Download or read book Design of a Single degree of freedom Exoskeleton for Thumb Rehabilitation in Conjunction with FINGER written by Kyle J. Morse and published by . This book was released on 2015 with total page 140 pages. Available in PDF, EPUB and Kindle. Book excerpt: This thesis presents the development of an exoskeleton for post-stroke thumb rehabilitation. This exoskeleton is a six-bar planar single-degree-of-freedom mechanism that controls the position and angle of the middle phalanx of the thumb. It is an add-on for the finger rehabilitation device FINGER for grasp training, which is a fundamental activity of daily living. The trajectory of the middle phalanx of a healthy human thumb was characterized with color-marker based motion tracking. Mechanisms were synthesized by minimizing the error between the end-effector of the mechanism solutions and the trajectory of the thumb. A mechanism solution was selected for design based on its manufacturability and mechanical advantage. Both the mechanism and an adjustable module to attach the mechanism to the housing for FINGER were designed, then manufactured using a combination of additive manufacturing and CNC machining. This provided a prototype for evaluation to inform future design efforts.

Download or read book Dual Reconfigurable Exoskeleton Hand System with Opposable Thumbs written by Peter Walker Ferguson and published by . This book was released on 2022 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Between a global pandemic, aging population, and labor shortages, there is an ongoing spike in the demand for healthcare that cannot be satisfied with traditional methods and the human workforce. Robotic technology offers a solution to this dilemma; applying robotics to healthcare is an active area of research that has begun to be widely commercialized. Whilethere are many potential avenues for robots to improve health and well-being, my research has focused on two areas in particular: the development of robotic hand exoskeletons for rehabilitation and the enhancement of robotic surgery via automation and sensor development. Exoskeletons have been shown to be effective for use in physical rehabilitation of numerous conditions including spinal cord injury and stroke. However, at present, the huge majority of exoskeleton systems are constructed for only the arm (from shoulder to wrist), back, lower limbs, or hands. Few systems have been developed that combine both full arm and hand systems, and those that do generally have limited actuation of the hand. This is partly because the mechanical complexity of the hand requires rigid hand exoskeletons to be complex and bulky if they are able to control many of the important degrees of freedom. This bulk and complexity makes the hand systems challenging to successfully integrate onto the distal end of an arm exoskeleton. However, there is significant demand for combined arm and hand rehabilitation exoskeletons because many activities of daily living, that physical therapy focuses on retraining, require reaching and grasping together. The overarching goals of this research are to develop a novel hand exoskeleton, experimentally evaluate its capabilities in preparation for application to stroke rehabilitation, and integrate it on the existing EXO-UL8 and concurrently developed BLUE SABINO upper limb exoskeleton systems. Chapter 1 provides an introduction on hand exoskeleton systems, with a focus on those designed for rehabilitation. My work on hand exoskeletons started by inheriting a hand exoskeleton mechanical design from Brando Dimapasoc, a graduating Master's Degree student, that was developed as part of NSF Award #1532239. The system was intended to be attached to the EXO-UL8 and BLUE SABINO arm exoskeletons, had six active and six passive degrees of freedom, had three reconfigurable linkages to control the thumb and two groupings of fingers, used a bowden cable transmission system to enable remote placement of actuators, and was optimized to fit 90% of the general population. However, the design had only been tested as a 3D-printed prototype in a modified and simplified form. Further, the necessary electronic hardware (other than motor and sensor selection) and control software had not been started. Thus, the first stage of my research was to bring this first-generation hand exoskeleton to a functional state. This involved the mechanical assembly, the electrical design and assembly, and the software and control development of the system. Through