Locomotion Of Bioinspired Underwater Soft Robots With Structural Compliance

Locomotion of Bioinspired Underwater Soft Robots with Structural Compliance

Author : Michael Ishida

Publisher :

Page : 0 pages

File Size : 17,71 MB

Release : 2022

Category :

ISBN :

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Book Description

Mobile robots are commonly used to perform tasks in underwater environments that are difficult for humans to endure, such as exploration, long-duration measurements, or maintenance and repair of underwater structures. Traditional underwater robots are often bulky and disruptive to the environment around it and are often adapted from engineered systems that were designed for operation in air. However, the underwater fluid environment is significantly different from the in-air environment and motivates the development of new robot paradigms specifically to address the challenges that arise from the surrounding water. I have taken inspiration from nature, which has evolved fast and efficient mechanisms for underwater locomotion, to design soft, bioinspired walking and swimming robots. In this work, I have explored several ways to design mobile robots specifically for the underwater fluid environment. To mitigate the negative effects of flow on an underwater walking robot, I created a soft inflatable structure that can be attached to the robot to alter the lift and drag forces on the robot and increase traction in flow. To create locomotion independent of the flow on the robot, I designed soft suction discs and soft linear actuators that enable adhesive-based locomotion. By leveraging interactions with fluid, I created a steerable, shape-changing robot that uses vectored jet propulsion to swim through open water. This work has the potential to enable more efficient locomotion in underwater environments more closely resembling the capabilities of biological systems.



Bioinspired Sensing, Actuation, and Control in Underwater Soft Robotic Systems

Author : Derek A. Paley

Publisher : Springer Nature

Page : 301 pages

File Size : 19,83 MB

Release : 2020-11-06

Category : Technology & Engineering

ISBN : 303050476X

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Book Description

This book includes representative research from the state‐of‐the‐art in the emerging field of soft robotics, with a special focus on bioinspired soft robotics for underwater applications. Topics include novel materials, sensors, actuators, and system design for distributed estimation and control of soft robotic appendages inspired by the octopus and seastar. It summarizes the latest findings in an emerging field of bioinspired soft robotics for the underwater domain, primarily drawing from (but not limited to) an ongoing research program in bioinspired autonomous systems sponsored by the Office of Naval Research. The program has stimulated cross‐disciplinary research in biology, material science, computational mechanics, and systems and control for the purpose of creating novel robotic appendages for maritime applications. The book collects recent results in this area.



Robot Fish

Author : Ruxu Du

Publisher : Springer

Page : 380 pages

File Size : 31,88 MB

Release : 2015-05-06

Category : Technology & Engineering

ISBN : 3662468700

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Book Description

This book provides a comprehensive coverage on robot fish including design, modeling and optimization, control, autonomous control and applications. It gathers contributions by the leading researchers in the area. Readers will find the book very useful for designing and building robot fish, not only in theory but also in practice. Moreover, the book discusses various important issues for future research and development, including design methodology, control methodology, and autonomous control strategy. This book is intended for researchers and graduate students in the fields of robotics, ocean engineering and related areas.



Actuation for Bioinspired, Soft, Swimming Robots

Author : Caleb Christianson

Publisher :

Page : 120 pages

File Size : 33,28 MB

Release : 2019

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ISBN :

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Book Description

It is often impractical or dangerous to send people to explore underwater environments. In these situations, it is preferable to send robots such as autonomous underwater vehicles or remotely operated vehicles instead. Unfortunately, robots impart their own risks: they are typically made of rigid materials that can become lodged in confined spaces or harm underwater creatures and structures. Additionally, propellers or jet thrusters are typically used for propulsion, which are power intensive, have low efficiency, and impose additional concerns of entanglement and damage to their environment. Finally, they generate considerable noise and vibration, thus adding to the ambient noise pollution and disturbing sea life, preventing researchers from being able to study more timid animals. In this dissertation, I describe physical mechanisms to develop bioinspired, soft, swimming robots with an emphasis on actuation. First, I present an approach to use an arrangement of six artificial muscles based on dielectric elastomer actuators (DEAs) to actuate a tethered robot capable of anguilliform-inspired locomotion. Next, I demonstrate pulsatile, jellyfish-inspired locomotion using DEAs with a simpler actuation and control strategy, enabling an untethered, soft, swimming robot. Finally, I explore an alternative actuation approach to achieve more robust locomotion in a cephalopod-inspired robot based on slowly storing elastic energy and then quickly releasing it to eject a pulsed jet for propulsion. The first two robots are silent and use actuators that have a high energy density and efficiency, but provide low output power and swim at low speeds. In the cephalopod-inspired robot, we trade silence and efficiency for power and speed. These results demonstrate actuation strategies for realizing bioinspired locomotion in soft, swimming robots that could be useful for structural diagnostics, environmental monitoring, or search and rescue.



