氧化石墨烯在火灾早期预警中的应用

石林; 郑鹏伦; 李正曦; 刘全义

doi:10.16511/j.cnki.qhdxxb.2025.21.017

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清华大学学报（自然科学版） ›› 2025, Vol. 65 ›› Issue (9) : 1784-1793. DOI: 10.16511/j.cnki.qhdxxb.2025.21.017

公共安全

氧化石墨烯在火灾早期预警中的应用

石林 ¹ ,
郑鹏伦 ¹^,² ,
李正曦 ³ ,
刘全义 ¹^,²^,*

作者信息 +

Application of graphene oxide in fire early warning

Lin SHI ¹ ,
Penglun ZHENG ¹^,² ,
Zhengxi LI ³ ,
Quanyi LIU ¹^,²^,*

Author information +

文章历史 +

摘要

火灾事故的频繁发生对人民生命财产安全构成了严重威胁, 提升火灾预警效率至关重要。石墨烯及其衍生物在阻燃及火灾预警领域的应用成为研究热点, 优异的电子传导率和比表面积使其在传感器领域具有应用潜力。该文综述了国内外在氧化石墨烯(GO)用于火灾早期预警的研究进展。首先, 概述了GO基传感器的工作原理; 然后, 详细介绍了GO本体材料和GO涂层材料的研究现状; 深入分析了这种传感器在多种应用场景和需求中的实际应用情况, 展示了其广泛的应用前景。最后, 综述了GO在火灾早期预警中的应用现状, 并展望未来的研究方向。

Abstract

Significance: The frequent occurrence of fire accidents poses a serious threat to the safety of people's lives and properties. Thus it is vital to improve the accuracy and efficiency of fire warning systems. Currently, fire alarm sensors or detector systems can be used to provide an early warning of potential fire hazards. Existing conventional fire alarm detectors include infrared (IR) and smoke detectors, that trigger alarms by detecting heat radiation or smoke particles. However, these systems are susceptible to interference from environmental factors, resulting in false alarms or delayed warnings (>100 s). Progress: Unlike traditional smoke alarms, new fire warning sensors can provide timely responses in the early stages of a fire, providing a stronger guarantee for fire safety. Therefore, there has been increasing interest in smart fire warning materials and sensors that combine traditional passive fire retardant strategies with active fire alarm response. Carbon-based two-dimensional (2D) nanomaterial graphene oxide (GO), a typical representative of smart fire warning materials, is characterized by its positive feedback between electrical conductivity and temperature. This paper reviews local and international research progress in the field of GO-based fire early warning sensors. The working principle of GO-based sensors is first summarized, followed by detailed descriptions of current research on GO body materials and GO coating materials. Furthermore, we analyze in depth the practical applications of such sensors in a variety of application scenarios and requirements, demonstrating their wide range of application prospects. We also categorize GO-based fire warning sensor warning signals into traditional and remote and IoT-based alarm signals and then elaborate on these. Finally, we provide a comprehensive summary of the research on GO-based fire early warning sensors, which shows that GO-based fire alarm materials can provide sensitive fire alarm signals within < 10s, making them more sensitive than conventional fire alarm systems. Based on such updated information, we summarize the future research directions in this field. Conclusions and Prospects: Future research should focus on several aspects. First, the fire warning and fire protection performance of the GO coating can be further optimized by developing new coating materials and improving the structural design, while ensuring that it can quickly respond to fire and effectively stop it from spreading. Second, in optimizing the design of the response of organics to GO, researchers should consider the thermal response sensitivity of the functional groups and the properties of the organics themselves. In particular, quantifying the number of functional groups and the effect of pyrolysis of organics on fire warning can help establish a synergistic quantitative relationship between them. Such a relationship helps to precisely regulate the properties of the materials, thus achieving accurate and efficient fire warning functions. Third, a more reasonable preparation method must be proposed to realize the precise control of the number and type of functional groups on the GO surface. This can be achieved by precisely controlling the conditions of the chemical reaction, including temperature, time, and pH levels. Finally, the GO fire warning and fireproof coating technology must be integrated with the Internet of Things to realize real-time data monitoring, as well as remote control and automated response systems to improve their level of intelligence.

导出引用

石林, 郑鹏伦, 李正曦, 等. 氧化石墨烯在火灾早期预警中的应用[J]. 清华大学学报（自然科学版）. 2025, 65(9): 1784-1793 https://doi.org/10.16511/j.cnki.qhdxxb.2025.21.017

Lin SHI, Penglun ZHENG, Zhengxi LI, et al. Application of graphene oxide in fire early warning[J]. Journal of Tsinghua University(Science and Technology). 2025, 65(9): 1784-1793 https://doi.org/10.16511/j.cnki.qhdxxb.2025.21.017

中图分类号： X932

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基金

国家自然科学青年基金项目(52202416)

国家自然科学联合基金项目(U2033206)

民机火灾科学与安全工程四川省重点实验室项目(MZ2022JB01)

四川省院省校合作项目(2024YFHZ0027)

青海省科技计划项目(2024-GX-C03)

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