testing, it was determined that a significant number of improvements must be made to the system in order for it to be suitable for use. Details of this work are contained in Chapter 2. With the lessons learned from development and testing of the first-generation hand exoskeleton, the next stage of my research involved the nearly complete redesign of the system in order to create the second-generation hand exoskeleton named the "Opposable-Thumb Hand Exoskeleton for Rehabilitation" or "OTHER Hand". As the name implies, the system is designed to control opposition/reposition of the thumb in addition to the flexion/extension of each digit. This is a notable feature, not only because of the importance of opposition/reposition in many grasping tasks, but also because only a handful of exoskeletons in the literature control this motion. The OTHER Hand shares a number of features with the first generation system, though the execution of each is different. It attaches to both the EXO-UL8 and BLUE SABINO arm exoskeletons, is actuated using a Bowden Cable transmission such that the motor pack can be located remotely, has three reconfigurable linkages to control the thumb and two groupings of fingers in order to enable nearly all grasps, and is optimized to fit 90% of the population. The system has six active and eight passive degrees of freedom per hand. Chapter 3 documents the design of the OTHER Hand. Due to the numerous novel design choices made for the OTHER Hand, combined with the mechanical complexity of the hand in general, and thumb in particular, it is not feasible to know with certainty the types of grasps that can be actuated in the exoskeleton for the wide range of hand shapes and sizes. As such, it is necessary to validate the design of the OTHER Hand through testing with a group of subjects. This was accomplished through adaptation of the Anthropomorphic Hand Assessment Protocol for use with an exoskeleton to test the ability of thirteen subjects to grasp and manipulate 25 objects of the Yale-Carnegie Mellon-Berkeley Object Set using eight prehensile grasps and two non-prehensile hand postures. Additionally, the OTHER Hand was mounted on the EXO-UL8, and both systems were manually controlled to verify compatibility, workspace, and ability to bi-manually grasp a sample object. Chapter 4 presents the testing protocol and results. While exoskeletons for rehabilitation is an increasingly popular research area, robotic surgical platforms already have widespread commercial use and profound effects on clinical outcomes. Classically, these systems are controlled directly by a surgeon at a console in the same or adjacent room. They can augment the senses and movement precision of the surgeon during open or laparoscopic surgery in order to enhance the surgeon's skills. However, surgeons commonly work exceptionally long hours in an environment where a single mistake can be fatal. Additionally, certain surgical subtasks are time-consuming, repetitive, and common to many different operations. Automating these subtasks has the potential to reduce the burden on surgeons while standardizing outcomes. Automation of one such subtask, soft tissue manipulation, is described in Chapter 5. Cataract surgery ranks among the most common operating room procedures worldwide. The aim of the surgery is to replace the clouded biological lens with a clear synthetic lens. Despite the prevalence, this operation is currently performed manually by a surgeon, and generally is fast, standardized, and safe. However, the human body is notably non-optimal for performing cataract surgery due to the transparency and fragility of the tissues of the eye. In order to remove the lens, it is standard to break it apart with phacoemulsification, use an irrigation/aspiration handpiece to aspirate the lens material, and then polish any remaining lens material from the capsular bag. Unfortunately, the back of this bag, the posterior capsule, is transparent, mere microns thin, and easily ruptured from contact, ultrasound energy, or pressure. Rupturing the posterior capsule causes the vitreous of the inner eye to spill out, resulting in critical failure of the surgery. Additional information about the location of the tool tip within the eye could be used to reduce the risk of such a failure. To this end, a proof-of-concept modification of a tool to add bioelectrical impedance sensing and tissue classification was developed and tested on porcine eyes. This research is summarized in Chapter 6

