Modelling of thrust generated by oscillation caudal fin of underwater bionic robot

A simplified model of the thrust force is proposed based on a caudal fin oscillation of an underwater bionic robot. The caudal fin oscillation is generalized by central pattern generators(CPGs). In this model, the drag coefficient and lift coefficient are the two critical parameters which are obtained by the digital particle image velocimetry(DPIV) and the force transducer experiment. Numerical simulation and physical experiments have been performed to verify this dynamic model.

RNA-seq analysis of a zebrafish caudal fin cell line in response to infection with spring viraemia of carp virus

A cell line,termed ZFIN,was established from the caudal fin of zebrafish and was shown to be susceptible to spring viremia of carp virus(SVCV).The ZFIN cells are epithelial like cells and have a moderate plasmid transfection efficiency of 13.9%.Using an RNA-seq approach,differentially expressed genes(DEGs)regulated by SVCV were identified.Infection of SVCV gave rise to 3931 DEGs and up-regulated DEGs were mostly enriched into the biological regulation and cellular processes,among which pathways for the type I interferon signaling and the response to exogenous dsRNA were the top two GO terms.Several KEGG signaling pathways including TLR signaling pathway,RLR receptor signaling pathway,cytosolic DNA-sensing pathway,NLR signaling pathway,cytokine-cytokine receptor interaction and ferroptosis were significantly enriched.Antiviral genes including ifnφ1,isg15 and mx were significantly up-regulated.In addition,key DEGs involved in autophagy were identified.The results indicate that the ZFIN cell line provides a useful in vitro tool for study on the gene functions and cellular responses to viral infection in fish.

The effects of caudal fin deformation on the hydrodynamics of thunniform swimming under self-propulsion

To investigate the effects of the caudal fin deformation on the hydrodynamic performance of the self-propelled thunniform swimming,we perform fluid-body interaction simulations for a tuna-like swimmer with thunniform kinematics.The 3-D vortices are visualized to reveal the role of the leading-edge vortex(LEV)in the thrust generation.By comparing the swimming velocity of the swimmer with different caudal fin flexure amplitudes fa,it is shown that the acceleration in the starting stage of the swimmer increases with the increase of fa,but its cruising velocity decreases.The results indicate that the caudal fin deformation is beneficial to the fast start but not to the fast cruising of the swimmer.During the entire swimming process,the undulation amplitudes of the lateral velocity and the yawing angular velocity decrease as fa increases.It is found that the formation of an attached LEV on the caudal fin is responsible for generating the low-pressure region on the surface of the caudal fin,which contributes to the thrust.Furthermore,the caudal fin deformation can delay the LEV shedding from the caudal fin,extending the duration of the low pressure on the caudal fin,which will cause the caudal fin to generate a drag-type force over a time period in one swimming cycle and reduce the cruising speed of the swimmer.

Hydrodynamics study of dolphin’s self-yaw motion realized by spanwise flexibility of caudal fin

The hydrodynamic performance of the virtual underwater vehicle under self-yaw is investigated numerically in this paper,we aim to explore the fluid laws behind this plane motion achieved by the bionic flexibility,especially the spanwise flexibility of the caudal fin.The kinematics of the chordwise flexible body and the spanwise flexible caudal fin are explored through dynamic mesh technology and user-defined functions(UDF).The 3-D Navier-Stokes equations are applied to simulate the viscid fluid surrounding the bionic dolphin.The study focuses on quantitative problems about the fluid dynamics behind the specific motion law,including speed of movement,energy loss and working efficiency.The current results show that the self-yaw can be composed of two motions,autonomous propulsion and active steering.In addition,the degree of the flexible caudal fin can produce different yaw effects.The chordwise phase differenceФis dominant in the propulsion function,while the spanwise phase differenceδhas a more noticeable effect on the steering function.The pressure distribution on the surface of the dolphin and the wake vortex generated in the flow field reasonably reveal the evolution of self-yaw.It properly turns out that the dolphin can combine the spanwise flexible caudal fin and the chordwise flexible body to achieve self-yaw motion.

