Flexible actuator by electric bending of saline solution-filled carbon nanotubes

Gao, Xiang; Zhang, Fu-Jian; Hu, Xinghao; Zhang, Zhong‐Qiang

doi:10.1088/1361-6463/ac55bf

Cited by 2 publications

(2 citation statements)

References 43 publications

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“…Auxetic metamaterials exhibit exceptional mechanical properties due to their counter‐intuitive deformation characteristics, making them valuable across various fields including acoustic engineering, [ 14,32 ] seismic engineering, [ 33,34 ] medical devices, [ 1,35 ] smart sensors, [ 36,37 ] and protective engineering. [ 38,39 ] In recent years, researchers have increasingly explored tensile‐expansive materials such as chiral structures, [ 40–43 ] reentrant structures, [ 27,44 ] and rotating polygonal structures, [ 45,46 ] focusing on their in‐plane impact properties. Chiral and antichiral structures demonstrate excellent mechanical attributes including impact and shear resistance, as well as cushioning and vibration absorption, combined with low density and high specific strength.…”

Section: Introductionmentioning

confidence: 99%

Out‐of‐Plane Dynamics of a Novel Auxetic Honeycomb with an Anti‐Trichiral Hierarchy

Guang,

Huang,

Deng

2024

Physica Status Solidi (b)

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This study extensively characterizes the out‐of‐plane stiffness and energy harvesting capabilities of a newly proposed anti‐trichiral hierarchical auxetic honeycomb structure, both mechanically and deformationally. By introducing a design concept based on the anti‐trichiral honeycomb (ATCH), a structure with superior out‐of‐plane load‐carrying capacity and excellent auxeticity is achieved. To validate the finite element model, compression simulations are conducted. Comparative investigations into the morphing characteristics and energy harvesting performance between the novel structure and the ATCH are performed. Additionally, the influence of various parameters on the comprehensive performance of the novel auxetic structure is explored. It has been found that the angle φ is most sensitive to the auxetic properties, while the ratio k significantly impacts energy absorption. This research advances the design of novel auxetic structures for potential applications in protective engineering.

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Section: Introductionmentioning

confidence: 99%

Out‐of‐Plane Dynamics of a Novel Auxetic Honeycomb with an Anti‐Trichiral Hierarchy

Guang,

Huang,

Deng

2024

Physica Status Solidi (b)

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“…As the most extensively investigated research area in the field of soft robotics, dexterous soft grippers inspired by human hands have been applied in various scenarios, such as in search and rescue missions [16], surgical operations [17,18], and kitchen utensil cleaning [19]. The actuation methods of soft grippers can be classified into three major categories: pneumatic-driven [20,21], tendon-or cable-driven [22,23], and soft active material-driven [24][25][26][27] (e.g. dielectric elastomer, shape memory alloy).…”

Section: Introductionmentioning

confidence: 99%

Reconfigurable bionic soft pneumatic gripper for fruit handling based on shape and size adaptation

Cheng¹,

Lu²,

Chen³

et al. 2022

J. Phys. D: Appl. Phys.

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A universal soft gripper for fruit grasping is challenging to develop. In this study, a modular and reconfigurable soft pneumatic gripper was designed. The designed gripper was inspired by the dexterous grasping of the human hand for fruits of different shapes and sizes. It comprised three soft extension actuators (SEAs), two soft rotation actuators (SRAs), and three soft bending actuators (SBAs). By adjusting SRAs, two grasping poses (claw and clenching pose) could be made to hold fruits of different shapes. The grasping size under each pose could be continuously adjusted by SEAs to grasp fruits of different sizes. SBAs were used to mimic soft fingers for grasping. Theoretical and simulation models were established to predict the relationships between deformations and pressures of SEAs, SRAs, and SBAs. The deformation characteristics of these actuators were experimentally investigated. It was shown that, by inflating SEAs, the grasping sizes under the claw and clenching poses could be increased by 87.5% and 94.5%, respectively. Furthermore, a visual recognition system was designed for automatically controlling the grasping pose and size. Grasping tests showed that, by reconfiguring the grasping pose and size, various fruits, vegetables, and foods with weights from 32 to 786 g (24.6 folds) and diameters from 30 to 141 mm (4.7 folds) could be successfully grasped, indicating the broad applicability of our all-pneumatic soft gripper.

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Flexible actuator by electric bending of saline solution-filled carbon nanotubes

Cited by 2 publications

References 43 publications

Out‐of‐Plane Dynamics of a Novel Auxetic Honeycomb with an Anti‐Trichiral Hierarchy

Out‐of‐Plane Dynamics of a Novel Auxetic Honeycomb with an Anti‐Trichiral Hierarchy

Reconfigurable bionic soft pneumatic gripper for fruit handling based on shape and size adaptation

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