Download or read book Design and Development of a Portable Five fingered Hand Rehabilitation Exoskeleton written by Harish Devaraj and published by . This book was released on 2012 with total page 328 pages. Available in PDF, EPUB and Kindle. Book excerpt: The aim of this thesis is to present a low cost, lightweight and portable five-fingered hand exoskeleton in order to help post-stroke patients regain and improve their somatic motor functions. Human hands are the most dexterous and the most versatile part of the human body. The complexity of the hand anatomical structure as well as its wide range of Degrees of Freedom (DOF) capabilities makes the development of a rehabilitation hand exoskeleton highly demanding and challenging. The proposed five-fingered hand exoskeleton integrates three major modules: finger modules, dorsal plate module and actuator housing. The finger modules, stereo-lithographed from epoxy resin and laser cut from aluminum sheets, are assembled on to the dorsal plate module laser cut from Perspex, thereby placing a robust yet lightweight system over the patient's hand. The movements of these finger modules are achieved by implementing pneumatic artificial muscles (air muscles) with antagonist springs to keep each air muscle in extended state. These air muscles are mounted on an aluminum actuator housing designed to be worn around the forearm. A pair of air muscles controls each of the finger modules with the exception of the thumb module which is actuated by a linear actuator and air muscle simultaneously. When actuated, the linear pull of the air muscles is translated to flexion of the finger modules by means of braided dial cords analogous to the tendon muscles. Elastomers present in the upper surface of the finger modules cause finger extension and at the same time maintains the tendon cable tension with minimal impact on actuator performance. The interphalangeal joints are coupled together and are actuated simultaneously by a single air muscle while the second air muscle actuates the metacarpophalangeal joint. Integrated with the air musclespring assembly, a novel polypyrrole based strain sensor provides feedback on the orientation of the finger modules. The user interacts with the hand exoskeleton via a LabVIEW based Graphical User Interface (GUI). A PID controller embedded within the LabVIEW program controls the rate of finger module movements. The hardware linking the LabVIEW GUI with the exoskeleton system includes data acquisition device, electronic interface circuitry and a set of electro-pneumatic pressure regulating valves. The prototype's effectiveness testing covered joint motion analysis, positional capabilities, range of motion measurements and other factors that validate the usage of exoskeleton as a safe and reliable rehabilitation device. With an effectiveness of up to 81%, this work validates the prototype as a possible rehabilitation device.

Download or read book Additions and Improvements to the Mechanical Design of the FINGER Exoskeleton written by Marshall O. Townsend and published by . This book was released on 2020 with total page 70 pages. Available in PDF, EPUB and Kindle. Book excerpt: Rehabilitation robots are important tools for post stroke movement training and efficacy quantification. The Finger INdividuating Grasp and Exercise Robot (FINGER) is a robotic exoskeleton designed to administer and study finger movement training. Developed nearly a decade ago and used for numerous investigative studies, the FINGER exoskeleton is currently in the process of being updated. This thesis covers design improvements to the FINGER 8-bar mechanisms, development of novel finger cuffs, and initial solid-model design prototyping of a spherical 5-bar mechanism for thumb training. The 8-bar mechanisms that FINGER uses to actuate the index and middle fingers were redesigned with thicker links to increase rigidity and to reduce high stress concentrations. The joints of the mechanism were modified to use larger bearings with an extended inner race, allowing them to be easily spaced without the need for shims. The mechanism was also modified to extend an additional fifteen degrees to allow the user to fully open their index and middle fingers. Feedback from patients and clinicians about the fit and function of FINGER has been used to redesign the finger cuffs to be more comfortable, and to be easier to don and doff. This was achieved by adding BOA℗ʼ ratchet dials which use braided metal cables that size the cuffs; the cables loop over a hook on the opposite side. The cable is covered by a leather strap which increases comfort, keeps the cable properly aligned, and prevents direct contact between the cable and the skin. Thumb trajectory information, recorded using a marker-based motion capture system, was used for the kinematic design of a spherical 5-bar mechanism. This mechanism will be actuated by the same linear actuators as FINGER, which are fixed to a platform on which FINGER is secured. A proposed design, including the location of these actuators, is presented. The thumb is connected to the mechanism through a cuff with a BOA℗ʼ dial and a leather strap, similar to the finger cuffs. The thumb cuff rotates freely so the thumb can assume a comfortable orientation.

Download or read book The Human Hand as an Inspiration for Robot Hand Development written by Ravi Balasubramanian and published by Springer. This book was released on 2014-01-03 with total page 573 pages. Available in PDF, EPUB and Kindle. Book excerpt: “The Human Hand as an Inspiration for Robot Hand Development” presents an edited collection of authoritative contributions in the area of robot hands. The results described in the volume are expected to lead to more robust, dependable, and inexpensive distributed systems such as those endowed with complex and advanced sensing, actuation, computation, and communication capabilities. The twenty-four chapters discuss the field of robotic grasping and manipulation viewed in light of the human hand’s capabilities and push the state-of-the-art in robot hand design and control. Topics discussed include human hand biomechanics, neural control, sensory feedback and perception, and robotic grasp and manipulation. This book will be useful for researchers from diverse areas such as robotics, biomechanics, neuroscience, and anthropologists.

