Fast fluid heating by adaptive flow reorientation

TL;DR

This paper develops an adaptive flow reorientation strategy that significantly accelerates fluid heating by optimizing flow control based on thermal behavior, outperforming traditional mixing-based methods across various conditions.

Contribution

It introduces a novel real-time adaptive flow control method that optimizes heat transfer by considering thermal effects, surpassing conventional mixing strategies.

Findings

Adaptive flow reorientation accelerates fluid heating.

The method outperforms traditional periodic mixing schemes.

Performance is consistent across different flow conditions.

Abstract

Scalar transport (e.g. heat or chemical species) in laminar flows is key to many industrial activities and fluid stirring by flow reorientation is a common way to enhance this process. However, "How best to stir?" remains a major challenge. This study aims to contribute to existing solutions by the development of a dedicated flow-control strategy for the fast heating of a cold fluid via a hot boundary in a representative case study. Fluid deformation acts as the "thermal actuator" via which the flow affects heat transfer yet this may both enhance and diminish heat exchange between fluid parcels and thus restricts the beneficial impact of flow. Moreover, the impact of fluid deformation on the global fluid heating is primarily confined to the proximity of the moving boundary that drives the flow. These insights make incorporation of thermal behaviour essential for effective flow-based enhancement strategies and expose fluid mixing, the conventional approach in industry, as potentially sub-optimal. The notion that global heating encompasses two concurrent processes, i.e. increasing energy content and thermal homogenisation, yields the relevant metrics for the formulation of the control problem as the minimisation of a dedicated cost function. This facilitates step-wise determination of the "best" flow reorientation from predicted future evolutions of actual intermediate states and thereby paves the way to (real-time) regulation of scalar transport by flow control. Performance analyses reveal that this "adaptive flow reorientation" significantly accelerates fluid heating and thus is superior to conventional periodic schemes (designed for efficient fluid mixing) both in consistency and effectiveness. The controller in fact never selects these periodic schemes and achieves the same superior performance for all flow conditions irrespective of whether said mixing occurs.