TY - JOUR
T1 - Numerical study of heat transfer in ascending mixed convection with internal heat generation
AU - Kasam, Alisha
AU - Lee, Jeong Ik
AU - Shwageraus, Eugene
N1 - Funding Information:
The first author acknowledges financial support from The Winston Churchill Foundation of the United States , The Cambridge Commonwealth , European & International Trust and a Churchill Pochobradsky Scholarship . We thank Dr Andrea Giusti and Xinyu Zhao of the University of Cambridge for assistance with OpenFOAM models, and Professor Stuart Cant of the University of Cambridge for valuable discussions. This work was performed using the Cambridge Service for Data Driven Discovery (CSD3) operated by the University of Cambridge Research Computing Service ( http://www.csd3.cam.ac.uk/ ), provided by Dell EMC and Intel using Tier-2 funding from the Engineering and Physical Sciences Research Council , and DiRAC funding from the Science and Technology Facilities Council ( www.dirac.ac.uk ).
Publisher Copyright:
© 2019 Elsevier Ltd
PY - 2019/11/1
Y1 - 2019/11/1
N2 - This study explores heat transfer behaviour in mixed convection of a fluid with internal heat generation, a situation found in chemical and nuclear engineering contexts. Computational fluid dynamics is used to simulate laminar ascending mixed convection flow of a heat-generating fluid in a vertical cylinder with uniformly cooled wall, based on a liquid nuclear fuel concept. A new non-dimensional parameter, the IHG-flux number Ω, is developed to express the balance of axial convection versus radial conduction heat transfer. It was found that heat transfer behaviour depends on this parameter, and it can be used as the transition criterion to categorise the simulated results into three distinct heat transfer regimes. A heat transfer correlation using Ω was also developed for Regime I with small values of Ω, where convection and conduction effects are balanced in a stable flow. In Regime II at intermediate Ω, stronger convection gives rise to flow instability. In Regime III with large Ω, convection dominates and the temperature profile inverts so that the maximum temperature occurs at the wall, while instability remains likely.
AB - This study explores heat transfer behaviour in mixed convection of a fluid with internal heat generation, a situation found in chemical and nuclear engineering contexts. Computational fluid dynamics is used to simulate laminar ascending mixed convection flow of a heat-generating fluid in a vertical cylinder with uniformly cooled wall, based on a liquid nuclear fuel concept. A new non-dimensional parameter, the IHG-flux number Ω, is developed to express the balance of axial convection versus radial conduction heat transfer. It was found that heat transfer behaviour depends on this parameter, and it can be used as the transition criterion to categorise the simulated results into three distinct heat transfer regimes. A heat transfer correlation using Ω was also developed for Regime I with small values of Ω, where convection and conduction effects are balanced in a stable flow. In Regime II at intermediate Ω, stronger convection gives rise to flow instability. In Regime III with large Ω, convection dominates and the temperature profile inverts so that the maximum temperature occurs at the wall, while instability remains likely.
KW - Computational fluid dynamics (CFD)
KW - Internal heat generation
KW - Mixed convection
UR - http://www.scopus.com/inward/record.url?scp=85065705243&partnerID=8YFLogxK
U2 - 10.1016/j.anucene.2019.05.004
DO - 10.1016/j.anucene.2019.05.004
M3 - Article
AN - SCOPUS:85065705243
SN - 0306-4549
VL - 133
SP - 138
EP - 144
JO - Annals of Nuclear Energy
JF - Annals of Nuclear Energy
ER -