Near-wall Reynolds stress modelling for RANS and hybrid RANS/LES methods

Similar documents
Numerical Methods in Aerodynamics. Turbulence Modeling. Lecture 5: Turbulence modeling

Transition Modeling Activities at AS-C²A²S²E (DLR)

Available online at ScienceDirect. Procedia Engineering 79 (2014 ) 49 54

Zonal hybrid RANS-LES modeling using a Low-Reynolds-Number k ω approach

There are no simple turbulent flows

Resolving the dependence on free-stream values for the k-omega turbulence model

Turbulent eddies in the RANS/LES transition region

Initial Efforts to Improve Reynolds Stress Model Predictions for Separated Flows

RECONSTRUCTION OF TURBULENT FLUCTUATIONS FOR HYBRID RANS/LES SIMULATIONS USING A SYNTHETIC-EDDY METHOD

Masters in Mechanical Engineering. Problems of incompressible viscous flow. 2µ dx y(y h)+ U h y 0 < y < h,

Hybrid LES RANS Method Based on an Explicit Algebraic Reynolds Stress Model

Hybrid RANS/LES Simulations of Supersonic base flow

Numerical investigation of swirl flow inside a supersonic nozzle

Turbulence Modeling I!

Boundary-Layer Theory

Turbulent Boundary Layers & Turbulence Models. Lecture 09

Explicit algebraic Reynolds stress models for internal flows

Comparison of Turbulence Models in the Flow over a Backward-Facing Step Priscila Pires Araujo 1, André Luiz Tenório Rezende 2

Wall treatments and wall functions

Platzhalter für Bild, Bild auf Titelfolie hinter das Logo einsetzen

Perspectives on Reynolds Stress Modeling Part I: General Approach. Umich/NASA Symposium on Advances in Turbulence Modeling

WALL ROUGHNESS EFFECTS ON SHOCK BOUNDARY LAYER INTERACTION FLOWS

Transitionsmodellierung technischer Strömungen

Part 3. Stability and Transition

Novel uses of DNS with turbulent separation for RANS models

Shock/boundary layer interactions

AER1310: TURBULENCE MODELLING 1. Introduction to Turbulent Flows C. P. T. Groth c Oxford Dictionary: disturbance, commotion, varying irregularly

Attached and Detached Eddy Simulation

Review and Assessment of Turbulence Transition Models

Direct Numerical Simulations of Transitional Flow in Turbomachinery

Hybrid RANS/LES employing Interface Condition with Turbulent Structure

Computation of hypersonic shock boundary layer interaction on a double wedge using a differential Reynolds Stress Model

STRESS TRANSPORT MODELLING 2

SG Turbulence models for CFD

Introduction to PDEs and Numerical Methods Tutorial 5. Finite difference methods equilibrium equation and iterative solvers

RANS modeling for compressible and transitional flows

Direct Numerical Simulation of Jet Actuators for Boundary Layer Control

Tutorial School on Fluid Dynamics: Aspects of Turbulence Session I: Refresher Material Instructor: James Wallace

Numerical investigations of separation-induced transition on high-lift low-pressure turbine using RANS and LES methods

Conjugate Heat Transfer Analysis of a high loaded convection cooled Vane with STAR-CCM+

A high-order discontinuous Galerkin solver for 3D aerodynamic turbulent flows

Table of Contents. Foreword... xiii. Preface... xv

Simulation of low Mach number flows

Mestrado Integrado em Engenharia Mecânica Aerodynamics 1 st Semester 2012/13

FLUTTER PREDICTION IN THE TRANSONIC FLIGHT REGIME WITH THE γ-re θ TRANSITION MODEL

A dynamic global-coefficient subgrid-scale eddy-viscosity model for large-eddy simulation in complex geometries

Examination of the Shear Stress Transport Assumption with a Low-Reynolds Number k ω Model for Aerodynamic Flows

C. Mockett, M. Fuchs & F. Thiele

Simulations for Enhancing Aerodynamic Designs

NONLINEAR FEATURES IN EXPLICIT ALGEBRAIC MODELS FOR TURBULENT FLOWS WITH ACTIVE SCALARS

LAMINAR-TURBULENT TRANSITION FOR ATTACHED AND SEPARATED FLOW

The Simulation of Wraparound Fins Aerodynamic Characteristics

Compressible Flow LES Using OpenFOAM

AA214B: NUMERICAL METHODS FOR COMPRESSIBLE FLOWS

Introduction to ANSYS FLUENT

CFD in Heat Transfer Equipment Professor Bengt Sunden Division of Heat Transfer Department of Energy Sciences Lund University

Design of a Droopnose Configuration for a Coanda Active Flap Application. Marco Burnazzi and Rolf Radespiel

