A Reversible, Versatile Skin‐Attached Haptic Interface Platform with Bioinspired Interconnection Architectures Capable of Resisting Sweat and Vibration

Author:

Kim Jinhyung1,Hwang Gui Won1,Song Minwoo1,Lim Dohyun1,Kim Jae‐Ik2,Choi Jin‐Ho2,Lee Yeon Soo1,Kim Da Wan2,Yang Tae‐Heon23,Pang Changhyun14ORCID

Affiliation:

1. School of Chemical Engineering Sungkyunkwan University (SKKU) 2066 Seobu‐ro, Jangan‐gu Suwon 16419 Republic of Korea

2. Department of Electronic Engineering Korea National University of Transportation Chungju‐si Chungbuk 27469 Republic of Korea

3. Department of Mechanical Engineering Konkuk University Seoul 05029 Republic of Korea

4. Samsung Advanced Institute for Health Science & Technology (SAIHST) Sungkyunkwan University (SKKU) 2066 Seobu‐ro, Jangan‐gu Suwon 16419 Republic of Korea

Abstract

AbstractA stable conformal interface technology for rough and sweaty complex skin is essential for a haptic interface capable of delivering sophisticated mechanical stimuli. However, conventional polymeric/hydrogel‐based skin adhesives cannot maintain adequate adhesion interaction performance at the haptic interface due to repetitive vibrations or sweaty skin. This study reports a reversible, versatile skin‐attached haptic interface platform, which embeds the hybrid architecture of a water‐drainable hexagonal array of frog toe pads and the energy‐dissipation matrix of snail pedal muscles with interconnected structures. The hybrid frog–snail‐inspired adhesive patch exhibits remarkable adhesion in pulling and shear directions under both dry and sweaty conditions. Furthermore, the microchannels between the hexagonal array can effectively drain liquid under sweaty conditions while also enhancing skin‐conformal contacts. The adhesion force enhanced by energy‐dissipation is analyzed considering a simple theory based on the adhesion, elastic, dissipation energies, and geometric features, resulting in the vibration‐resistant characteristics against diverse dry and wet vibration environments (vibrational frequency: 1–150 Hz). Bioinspired integrated skin‐attached haptic interface platform demonstrates the versatility of being reversibly applicable to various skin surfaces such as fingers, arms, and legs, yielding the feasibility of dynamic handling a basketball with multiple contacts and impacts in virtual reality (VR).

Funder

National Research Foundation of Korea

Ministry of Science and ICT, South Korea

Ministry of Trade, Industry and Energy

Publisher

Wiley

Subject

Electrochemistry,Condensed Matter Physics,Biomaterials,Electronic, Optical and Magnetic Materials

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