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Scalable production of high-performing woven lithium-ion fibre batteries

机译:可扩展的高性能编织锂离子纤维电池生产

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摘要

Rechargeable lithium-ion batteries produced in the form of metre-long fibres can be woven into sturdy, washable textiles on an industrial loom and used to power other fabric-based electronic components.Fibre lithium-ion batteries are attractive as flexible power solutions because they can be woven into textiles, offering a convenient way to power future wearable electronics(1-4). However, they are difficult to produce in lengths of more than a few centimetres, and longer fibres were thought to have higher internal resistances(3,5) that compromised electrochemical performance(6,7). Here we show that the internal resistance of such fibres has a hyperbolic cotangent function relationship with fibre length, where it first decreases before levelling off as length increases. Systematic studies confirm that this unexpected result is true for different fibre batteries. We are able to produce metres of high-performing fibre lithium-ion batteries through an optimized scalable industrial process. Our mass-produced fibre batteries have an energy density of 85.69 watt hour per kilogram (typical values(8) are less than 1 watt hour per kilogram), based on the total weight of a lithium cobalt oxide/graphite full battery, including packaging. Its capacity retention reaches 90.5% after 500 charge-discharge cycles and 93% at 1C rate (compared with 0.1C rate capacity), which is comparable to commercial batteries such as pouch cells. Over 80 per cent capacity can be maintained after bending the fibre for 100,000 cycles. We show that fibre lithium-ion batteries woven into safe and washable textiles by industrial rapier loom can wirelessly charge a cell phone or power a health management jacket integrated with fibre sensors and a textile display.
机译:以仪表长纤维的形式生产的可充电锂离子电池可以编织在工业织机上的坚固,可洗的纺织品中,并用于为其他基于织物的电子元件供电。锂离子电池作为灵活的电源解决方案具有吸引力,因为它们具有灵活的电源解决方案可以编织成纺织品,为未来的可穿戴电子产品(1-4)提供便捷的方法。然而,它们难以产生超过几厘米以上的长度,并且认为较长的纤维具有较高的内部电阻(3,5),其受损电化学性能(6,7)。在这里,我们表明这种纤维的内部电阻具有与纤维长度的双曲线Cotangent功能关系,其中在平衡之前首先降低随着长度的增加。系统研究证实,对于不同的纤维电池,这一意外结果是正确的。我们能够通过优化的可扩展工业过程生产高性能的纤维锂离子电池。我们的大规模纤维电池的能量密度为85.69瓦特小时每公斤(典型值(8)小于每公斤速度小于1瓦),基于钴氧化物/石墨全电池的总重量,包括包装。 500充放电循环后的容量保持率为90.5%,在1C速率下93%(与0.1C速率)相比,与袋细胞等商业电池相当。弯曲纤维100,000个循环后,可以保持超过80%的容量。我们展示纤维锂离子电池由工业剑杆织机织造成安全可清洗的纺织品,可以通过光纤传感器和纺织品显示,无线地充电手机或电源一体的健康管理夹克。

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  • 来源
    《Nature 》 |2021年第7874期| 57-63| 共7页
  • 作者

    He Jiqing; Lu Chenhao; Jiang Haibo; Han Fei; Shi Xiang; Wu Jingxia; Wang Liyuan; Chen Taiqiang; Wang Jiajia; Zhang Ye; Yang Han; Zhang Guoqi; Sun Xuemei; Wang Bingjie; Chen Peining; Wang Yonggang; Xia Yongyao; Peng Huisheng;

  • 作者单位

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ Acad Engn & Technol Inst Future Lighting Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ Acad Engn & Technol Inst Future Lighting Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

    Fudan Univ Dept Chem Shanghai Peoples R China|Fudan Univ Shanghai Key Lab Mol Catalysis & Innovat Mat Shanghai Peoples R China|Fudan Univ iChEM Collaborat Innovat Ctr Chem Energy Mat Shanghai Peoples R China;

    Fudan Univ Dept Chem Shanghai Peoples R China|Fudan Univ Shanghai Key Lab Mol Catalysis & Innovat Mat Shanghai Peoples R China|Fudan Univ iChEM Collaborat Innovat Ctr Chem Energy Mat Shanghai Peoples R China;

    Fudan Univ State Key Lab Mol Engn Polymers Shanghai Peoples R China|Fudan Univ Dept Macromol Sci Shanghai Peoples R China|Fudan Univ Lab Adv Mat Shanghai Peoples R China;

  • 收录信息 美国《科学引文索引》(SCI);美国《工程索引》(EI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
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