Design and Analysis of a Rigid‐Flexible Parallel Mechanism for a Neck Brace

Liu, Jingfang; Yan-xia, Cheng; Zhang, Shuang; Lu, Zhenxin; Gao, Guohua

doi:10.1155/2019/9014653

Cited by 6 publications

(7 citation statements)

References 36 publications

(41 reference statements)

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“…Their primary function is to assist people during the execution of specific movements by providing supplementary strength, making it possible, for instance, to deal with greater loads, to compensate for a lack of muscularity and to prevent from excessive fatigue. Wearable assistive devices, usually referred to as exoskeletons, are commonly designed to operate along their human counterparts, namely the lower/upper limbs or the neck area, though in the last case, if no particular functionalities are provided, the device could be better identified as a brace [24]. Ready examples of commercially available exoskeletons are the Mate, [19], the AirFrame [20] and the ShoulderX [21] for the upper limbs, the LegX [22] and the Hercule [25] for the lower limbs, and the Laevo V2 Fig.…”

Section: Introductionmentioning

confidence: 99%

Conceptual design and virtual prototyping of a wearable upper limb exoskeleton for assisted operations

Bilancia

Berselli

2021

Int J Interact Des Manuf

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This paper introduces a novel upper limb robotic exoskeleton designed to assist industrial operators in a wide range of manual repetitive tasks, such as tool handling and lifting/moving of heavy items. Due to its reduced size and high maneuverability, the proposed portable device may also be employed for rehabilitation purposes (e.g. as an aid for people with permanent neuromuscular diseases or post-stroke patients). Its primary function is to compensate the gravity loads acting on the human shoulder by means of a hybrid system consisting of four electric motors and three passive springs. The paper focuses on the exoskeleton mechanical design and virtual prototyping. After a preliminary review of the existent architectures and procedures aimed at defining the exoskeleton functional requirements, a detailed behavioral analysis is conducted using analytical and numerical approaches. The developed interactive model allows to simulate both kinematics and statics of the exoskeleton for every possible movement within the design workspace. To validate the model, the results have been compared with the ones achieved with a commercial multibody software for three different operator’s movements.

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Section: Introductionmentioning

confidence: 99%

Conceptual design and virtual prototyping of a wearable upper limb exoskeleton for assisted operations

Bilancia

Berselli

2021

Int J Interact Des Manuf

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“…Neck exoskeletons represent a viable alternative solution to not only support but also actively enable head-neck motions in ALS patients. To date, most neck exoskeletons use parallel mechanisms in their design to support the weight of the head and accommodate the large range, spatial rotations of the head [12], [13], [24]- [28]. This is because all actuators can…”

Section: Discussionmentioning

confidence: 99%

Preliminary Study on Effects of Neck Exoskeleton Structural Design in Patients With Amyotrophic Lateral Sclerosis

Demaree,

Brignone,

Bromberg

et al. 2024

IEEE Trans. Neural Syst. Rehabil. Eng.

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Neck muscle weakness due to amyotrophic lateral sclerosis (ALS) can result in dropped head syndrome, adversely impacting the quality of life of those affected. Static neck collars are currently prescribed to hold the head in a fixed upright position. However, these braces are uncomfortable and do not allow any voluntary headneck movements. By contrast, powered neck exoskeletons have the potential to enable head-neck movements. Our group has recently improved the mechanical structure of a state-of-the-art neck exoskeleton through a weighted optimization. To evaluate the effect of the structural changes, we conducted an experiment in which patients with ALS were asked to perform head-neck tracking tasks while using the two versions of the neck exoskeleton. We found that the neck muscle activation was significantly reduced when assisted by the structurally enhanced design compared to no assistance provided. The improved structure also improved kinematics tracking performance, allowing users to better achieve the desired head poses. In comparison, the previous design did not help reduce the muscle effort required to perform these tasks and even slightly worsened the kinematic tracking performance. It was also found that biomechanical benefits gained from using the structurally improved design were consistent across participants with both mild and severe neck weakness. Furthermore, we observed that participants preferred to use the powered neck exoskeletons to voluntarily move their heads and make eye contact during a conversation task rather than remain in a fixed upright position. Each of these findings highlights the importance of the structural design of neck exoskeletons in achieving desired biomechanical benefits and suggests that neck exoskeletons can be a viable method to improve the daily life of patients with ALS.

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“…The mechanism consisted of a series of links connected to both the top and fixed platforms through a sequence of joints in the following order: revolute joint (R), X-shaped compliant joint (X), and spherical joint (S). This construction was simple and lightweight, enabling smooth flexion/extension, left/right lateral bending, and axial rotational movements [38].…”

Section: Parallel Robot For Neck Assistancementioning

confidence: 99%

“…In the rehabilitation sphere, there are models such as 3-RPS [1] and 3-RRR [2]. In the context of assistance robots, configurations like 3-RRS [36], 3-RRR [37], and 3-RXS [38] are used. Humanoid robotics often favor cable-driven mechanisms [3,39,[41][42][43].…”

mentioning

confidence: 99%

“…The performance evaluation of parallel robots is multi-faceted, typically incorporating metrics such as speed [28,59], accuracy [33,53,57,84,104,108], repeatability, loadcarrying capacity [79,80], energy efficiency, and safety [96]. Methods for performance evaluation include computational methods, and simulations for statistical analysis and finite element analysis (FEA) for mechanical property evaluation are popular choices [38]. Furthermore, various software tools were prevalent for simulation and analysis in the studies reviewed.…”

mentioning

confidence: 99%

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A Review of Parallel Robots: Rehabilitation, Assistance, and Humanoid Applications for Neck, Shoulder, Wrist, Hip, and Ankle Joints

Abarca,

Elias

2023

Robotics

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This review article presents an in-depth examination of research and development in the fields of rehabilitation, assistive technologies, and humanoid robots. It focuses on parallel robots designed for human body joints with three degrees of freedom, specifically the neck, shoulder, wrist, hip, and ankle. A systematic search was conducted across multiple databases, including Scopus, Web of Science, PubMed, IEEE Xplore, ScienceDirect, the Directory of Open Access Journals, and the ASME Journal. This systematic review offers an updated overview of advancements in the field from 2012 to 2023. After applying exclusion criteria, 93 papers were selected for in-depth review. This cohort included 13 articles focusing on the neck joint, 19 on the shoulder joint, 22 on the wrist joint, 9 on the hip joint, and 30 on the ankle joint. The article discusses the timeline and advancements of parallel robots, covering technology readiness levels (TRLs), design, the number of degrees of freedom, kinematics structure, workspace assessment, functional capabilities, performance evaluation methods, and material selection for the development of parallel robotics. It also examines critical technological challenges and future prospects in rehabilitation, assistance, and humanoid robots.

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Design and Analysis of a Rigid‐Flexible Parallel Mechanism for a Neck Brace

Cited by 6 publications

References 36 publications

Conceptual design and virtual prototyping of a wearable upper limb exoskeleton for assisted operations

Conceptual design and virtual prototyping of a wearable upper limb exoskeleton for assisted operations

Preliminary Study on Effects of Neck Exoskeleton Structural Design in Patients With Amyotrophic Lateral Sclerosis

A Review of Parallel Robots: Rehabilitation, Assistance, and Humanoid Applications for Neck, Shoulder, Wrist, Hip, and Ankle Joints

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