Tailoring Artificial Muscles for the Design and Development of Soft Underwater Robots

Author : Yara Almubarak

Publisher :

Page : 0 pages

File Size : 44,24 MB

Release : 2021

Category : Artificial limbs

ISBN :

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Book Description

Soft robots made out of highly deformable materials have many degrees of freedom similar to animals found in nature, and such robots are essential for numerous applications in harsh environments. Recently, soft robots are favored over rigid structures for their highly compliant material, high deformation properties at low forces and ability to operate in difficult (high pressure) environments. However, it is challenging to fabricate complex designs that satisfy application constraints due to the combined effects of material properties, actuation method, and structural geometry on the performance of the soft robot. Therefore, a robot must be comprised of both rigid and soft materials to achieve complex body morphologies. Specifically, underwater exploration or inspection requires suitable robotic systems capable of maneuvering, manipulating objects, and operating untethered in complex environmental conditions. Traditional robots have been used to perform many tasks underwater. However, they have limited degrees of freedom, limited manipulation capabilities, and have disruptive interactions with aquatic life. Research in biomimetic soft robotics seeks to incorporate the natural flexibility and agility of aquatic species into man-made technologies to improve its current capabilities. In this dissertation, we present different robotic structures for use in various exploratory and transportation missions. First, we start by characterizing unconventional artificial muscles used as the main actuators in the robots such as the twisted and coiled polymer fishing line (TCPFL) and NiTi shape memory alloy (SMA) actuators. As compared to current conventional actuators such as stepper motors and pnuematic systems, artificial muscles play a vital role in soft robotics due to their compliance, high strain, light weight, and low noise. Second, we show the design and testing of a fully functioning jellyfish like robot (Kryptojelly) that is capable of performing multidirectional swimming utilizing NiTi SMA actuators. Kryptojelly is a 260 mm bell diameter robot, constructed from a 3D printed rigid structure and a soft silicone bell that closely mimics the biological locomotion and appearance of a jellyfish species known as Chrysaora which has long tentacles. Third, an octopus-like robot (Kraken) having a 250 mm size dome, is presented that utilizes a hybrid actuation technology consisting of stepper motors and twisted and coiled polymer fishing line muscles (TCPFL). Kraken is equipped with interchangeable arm configurations that are actuated by both TCP muscles and stepper motors. We show Kraken operating wirelessly underwater in a swimming pool. Its soft arm structure helps grasp irregular objects underwater delicately. Fourth, we present a functionally graded (FGM) multidirectional 3D printed joint like soft robotic structure. The 3D printed structure is made of three rigid ball and socket joints connected in series, and actuated by twisted and coiled polymer fishing line (TCPFL) actuators, which are confined in the FGM accordion shaped channels. The FGM multidirectional joint is characterized and is shown performing different functionalities silently such as crawling, rolling, and bending while a camera is mounted at the tip of the structure. Moreover, experimental results of Kryptojelly performing underwater transportation tasks is demonstrated by picking a 70g object through electromagnet atatched to the robot. Swimming speeds of the robot while carrying trasporting tools are analyzed and presented, which is an effort to use soft robots in underwater repair tasks. Lastly, a simplified predictive model of the fishing line artificial muscles based on heat transfer is presented to estimate the actuation temperature and strain considering material properties, geometry and input parameters and validating the model results with experimental results. The work presented in this dissertation attempts to address the fundamental problems in actuation and design of soft robots and shows the great potential of employing artificial actuators in biomimetic soft robots, which can be deployed for eco-friendly exploratory missions or other applications.



