineering A, 525(1–2), 1–6.
    4. Wang, P., Xu, S., Li, Z., Yang, J., Zheng, H., & Hu, S. (2014). Temperature effects on the
    mechanical behavior of aluminum foam under dynamic loading. Materials Science and
    Engineering A, 599, 174–179.

    Cite this article as:

    Khanna S and Sinha A. (2022). Mechanical Response of Lightweight Graphene Reinforced Aluminum Foams at High Strain Rates and High Temperature. In F. Kongoli, F. Marquis, N. Chikhradze, T. Prikhna, M. De Campos, S. Lewis, S. Miller, S. Thomas. (Eds.), Sustainable Industrial Processing Summit SIPS2022 Volume 18 Intl. Symp on Advanced Materials, Polymers, Composite, Nanomaterials, Nanotechnologies and Manufacturing (pp. 75-76). Montreal, Canada: FLOGEN Star Outreach