Comparison of different {kappa}-{epsilon} models for indoor air flow computations
- Massachusetts Inst. of Tech., Cambridge, MA (United States). Dept. of Architecture
In this article, five {kappa}-{epsilon}, two-equation models are studied: the standard {kappa}-{epsilon} model, a low-Reynolds-number {kappa}-{epsilon} model, a two-layer {kappa}-{epsilon} model, a two-scale {kappa}-{epsilon} model, and a renormalization group (RNG) {kappa}-{epsilon} model. They are evaluated for their performance in predicting natural convection, forced convection, and mixed convection in rooms, as well as an impinging jet flow. Corresponding experimental data from the literature are used for validation. It is found that the prediction of the mean velocity is more accurate than that of the turbulent velocity. These models are neither able to predict anisotropic turbulence correctly nor to pick up the secondary recirculation of indoor air flow; otherwise the performance of the standard {kappa}-{epsilon} model is good. The RNG {kappa}-{epsilon} model is slightly better than the standard {kappa}-{epsilon} model and is therefore recommended for simulations of indoor air flow. The performance of the other models is not stable.
- Sponsoring Organization:
- USDOE
- OSTI ID:
- 137115
- Journal Information:
- Numerical Heat Transfer. Part B, Fundamentals, Journal Name: Numerical Heat Transfer. Part B, Fundamentals Journal Issue: 3 Vol. 28; ISSN 1040-7790; ISSN NHBFEE
- Country of Publication:
- United States
- Language:
- English
Similar Records
Comparison of linear and nonlinear RNG-based {kappa}-{epsilon} models for incompressible turbulent flows
A comparison of the linear and nonlinear [kappa]-[epsilon] turbulence models in combustors