Modeling, design &amp; characterization of a novel Passive Variable Stiffness Joint (pVSJ)

Awad, Mohammad I.; Gan, Dongming; Cempini, Marco; Cortese, Mario; Vitiello, Nicola; Dias, Jorge; Dario, P.; Seneviratne, Lakmal

doi:10.1109/iros.2016.7759074

Cited by 27 publications

(21 citation statements)

References 25 publications

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“…The system utilizes a lever mechanism with discrete lever arm lengths. The lever arm mechanism and the discrete variable stiffness actuators have been used in our previous passive exoskeleton design [13][14][15]. The paper is organized as follows: In section 2, the concept and the modeling of the variable stiffness mechanism is proposed.…”

Section: Citationmentioning

confidence: 99%

Modeling, Simulation and Proof-of-Concept of an Augmentation Ankle Exoskeleton with a Manually-Selected Variable Stiffness Mechanism

Abdulmajeed¹,

Al-Kaabi²,

Awad³

et al. 2020

Ann Robot Automation

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Section: Citationmentioning

confidence: 99%

Modeling, Simulation and Proof-of-Concept of an Augmentation Ankle Exoskeleton with a Manually-Selected Variable Stiffness Mechanism

Abdulmajeed¹,

Al-Kaabi²,

Awad³

et al. 2020

Ann Robot Automation

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“…Unfortunately, this model, commonly used for describing the stiffness of a torsional spring made with a beam [22], is not accurate enough to describe the real behavior observed experimentally (cf. section V).…”

Section: A First Model: Beam Spring Behaviormentioning

confidence: 99%

“…Active length of the lever As for most of the VLM mechanisms described in the literature, Awad et al proposed the pVSJ, a variable stiffness joint with a variable lever mechanism which applies forces on two springs [22] (torsional in that particular case). The pVSJ has a large range of stiffness (theoretically from 0 Nm/rad to more than 1000 Nm/rad) for a variable lever length from 0 mm to 30 mm, but the design approach does not allow miniaturization to a human finger size.…”

Section: Introductionmentioning

confidence: 99%

A Variable Stiffness Robotic Probe for Soft Tissue Palpation

Herzig

Maiolino

Iida

et al. 2018

IEEE Robot. Autom. Lett.

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Abstract-During abdominal palpation diagnosis, a medical practitioner would change the stiffness of their fingers in order to improve the detection of hard nodules or abnormalities in soft tissue to maximise haptic information gain via tendons. Our recent experiments using a controllable stiffness robotic probe representing a human finger also confirmed that such stiffness control in the finger can enhance the accuracy of detecting hard nodules in soft tissue. However, the limited range of stiffness achieved by the antagonistic springs variable stiffness joint subject to size constraints made it unsuitable for a wide range of physical examination scenarios spanning from breast to abdominal examination. In this paper, we present a new robotic probe based on a variable lever mechanism (VLM) able to achieve stiffness ranging from 0.64 N.m/rad to 1.06 N.m/rad, that extends the maximum stiffness by around 16 times and the stiffness range by 33 times. This paper presents the mechanical model of the novel probe, the Finite Element (FE) simulation as well as experimental characterization of the stiffness response for lever actuation.

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“…In PVSJ [16] and TSA [17] change the stiffness of joints by changing the position of the force points on the torsion springs. This method has a large range of stiffness adjustment, but the space utilization rate is low.…”

Section: Introductionmentioning

confidence: 99%

A Design and Modeling of the Bionic Variable Stiffness Unit Based on the Elbow Joint

Cheng

Liu

2018

2018 3rd International Conference on Robotics and Automation Engineering (ICRAE)

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Due to problems of slow response speed and complex mechanisms, the application of variable stiffness joints is limited. The variable stiffness element can be divided into the part with variable stiffness and the part with adjustable external force point. The variable stiffness part adopts the lever principle and changes the stiffness of the joint by changing the length of the lever arm. The external force adjustment part adopts the two-stage four-bar mechanism, which transforms the gravity of the object into the horizontal movement of the slider on the guide rail. The response speed of the unit is greatly improved by the use of the pure mechanism. It is ensured that the stiffness of the variable stiffness unit can be adjusted at the same time with smaller size and a wide range of stiffness adjustment. Based on the elbow joint, a bionic variable stiffness unit is proposed. It can automatically change the stiffness according to the different grasping of a weight, which is same as the human arm. On the basic of/According to the derivation of the Variable Stiffness Unit mathematical model, the three-dimensional model of the Variable Stiffness unit is drawn.

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Modeling, design & characterization of a novel Passive Variable Stiffness Joint (pVSJ)

Cited by 27 publications

References 25 publications

Modeling, Simulation and Proof-of-Concept of an Augmentation Ankle Exoskeleton with a Manually-Selected Variable Stiffness Mechanism

Modeling, Simulation and Proof-of-Concept of an Augmentation Ankle Exoskeleton with a Manually-Selected Variable Stiffness Mechanism

A Variable Stiffness Robotic Probe for Soft Tissue Palpation

A Design and Modeling of the Bionic Variable Stiffness Unit Based on the Elbow Joint

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