Topology Optimization of the Caudal Fin of the Three-Dimensional Self-Propelled Swimming Fish

Based on the boundary vorticity-flux theory,topology optimization of the caudal fin of the three-dimensional self-propelled swimming fish is investigated by combining unsteady computational fluid dynamics with moving boundary and topology optimization algorithms in this study.The objective functional of topology optimization is the function of swimming efficiency,swimming speed and motion direction control.The optimal caudal fin,whose topology is different from that of the natural fish caudal fin,make the 3D bionic fish achieve higher swimming efficiency,faster swimming speed and better maneuverability.The boundary vorticity-flux on the body surface of the 3D fish before and after optimization reveals the mechanism of high performance swimming of the topology optimization bionic fish.The comparative analysis between the swimming performance of the 3D topology optimization bionic fish and the 3D lunate tail bionic fish is also carried out,and the wake structures of two types of bionic fish show the physical nature that the swimming performance of the 3D topology optimization bionic fish is significantly better than the 3D lunate tail bionic fish.

NUMERICAL AND EXPERIMENTAL STUDIES OF INFLUENCE OF THE CAUDAL FIN SHAPE ON THE PROPULSION PERFORMANCE OF A FLAPPING CAUDAL FIN

This article presents a comprehensive study of the effects of the caudal fin shape on the propulsion performance of a candal fin in harmonic heaving and pitching.A numerical simulation based on an unsteady panel method was carried out to analyze the hydrodynamic performance of flapping caudal fins of three shapes(the whale caudal fin with the largest projected area,the dolphin caudal fin with the median projected area,and the tuna caudal fin with the smallest projected area).Then,a series of hydrodynamic experiments for three caudal fin shapes were performed.Both computational and experimental results indicate that the tuna caudal fin produces the highest efficiency.However the mean thrust coefficient of the tuna caudal fin is the smallest.It is found that although the mean thrust coefficient for the tuna caudal fin is not large,the input power of the tuna caudal fin is also quite small.So the tuna caudal fin achieves a high efficiency.

EXPERIMENT ON THE CHARACTERISTICS OF 3-D VORTEX RING BEHIND A FLEXIBLE OSCILLATING CAUDAL FIN

A test for the wake vortex of a flexible oscillating caudal fin is carried out with Digital Particle Image Velocimetry(DPIV),and the variation of vortex distance and the vorticity in the range of oscillating frequency from 0.704 Hz to 1.17 Hz are analyzed.It is found that with the increase of the oscillating frequency,the vortex distance decreases and the peak of the vorticity increases,When the Strouhal number is smaller than 0.49,a larger thrust component is obtained.The distribution of the velocity circulation and the vortex distance in the different spanwise section of the caudal fin are given,and then the dimension of the vortex ring is determined. The radius of the vortex ring is 79.3 mm and the average velocity circulation is 28152.9 mm2/s at the oscillating frequency of 0.835 Hz.The model of 3-D vortex ring chain of flexible oscillating caudal fin is constructed based on the information of wake vortex field. Finally,an effective analysis method is provided for establishing the relationship of oscillating parameters for the caudal fin and the wake structure and the intrinsic mechanism of efficient fish swimming is investigated.

Principle and Experimental Verification of Caudal-fin-type Piezoelectric-stack Pump with Variable-cross-section Oscillating Vibrator

In the traditional flow-resistance-differential (FRD) type valve-less piezoelectric pump,the generated outflow and pressure are discontinuous because of the inherent periodicity and fluctuation of the pump.To overcome these drawbacks,utilizing the bending vibration of piezoelectric bimorph to drive fluid was conducted.However,our investigation on the current status of this piezoelectric bimorph pump shows that larger driving force and vibration amplitude are required for fluid pumping;the pumping can be realized through the centrifugal force;and the mechanism of fluid pumping is no longer further studied.Based on these cases,the paper designed a piezoelectric-stack pump with variable-cross-section oscillating (VCSO) vibrator by imitating the swing of the caudal-fin of tuna,and the pump is neither the rotating type nor the volumetric type according to the taxonomy.The interaction between the oscillating vibrator and the fluid parcel is firstly analyzed from the viewpoint of momentum conservation,and the analytical expression of pump flow rate is obtained.Then the modal and harmonic response analyses on the vibrator immerged in water are carried out.From the analyses the first two orders resonance frequencies are 832 Hz and 1 939 Hz,respectively,and the peak value of the tip amplitude is 0.6 mm.Laser Doppler vibrometer is used to measure both the frequency and vibration amplitude,and the determined first two orders resonance frequencies are 617 Hz and 1 356 Hz,respectively.The measured tip amplitude reaches to the peak value of 0.3 mm.At last,experimental measurement for the flow rates with different driving frequencies is conducted.The results show that the flow rate can reach 560 mL/min at 1 370 Hz when the pump runs under the backpressure of 30 mm water column.And the flow rate is as much as 560% of that of experiment results carried out by researchers from Brazil.The proposed pump innovates in both theory and taxonomy;in addition,the pump overcomes the drawbacks such as large flow fluctuation and low flow rate in the traditional FRD type pumps,which will help to broaden the application of the valve-less piezoelectric pump.