Physical Origin of Biological Propulsion and Inspiration for Underwater Robotic Applications

Author : Xinghua Jia

Publisher :

Page : 198 pages

File Size : 50,93 MB

Release : 2017

Category :

ISBN :

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Book Description

Robotic design, especially in underwater robots, is critical to research, national defense, deep sea exploration and sea disaster rescue. Developing an advanced underwater robot, however, is complicated, as it involves propulsion, depth regulation, motion between propellers and other auxiliary system coordination, as well as sensing and feedback signals synchronization. Additionally, it is more challenging to manage the aquatic environment and guarantee the robotic design. In particular, the propulsion system could fit well in this environment and allow for efficient swimming. These challenges make the development of an underwater robot much more difficult, and finding the best solutions to building a robot in a standard and robust manner is critical to satisfying the large amount of requirements of the underwater robots in different perspectives. Aquatic creatures have developed swimming capabilities far superior in many ways to what has been achieved by nautical science and technology and have inspired alternative ideas of developing smart and advanced novel robotic mechanisms for propulsion in different fluid environments. Many bioinspired aquatic robots mimic the structure design, locomotion behaviors and even control method of their counterparts in nature and achieved great swimming performance. The further development of a more general design methodology for bioinspired underwater robots, however, has been impeded due to the diversity of biological sources for underwater propulsion. Consequently, there have been several studies attempting to understand basic propulsion principles to synchronize the biological diversity. In this dissertation, we first review the current stages and challenges of design of underwater robots. Afterwards, we provided a methodology for the design of efficient underwater robots from a biological perspective at multiple scales. To achieve this goal, we introduced the unique propulsion features of aquatic species in terms of locomotion mechanism as the swimmer increased in size from the micro/nanoscale to the macro-scale. Then, we discussed the biological propulsion principles for aquatic robotic design, including design of propeller, body, propulsion appendages, locomotion control and auxiliary system. In addition, we introduced the method for the implementation of bioinspired robots, including mechanical design, electronic engineering and system integration (Chapter 1). The following chapters show that four aquatic robots from the micro/nanoscale to the macro-scale were designed by learning unique features from biology and providing specific investigation of propulsion principle for robotic design at each scale. We validated and demonstrated the design of each robot using both mathematical model based simulation and hardware implemented robot experiments. In chapter 2, propulsion was investigated at micro/nanoscale (body length10-2m). Due to the constraints imposed at micro/nanoscale which has low Reynolds number (Re



Between Sea and Sky: Aerial Aquatic Locomotion in Miniature Robots

Author : Raphael Zufferey

Publisher : Springer

Page : 0 pages

File Size : 35,9 MB

Release : 2023-01-05

Category : Technology & Engineering

ISBN : 9783030895778

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Book Description

This book reports on the state of the art in the field of aerial-aquatic locomotion, focusing on the main challenges concerning the translation of this important ability from nature to synthetic systems, and describing innovative engineering solutions that have been applied in practice by the authors at the Aerial Robotics Lab of Imperial College London. After a general introduction to aerial-aquatic locomotion in nature, and a summary of the most important engineering achievements, the book introduces readers to important physical and mathematical aspects of the multimodal locomotion problem. Besides the basic physics involved in aerial-aquatic locomotion, the role of different phenomena happening in fluids, or those due to structural mechanics effects or to power provision, are presented in depth, across a large dimension range, from millimeters to hundreds of meters. In turn, a practice-oriented discussion on the obstacles and opportunities of miniaturization, for both robots and animals is carried out. This is followed by applied engineering considerations, which describe relevant hardware considerations involved in propulsion, control, communication and fabrication. Different case studies are analyzed in detail, reporting on the latest research carried out by the authors, and covering topics such as propulsive aquatic escape, the challenging mechanics of water impact, and a hybrid sailing and flying aircraft. Offering extensive and timely information on the design, construction and operation of small-scale robots, and on multimodal locomotion, this book provides researchers, students and professionals with a comprehensive and timely reference guide to the topic of aerial-aquatic locomotion, and the relevant bioinspired approaches. It is also expected to inspire future research and foster a stronger multidisciplinary discussion in the field.



