Hydrodynamics of Biomimetic Marine Propulsion and Trends in Computational Simulations

[Abstract] The aim of the present paper is to provide the state of the works in the field of hydrodynamics and computational simulations to analyze biomimetic marine propulsors. Over the last years, many researchers postulated that some fish movements are more efficient and maneuverable than traditional rotary propellers, and the most relevant marine propulsors which mimic fishes are shown in the present work. Taking into account the complexity and cost of some experimental setups, numerical models offer an efficient, cheap, and fast alternative tool to analyze biomimetic marine propulsors. Besides, numerical models provide information that cannot be obtained using experimental techniques. Since the literature about trends in computational simulations is still scarce, this paper also recalls the hydrodynamics of the swimming modes occurring in fish and summarizes the more relevant lines of investigation of computational models

Review of Computational Fluid Dynamics Analysis in Biomimetic Applications for Underwater Vehicles

Biomimetics, which draws inspiration from nature, has emerged as a key approach in the development of underwater vehicles. The integration of this approach with computational fluid dynamics (CFD) has further propelled research in this field. CFD, as an effective tool for dynamic analysis, contributes significantly to understanding and resolving complex fluid dynamic problems in underwater vehicles. Biomimetics seeks to harness innovative inspiration from the biological world. Through the imitation of the structure, behavior, and functions of organisms, biomimetics enables the creation of efficient and unique designs. These designs are aimed at enhancing the speed, reliability, and maneuverability of underwater vehicles, as well as reducing drag and noise. CFD technology, which is capable of precisely predicting and simulating fluid flow behaviors, plays a crucial role in optimizing the structural design of underwater vehicles, thereby significantly enhancing their hydrodynamic and kinematic performances. Combining biomimetics and CFD technology introduces a novel approach to underwater vehicle design and unveils broad prospects for research in natural science and engineering applications. Consequently, this paper aims to review the application of CFD technology in the biomimicry of underwater vehicles, with a primary focus on biomimetic propulsion, biomimetic drag reduction, and biomimetic noise reduction. Additionally, it explores the challenges faced in this field and anticipates future advancements

3D locomotion biomimetic robot fish with haptic feedback

This thesis developed a biomimetic robot fish and built a novel haptic robot fish system based on the kinematic modelling and three-dimentional computational fluid dynamic (CFD) hydrodynamic analysis. The most important contribution is the successful CFD simulation of the robot fish, supporting users in understanding the hydrodynamic properties around it

Developing High Performance Linear Carangiform Swimming

This thesis examines the linear swimming motion of Carangiform fish, and investigates how to improve the swimming performance of robotic fish within the fields of kinematic modeling and mechanical engineering, in a successful attempt to replicate the high performance of real fish. Intensive research was conducted in order to study the Carangiform swimming motion, where observational studies of the common carp were undertaken. Firstly, a full-body length Carangiform swimming motion is proposed to coordinate the anterior, mid-body and posterior displacements in an attempt to reduce the large kinematic errors in the existing free swimming robotic fish. It optimizes the forces around the centre of mass and initiates the starting moment of added mass upstream therefore increasing performance, in terms of swimming speed. The introduced pattern is experimentally tested against the traditional approach (of posterior confined body motion). A first generation robotic fish is devised with a novel mechanical drive system operating in the two swimming patterns. It is shown conclusively that by coordinating the full-body length of the Carangiform swimming motion a significant increase in linear swimming speed is gained over the traditional posterior confined wave form and reduces the large kinematic errors seen in existing free swimming robotic fish (Achieving the cruising speeds of real fish). Based on the experimental results of the first generation, a further three robotic fish are developed: (A) iSplash-OPTIMIZE: it becomes clear that further tuning of the kinematic parameters may provide a greater performance increase in the distance travelled per tail beat. (B) iSplash-II: it shows that combining the critical aspects of the mechanical drive system of iSplash-I with higher frequencies and higher productive forces can significantly increase maximum velocity. This prototype is able to outperform real Carangiform fish in terms of average maximum velocity (measured in body lengths/ second) and endurance, the duration that top speed is maintained. (C) iSplash-MICRO: it verifies that the mechanical drive system could be reduced in scale to improve navigational exploration, whilst retaining high-speed swimming performance. A small robotic fish is detailed with an equivalent maximum velocity (BL/s) to real fish

