An Experimental and Simulation Study of the Active Camber Morphing Concept on Airfoils Using Bio-Inspired Structures

Dharmdas, Alexsteven; Patil, Arun Y.; Baig, Azar; Hosmani, Owais Z.; Mathad, Shridhar N.; Patil, Mallikarjunagouda B.; Kumar, Raman; Kotturshettar, Basavaraj B.; Fattah, Islam Md Rizwanul

doi:10.3390/biomimetics8020251

Cited by 8 publications

(7 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In accordance with the assumptions of Section 3, the computation of the dynamics of the manta robot consists of two following initial value problems (IVP): (1). the passive tree-like PRB dynamics ruling the internal flexible fin motions; (2).…”

Section: Computational Aspect Of Flexible-rigid Coupling System Based...mentioning

confidence: 99%

See 1 more Smart Citation

A Rigid-Flexible Coupling Dynamic Model for Robotic Manta with Flexible Pectoral Fins

Qu,

Xie,

Zhang

et al. 2024

JMSE

View full text Add to dashboard Cite

The manta ray, exemplifying an agile swimming mode identified as the median and paired fin (MPF) mode, inspired the development of underwater robots. Robotic manta typically comprises a central rigid body and flexible pectoral fins. Flexible fins provide excellent maneuverability. However, due to the complexity of material mechanics and hydrodynamics, its dynamics are rarely studied, which is crucial for the advanced control of robotic manta (such as trajectory tracking, obstacle avoidance, etc.). In this paper, we develop a multibody dynamic model for our novel manta robot by introducing a pseudo-rigid body (PRB) model to consider passive deformation in the spanwise direction of the pectoral fins while avoiding intricate modeling. In addressing the rigid-flexible coupling dynamics between flexible fins and the actuation mechanism, we employ a sequential coupling technique commonly used in fluid-structure interaction (FSI) problems. Numerical examples are provided to validate the MPF mode and demonstrate the effectiveness of the dynamic model. We show that our model performs well in the rigid-flexible coupling analysis of the manta robot. In addition to the straight-swimming scenario, we elucidate the viability of tailoring turning gaits through systematic variations in input parameters. Moreover, compared with finite element and CFD methods, the PRB method has high computational efficiency in rigid-flexible coupling problems. Its potential for real-time computation opens up possibilities for future model-based control.

show abstract

Section: Computational Aspect Of Flexible-rigid Coupling System Based...mentioning

confidence: 99%

“…Bionic underwater robots have presented several desired properties, gradually becoming a rapidly evolving research area in recent years [1,2]. Unlike ordinary underwater vehicles, these bio-inspired robots achieve propulsion through the undulating motion of their flexible bodies and fins.…”

Section: Introduction 1manta Robotmentioning

confidence: 99%

A Rigid-Flexible Coupling Dynamic Model for Robotic Manta with Flexible Pectoral Fins

Qu,

Xie,

Zhang

et al. 2024

JMSE

View full text Add to dashboard Cite

show abstract

“…Robotics for flight is a popular topic of research. For mechanical wing systems, the behavior of birds in adapting to their wing morphologies has been mimicked to maximize aerodynamics under different flight conditions [18]. The leg and claw structures of birds are also a common inspiration for designing landing and takeoff mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Design and Assessment of Bird-Inspired 3D-Printed Models to Evaluate Grasp Mechanics

Senthil,

Vishanagra,

Sparkman

et al. 2024

Biomimetics

View full text Add to dashboard Cite

Adapting grasp-specialized biomechanical structures into current research with 3D-printed prostheses may improve robotic dexterity in grasping a wider variety of objects. Claw variations across various bird species lend biomechanical advantages for grasping motions related to perching, climbing, and hunting. Designs inspired by bird claws provide improvements beyond a human-inspired structure for specific grasping applications to offer a solution for mitigating a cause of the high rejection rate for upper-limb prostheses. This research focuses on the design and manufacturing of two robotic test devices with different toe arrangements. The first, anisodactyl (three toes at the front, one at the back), is commonly found in birds of prey such as falcons and hawks. The second, zygodactyl (two toes at the front, two at the back), is commonly found in climbing birds such as woodpeckers and parrots. The evaluation methods for these models included a qualitative variable-object grasp assessment. The results highlighted design features that suggest an improved grasp: a small and central palm, curved distal digit components, and a symmetrical digit arrangement. A quantitative grip force test demonstrated that the single digit, the anisodactyl claw, and the zygodactyl claw designs support loads up to 64.3 N, 86.1 N, and 74.1 N, respectively. These loads exceed the minimum mechanical load capabilities for prosthetic devices. The developed designs offer insights into how biomimicry can be harnessed to optimize the grasping functionality of upper-limb prostheses.

show abstract

“…Natural composites provide an excellent template of tightly balanced design traits optimized over several millennia through evolutionary forces [35,36]. Bioinspired features have guided the development of multiple engineered solutions in recent years [37][38][39]. In the context of 2D natural systems, layered architecture with carefully designed interfaces is the hallmark of many natural composites, allowing them to achieve strength and functionality far exceeding their constituents [35,36].…”

Section: Introductionmentioning

confidence: 99%

Bioinspired Design Rules from Highly Mineralized Natural Composites for Two-Dimensional Composite Design

Prasad,

Varshney,

Nepal

et al. 2023

Biomimetics

View full text Add to dashboard Cite

Discoveries of two-dimensional (2D) materials, exemplified by the recent entry of MXene, have ushered in a new era of multifunctional materials for applications from electronics to biomedical sensors due to their superior combination of mechanical, chemical, and electrical properties. MXene, for example, can be designed for specialized applications using a plethora of element combinations and surface termination layers, making them attractive for highly optimized multifunctional composites. Although multiple critical engineering applications demand that such composites balance specialized functions with mechanical demands, the current knowledge of the mechanical performance and optimized traits necessary for such composite design is severely limited. In response to this pressing need, this paper critically reviews structure–function connections for highly mineralized 2D natural composites, such as nacre and exoskeletal of windowpane oysters, to extract fundamental bioinspired design principles that provide pathways for multifunctional 2D-based engineered systems. This paper highlights key bioinspired design features, including controlling flake geometry, enhancing interface interlocks, and utilizing polymer interphases, to address the limitations of the current design. Challenges in processing, such as flake size control and incorporating interlocking mechanisms of tablet stitching and nanotube forest, are discussed along with alternative potential solutions, such as roughened interfaces and surface waviness. Finally, this paper discusses future perspectives and opportunities, including bridging the gap between theory and practice with multiscale modeling and machine learning design approaches. Overall, this review underscores the potential of bioinspired design for engineered 2D composites while acknowledging the complexities involved and providing valuable insights for researchers and engineers in this rapidly evolving field.

show abstract

An Experimental and Simulation Study of the Active Camber Morphing Concept on Airfoils Using Bio-Inspired Structures

Cited by 8 publications

References 45 publications

A Rigid-Flexible Coupling Dynamic Model for Robotic Manta with Flexible Pectoral Fins

A Rigid-Flexible Coupling Dynamic Model for Robotic Manta with Flexible Pectoral Fins

Design and Assessment of Bird-Inspired 3D-Printed Models to Evaluate Grasp Mechanics

Bioinspired Design Rules from Highly Mineralized Natural Composites for Two-Dimensional Composite Design

Contact Info

Product

Resources

About