Abstract
Latent heat thermal energy storages (LHTES) exploit the high energy density of phase change material (PCM).
The typically low thermal conductivity of PCM limits the charging and discharging rates and poses considerable
challenges for dynamic storage operation. To operate LHTES efficiently and to exploit their full potential, new
methods are required to obtain accurate and fast models for state of charge estimation and control tasks. In
LHTES the heat transfer in low viscosity PCM is driven by conduction and also significantly by convective
transport. In previous works, various high-precision models have been developed which employ finite element,
difference and volume methods to solve the coupled NavierStokes and energy equations, but they incur large
computational effort. In the present work, a novel, high-fidelity model reduction technique is proposed to
achieve real-time capability while preserving high model accuracy. The idea is to short-cut the laborious solution
of the NavierStokes equations by an efficiently parametrized, data-based model which approximates the stream
function of the typical convection flow pattern by singular value decomposition. To account for the complexity of
the solution-dependent flow domain, a suitable transformation method is proposed. The efficiency and accuracy
of the proposed reduction method is demonstrated in typical operating modes.
Original language | English |
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Number of pages | 15 |
Journal | Applied Thermal Engineering |
Volume | 184 |
Issue number | 116228 |
DOIs | |
Publication status | Published - 2021 |
Research Field
- Efficiency in Industrial Processes and Systems