morinson 发表于 2017-9-1 00:35:21

蛇怪蜥蜴踏水奔跑机理研究及仿生机构设计

蛇怪蜥蜴踏水奔跑机理研究及仿生机构设计








蛇怪蜥蜴踏水奔跑机理研究及仿生机构设计
张仲志1, 高飞1, 宋彬1, 郭劭琰1, 吕建刚1, 马超2
1. 军械工程学院车辆与电气工程系,河北 石家庄 050003;
2. 武汉军械士官学校特种车辆教研室,湖北 武汉 430075

Mechanism Study and Bionic Design of Water Running of Basilisk Lizard
ZHANG Zhongzhi1, GAO Fei1, SONG Bin1, GUO Shaoyan1, Lü Jiangang1, MA Chao2
1. Department of Vehicle and Electrical Engineering, Mechanical Engineering College, Shijiazhuang 050003, China;
2. Department of Special Vehicle, Wuhan Ordnance Petty Officer Institute, Wuhan 430075, China







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摘要 蛇怪蜥蜴踏水奔跑过程中,脚掌会在气穴封闭前移出水面,并不断调整姿态适应变化的流场.为分析踏水机理,增加了对出水过程的研究,建立了脚掌进出水流体动力学模型,运用RNG(renormalization group)k-ε湍流方程,结合气穴扩张收缩变化,获得了最优上提时间.进一步针对脚掌姿态调整行为,解析了3维驱动力随入水角度的变化规律,推导了托举力与速度的数学函数,并通过实验初步验证了数值计算模型的正确性.以蛇怪蜥蜴为仿生对象,将脚掌往复踏水转变为叶片旋转击水,设计了水面矢量推进器,增加了驱动力输出维数,建立流体动力学模型,分析了叶片数量对力学性能的影响.进行推进器应用实验,实现了水面平台在10.6°仰角下的滑水航行.

关键词 : 踏水机理,固液作用,仿生设计,滑水航行   
Abstract:When running on water surface, basilisk lizard will pull its foot upward before the air cavity closes and adjust position to adapt to the unsteady fluid field. To obtain the mechanism of water running, the hydrodynamic model of foot to enter water and come out of water is presented, in which the coming-out-of-water process is considered. Combined with RNG (renormalization group) k-ε turbulence equation, the optimal time of coming-out-of-water is obtained by analyzing expansion and contraction of air cavity. In view of adjustment of foot position, 3-dimensional driving forces changing with angle of entering water are analyzed, and the function between lift force and velocity is derived. By experiment, it is validated primarily that the numerical model is correct. For the bionic basilisk lizard, a water surface vector propeller is designed with transforming foot movement into impeller rotation, and the dimension of driving force is increased. The hydrodynamic model of the propeller is established to analyze the influence of impeller quantity on mechanical property. In the experiment of propeller application, the water surface device realizes hydroplaning navigation with pitch angle 10.6°.
Key words: mechanism of water running         solid-liquid mutual action         bionic design         hydroplaning navigation
收稿日期: 2016-06-01   

1:Q811.6

U664.3

基金资助:国家部委项目(NHA15063)
通讯作者: 张仲志,shanshizhi@126.com    E-mail: shanshizhi@126.com
作者简介: 张仲志(1989-),男,博士生.研究领域:水面运动机理分析,仿生机器人.

引用本文:   
张仲志, 高飞, 宋彬, 郭劭琰, 吕建刚, 马超. 蛇怪蜥蜴踏水奔跑机理研究及仿生机构设计. 机器人, 2016, 38(6): 760-768.      
ZHANG Zhongzhi, GAO Fei, SONG Bin, GUO Shaoyan, Lü Jiangang, MA Chao. Mechanism Study and Bionic Design of Water Running of Basilisk Lizard. ROBOT, 2016, 38(6): 760-768.



链接本文:
http://robot.sia.cn/CN/10.13973/j.cnki.robot.2016.0760    或   http://robot.sia.cn/CN/Y2016/V38/I6/760





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