新型火箭挂索回收非对称可变节流双级液压伸缩阻尼杆

doi:10.3901/JME.260012

机械工程学报 ›› 2026, Vol. 62 ›› Issue (1): 182-194.doi: 10.3901/JME.260012

• 特邀专栏：运载火箭机构技术 • 上一篇

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新型火箭挂索回收非对称可变节流双级液压伸缩阻尼杆

位仁磊^1,2, 马红鹏³, 吴帅^1,2, 陈泰麒^1,2, 焦宗夏^1,2

1. 北京航空航天大学自动化科学与电气工程学院北京 100191;
2. 北京航空航天大学飞行器一体化控制全国重点实验室北京 100191;
3. 北京宇航系统工程研究所北京 100076

收稿日期:2025-03-31 修回日期:2025-07-14 发布日期:2026-02-13
作者简介:位仁磊，男，1996年出生，博士研究生。主要研究方向为电液伺服元件和系统。E-mail：14031147@buaa.edu.cn
吴帅(通信作者)，男，1980年出生，博士，副研究员，博士研究生导师。主要研究方向为电液伺服元件与系统和数字液压。E-mail：ws@buaa.edu.cn
基金资助:
国家自然科学基金资助项目(U24B6005, 52275045)。

Asymmetric Variable Damping Characteristics of Two-stage Telescopic Hydraulic Damper

WEI Renlei^1,2, MA Hongpeng³, WU Shuai^1,2, CHEN Taiqi^1,2, JIAO Zongxia^1,2

1. School of Automation Science and Electrical Engineering, Beihang University, Beijing 100191;
2. Science and Technology on Aircraft Control Laboratory, Beihang University, Beijing 100191;
3. Beijing Institute of Astronautical Systems Engineering, Beijing 100076

Received:2025-03-31 Revised:2025-07-14 Published:2026-02-13

摘要/Abstract

摘要： 传统的腿式火箭回收采用垂直着陆方式，在火箭着陆时，火箭需要保持接近竖直姿态且着陆速度和角速度接近于零，否则可能着陆失败。相较之下，索式火箭回收采用上端悬挂回收，承受的过载更小，容许侧向速度和姿态控制偏差范围更大，回收稳定性更好。其中，为了确保挂索过程的稳定，挂索装置的拦阻杆需要在即将着陆时快速向下展开。在挂索后，挂索装置能提供较大阻尼，减缓冲击。针对这种需求，提出一种新型的非对称变阻尼阀结构的双级液压伸缩阻尼杆。该阻尼杆通过非对称变阻尼阀，在展开阶段提供小阻尼，实现挂索机构快速展开；在缩回阶段提供大阻尼，实现阻尼缓冲功能并保证挂索钩可靠挂索不脱钩。对提出的非对称可变节流双级液压伸缩阻尼杆建模，仿真分析其非对称阻尼特性与缩回压力冲击特性。经仿真和实验对比验证模型准确性。最后针对火箭着陆挂索工况，进行集成仿真验证。通过集成验证模型，分析不同阻尼参数对挂索过程的影响。结果表明，提出的非对称可变节流双级液压伸缩阻尼杆具有良好的非对称变阻尼特性，可以保证可靠挂索。研究成果为索式火箭回收系统中阻尼杆的设计与优化提供了理论依据和技术支持。

关键词: 索式火箭回收, 双级液压阻尼杆, 非对称变阻尼, 压力冲击

Abstract: Traditional reusable rocket landing relies on a vertical landing method. It requires a precise vertical attitude and both velocity and angular velocity close to zero. In contrast, tethered reusable rocket approaches offer improved stability by employing upper suspension, which tolerates a larger range of lateral velocity and attitude control deviations and experiences lower overloads. It requires the recovery hook to deploy rapidly just prior to landing to ensure the stability. What’s more, it’s required to provide substantial damping after capture to mitigate impact. To address this challenge, a novel dual-stage hydraulic damper is presented, incorporating a non-symmetric variable damping valve. This damper is designed to provide low damping during hook deployment, enabling rapid extension. Moreover, the damper provides high damping during retraction, implementing impact buffering and ensuring reliable tether capture without unhooking. A model of the proposed non-symmetric variable orifice dual-stage hydraulic extension damper rod has been developed and validated through both simulation and experimentation. The model accurately predicts the damper’s non-symmetric damping characteristics and the pressure impact during retraction. Finally, integrated simulations were conducted to evaluate the damper’s performance under realistic landing and tether capture conditions. Analyze the influence of different damping parameters on the tether capture process. The results demonstrate that the proposed damper achieves effective non-symmetric variable damping, ensuring reliable tether capture. These findings provide a theoretical foundation and technical support for the design and optimization of damper rods in tethered reusable rocket applications.

Key words: cable-type rocket recovery, two-stage telescopic hydraulic damper, asymmetric variable damping, pressure shock

中图分类号:

TG156

位仁磊, 马红鹏, 吴帅, 陈泰麒, 焦宗夏. 新型火箭挂索回收非对称可变节流双级液压伸缩阻尼杆[J]. 机械工程学报, 2026, 62(1): 182-194.

WEI Renlei, MA Hongpeng, WU Shuai, CHEN Taiqi, JIAO Zongxia. Asymmetric Variable Damping Characteristics of Two-stage Telescopic Hydraulic Damper[J]. Journal of Mechanical Engineering, 2026, 62(1): 182-194.

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新型火箭挂索回收非对称可变节流双级液压伸缩阻尼杆

Asymmetric Variable Damping Characteristics of Two-stage Telescopic Hydraulic Damper

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