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3D‐Printed Electrohydrodynamic Pump and Development of Anti‐Swelling Organohydrogel for Soft Robotics

Yangyang Xin, Xinran Zhou, Ming Rui Joel Tan, Shaohua Chen, Pei-Wen Huang, Yawei Jiang, Wenting Wu, Dace Gao, Jian Lv, Shlomo Magdassi, Pooi See Lee

2025Advanced Materials32 citationsDOIOpen Access PDF

Abstract

Abstract This study introduces advancements in electrohydrodynamic (EHD) pumps and the development of a 3D‐printable anti‐swelling organohydrogel for soft robotics. Using digital light processing (DLP)technology, precise components with less than 1% size variation are fabricated, enabling a unique manifold pump array. This design achieves an output pressure of 90.2 kPa—18 times higher than traditional configurations—and a flow rate of 800 mL min −1 , surpassing previous EHD pumps. To address swelling issues in dielectric liquids, a novel organohydrogel is developed with Young's modulus of 0.33 MPa, 300% stretchability, and a swelling ratio under 10%. Its low swelling is attributed to the shield effect and edge length confinement effect. This durable material ensures consistent pump performance under mechanical stresses like bending and twisting, crucial for dynamic soft robotic environments. These innovations significantly improve EHD pump efficiency and reliability, expanding their potential applications in soft robotics, bioengineering, and vertical farming.

Topics & Concepts

ElectrohydrodynamicsSoft roboticsMaterials scienceSwellingNanotechnologySoft materialsRoboticsArtificial intelligenceBiomedical engineeringComposite materialComputer scienceEngineeringRobotElectric fieldQuantum mechanicsPhysicsDielectric materials and actuatorsAdvanced Sensor and Energy Harvesting MaterialsElectrohydrodynamics and Fluid Dynamics
3D‐Printed Electrohydrodynamic Pump and Development of Anti‐Swelling Organohydrogel for Soft Robotics | Litcius