Effects of rib geometries and property variations on heat transfer to supercritical water in internally ribbed tubes

Flow and heat transfer of supercritical water (SCW), which experiences dramatic thermophysical property variations and is regarded as Variable Property Fluid (VPF), was numerically studied in vertical upward internally ribbed tubes (IRT). The Shear-Stress Transport k-ω model was employed to solve th...

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Bibliographic Details
Published in:Applied thermal engineering 2015-03, Vol.78, p.303-314
Main Authors: Li, Zhouhang, Lu, Junfu, Tang, Guoli, Liu, Qing, Wu, Yuxin
Format: Article
Language:English
Subjects:
Computational fluid dynamics
Fluid flow
Fluids
Heat transfer
Internally ribbed tube
Mathematical models
Rib geometries
Supercritical water
Tubes
Turbulence
Turbulent flow
Variable property fluid
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Summary:Flow and heat transfer of supercritical water (SCW), which experiences dramatic thermophysical property variations and is regarded as Variable Property Fluid (VPF), was numerically studied in vertical upward internally ribbed tubes (IRT). The Shear-Stress Transport k-ω model was employed to solve the turbulent flow and conjugate heat transfer. After validating the model against experimental data from IRT with different geometries, effects of rib geometries on heat transfer to SCW were studied at a pressure of 25 MPa, mass velocity between 600 and 1000 kg/(m2s) and heat flux between 200 and 470 kW/m2. Impact of property variations in IRT is analyzed by comparing SCW flow and Constant Property Fluid (CPF) flow. For the CPF case, IRT always has superior performance over smooth tubes. As for SCW flow, rib geometries play only a small role in both average and local heat transfer under conditions of forced convection. While in mixed convection rib geometries have a significant effect on heat transfer by suppressing the buoyancy effect along the whole circumference to different extents, and by helping SCW recover its large cooling capacity. Internal ribs can more efficiently improve heat transfer to VPF when compared with CPF at the same Reynolds number. •Roles of rib geometries in heat transfer differ when the flow condition changes.•In forced convection rib geometries have little effect on heat transfer.•In mixed convection internal ribs inhibit buoyancy along the entire circumference.•Internal ribs help supercritical water recover its great cooling capacity.•Ribs improve heat transfer more efficiently when sharp property variations occur.
ISSN:1359-4311
DOI:10.1016/j.applthermaleng.2014.12.067