Shape optimization of the caudal fin of the three-dimensional self-propelled swimming fish

Shape optimization of the caudal fin of the three-dimensional self-propelled swimming fish,to increase the swimming efficiency and the swimming speed and control the motion direction more easily,is investigated by combining optimization algorithms,unsteady computational fluid dynamics and dynamic control in this study.The 3D computational fluid dynamics package contains the immersed boundary method,volume of fluid method,the adaptive multi-grid finite volume method and the control strategy of fish swimming.Through shape optimizations of various swimming speeds,the results show that the optimal caudal fins of different swimming modes are not exactly the same shape.However,the optimal fish of high swimming speed,whose caudal fin shape is similar to the crescent,also have higher efficiency and better maneuverability than the other optimal bionic fish at low and moderate swimming speeds.Finally,the mechanisms of vorticity creation of different optimal bionic fish are studied by using boundary vorticity-flux theory,and three-dimensional wake structures of self-propelled swimming of these fish are comparatively analyzed.The study of vortex dynamics reveals the nature of efficient swimming of the 3D bionic fish with the lunate caudal fin.

NUMERICAL SIMULATION OF THE HYDRODYNAMIC PERFORMANCE OF AN UNSYMMETRICAL FLAPPING CAUDAL FIN

A comprehensive numerical simulation of the hydrodynamic performance of a caudal fin with unsymmetric flapping motion is carried out. The unsymmetrical motion is induced by adding a pitch bias or a heave bias. A numerical simulation program based on the unsteady panel method is developed to simulate the hydrodynamics of an unsymmetrical flapping caudal fin. A CFD code based on Navier-Stokes equations is used to analyze the flow field. Computational results of both the panel method and the CFD method indicate that the hydrodynamics are greatly affected by the pitch bias and the heave bias. The mean lateral force coefficient is not zero as in contrast with the symmetrical flapping motion. By increasing the pitch bias angle, the mean thrust force coefficient is reduced rapidly. By adding a heave bias, the hydrodynamic coefficients are separated as two parts: in one part, the amplitude is the heave amplitude plus the bias and in the other part, it is the heave amplitude minus the bias. Analysis of the flow field shows that the vortex distribution is not symmetrical, which generates the non-zero mean lateral force coefficient.

Using spanwise flexibility of caudal fin to improve swimming performance for small fishlike robots

This paper examines the beneficial effects of the spanwise flexibility of the caudal fin for the improvement of the swimming performance for small fishlike robots. A virtual swimmer is adopted for controlled numerical experiments by varying the spanwise flexible trajectories and the spanwise flexible size of the caudal fin while keeping the body kinematics fixed. 3-D Navier-Stokes equations are used to compute the viscous flow over the robot. Elliptical, parabolic and hyperbola trajectories are chosen to describe the spanwise flexible profile of the caudal fin. According to the sign(positive or negative) of the phase difference of the swinging motion, the spanwise flexibility can be divided into the fin surface of "bow" and the fin surface of "scoop". It is observed that for both the fin surface of "bow" and the fin surface of "scoop", the spanwise elliptical trajectory has the optimal swimming velocity, thrust, lateral force, and efficiency. With comparisons, using the flexible caudal fin with the fin surface of "bow", the lateral force and the power consumption can be reduced effectively and the swimming stability can be increased while reducing little the swimming velocity and thrust. Meanwhile, using the flexible caudal fin with the fin surface of "scoop" can greatly improve the swimming velocity, thrust, and efficiency while increasing part of the lateral force and the power consumption. Three-dimensional flow structures clearly indicate the evolution process around the swimming robot. It is suggested that the fish, the dolphin, and other aquatic animals may benefit their hydrodynamic performance by the spanwise flexibility of the caudal fin.