Hydrodynamics of pitching foils: flexibility and ground effects

En termes de propulsió la rigidesa flexural i l'efecte terra en una placa rectangular en piteig pur han estat investigats. Velocimetria per imatges per partícules, mesures de forces i moments amb una cèl·lula de carga de 6 eixos, mesures de velocitat i adquisició d'imatges de la cinemàtica de la placa han estat realitzades per estudiar els patrons de flux i les forces hidrodinàmiques en plaques de diferent flexibilitat. La presència de la paret va millorar la velocitat de creuer fins a un 25% i l'empenta fins a un 45% per angles escombrats de 160 i 240 graus. El mecanisme físic sota aquest efecte és discutit estudiant els camps de vorticitat produïts per l'estela de l'aleta bioinspirada en un rajiforme. Les forces hidrodinàmiques linkejades a les tècniques de visualització, van permetre calcular eficiències i camps de vorticitat promitjats en fase. Aquestes dades van revelar com l'angle escombrat de la placa juga un paper fonamental en la distribució de moment en l'estela d'una placa rígida per incrementar la propulsió. En termes de rigidesa flexural, l'òptima flexibilitat va ser determinada amb una placa semi-flexible amb una eficiència d'un 69% amb un angle d'atac de 72 graus.En términos de propulsión la rigidez flexural y el efecto suelo en una placa rectangular en puro picheo han sido investigados. Velocimetría de imágenes por partículas, medidas de fuerzas y momentos con una célula de carga de 6 ejes, medidas de velocidad y adquisiciones de imágenes de la cinemática de la placa han sido realizadas para estudiar los patrones de flujo y las fuerzas hidrodinámicas en placas con diferentes flexibilidad. La presencia de la pared mejoró la velocidad de crucero hasta en un 25% y el empuje hasta un 45% para ángulos barridos de 160 y 240 grados. El mecanismo físico bajo este efecto es discutido estudiando los campos de vorticidad producidos por la estela de la aleta bioinspirada en un rajiforme. Las fuerzas hidrodinámicas linkadas a las técnicas de visualización, permitieron calcular eficiencias y campos de vorticidad promediados en fase. Estos datos revelaron como el ángulo barrido de la placa juega un papel fundamental en la distribución de momento en la estela de un foil rígido para incrementar la propulsión. En términos de rigidez flexural la óptima flexibilidad fue determinada con la placa semi-flexible con una eficiencia de un 69% con un ángulo de ataque de 72 grados.The roles of the chordwise flexural stiffness and ground effect in a rectangular plate undergoing in pure pitching motion have been investigated. Digital Particle image velocimetry (DPIV), load measurement with a 6-axes balance, measurements of the swimming speed and image acquisition of the kinematics of the foil have been done to study the flow patterns and hydrodynamics forces around the flapping flexible plates. The presence of the wall enhances the cruising velocity in some cases up to 25% and the thrust by a 45% , for swept angles of 160 and 240°. The physical mechanisms underlying of this effect are discussed by studying the vorticity dynamics in the wake of the foil. Experimental data of the hydrodynamic forces and moments allowed to obtain the efficiencies of the flapping propulsion. These load measurements were linked to the wakes of the flapping foils in order to reveal configurations with higher thrust. The momentum distribution in the wake of the foil has allowed the physical explanation for the cases with highest thrust production capacity. In terms of flexural stiffness, the optimum flexibility has been determined with the semi − flexible plate up to 69% of efficiency under a swept angle of 72 degrees for Re = O(10^4) tested in the investigation

Bio-Inspired Design of Vehicles that Operate in Complex Environments

This dissertation focuses on defining underlying mechanisms to enable the bio-inspired design of aerodynamic and/or hydrodynamic vehicles that operate within complex environments. This dissertation introduces four overarching research gaps found in current bio-inspired design research and four corresponding approach questions that guide the framework of the presented research. This research addresses the issues of a lack in determining “better” inspirational options for designers to use, a lack of automated methods within the field of bio-inspired design, a lack in a mechanical ranking system that is based on biology, and a lack of focus on capability an mobility linking the bio and mechanical world. This dissertation addresses these gaps through approach questions, used to design an Animal Specification Mobility Analysis (ASMA) methodology. This design methodology guides a designer to a potential bio-inspiration using simulations based on measurable specifications. These specifications help determine a score that represents the functionality of an animal within an environment. These scores supplement rank-able mobility characteristics that mathematically define what an animal may be capable of in terms of movement. The presented methodology is validated through three types of bio-inspired scenarios, each representing the current types of bio-inspired design processes