Revisiting low-fidelity two-fluid models for gas–solids transport
N Adeleke, M Adewumi, T Ityokumbul - Journal of Computational Physics, 2016 - Elsevier
N Adeleke, M Adewumi, T Ityokumbul
Journal of Computational Physics, 2016•ElsevierTwo-phase gas–solids transport models are widely utilized for process design and
automation in a broad range of industrial applications. Some of these applications include
proppant transport in gaseous fracking fluids, air/gas drilling hydraulics, coal-gasification
reactors and food processing units. Systems automation and real time process optimization
stand to benefit a great deal from availability of efficient and accurate theoretical models for
operations data processing. However, modeling two-phase pneumatic transport systems …
automation in a broad range of industrial applications. Some of these applications include
proppant transport in gaseous fracking fluids, air/gas drilling hydraulics, coal-gasification
reactors and food processing units. Systems automation and real time process optimization
stand to benefit a great deal from availability of efficient and accurate theoretical models for
operations data processing. However, modeling two-phase pneumatic transport systems …
Abstract
Two-phase gas–solids transport models are widely utilized for process design and automation in a broad range of industrial applications. Some of these applications include proppant transport in gaseous fracking fluids, air/gas drilling hydraulics, coal-gasification reactors and food processing units. Systems automation and real time process optimization stand to benefit a great deal from availability of efficient and accurate theoretical models for operations data processing. However, modeling two-phase pneumatic transport systems accurately requires a comprehensive understanding of gas–solids flow behavior. In this study we discuss the prevailing flow conditions and present a low-fidelity two-fluid model equation for particulate transport. The model equations are formulated in a manner that ensures the physical flux term remains conservative despite the inclusion of solids normal stress through the empirical formula for modulus of elasticity. A new set of Roe–Pike averages are presented for the resulting strictly hyperbolic flux term in the system of equations, which was used to develop a Roe-type approximate Riemann solver. The resulting scheme is stable regardless of the choice of flux-limiter. The model is evaluated by the prediction of experimental results from both pneumatic riser and air-drilling hydraulics systems. We demonstrate the effect and impact of numerical formulation and choice of numerical scheme on model predictions. We illustrate the capability of a low-fidelity one-dimensional two-fluid model in predicting relevant flow parameters in two-phase particulate systems accurately even under flow regimes involving counter-current flow.
Elsevier