Download or read book Mechanism and Machine Science written by Dibakar Sen and published by Springer Nature. This book was released on 2020-07-01 with total page 873 pages. Available in PDF, EPUB and Kindle. Book excerpt: This volume presents select papers from the Asian Conference on Mechanism and Machine Science 2018. This conference includes contributions from both academic and industry researchers and will be of interest to scientists and students working in the field of mechanism and machine science.

Download or read book Design and Implementation of a Computer Controlled Three Degree of freedom Robot Finger written by Lynn Christine Cameron and published by . This book was released on 1988 with total page 132 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book DESIGN AND DEVELOPMENT OF LOW COST HAND FINGER EXOSKELETON FOR REHABILITATION OF STROKE PATIENT written by WALEED RAUF (TP024225) and published by . This book was released on 2016 with total page 99 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Robotic slave hand thumb design with three independent degrees of freedom written by Michael C. Wrege and published by . This book was released on 1989 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Exoskeleton Robot for Finger Rehabilitation written by David Gardner and published by . This book was released on 2012 with total page 196 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Spring Operated Wearable Enhancer for Upper Limb Rehabilitation written by Ji Chen and published by . This book was released on 2016 with total page 139 pages. Available in PDF, EPUB and Kindle. Book excerpt: Stroke commonly results in abnormal muscle synergy, spasticity, muscle weakness and neural couplings. Stroke patients often present with movement deficits with respect to range of motion (ROM), joint coordination, and movement smoothness in the affected arm and hand. Our previous work showed that HandSOME, a spring-powered hand exoskeleton that compensates for flexor tone in the fingers and thumb, improves ROM and function while worn. This study aims to 1) investigate if an independent home therapy program using HandSOME can improve unassisted ROM and functional grasp of the affected hand, and 2) to design a portable and light-weight exoskeleton suitable for home based arm rehabilitation. This dissertation was broken into four components. 1) Individuals with chronic stroke completed a 4-week home intervention using HandSOME. Outcome measures were collected before and after the intervention and in a 3-month follow up. Changes in Fugl-Meyer Assessment (FMA) and Action Research Arm Test (ARAT) were used as primary outcome measures. Kinematic data were also collected to evaluate changes in ROM of the fingers and thumb, and hand movement efficiency (measure of proximal arm control). Seven individuals with chronic stroke completed the home therapy program. Five responded well to the intervention with gains of 6 or more on the ARAT or the FMA. The five responders had significant improvements in hand movement efficiency (p = 0.038). At the 3-month follow up, ROM gains were no longer significant and clinical score improvements were partially lost. 2) While the HandSOME enabled adequate range of motion at the fingers, some subjects had difficulty supinating the forearm enough to properly grasp objects and finger extension ability would degrade as the arm was lifted against gravity. A five-degree-of-freedom (DOF) spring operated movement enhancer for arm rehabilitation (SpringWear) was designed to address these issues. A list of prototypes were fabricated to refine the design. The current version SpringWear 1.0 uses the same spring technology used in HandSOME to provide assistance in three DOFs: forearm supination or pronation, elbow extension, and shoulder elevation. 3) A preliminary study was conducted to evaluate SpringWear 1.0 usability when chronic stroke patients perform ROM and functional tasks. Maximum angles in shoulder elevation, forearm supination or pronation, elbow extension and shoulder elevation, are all significantly increased when wearing this device, whereas only ROM in elbow flexion extension is significantly increased (p

