• Liquid safety cushioning technology

    From ScienceDaily@1337:3/111 to All on Fri Jul 14 22:30:26 2023
    Liquid safety cushioning technology
    A breakthrough in material design will help football players, car
    occupants and hospital patients

    Date:
    July 14, 2023
    Source:
    University of Virginia School of Engineering and Applied Science
    Summary:
    Mechanical engineering and materials science advancements could
    revolutionize safety equipment for athletes and more.


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    FULL STORY ==========================================================================
    The discovery that football players were unknowingly acquiring permanent
    brain damage as they racked up head hits throughout their professional
    careers created a rush to design better head protection. One of these inventions is nanofoam, the material on the inside of football helmets.

    Thanks to mechanical and aerospace engineering associate professor Baoxing
    Xu at the University of Virginia and his research team, nanofoam just
    received a big upgrade and protective sports equipment could, too. This
    newly invented design integrates nanofoam with "non-wetting ionized
    liquid," a form of water that Xu and his research team now know blends perfectly with nanofoam to create a liquid cushion. This versatile
    and responsive material will give better protection to athletes and
    is promising for use in protecting car occupants and aiding hospital
    patients using wearable medical devices.

    The team's research was recently published inAdvanced Materials.

    For maximum safety, the protective foam sandwiched between the inner
    and outer layers of a helmet should not only be able to take one hit
    but multiple hits, game after game. The material needs to be cushiony
    enough to create a soft place for a head to land, but resilient enough
    to bounce back and be ready for the next blow. And the material needs
    to be resilient but not hard, because "hard" hurts heads, too. Having
    one material do all of these things is a pretty tall order.

    The team advanced their work previously published in theProceedings of
    the National Academy of Sciences, which started exploring the use of
    liquids in nanofoam, to create a material that meets the complex safety
    demands of high- contact sports.

    "We found out that creating a liquid nanofoam cushion with ionized water instead of regular water made a significant difference in the way the
    material performed," Xu said. "Using ionized water in the design is a breakthrough because we uncovered an unusual liquid-ion coordination
    network which made it possible to create a more sophisticated material."
    The liquid nanofoam cushion allows the inside of the helmet to compress
    and disperse the impact force, minimizing the force transmitted to
    the head and reducing the risk of injury. It also regains its original
    shape after impact, allowing for multiple hits and ensuring the helmet's continued effectiveness in protecting the athlete's head during the game.

    "An added bonus," Xu continued, "is that the enhanced material is more
    flexible and much more comfortable to wear. The material dynamically
    responds to external jolts because of the way the ion clusters and
    networks are fabricated in the material." "The liquid cushion can be
    designed as lighter, smaller and safer protective devices," said associate professor Weiyi Lu, a collaborator from civil engineering at Michigan
    State University. "Also, the reduced weight and size of the liquid
    nanofoam liners will revolutionize the design of the hard shell of future helmets. You could be watching a football game one day and wonder how the smaller helmets protect the players' heads. It could be because of our
    new material." In traditional nanofoam, the protection mechanism relies
    on material properties that react when it gets crunched, or mechanically deformed, such as "collapse" and "densification." Collapse is what it
    sounds like, and densification is the severe deformation of foam on
    strong impact. After the collapse and densification, the traditional
    nanofoam doesn't recover very well because of the permanent deformation
    of materials -- making the protection a one-time deal. When compared to
    the liquid nanofoam, these properties are very slow (a few milliseconds)
    and cannot accommodate the "high-force reduction requirement," which
    means it can't effectively absorb and dissipate high-force blows in the
    short time window associated with collisions and impacts.

    Another downside of traditional nanofoam is that, when subjected to
    multiple small impacts that don't deform the material, the foam becomes completely "hard" and behaves as a rigid body that cannot provide
    protection. The rigidness could potentially lead to injuries and damage
    to soft tissues, such as traumatic brain injury (TBI).

    By manipulating the mechanical properties of materials -- integrating nanoporous materials with "non-wetting liquid" or ionized water -- the
    team developed a way to make a material that could respond to impacts
    in a few microseconds because this combination allows for superfast
    liquid transport in a nanoconfined environment. Also, upon unloading,
    i.e., after impacts, due to its non-wetting nature, the liquid nanofoam
    cushion can return to its original form because the liquid is ejected out
    of the pores, thereby withstanding repeated blows. This dynamic conforming
    and reforming ability also remedies the problem of the material becoming
    rigid from micro-impacts.

    The same liquid properties that make this new nanofoam safer for athletic
    gear also offer a potential use in other places where collisions happen,
    like cars, whose safety and material protective systems are being
    reconsidered to embrace the emerging era of electric propulsion and
    automated vehicles. It can be used to create protective cushions that
    absorb impacts during accidents or help reduce vibrations and noise.

    Another purpose that might not be as evident is the role liquid nanofoam
    can play in the hospital setting. The foam can be used in wearable
    medical devices like a smartwatch, which monitors your heart rate and
    other vital signs. By incorporating liquid nanofoam technology, the
    watch can have a soft and flexible foam-like material on its underside
    and help improve the accuracy of the sensors by ensuring proper contact
    with your skin. It can conform to the shape of your wrist, making it comfortable to wear all day. Additionally, the foam can provide extra protection by acting as a shock absorber. If you accidentally bump your
    wrist against a hard surface, the foam can help cushion the impact and
    prevent any harm to the sensors or your skin.

    * RELATED_TOPICS
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    # Brain_Injury # Multiple_Sclerosis #
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    o Matter_&_Energy
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    * RELATED_TERMS
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    Story Source: Materials provided
    by University_of_Virginia_School_of_Engineering_and_Applied
    Science. Original written by Wende Whitman. Note: Content may be edited
    for style and length.


    ========================================================================== Journal Reference:
    1. Yuan Gao, Mingzhe Li, Chi Zhan, Haozhe Zhang, Mengtian Yin,
    Weiyi Lu,
    Baoxing Xu. Nanoconfined Water‐Ion Coordination Network
    for Flexible Energy Dissipation Device. Advanced Materials, 2023;
    DOI: 10.1002/adma.202303759 ==========================================================================

    Link to news story: https://www.sciencedaily.com/releases/2023/07/230714163215.htm

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