Stiffness Control With Shape Memory Polymer in Underactuated Robotic Origamis

Firouzeh, Amir; Salerno, Marco; Paik, Jamie

doi:10.1109/tro.2017.2692266

Cited by 95 publications

(64 citation statements)

References 36 publications

(38 reference statements)

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“…The stiffness change enables two grasping modes: a stiff mode to exert large forces, and a soft mode to gently handle the object, a sponge in this case. Moreover, the same group showed another gripper with similar tendon‐origami configuration, which exhibited independent stiffness control of every SMP joint for achieving various finger shapes, or multiple grasping modes thanks to different origami patterns enabling bending about multiple axes (Figure b) …”

Section: Gripping By Controlled Stiffnessmentioning

confidence: 99%

Soft Robotic Grippers

et al. 2018

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Advances in soft robotics, materials science, and stretchable electronics have enabled rapid progress in soft grippers. Here, a critical overview of soft robotic grippers is presented, covering different material sets, physical principles, and device architectures. Soft gripping can be categorized into three technologies, enabling grasping by: a) actuation, b) controlled stiffness, and c) controlled adhesion. A comprehensive review of each type is presented. Compared to rigid grippers, end-effectors fabricated from flexible and soft components can often grasp or manipulate a larger variety of objects. Such grippers are an example of morphological computation, where control complexity is greatly reduced by material softness and mechanical compliance. Advanced materials and soft components, in particular silicone elastomers, shape memory materials, and active polymers and gels, are increasingly investigated for the design of lighter, simpler, and more universal grippers, using the inherent functionality of the materials. Embedding stretchable distributed sensors in or on soft grippers greatly enhances the ways in which the grippers interact with objects. Challenges for soft grippers include miniaturization, robustness, speed, integration of sensing, and control. Improved materials, processing methods, and sensing play an important role in future research.

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Section: Gripping By Controlled Stiffnessmentioning

confidence: 99%

Soft Robotic Grippers

et al. 2018

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“…As a result, the finger would bend at low stiffness joints when pressurized air flows in the air chamber. Except for soft pneumatic fingers, SMP has also been applied in tendon-driven under-actuated robotic origamis for stiffness control [15].…”

Section: Glass/phase Transition-based Methodsmentioning

confidence: 99%

“…What's more, we will also present a possible alternative for stiffness modulation in soft robotic design and development. Gripper [13], robotic origami [15], legged robot [22] and load bearing functional part [16,23] Viscosity-based methods Electric/magnetic field Viscosity change ERF, MRF, electroactive gel…”

Section: Introductionmentioning

confidence: 99%

Principles and methods for stiffness modulation in soft robot design and development

Yang

Chen

2018

Bio-des. Manuf.

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Compared to traditional rigid robots, soft robots, primarily made of deformable, or less rigid materials, have good adaptability, conformability and safety in interacting with the environment. Although soft robots have shown great potentials for extended applications and possibilities that are impossible or difficult for rigid body robots, it is of great importance for them to have the capability of controllable stiffness modulation. Stiffness modulation allows soft robots to have reversible change between the compliant, or flexible state and the rigid state. In this paper, we summarize existing principles and methods for stiffness modulation in soft robotic development and divide them into four groups based on their working principles. Acoustic-based methods have been proposed as the potential fifth group in stiffness modulation of soft robots. Initial design proposals based on the proposed acoustic method are presented, and challenges in further development are highlighted.

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“…Della Santina et al [16] present an impedance controller for a soft continuum robot using a Piecewise Constant Curvature assumption to link the soft robot to an equivalent rigid robot representation. In the soft robot community, numerous works have focused on obtaining actuators with variable stiffness using, for example, particle jamming [17], shape memory polymers [18], magnetorheology [19], and antagonistic soft actuation [20]. These approaches allow local modification and control of stiffness, but do not necessarily take into account the compliance of the whole structure of the robot or consider the apparent end-effector stiffness.…”

Section: B Related Workmentioning

confidence: 99%