Download This PaperDesign and Optimization of Pressure-Tolerant Flexible Systems Under Extreme Hydrostatic Pressure
15 Pages Posted: 3 Mar 2025
Abstract
Soft robots have been increasingly developed and deployed for deep-sea applications in recent years. Unlike traditional underwater robots that rely on bulky pressure vessels for protection, some soft robots can be directly exposed to hydrostatic pressure utilizing a polymer-encapsulation approach. This approach optimizes the structure of electronic components in soft robots to eliminate high-pressure interfaces, yet clear design guidelines remain absent due to its complexity. This paper introduces a design methodology for pressure-tolerant electronics, that leverages the Eshelby inclusion theory and finite element analysis. A parameter κ called the geometric coherence index for numerical optimization is proposed to evaluate the arrangement of PCB components. Calculations and simulations have demonstrated that the optimized circuit board components exhibit a reduction of up to 45.5% in both maximum and average shear stress under high hydrostatic pressure. A circuit board prototype has been manufactured and then tested at a depth of 10,900 m in the Mariana Trench. Field tests have confirmed the effectiveness of this method, demonstrating its potential for improving deep-sea exploration technologies.
Keywords: Pressure-tolerant systems, Soft robots, Mechanical optimization design, Eshelby inclusion, Extreme hydrostatic pressure
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