A New Modified k-ɛ Turbulence Model for Predicting Compressible Flow in Non- Symmetrical Planar-Curvature Converging-Diverging Supersonic Nozzle

Authors

  • Hariyotejo Pujowidodor Center for Thermodynamics Engine and Propulsion (BT2MP-BPP Teknologi), Puspiptek Area, Setu, South Tangerang, banten, Indonesia
  • Ahmad Indra Siswantara Department of Mechanical Engineering, Faculty of Engineering, University of Indonesia, Depok, West Java, Indonesia
  • Budiarso Department of Mechanical Engineering, Faculty of Engineering, University of Indonesia, Depok, West Java, Indonesia
  • Gun Gun Ramdlan Gunadi Department of Mechanical Engineering, State Polytechnic of Jakarta, Depok,West Java, Indonesia
  • Candra Damis Widiawaty Department of Mechanical Engineering, State Polytechnic of Jakarta, Depok,West Java, Indonesia

Keywords:

Dissipation rate, RSM, turbulence kinetic energy, k-ε RNG, k-ε standard

Abstract

Convergent-Divergent (CD) nozzle of a compressible fluid is a common device to

accelerate fluid flow to a higher supersonic speed and to direct or modify the fluid flow.

CD nozzle has been applied in wide range of fluid equipment such as turbine power,

chemical mixing equipment, turbo-jet engine, and rocket. The performance of CD

nozzle is strongly affected by its geometry at certain pressure ratio and the flow

characteristic. In the case of complicated flow phenomena within a supersonic flow,

especially in the turbulence flow, many studies use the computational simulation to

obtain the detailed behavior and properties of flow. However, the k-epsilon turbulence

model has limitations in predicting the effect of dissipation due to the viscous friction.

This study aims to propose the new modified k-ε turbulence model in planar- curvature

Convergent-Divergent (CD) nozzle of a compressible fluid. Two equations model of

modified Standard k-ε for predicting the compressible flow within planar- curvature CD

nozzle was discussed. The simulation model was run in 2D and steady, while fluid was

assumed as an ideal gas with domain size was 0.65 m length, 0.071 m width. In

addition, it has been discretized in 3510 structured independent grid cells. The results

depicted that in the divergent section of the nozzle (supersonic region), the fluid

expansion caused the change in fluid parameters such as time-average of pressure,

temperature, density, and velocity. This study found that the expanded cross-sectional

area with non-symmetrical planar curvature affected the turbulence behavior and

properties. Furthermore, the new modified constants of c2 in dissipation equation and

cμ of eddy viscosity model could give a better prediction than the original constant of

the k-ε turbulence model.

 

 

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Published

2024-10-14

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