基于CFD的仿生水动力学数值计算方法及其验证

鱼类经过长期的进化与自然选择,有着优异的水中游动能力,鱼类借助尾鳍能够进行快速高效的定向游动和快速启动/机动,借助胸鳍能够进行前进、后退和灵活的转向。本文基于计算流体力学(CFD)方法,给出适用于求解鱼类尾鳍/胸鳍的刚性运动以及身体躯干的柔性运动的网格划分策略,对仿生尾鳍、仿生胸鳍和仿生鱼在均匀来流中的水动力性能以及仿生鱼在静水中的自主游动进行数值计算。结果表明:基于CFD方法,采用结构与非结构混合的网格划分策略,应用动网格方法能够对仿生鱼的各类鳍及身体躯干的刚性或柔性运动进行有效的模拟,通过与实验结果进行对比,验证了对水动力性能求解的有效性。数值计算方法和验证算例对仿生水动力学的研究具有一定的理论参考意义。

尾鳍摆动推进水动力与流动涡结构特征分析

作为BCF(body-caudalfin)推进模式中的典型代表,金枪鱼游动快,是重要的仿生研究对象之一。本文基于弹性光顺模型和局部网格重构模型动网格技术,建立仿金枪鱼尾鳍摆动推进流场RANS数值计算及涡结构提取分析方法,通过网格无关性验证,并与其它研究结果的比较验证数值计算方法的有效性。对尾鳍摆动推进过程中主要涡结构的产生与演化研究表明,尾鳍摆动推进水动力由St数主控,尾流中环状涡结构呈“之”形交错分布,并且随着St数增加,涡结构逐渐从单列演变成双列,推力系数逐渐增大。

鱼类叉状尾鳍效率转捩点水动力性能研究

鲔科鱼类具有较高的游动速度和游动效率,因此成为了仿生机器鱼的理想生物原型。为了研究鲔科鱼类叉状尾鳍效率转捩点的水动力特征,针对推力和功耗的源项进行重点分析。尾鳍模型采用了相同的表面面积、展弦比和叉长。为了统一尾鳍形状的尺度,采用扫掠角用于表征不同的叉状尾鳍平面结构。研究发现鲔科鱼类尾鳍扫掠角的增加弱化了尾鳍的有效面积,导致了尾鳍摆动时推动流体向下游运动而受到的反作用力降低,因此尾鳍的推进能力也会随之衰退。另外,扫掠角的增加也引起了前缘涡强度的增加和前缘涡的发展,从而造成了更大的涡增推力。然而,过分增加扫掠角尽管存在功耗下降的优势,但也引起推力和水动力效率的下降,特别是对于高斯特劳哈尔数的情况。通过对推力的源项进行分析发现扫掠角对附加质量力和涡增推力存在相反的作用机制。

宽口裂腹鱼尾鳍细胞系的建立及其应用

宽口裂腹鱼为塔里木河水系的特有物种。为建立其尾鳍细胞系,笔者采用组织块法和胰酶消化法相结合,分别用含胎牛血清的DME/F12培养基体外培养尾鳍组织。初步建立宽口裂腹鱼尾鳍细胞系,细胞传代培养至45代。细胞呈悬浮生长,最适培养液为DME/F12,最适胎牛血清质量分数为20%,最适温度为25℃。第10代细胞的群体倍增时间为24.94 h,细胞呈“S”型生长。第6代细胞液氮冷冻保存180 d后复苏,经台盼蓝染色计数,(88.72±0.99)%的宽口裂腹鱼尾鳍细胞系具有活性,复苏后增殖速度快,可正常传代。细菌、真菌、支原体的鉴定未发现污染。第10代细胞线粒体16S rRNA基因测序结果与GenBank中基因序列做一致性对比,宽口裂腹鱼尾鳍细胞系与NC036933.1的一致率达99.91%,从分子水平证明,宽口裂腹鱼尾鳍细胞系来自宽口裂腹鱼。NaCl质量分数为8‰时,宽口裂腹鱼尾鳍细胞系的相对增殖率最高;NaHCO3质量浓度为7 g/L时,宽口裂腹鱼尾鳍细胞系的相对增殖率最高;宽口裂腹鱼尾鳍细胞系的相对增殖率随盐碱度增加呈先升后降趋势。

