自展浮体泛水展开临界状态动力学分析
Dynamic Analysis of the Critical State of Self-Expanding Floating Body When Water Overflows
DOI: 10.12677/dsc.2026.153024, PDF,   
作者: 徐 磊*, 邴浩千:中国人民解放军63983部队,江苏 无锡;吴春明, 钱立新:无锡红旗船厂有限公司,江苏 无锡
关键词: 浮体扭力杆临界状态动力学Floating Body Torsion Bar Critical State Dynamics
摘要: 自展浮体是一种依靠自身扭力杆实现泛水展开的可折叠浮体结构,但在研制设计过程中,扭力杆所需提供扭矩大小缺乏理论计算方法。本文对自展浮体的中箱和边箱分别采用运动学和动力学进行分析,根据运动学基本原理和力矩平衡原理,分别推导出了中箱和边箱的物理模型运功和受力解析表达式,对比了边箱的展开扭矩和扭力杆扭矩的变化趋势,从而对边箱展开的临界状态进行动力学分析,对自展浮体的设计计算,特别是扭力杆的选型,提供一定的理论依据。
Abstract: The self-deploying floating body is a foldable floating body structure that can be deployed by flooding through its own torsion bars. However, during the research and design process, there is a lack of theoretical calculation methods for the torque required by the torsion bars. In this paper, kinematics and dynamics are respectively applied to analyze the middle box and side boxes of the self - deploying floating body. Based on the basic principles of kinematics and the principle of moment balance, analytical expressions for the motion and force of the physical models of the middle box and side boxes are derived respectively. The changing trends of the deployment torque of the side boxes and the torque of the torsion bars are compared, so as to conduct a dynamic analysis of the critical state of the side box deployment. This provides a certain theoretical basis for the design and calculation of the self-deploying floating body, especially for the selection of torsion bars.
文章引用:徐磊, 吴春明, 邴浩千, 钱立新. 自展浮体泛水展开临界状态动力学分析[J]. 动力系统与控制, 2026, 15(3): 229-237. https://doi.org/10.12677/dsc.2026.153024

参考文献

[1] 吴培德, 刘建成, 林铸明, 等. 带式舟桥[M]. 北京: 国防工业出版社, 2005: 40-45.
[2] 江增涛, 王亚兰, 陈石昌. 浅谈动力舟桥在抢险救援中的应用[J]. 红水河, 2023, 42(4): 133-136.
[3] Russell, B.R. and Thrall, A.P. (2013) Portable and Rapidly Deployable Bridges: Historical Perspective and Recent Technology Developments. Journal of Bridge Engineering, 18, 1074-1085. [Google Scholar] [CrossRef
[4] Robinson, M.J. and Kosmatka, J.B. (2008) Development of a Short-Span Fiber-Reinforced Composite Bridge for Emergency Response and Military Applications. Journal of Bridge Engineering, 13, 388-397. [Google Scholar] [CrossRef
[5] Palo, P. (2005) Mobile Offshore Base: Hydrodynamic Advancements and Remaining Challenges. Marine Structures, 18, 133-147. [Google Scholar] [CrossRef
[6] Russell, B.R., Thrall, A.P., Padula, J.A. and Fowler, J.E. (2014) Reconceptualization and Optimization of a Rapidly Deployable Floating Causeway. Journal of Bridge Engineering, 19, 1040-1053. [Google Scholar] [CrossRef
[7] 孙永岗. 波浪作用下带式浮桥动力响应特性研究[D]: [硕士学位论文]. 上海: 上海交通大学, 2016.
[8] 孙文俊. 渡河桥梁装备研究方法[M]. 北京: 国防工业出版社, 2002.
[9] 马帅, 程建生, 段金辉, 王儒, 陈鹏辉. 舟桥单双耳接头裂纹应力强度因子研究[J]. 热加工工艺, 2024, 53(4): 115-118, 126.
[10] 姜鹏宇, 林铸明, 孙建群. 移动载荷作用下浮桥流固耦合分析[C]//中国钢结构协会海洋结构分会, 中国造船工程学会船舶力学学术委员会结构强度学组, 中国造船工程学会船舶力学学术委员会载荷和响应学组. 中国钢结构协会海洋结构分会学术论文集. 无锡: 《船舶力学》编辑部, 2015: 306-311.
[11] 陈启飞, 黄亚新, 王建平, 程建生. 玻璃钢/钢材符合结构带式舟桥方舟的研制[J]. 纤维符合材料, 2002(1): 27-29.
[12] 丁勇, 林铸明, 李欢, 蔡正宇. 带式舟桥泛水展开过程中扭力杆受力计算模型[J]. 陆军工程大学学报, 2022, 1(2): 53-59.

为你推荐