Download or read book Design of a Computer Controlled Three Degree of freedom Robot Finger written by Lynn C. Cameron and published by . This book was released on 1988 with total page 17 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Download or read book Wearable Robots written by José L. Pons and published by John Wiley & Sons. This book was released on 2008-04-15 with total page 358 pages. Available in PDF, EPUB and Kindle. Book excerpt: A wearable robot is a mechatronic system that is designed around the shape and function of the human body, with segments and joints corresponding to those of the person it is externally coupled with. Teleoperation and power amplification were the first applications, but after recent technological advances the range of application fields has widened. Increasing recognition from the scientific community means that this technology is now employed in telemanipulation, man-amplification, neuromotor control research and rehabilitation, and to assist with impaired human motor control. Logical in structure and original in its global orientation, this volume gives a full overview of wearable robotics, providing the reader with a complete understanding of the key applications and technologies suitable for its development. The main topics are demonstrated through two detailed case studies; one on a lower limb active orthosis for a human leg, and one on a wearable robot that suppresses upper limb tremor. These examples highlight the difficulties and potentialities in this area of technology, illustrating how design decisions should be made based on these. As well as discussing the cognitive interaction between human and robot, this comprehensive text also covers: the mechanics of the wearable robot and it’s biomechanical interaction with the user, including state-of-the-art technologies that enable sensory and motor interaction between human (biological) and wearable artificial (mechatronic) systems; the basis for bioinspiration and biomimetism, general rules for the development of biologically-inspired designs, and how these could serve recursively as biological models to explain biological systems; the study on the development of networks for wearable robotics. Wearable Robotics: Biomechatronic Exoskeletons will appeal to lecturers, senior undergraduate students, postgraduates and other researchers of medical, electrical and bio engineering who are interested in the area of assistive robotics. Active system developers in this sector of the engineering industry will also find it an informative and welcome resource.

Download or read book Introduction to Finite Element Analysis and Design written by Nam-Ho Kim and published by John Wiley & Sons. This book was released on 2018-05-24 with total page 1074 pages. Available in PDF, EPUB and Kindle. Book excerpt: Introduces the basic concepts of FEM in an easy-to-use format so that students and professionals can use the method efficiently and interpret results properly Finite element method (FEM) is a powerful tool for solving engineering problems both in solid structural mechanics and fluid mechanics. This book presents all of the theoretical aspects of FEM that students of engineering will need. It eliminates overlong math equations in favour of basic concepts, and reviews of the mathematics and mechanics of materials in order to illustrate the concepts of FEM. It introduces these concepts by including examples using six different commercial programs online. The all-new, second edition of Introduction to Finite Element Analysis and Design provides many more exercise problems than the first edition. It includes a significant amount of material in modelling issues by using several practical examples from engineering applications. The book features new coverage of buckling of beams and frames and extends heat transfer analyses from 1D (in the previous edition) to 2D. It also covers 3D solid element and its application, as well as 2D. Additionally, readers will find an increase in coverage of finite element analysis of dynamic problems. There is also a companion website with examples that are concurrent with the most recent version of the commercial programs. Offers elaborate explanations of basic finite element procedures Delivers clear explanations of the capabilities and limitations of finite element analysis Includes application examples and tutorials for commercial finite element software, such as MATLAB, ANSYS, ABAQUS and NASTRAN Provides numerous examples and exercise problems Comes with a complete solution manual and results of several engineering design projects Introduction to Finite Element Analysis and Design, 2nd Edition is an excellent text for junior and senior level undergraduate students and beginning graduate students in mechanical, civil, aerospace, biomedical engineering, industrial engineering and engineering mechanics.