仿生机器鱼胸尾鳍联动水动力学性能分析

针对尾鳍摆动仿生机器鱼游动迟缓、姿态不稳定的问题,文中提出一种胸尾鳍联动的仿生机器鱼,实现了仿生机器鱼外部轮廓、内部布局设计,提出了仿生机器鱼运动控制系统,为仿真和实验提供硬件基础;改进了仿生机器鱼运动学模型,提出了水动力学仿真中鱼体轮廓改变的运动函数;基于仿生机器鱼游动水动力学仿真分析,得到最优运动参数以及最优运动参数下的应力、流速、涡情况;采用仿真最优胸尾鳍运动幅度结果,改变胸尾鳍运动频率,设计实验研究了仿生机器鱼游动水动力学性能。仿真结果表明,以尾鳍摆动幅度72 mm、胸鳍转动角度水平正负45°、胸尾鳍运动频率均为3 Hz等运动参数进行仿真,无胸鳍辅助游动的推进力为2 N,有胸鳍辅助游动的推进力为2.6 N;实验分析结果表明,以最佳运动参数实验,无胸鳍辅助游动的推进力为1.57 N,有胸鳍辅助游动的推进力为2.57 N。仿真和实验均说明,有胸鳍辅助鱼体游动的推进力更大。

基于双向流固耦合仿真的新月形尾鳍水动力学特性研究

以新月形仿生机器鱼尾鳍为研究对象,基于双向流固耦合仿真技术,研究了新月形仿生机器鱼尾鳍的结构参数和运动参数对其水动力学参数的影响关系。结果表明:增大尾鳍摆角幅度和摆动频率有利于提高推进力,同时也带来了游动的不稳定性;相比于等厚度柔性尾鳍,变厚度柔性尾鳍具有更好的推进性能,符合真实鱼类尾鳍结构特征;柔性大面积新月形尾鳍的推进性能最优。

美洲鲥仔稚鱼脊柱及附肢骨骼系统的早期发育

使用软骨-硬骨双染色技术,描述了美洲鲥(Alosa sapidissima)仔稚鱼(1~51日龄)脊柱、胸鳍、尾鳍、背鳍等附肢骨骼的形态发育特征。结果显示,脊柱的发育开始于10日龄仔鱼尾部的髓弓、脉弓和尾下骨的出现,16日龄髓弓和脉弓延伸形成髓棘和脉棘,19日龄脊柱出现分节的硬骨环,23日龄所有椎体形成。各附鳍支鳍骨发育顺序先后依次为胸鳍、尾鳍、背鳍、臀鳍和腹鳍。胸鳍在2日龄时出现乌喙骨,13日龄形成软骨质的胸鳍支鳍骨,19日龄仔鱼肩带和上匙骨开始骨化;尾鳍的尾下骨最早出现在5日龄,12日龄尾鳍形成2枚尾上骨、1枚尾杆骨和6枚尾下骨,19日龄仔鱼尾椎和尾鳍率先开始骨化,直至23日龄尾鳍骨骼系统钙化完全。最终背鳍和臀鳍分别形成18和22根鳍条。美洲鲥骨骼发育研究对其早期发育功能趋向、环境优化及分类鉴定有重要作用。

仿生鱼鳍运动仿真分析及试验研究

仿生水下推进技术的研究日益受到科研工作者的青睐,尤其是仿生机器鱼的研究日益引起关注。在对柔性长鳍波动推进模型研究的基础上,提出一种尾鳍摆动与长鳍波动组合推进的模型,目的是为了提高已有柔性长鳍波动模型的推进性能。对柔性长鳍波动推进模型和组合推进模型进行介绍,着重利用计算流体动力学方法分别对刚性尾鳍摆动模型和柔性长鳍波动模型进行二维数值计算,并对仿真结果进行对比和分析,对模型进行简易流场显示试验,为进一步研究组合鳍的推进特性奠定了基础,同时便于和今后模型的试验数据进行对比分析。

仿鱼尾潜器推进系统的水动力分析

以开发适用于小型潜器的仿生操纵与推进系统为研究背景 ,对金枪鱼的月牙形尾鳍进行水动力分析。文中将金枪鱼的尾鳍处理为在做横移和摇摆的耦合运动的同时 ,以某一匀速向前运动的月牙形刚性尾翼。计算中应用了双曲面元和压力库塔条件 ,利用面元法计算分析该三维尾翼的非定常水动力性能。探讨了前进速度、横荡和摇首的幅度。