Problem 4.3. Problem 4.4

Perspective on Turbulence Modeling using Reynolds Stress Models : Modification for pressure gradients

GARTEUR/TP-108-2, FFA TN GARTEUR LIMITED 2 GARTEUR LIMITED

Computation of Complex Compressible Aerodynamic Flows with a Reynolds Stress Turbulence Model

Large eddy simulation of turbulent flow over a backward-facing step: effect of inflow conditions

Challenges for RANS Models in Turbomachinery Flows

OpenFOAM Simulations for MAV Applications

Process Chemistry Toolbox - Mixing

Numerical Investigation of the Transonic Base Flow of A Generic Rocket Configuration

Uncertainty Quantification of Turbulence Model Closure Coefficients on Openfoam and Fluent for Mildly Separated Flows

A Multi-Dimensional Limiter for Hybrid Grid

Turbulence - Theory and Modelling GROUP-STUDIES:

AN UNCERTAINTY ESTIMATION EXAMPLE FOR BACKWARD FACING STEP CFD SIMULATION. Abstract

WALL PRESSURE FLUCTUATIONS IN A TURBULENT BOUNDARY LAYER AFTER BLOWING OR SUCTION

arxiv: v1 [physics.flu-dyn] 15 Oct 2014

Platzhalter für Bild, Bild auf Titelfolie hinter das Logo einsetzen

Introduction to Turbulence AEEM Why study turbulent flows?

Physics of turbulent flow

Introduction to Turbulence and Turbulence Modeling

Development and Application of Hybrid Wray- Agarwal Turbulence Model and Large-Eddy Simulation

Turbulence modelling. Sørensen, Niels N. Publication date: Link back to DTU Orbit

A parametrized non-equilibrium wall-model for large-eddy simulations

Active Control of Separated Cascade Flow

arxiv: v1 [physics.flu-dyn] 4 Aug 2014

EFFECT OF REYNOLDS NUMBER ON THE UNSTEADY FLOW AND ACOUSTIC FIELDS OF SUPERSONIC CAVITY

Large-eddy simulations for wind turbine blade: rotational augmentation and dynamic stall

DETACHED-EDDY SIMULATION OF FLOW PAST A BACKWARD-FACING STEP WITH A HARMONIC ACTUATION

An evaluation of a conservative fourth order DNS code in turbulent channel flow

Colloquium FLUID DYNAMICS 2012 Institute of Thermomechanics AS CR, v.v.i., Prague, October 24-26, 2012 p.

Hybrid RANS/LES simulations of a cavitating flow in Venturi

BOUNDARY LAYER FLOWS HINCHEY

Publication 97/2. An Introduction to Turbulence Models. Lars Davidson, lada

The Scale-Adaptive Simulation Method for Unsteady Turbulent Flow Predictions. Part 1: Theory and Model Description

Royal Aeronautical Society 2016 Applied Aerodynamics Conference Tuesday 19 th Thursday 21 st July Science Centre, Bristol, UK

Optimizing calculation costs of tubulent flows with RANS/LES methods

DG Methods for Aerodynamic Flows: Higher Order, Error Estimation and Adaptive Mesh Refinement

FLOW-NORDITA Spring School on Turbulent Boundary Layers1

Prospects for High-Speed Flow Simulations

HEAT TRANSFER IN A RECIRCULATION ZONE AT STEADY-STATE AND OSCILLATING CONDITIONS - THE BACK FACING STEP TEST CASE

MODELLING OF INFLUENCE OF TURBULENT TRANSITION ON HEAT TRANSFER CONDITIONS KRZYSZTOF BOCHON, WŁODZIMIERZ WRÓBLEWSKI

Assessment of Various Diffuser Structures to Improve the Power Production of a Wind Turbine Rotor

1. Introduction Some Basic Concepts

Masters in Mechanical Engineering Aerodynamics 1 st Semester 2015/16

Transcription:

Platzhalter für Bild, Bild auf Titelfolie hinter das Logo einsetzen Near-wall Reynolds stress modelling for RANS and hybrid RANS/LES methods Axel Probst (now at: C 2 A 2 S 2 E, DLR Göttingen) René Cécora, Rolf Radespiel (Institute of Fluid Mechanics, TU Braunschweig) TAU-User Meeting 2011, 18.10.-19.10.2011, DLR Braunschweig

Outline Motivation Near-wall Reynolds-stress (U)RANS modelling model description and implementation validation for subsonic flows validation for transonic flows RSM-based hybrid RANS/LES (DES) modelling Conclusion TAU-User Meeting 2011 Page 2

