Ultra-Sensitive & Fully-Soft Pneumatic Valve for High-Speed Oscillatory Applications

Mostafa Mousa; Yuxuan Wang; Ashkan Rezanejad; Antonio Forte

Ultra-Sensitive & Fully-Soft Pneumatic Valve for High-Speed Oscillatory Applications

Mostafa Mousa, Yuxuan Wang, Ashkan Rezanejad, Antonio Forte^*

^*Corresponding author for this work

Research output: Contribution to conference types › Paper › peer-review

Abstract

Recently, soft valves have been designed to enhance functionality in soft robots and achieve embodied control. However, most designs still use rigid components, need high control pressure to activate, and are not able to generate high-frequency oscillations. Here, we present a fully-soft valve, which can be triggered by kinking an elastomeric sleeve by using an inflatable origami pouch. The valve is compatible with high supply pressures and can interrupt a flow 100 times larger than its control signal. Afterwards, we use the valve to build fluidic oscillator circuits. These circuits exhibit high frequency oscillations which are tunable on the fly by sliding the valve actuator. We demonstrate the applicability of the circuit by driving a robot that swims at 0.5
BL/s-1. Furthermore, we demonstrate that multiple valves can be used to create amplification circuits, able to drive stiffer pneumatic actuators. Such circuits can amplify pressure signals by 10 folds, using only 2 valves.

Original language	English
Publication status	Accepted/In press - 3 Jan 2025

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title = "Ultra-Sensitive & Fully-Soft Pneumatic Valve for High-Speed Oscillatory Applications",

abstract = "Recently, soft valves have been designed to enhance functionality in soft robots and achieve embodied control. However, most designs still use rigid components, need high control pressure to activate, and are not able to generate high-frequency oscillations. Here, we present a fully-soft valve, which can be triggered by kinking an elastomeric sleeve by using an inflatable origami pouch. The valve is compatible with high supply pressures and can interrupt a flow 100 times larger than its control signal. Afterwards, we use the valve to build fluidic oscillator circuits. These circuits exhibit high frequency oscillations which are tunable on the fly by sliding the valve actuator. We demonstrate the applicability of the circuit by driving a robot that swims at 0.5 BL/s-1. Furthermore, we demonstrate that multiple valves can be used to create amplification circuits, able to drive stiffer pneumatic actuators. Such circuits can amplify pressure signals by 10 folds, using only 2 valves.",

author = "Mostafa Mousa and Yuxuan Wang and Ashkan Rezanejad and Antonio Forte",

year = "2025",

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TY - CONF

T1 - Ultra-Sensitive & Fully-Soft Pneumatic Valve for High-Speed Oscillatory Applications

AU - Mousa, Mostafa

AU - Wang, Yuxuan

AU - Rezanejad, Ashkan

AU - Forte, Antonio

PY - 2025/1/3

Y1 - 2025/1/3

N2 - Recently, soft valves have been designed to enhance functionality in soft robots and achieve embodied control. However, most designs still use rigid components, need high control pressure to activate, and are not able to generate high-frequency oscillations. Here, we present a fully-soft valve, which can be triggered by kinking an elastomeric sleeve by using an inflatable origami pouch. The valve is compatible with high supply pressures and can interrupt a flow 100 times larger than its control signal. Afterwards, we use the valve to build fluidic oscillator circuits. These circuits exhibit high frequency oscillations which are tunable on the fly by sliding the valve actuator. We demonstrate the applicability of the circuit by driving a robot that swims at 0.5 BL/s-1. Furthermore, we demonstrate that multiple valves can be used to create amplification circuits, able to drive stiffer pneumatic actuators. Such circuits can amplify pressure signals by 10 folds, using only 2 valves.

AB - Recently, soft valves have been designed to enhance functionality in soft robots and achieve embodied control. However, most designs still use rigid components, need high control pressure to activate, and are not able to generate high-frequency oscillations. Here, we present a fully-soft valve, which can be triggered by kinking an elastomeric sleeve by using an inflatable origami pouch. The valve is compatible with high supply pressures and can interrupt a flow 100 times larger than its control signal. Afterwards, we use the valve to build fluidic oscillator circuits. These circuits exhibit high frequency oscillations which are tunable on the fly by sliding the valve actuator. We demonstrate the applicability of the circuit by driving a robot that swims at 0.5 BL/s-1. Furthermore, we demonstrate that multiple valves can be used to create amplification circuits, able to drive stiffer pneumatic actuators. Such circuits can amplify pressure signals by 10 folds, using only 2 valves.

M3 - Paper

ER -

Ultra-Sensitive & Fully-Soft Pneumatic Valve for High-Speed Oscillatory Applications

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