A novel under-actuated bionic hand and its grasping stability analysis

Li, Xin; Huang, Qiang; Zhu, Jinying; Han, Jianda

doi:10.1177/1687814016688859

Cited by 10 publications

(6 citation statements)

References 26 publications

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“…The articles [18], [20], [22], [23], [26], [29] exhibit a single degree of freedom and are unable to grasp objects with irregular shapes, a situation addressed in this article by employing the non-linked doubletendon arrangement. On the other hand, the articles [19], [27], [28], [30]- [32] feature a mechanical finger design with more than one degree of freedom, enabling them to grasp objects with irregular shapes. However, they lack a closed-loop control strategy, an aspect that is considered in the present article.…”

Section: Performance Of the Resultsmentioning

confidence: 99%

“…In [17] a hand controlled by various types of signals is presented, these are encephalographic, myoelectric, voice and gestures, the project provides a comprehensive explanation of the methods used to acquire the different signals; however, to move the hand, a control law is not used, that is, it is an open loop system. In [18], [19], it was also observed that they use myoelectric sensors as triggers of the control action. In [20]- [23], a hand prototype with five fingers divided into three parts (phalanges), joined by a small pulleys system is presented, in which, to perform the bending movement a direct current motor is used at the base, which acts on a wire (or cable) which runs through the inside of the finger and connects to the distal phalanx.…”

Section: Introductionmentioning

confidence: 99%

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Optimal Control and Grasping for a Robotic Hand with a Non-linked Double Tendon Arrangement

Sánchez-Garnica,

Rodríguez-Guerrero,

Ortega-Palacios

et al. 2024

IEEE Latin Am. Trans.

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After comparing different robotic hand projects, a problem is identified: when a finger has a degree of freedom, the hand is unable to grasp irregularly shaped objects. This article proposes a solution. The use of a non-linked doubletendon arrangement in the fingers allows them to have free movement; coupled with the use of Inertial Measurement Units to determine its position, ensures that, despite having one degree of freedom per finger, the hand can effectively grasp irregular objects. Additionally, a web application is developed to control hand movements through voice commands. Finally, due to the necessity for these types of devices to be mobile, an optimal control law is used to minimize energy consumption, thereby increasing autonomy when the hand is powered by batteries. As an additional note, the conducted experiments reveal that the movement of all fingers occurs simultaneously, demonstrating that parallel multitasking programming techniques effectively fulfill that purpose.

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Section: Performance Of the Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimal Control and Grasping for a Robotic Hand with a Non-linked Double Tendon Arrangement

Sánchez-Garnica,

Rodríguez-Guerrero,

Ortega-Palacios

et al. 2024

IEEE Latin Am. Trans.

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show abstract

“…The derived grasper can increase its robustness against external force perturbations. The UnderActuated UA finger [45] presented in the second row of Table 5 uses as the driving input the mechanical torque applied to link 1 (it does not have the interchangeability that characterizes the patent [43]). A and B are the MCP and PIP joints and once the link 3 is in contact with the object, the torsion spring 5 allows under actuation to be activated (in this case BE and ED are collinear).…”

Section: Referencementioning

confidence: 99%

Advances in Finger and Partial Hand Prosthetic Mechanisms

et al. 2020

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Approximately 70% of the upper extremity amputations refers to partial hand loss with the involvement of one or more fingers. Historically, this type of limb amputation has been addressed adopting simple opposition designs that use the movement of the residual digit for grasping against a fixed device. Nevertheless, in the last few years, technological advances, and the introduction of modern computer-aided tools for the synthesis and functional design of mechanisms have led to the development of smaller, more robust systems that are constantly improving body-powered and electrically-powered prototypes. This paper surveys cutting-edge solutions proposed in research or available on the market for single finger or partial hand prostheses. First, the main design requirements are outlined. Then, a wide number of prototypes are detailed underlying advantages and drawbacks. The overall goal is to create a solid starting point for the study and development of the next generation of prostheses that can be developed to advance the current state-of-the-art.

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“…Others adopted flexible fingers, fingers with flexible surfaces as an interface for grasping, or fingers with flexible joints [4][5][6][7][8][9][10]. Moreover, under-actuated mechanisms have also been employed to achieve safe and stable grasping [11][12][13][14][15][16][17][18]. While these approaches have proved effective, the levels of control and accuracy are still far from the biomimicry of natural grasping.…”

Section: Introductionmentioning

confidence: 99%

A Systematic Approach to Stable Grasping of a Two-Finger Robotic Hand Activated by Jamming of Granular Media

et al. 2023

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A systematic approach is presented to achieve the stable grasping of objects through a two-finger robotic hand, in which each finger cavity was filled with granular media. The compaction of the latter, controlled by vacuum pressure, was used to adjust the structural and contact stiffness of the finger. The grasping stability was studied under the concurrent effect of an external torque and applied vacuum pressure. Stable grasping was defined as the no slippage condition between the grasped object and the two fingers. Three control schemes were adopted and applied experimentally to ensure the effectiveness of the grasping process. The results showed that stable and unstable grasping regions exist for each combination of applied torque and vacuum pressure. The two-finger robotic hands can be further improved for applications that require high load-carrying capabilities.

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A novel under-actuated bionic hand and its grasping stability analysis

Cited by 10 publications

References 26 publications

Optimal Control and Grasping for a Robotic Hand with a Non-linked Double Tendon Arrangement

Optimal Control and Grasping for a Robotic Hand with a Non-linked Double Tendon Arrangement

Advances in Finger and Partial Hand Prosthetic Mechanisms

A Systematic Approach to Stable Grasping of a Two-Finger Robotic Hand Activated by Jamming of Granular Media

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