Geometric theory of flexible and expandable tubes conveying fluid: equations, solutions and shock waves

TL;DR

This paper develops a comprehensive geometric theory for the dynamics of flexible, expandable tubes conveying fluid, including shock wave propagation, applicable to biological and industrial high-speed flow scenarios.

Contribution

It introduces a variational framework extending Cosserat rod theory to model arbitrary deformations, elasticity, and flow conditions in flexible, expandable tubes.

Findings

Derived conservation laws and Rankine-Hugoniot conditions for shock waves in flexible tubes.

Presented explicit solutions demonstrating the theory's applicability.

Applicable to biological flows and high-speed industrial gas transport.

Abstract

We present a theory for the three-dimensional evolution of tubes with expandable walls conveying fluid. Our theory can accommodate arbitrary deformations of the tube, arbitrary elasticity of the walls, and both compressible and incompressible flows inside the tube. We also present the theory of propagation of shock waves in such tubes and derive the conservation laws and Rankine-Hugoniot conditions in arbitrary spatial configuration of the tubes, and compute several examples of particular solutions. The theory is derived from a variational treatment of Cosserat rod theory extended to incorporate expandable walls and moving flow inside the tube. The results presented here are useful for biological flows and industrial applications involving high speed motion of gas in flexible tubes.