Embedded TCP and SMA Actuators for Use in Flexible Structures of Bioinspired Robots and Humanoids

Author : Yara Abdulsattar Almubarak

Publisher :

Page : pages

File Size : 26,38 MB

Release : 2018

Category : Androids

ISBN :

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Book Description

Soft robots consist of elastomeric materials, compliant actuators, and sensors that enable them to be used for numerous applications due to their flexibility, lightweight, and many degrees of freedom. Many actuators such as pneumatic actuators and servomotors introduce many design constraints due to their size, weight, and cost. Moreover, vibration and noise are undesired attributes that preclude the use of the robot. Smart materials play a vital role in the field of soft robotics since they can be used as sensors and actuators. This thesis presents the design and characterization of three robotic structures that are actuated by twisted and coiled polymer (TCP) muscles and shape memory alloys (SMA). First, a soft silicone skin embedded with TCP muscles that shows two unique modes of actuation is presented. The two actuation modes (undulatory and bending) depend on the muscle placement, skin thickness, applied voltage, and actuation time. Second, a humanoid head actuated using fully embedded TCP muscles featuring basic facial expressions, head nodding and jaw movement is presented. Third, an underwater jellyfish-like robot actuated by SMA muscles is developed. Several studies for the bell segment actuation were conducted to determine the influence of power input, bell geometry, and number of spring steels embedded within the elastomer. Studying these different application domains experimentally plays an important role in gaining new knowledge on design, fabrication, and performance of smart materials and soft robots.



From Cell to Robot

Author : Jörg Bandura

Publisher : Sudwestdeutscher Verlag Fur Hochschulschriften AG

Page : 108 pages

File Size : 47,24 MB

Release : 2015-12-02

Category :

ISBN : 9783838151564

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Book Description

Bionics or biomimetics is an interdisciplinary scientific approach to apply naturally developed biological systems, methods and solutions to the study and design of technology as an exclusive mutuality between life sciences and technology sciences, such as robotics. Robots are artificial agents which have much in common with biological agents in case of the need to adapt to their environment. Soft robots have a rather flexible skin or shape, propulsing itself with some type of crawling movement and are able to deform and adapt to obstacle, which is advantageous over classical wheeled or legged propulsion. Most of bio-inspired climbing robots have the disadvantage of using legs for locomotion. The idea is to find a new biological model for a bi-inspired robotic locomotion device. Surprisingly, single cells, such as amoebae or animal tissue cells have a deformable shape and the ability to crawl on surfaces by adhesion. A perfect model for a new bio-inspired locomotion device. This book demonstrates that it is possible to transfer the biophysical locomotion mechanism of cell migration to a computational simulation model of a soft robot with a crawling cell like locomotion.



Proceedings of 2022 International Conference on Autonomous Unmanned Systems (ICAUS 2022)

Author : Wenxing Fu

Publisher : Springer Nature

Page : 3985 pages

File Size : 42,91 MB

Release : 2023-03-10

Category : Technology & Engineering

ISBN : 981990479X

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Book Description

This book includes original, peer-reviewed research papers from the ICAUS 2022, which offers a unique and interesting platform for scientists, engineers and practitioners throughout the world to present and share their most recent research and innovative ideas. The aim of the ICAUS 2022 is to stimulate researchers active in the areas pertinent to intelligent unmanned systems. The topics covered include but are not limited to Unmanned Aerial/Ground/Surface/Underwater Systems, Robotic, Autonomous Control/Navigation and Positioning/ Architecture, Energy and Task Planning and Effectiveness Evaluation Technologies, Artificial Intelligence Algorithm/Bionic Technology and Its Application in Unmanned Systems. The papers showcased here share the latest findings on Unmanned Systems, Robotics, Automation, Intelligent Systems, Control Systems, Integrated Networks, Modeling and Simulation. It makes the book a valuable asset for researchers, engineers, and university students alike.