Towards the design of a prosthetic underactuated hand

Laliberté, Thierry; Baril, Mathieu; Guay, F.; Gosselin, Clément

doi:10.5194/ms-1-19-2010

Cited by 34 publications

(20 citation statements)

References 19 publications

(22 reference statements)

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“…Scientific papers have been published regarding research in the field of 3D-printed upper limb prostheses. [1][2][3][4][5][6][7] People are developing prostheses individually, and large communities have been established. Most of the development of 3D-printed prostheses began after the establishment of the global community e-NABLE.…”

Section: Introductionmentioning

confidence: 99%

3D-printed upper limb prostheses: a review

Kate

Smit

Breedveld

2017

Disability and Rehabilitation: Assistive Technology

254

182

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Goal: This paper aims to provide an overview with quantitative information of existing 3D-printed upper limb prostheses. We will identify the benefits and drawbacks of 3D-printed devices to enable improvement of current devices based on the demands of prostheses users. Methods: A review was performed using Scopus, Web of Science and websites related to 3D-printing. Quantitative information on the mechanical and kinematic specifications and 3D-printing technology used was extracted from the papers and websites. Results: The overview (58 devices) provides the general specifications, the mechanical and kinematic specifications of the devices and information regarding the 3D-printing technology used for hands. The overview shows prostheses for all different upper limb amputation levels with different types of control and a maximum material cost of $500. Conclusion: A large range of various prostheses have been 3D-printed, of which the majority are used by children. Evidence with respect to the user acceptance, functionality and durability of the 3D-printed hands is lacking. Contrary to what is often claimed, 3D-printing is not necessarily cheap, e.g., injection moulding can be cheaper. Conversely, 3D-printing provides a promising possibility for individualization, e.g., personalized socket, colour, shape and size, without the need for adjusting the production machine. ä IMPLICATIONS FOR REHABILITATIONUpper limb deficiency is a condition in which a part of the upper limb is missing as a result of a congenital limb deficiency of as a result of an amputation. A prosthetic hand can restore some of the functions of a missing limb and help the user in performing activities of daily living. Using 3D-printing technology is one of the solutions to manufacture hand prostheses. This overview provides information about the general, mechanical and kinematic specifications of all the devices and it provides the information about the 3D-printing technology used to print the hands. ARTICLE HISTORY

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Section: Introductionmentioning

confidence: 99%

3D-printed upper limb prostheses: a review

Kate

Smit

Breedveld

2017

Disability and Rehabilitation: Assistive Technology

254

182

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“…The work presented here is a key aspect of a project [19] with the goal of creating an underactuated prosthetic hand [20] capable of restituting exteroception [21] as well as proprioception [22] to amputees. As part of the work on proprioception, we are currently designing a strain-sensing glove similar to that previously proposed [17] for the purpose of measuring the configuration of an artificial hand.…”

mentioning

confidence: 99%

A Soft Strain Sensor Based on Ionic and Metal Liquids

et al. 2013

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Abstract-A novel soft strain sensor capable of withstanding strains of up to 100% is described. The sensor is made of a hyperelastic silicone elastomer that contains embedded microchannels filled with conductive liquids. This is an effort of improving the previously reported soft sensors that uses a single liquid conductor. The proposed sensor employs a hybrid approach involving two liquid conductors: an ionic solution and an eutectic gallium-indium alloy. This hybrid method reduces the sensitivity to noise that may be caused by variations in electrical resistance of the wire interface and undesired stress applied to signal routing areas. The bridge between these two liquids is made conductive by doping the elastomer locally with nickel nanoparticles. The design, fabrication, and characterization of the sensor are presented.Index Terms-Wearable sensors, microfluidics, strain measurement, ionic solution, eutectic gallium indium (eGaIn).

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“…In particular, tendon-driven robotic and prosthetic hands utilize Teflon-or nylon-coated cables and pulleys, and aim toward frictionless tendon transmission. This is due to friction introducing a number of unwanted side effects, such as (1) nonlinearities [45], (2) hysteresis effects, and (3) energy and power losses [18,22,51]. Designers of robotic hands such as the Shadow hand [43], the smart hand [53], and other tendon-driven prosthetic hands [13,15,16] either intentionally try to minimize friction in their systems (especially in the tendon-pulley system), or consider friction to have no importance in their performance.…”

Section: Introductionmentioning

confidence: 99%

Modeling the Frictional Interaction in the Tendon-Pulley System of the Human Finger for Use in Robotics

2013

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Physiological studies of the human finger indicate that friction in the tendon-pulley system accounts for a considerable fraction of the total output force (9-12%) in a high-load static posteccentric configuration. Such a phenomenon can be exploited for robotic and prosthetic applications, as it can result in (1) an increase of output force or (2) a reduction of energy consumption and actuator weight. In this study, a simple frictional, two-link, one-degree-of-freedom model of a human finger was created. The model is validated against in vitro human finger data, and its behavior is examined with respect to select physiological parameters. The results point to clear benefits of incorporating friction in tendon-driven robotic fingers for actuator mass and output force. If it is indeed the case that the majority of high-load hand grasps are posteccentric, there is a clear benefit of incorporating friction in tendon-driven prosthetic hand replacements.

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Towards the design of a prosthetic underactuated hand

Cited by 34 publications

References 19 publications

3D-printed upper limb prostheses: a review

3D-printed upper limb prostheses: a review

A Soft Strain Sensor Based on Ionic and Metal Liquids

Modeling the Frictional Interaction in the Tendon-Pulley System of the Human Finger for Use in Robotics

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