Download or read book Design of a Novel Task based Knee Rehabilitation Exoskeleton Device with Assist as needed Control Strategy written by Visharath Adhikari and published by . This book was released on 2017 with total page 83 pages. Available in PDF, EPUB and Kindle. Book excerpt: This thesis aims to design a novel task based knee rehabilitation exoskeleton device through kinematic synthesis. In contrast to prevailing research efforts, which attempt to mimic the human limb by assigning each human joint with an equivalent exoskeleton joint (e.g. a hinge joint for the elbow and knee), this thesis provides an alternative systematic approach for the design of exoskeletons to assist the complex 3D motions of the human Knee. With this method, it is not necessary to know the anatomy of the targeted limb, but rather to define the motion of the exoskeleton segments based on its point of attachment to the limb. Good alignment is often difficult and the distances between joints must be adjusted to accommodate the variety of human size. Furthermore, attempting to align each robotic joint axis with its human counterpart assumes that the position of the axis can be accurately known, and that such a fixed axis exists for the range of motion of the joint or set of joints, which is not always the case. In human- exoskeletons synergy, especially in industrial settings and rehabilitation applications, due to the repetitive and strenuous nature of the task, the fit, comfort and usability of these exoskeletons are important for the safety of the user and for the automation of the task. Improper fitting may lead an exoskeleton to move in a way that exceeds the range of movement of the human body and tear muscle ligaments or dislocate joints. In this thesis, to study the motion of the desired clinical trajectories of the human knee, the state-of-the-art of motion capture and data analysis techniques are utilized. The collected experimental kinematic data is used as an input to the kinematic synthesis. Parallel mechanisms with single degree-of-freedom (DOF) are considered to generate the complex 3D motions of the lower leg. An exact workspace synthesis approach is utilized, in which, the parameterized forward kinematics equations of each serial chain are to be converted to implicit equations via elimination. The implicit description of the workspace is made to be a function of the structural parameters of the serial chain, making it easy to relate those parameters to the motion capture data. A prototype of the mechanism has been built using 3D printing technology. And an Electromyography (EMG) signals and Force sensing resistors (FSR) are utilized to implement an assist as needed controller. The EMG signal is captured from the user leg and force sensing resistors (FSR) are applied at the attachment point of the exoskeleton and the leg, this helps to get the amount of force applied by the exoskeleton to the leg as well as for recovery tracking. The assist as needed controller eliminates the need of constant supervision, and hence saves time and reduces cost of the rehabilitation process.

Download or read book Human Hand Function written by Lynette A. Jones and published by Oxford University Press. This book was released on 2006-04-20 with total page 279 pages. Available in PDF, EPUB and Kindle. Book excerpt: Surveying normal hand function in health individuals, this book presents a conceptual framework for analysing what is known about it. It organises human-hand research on a continuum that ranges from activities that are sensory to those with a strong motor component. It is useful for researchers in neuroscience, cognitive science, and gerontology.

Download or read book Biologically Inspired Robotics written by Yunhui Liu and published by CRC Press. This book was released on 2011-12-21 with total page 343 pages. Available in PDF, EPUB and Kindle. Book excerpt: Robotic engineering inspired by biology—biomimetics—has many potential applications: robot snakes can be used for rescue operations in disasters, snake-like endoscopes can be used in medical diagnosis, and artificial muscles can replace damaged muscles to recover the motor functions of human limbs. Conversely, the application of robotics technology to our understanding of biological systems and behaviors—biorobotic modeling and analysis—provides unique research opportunities: robotic manipulation technology with optical tweezers can be used to study the cell mechanics of human red blood cells, a surface electromyography sensing system can help us identify the relation between muscle forces and hand movements, and mathematical models of brain circuitry may help us understand how the cerebellum achieves movement control. Biologically Inspired Robotics contains cutting-edge material—considerably expanded and with additional analysis—from the 2009 IEEE International Conference on Robotics and Biomimetics (ROBIO). These 16 chapters cover both biomimetics and biorobotic modeling/analysis, taking readers through an exploration of biologically inspired robot design and control, micro/nano bio-robotic systems, biological measurement and actuation, and applications of robotics technology to biological problems. Contributors examine a wide range of topics, including: A method for controlling the motion of a robotic snake The design of a bionic fitness cycle inspired by the jaguar The use of autonomous robotic fish to detect pollution A noninvasive brain-activity scanning method using a hybrid sensor A rehabilitation system for recovering motor function in human hands after injury Human-like robotic eye and head movements in human–machine interactions A state-of-the-art resource for graduate students and researchers in the fields of control engineering, robotics, and biomedical engineering, this text helps readers understand the technology and principles in this emerging field.