Flexible smart sensing skin for “Fly-by-Feel” morphing aircraft

Huang, YongAn; Zhu, Chen; Xiong, Wenhao; Wang, Yu; Jiang, Yonggang; Qiu, Lei; Guo, Dongliang; Hou, Chunfeng; Jiang, Shan; Yang, Zhaoxi; Wang, Bo; Wang, Lu; Yin, Zhouping

doi:10.1007/s11431-020-1793-0

Cited by 42 publications

(31 citation statements)

References 224 publications

(206 reference statements)

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Section: Resultsmentioning

confidence: 99%

“…This is especially meaningful for complex application scenarios, i.e., soft robots with deformable surfaces, [50] biointegrated devices on hearts [51] and bladders, [52] and flexible smart skin on morphing aircraft. [53] A flexible tube-like E-armor is fabricated to mimic the dynamic process of the snake swallowing an egg. The E-armor is equipped with flexible pressure sensors (Figure 6A) along its length, based on a cavity structural design, for the perception of the egg via the pressure-induced capacitance change.…”

Section: Functional Soft-hinge Kiri-mm E-armor Systemsmentioning

confidence: 99%

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A Snakeskin‐Inspired, Soft‐Hinge Kirigami Metamaterial for Self‐Adaptive Conformal Electronic Armor

et al. 2022

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A majority of soft‐body creatures evolve armor or shells to protect themselves. Similar protection demand is for flexible electronics working in complex environments. Existing works mainly focus on improving the sensing capabilities such as electronic skin (E‐skin). Inspired by snakeskin, a novel electronic armor (E‐armor) is proposed, which not only possesses mechanical flexibility and electronic functions similar to E‐skin, but is also able to protect itself and the underlying soft body from external physical damage. The geometry of the kirigami mechanical metamaterial (Kiri‐MM) ensures auxetic stretchability and meanwhile large areal coverage for sufficient protection. Moreover, to suppress the inherent but undesired out‐of‐plane buckling of conventional Kiri‐MMs for conformal applications, soft hinges are used to form a distinct soft (hinges)‐rigid (tiles) configuration. Analytical, computational, and experimental studies of the mechanical behaviors of the soft‐hinge Kiri‐MM E‐armor demonstrate the merits of this design, i.e., stretchability, conformability, and protectability, as applied to flexible electronics. Deploying a conductive soft material at the hinges enables facile wiring strategies for large‐scale circuit arrays. Functional E‐armor systems for controllable display and sensing purposes provide simple examples of a wide spectrum of applications of this concept.

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Section: Resultsmentioning

confidence: 99%

Section: Functional Soft-hinge Kiri-mm E-armor Systemsmentioning

confidence: 99%

A Snakeskin‐Inspired, Soft‐Hinge Kirigami Metamaterial for Self‐Adaptive Conformal Electronic Armor

et al. 2022

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“…So, it is crucial to accurately measure the parameter of such an aircraft’s structures and external environment. Recently, there have been more and more demands to apply flexible pressure sensor arrays in curved aircraft structures [ 121 ]. For example, to measure the pressure in wind-flow surroundings, a range-programmable capacitive pressure sensor array was demonstrated by Xiong et al [ 122 ].…”

Section: Application Of Flexible Pressure Sensor Arraysmentioning

confidence: 99%

Recent Progress in Flexible Pressure Sensor Arrays

Duan

et al. 2022

Nanomaterials

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Flexible pressure sensors that can maintain their pressure sensing ability with arbitrary deformation play an essential role in a wide range of applications, such as aerospace, prosthetics, robotics, healthcare, human–machine interfaces, and electronic skin. Flexible pressure sensors with diverse conversion principles and structural designs have been extensively studied. At present, with the development of 5G and the Internet of Things, there is a huge demand for flexible pressure sensor arrays with high resolution and sensitivity. Herein, we present a brief description of the present flexible pressure sensor arrays with different transduction mechanisms from design to fabrication. Next, we discuss the latest progress of flexible pressure sensor arrays for applications in human–machine interfaces, healthcare, and aerospace. These arrays can monitor the spatial pressure and map the trajectory with high resolution and rapid response beyond human perception. Finally, the outlook of the future and the existing problems of pressure sensor arrays are presented.

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“…Flexible smart skins, as perceptional parts of wearable healthcare devices, bionic robots, and intelligent aircrafts, play key roles in diverse tasks including physiological signal detection, joint movement control, and flight-state monitoring. − Due to excellent dexterity and conformability, stretchable strain sensors based on nanomaterial thin films have aroused extensive interest to equip flexible smart skins with essential motion-monitoring functions. − Despite the development in this field, stretchable strain sensors are still limited due to the lack of integration capability to simultaneously detect small and large strains for practical applications. Sensitivity is a paramount metric to assess the capability of strain sensors to precisely detect subtle strain signals.…”

Section: Introductionmentioning

confidence: 99%

High-Performance Strain Sensors Based on Au/Graphene Composite Films with Hierarchical Cracks for Wide Linear-Range Motion Monitoring

Cheng

Cai

et al. 2022

ACS Appl. Mater. Interfaces

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Stretchable strain sensors based on nanomaterial thin films have aroused extensive interest for the strain perception of smart skins. However, it still remains challenging to have them achieve high sensitivity over wide linear working ranges. Herein, we propose a facile strategy to fabricate stretchable strain sensors based on Au/graphene composite films (AGCFs) with hierarchical cracks and demonstrate their superior sensing performances. The polydimethylsiloxane substrates were covered with self-assembled graphene films (SAGFs) and sputtered with Au, and then prestretching was applied to introduce hierarchical cracks. The AGCF strain sensors exhibited high sensitivity (gauge factor (GF) ≈ 153) and favorable linearity (R 2 ≈ 0.9975) in the wide working range (0–20%) with ultralow overshooting (∼1.7% at 20%), fast response (<42.5 ms), and also excellent cycling stability (1500 cycles). Besides, these patternable sensors could further achieve higher GF (∼320) via pattern designing. The dominant effect of the intermediate wrinkled SAGFs in forming hierarchical cracks was studied, and the linear sensing mechanism of the as-formed fractal microstructures was also revealed in detail. Moreover, the AGCF strain sensors were tested for motion monitoring of the human body and electronic bird. Due to the remarkable versatility, scalable fabrication, and integration capability, these sensors demonstrate great potential to construct smart skins.

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Flexible smart sensing skin for “Fly-by-Feel” morphing aircraft

Cited by 42 publications

References 224 publications

A Snakeskin‐Inspired, Soft‐Hinge Kirigami Metamaterial for Self‐Adaptive Conformal Electronic Armor

A Snakeskin‐Inspired, Soft‐Hinge Kirigami Metamaterial for Self‐Adaptive Conformal Electronic Armor

Recent Progress in Flexible Pressure Sensor Arrays

High-Performance Strain Sensors Based on Au/Graphene Composite Films with Hierarchical Cracks for Wide Linear-Range Motion Monitoring

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