液态金属驱动水下软体机器人研究进展综述

蔡乐尧; 王神龙

doi:10.11993/j.issn.2096-3920.2025-0080

液态金属驱动水下软体机器人研究进展综述

doi: 10.11993/j.issn.2096-3920.2025-0080

蔡乐尧,
王神龙^,

上海理工大学机械工程学院, 上海, 200093

基金项目: 国家自然科学基金面上项目(12172226); 中央高校基本科研业务费专项资金(CSA-TS202404) .

详细信息

通讯作者:
王神龙(1989-), 男, 副教授、博士生导师, 主要研究方向为仿生软体机器人.

中图分类号: U674.91; TJ63
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出版历程
- 收稿日期: 2025-06-27
- 修回日期: 2025-08-14
- 录用日期: 2025-08-18
- 网络出版日期: 2025-09-08

A Review of Research Progress on Liquid Metal-Driven Soft Robotics

CAI Yueyao,
WANG Shenlong^,

School of Mechanical Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China

摘要

摘要: 随着软体机器人关键技术的快速发展, 液态金属因其独特的低熔点、高导电性、高导热性和良好的流动性, 成为该领域的研究热点。液态金属, 如镓基合金, 通过磁性增强、电活性增强和结构优化等显著提升了其在驱动系统中的辅助应用潜力。作为导电材料和柔性电极, 液态金属在驱动、传感和多自由度运动中的应用潜力。文中系统综述了液态金属的功能特性、驱动与传感技术, 并重点探讨了其在水下软体机器人中的应用现状与挑战。目前, 液态金属为电极的驱动器已实现电热驱动、电化学驱动和磁驱动等多种机制, 传感器则在高灵敏度应变检测、压力感知和多模态信号监测方面取得突破。然而, 水下应用中的多自由度运动仍面临驱动机制复杂、材料稳定性不足和控制系统不完善等技术难题。未来研究需进一步突破这些技术瓶颈, 以推动液态金属水下软体机器人的实用化进程。
- 液态金属 /
- 软体机器人 /
- 多自由度运动 /
- 水下应用 /
- 驱动与传感
Abstract: With the rapid advancement of key technologies in soft robotics, liquid metals have emerged as a focus in this field due to their unique properties, including low melting point, high electrical conductivity, superior thermal conductivity, and excellent fluidity. Gallium-based alloys have significantly enhanced their auxiliary application potential in actuation systems through approaches like magnetic reinforcement, electroactive enhancement, and structural optimization. As conductive materials and flexible electrodes, they demonstrate further promise in actuation, sensing, and multi-degree-of-freedom(multi-DOF) motion through approaches like magnetic reinforcement, electroactive enhancement, and structural optimization. This review systematically summarizes the functional characteristics, actuation mechanisms, and sensing technologies of liquid metals, with particular emphasis on their current applications and challenges in underwater soft robotics. To date, liquid metal-based actuators have achieved diverse actuation modes, including electrothermal, electrochemical, and magnetic driving mechanisms, while corresponding sensors have made breakthroughs in high-sensitivity strain detection, pressure sensing, and multimodal signal monitoring. Nevertheless, the realization of multi-DOF motion in underwater environments still faces technical challenges, such as complex actuation mechanisms, insufficient material stability, and imperfect control systems. Future research needs to further overcome these technical bottlenecks to advance the practical application of liquid metal-driven underwater soft robots.
- liquid metal /
- soft robotics /
- multi-degree-of-freedom motion /
- underwater applications /
- actuation and sensing

HTML全文

图 1 液态金属材料开发历程

Figure 1. Evolution of liquid metal materials

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图 2 基于磁性增强的液态金属的改性方法

Figure 2. Modification methods for liquid metals based on magnetic enhancement

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图 3 液态金属驱动器

Figure 3. Liquid metal actuators

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图 4 液态金属传感器

Figure 4. Liquid metal sensors

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图 5 液态金属仿生水母机器人LM-Jelly

Figure 5. Liquid metal biomimetic jellyfish robot LM-Jelly

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图 6 软电磁驱动仿乌贼喷射推进机器鱼

Figure 6. Soft electromagnetic actuator-based squid-inspired jet-propelled robotic fish

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图 7 多模态驱动液态金属机器人

Figure 7. Multimodal-driven liquid metal robot

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图 8 多自由度液态金属机器人

Figure 8. Multi-degree-of-freedom liquid metal robots

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表 1 常见液态金属的物理性能

Table 1. Physical properties of common liquid metals

液态金属	熔点 /°C	粘度 /(mPa·s)	电导率 /(S·m⁻¹)	热导率 /(W·m⁻¹·℃⁻¹)
汞Hg^[16]	−38.83	1.55	1.04×10⁶	8.34
镓Ga^[17]	29.8	1.37	6.73	29.3
铷Rb	39.3	0.48	1.1×10⁶	35.9
铯Cs	28.4	0.35	1.2×10⁶	35.9
钫Fr	27	0.3	0.03×10⁶	0.15
铟In^[18]	156.6		1.25×10⁷	81.6
锡Sn^[18]	231.9		8.7×10⁶	66.6
铋Bi^[18]	271.4		9×10⁵	7.87
GaIn21.4 (EGaIn)^[6]	15.6	1.99	3.4	26.43
GaSn13.4^[7]	21
GaAl0.9^[7]	25.9
Ga68.5In21.5Sn10 (Galinstan)^[19]	10.5	1.5	3.5	25.41

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表 2 液态金属驱动技术的水下适用性对比

Table 2. Underwater applicability comparison of liquid metal actuation technologies

驱动机制	原理	水下优势	水下局限性	传感协同价值
磁场控制	外磁场操控磁性液态金属液滴	无接触控制、穿透性强	需预混铁颗粒、负载能力弱(<100 mg)	磁定位、运动轨迹反馈
电场驱动	电化学调控表面张力	低电压(0.5 V)、应变大(87%)	需电解质环境、电极腐蚀	阻抗监测流体化学特性
光驱动	光热/光化学相变	无线能量传输、非接触	水下光衰减严重、响应慢	集成光学传感器实现闭环控制
超声波	声空化/声辐射力	穿透浑浊水体、无惧光学干扰	能量转化效率低(<5%)	声呐避障与通信集成

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