Motivation turbulence modelling is dominant limit to simulation accuracy (esp. at flight boundaries) Goals: 1. avoid known weaknesses of common eddy-viscosity models: isotropy-assumption, no curvature effects, Reynolds stress strain alignment, individual modelling of Reynolds stresses (RSM) 2. extend model validity down to walls: most models (e.g. present TAU models) neglect near-wall effects use of near-wall (i.e. Low-Reynolds) damping and specific length-scale variable 3. combat remaining RANS weakness in separation: use near-wall RSM in hybrid RANS/LES framework Main applications: focus on flight boundaries (stall, shock-induced separation, ) academic subsonic flows in 2D (airfoils) and 3D (engine inlets) in DFG-FOR1066 industrial subsonic and transonic flows (airfoils, wings, full aircrafts) in ComFliTe TAU-User Meeting 2011 Page 3

TAU-User Meeting 2011 Page 4 Ф ij : linear or quadratic redistribution + wall reflection DNS-based calibration of low-reynolds damping functions ( term-by-term ): D ij : gradient diffusion model (GGDH) from: Jakirlić (1997) Low-Re ε h -based RSM (Jakirlić et al. 2002, Probst et al. 2008): Near-wall Reynolds-stress model Reynolds-stress equation: l j l i x u x u 2 i j j i x u x u p il j jl i j i l l u u p u u u x ij ij D ij P ij k j i k x u u x

Length-scale equation total inhomogeneous Scale-supplying variable: homogeneous part of dissipation h 0. 5 D ε h -equation: homogeneous similar to classical ε-equations, but correct nearwall behaviour additional non-equilibrium terms: length-scale growth limiter sensitize model to pressure-gradients algebraic model to obtain ε h ij = f(εh ) two coefficient sets: original calibration: JHh-v1 RSM reduced dp/dx-sensitivity: JHh-v2 RSM Flat plate Re Θ = 1410 TAU-User Meeting 2011 Page 5

Implementation in TAU-Code General: based on present ω-rsm-implementations upwind convection schemes (Roe, Roe2nd) implicit source-term treatment benefits from LU-SGS and Full-Multigrid Special requirements: 2nd (mixed) derivatives of velocity local wall normals in the field (iterative) solution of relation ε h ij = f(εh ) computation of complex damping functions transition trip to induce turbulence onset wct. increase by factor ~1.5 compared to SSG/LRR-ω RSM Convergence history for HGR-01 airfoil, α = 4 TAU-User Meeting 2011 Page 6

Basic validation of RANS-RSM various generic flow cases subsonic/transonic, constant/variable pressure, transitional/turbulent, some examples: streamwise velocity Turbulent diffusor Oblique shock-bl interaction Laminar separation bubble TAU-User Meeting 2011 Page 7

Subsonic 2D flows single-element HGR-01 airfoil Re = 0,65x10 6, Ma = 0,07 maximum lift (α = 12 ) JHh-v1 RSM TAU-User Meeting 2011 Page 8

Subsonic 2D flows single-element HGR-01 airfoil Re = 1,3x10 6, Ma = 0,14 maximum lift (α = 12 ) JHh-v1 RSM TAU-User Meeting 2011 Page 9

Subsonic 3D flows engine inlet axisymmetric flow-through nacelle (DFG-FOR1066) Re = 1.3 x 10 6, computed transition (e N ) α = 23.5 separation topology θ = 180 JHh-v2 RSM JHh-v2 RSM α = 24.5 sep. onset and topology well captured by RSMs separation onset far too early with k-ω SST TAU-User Meeting 2011 Page 10

Transonic 2D flows RAE2822 airfoil Re = 6.5 x 10 6, α = 2.8 grid-converged results (736 x 176 points, shock refined) Case 9: Ma = 0.73 TAU-User Meeting 2011 Page 11

Transonic 2D flows RAE2822 airfoil Re = 6.5 x 10 6, α = 2.8 grid-converged results (736 x 176 points, shock refined) Case 9: Ma = 0.73 Case 10: Ma = 0.75 TAU-User Meeting 2011 Page 12

Transonic 3D flows wing flow Onera-M6 wing at Re = 11.72 x 10 6, Ma = 0.84 α = 4.08 : onset of shock-induced separation Menter SST SSG/LRR-ω-RSM JHh-v2 RSM TAU-User Meeting 2011 Page 13

Transonic 3D flows wing flow Onera-M6 wing at Re = 11.72 x 10 6, Ma = 0.84 α = 4.08 : onset of shock-induced separation TAU-User Meeting 2011 Page 14

Transonic 3D flows powered engine inlet industrial engine nacelle LARA with mass suction validation at start conditions with gust: low-ma onflow, large massflow, high incidence transonic flow portions, shock-induced separation disturbance of p tot in fan-plane DC60 JHh-v2 RSM JHh-v2 RSM separation onset just about 0.5-1 too early TAU-User Meeting 2011 Page 15

Basic ε h -RSM-based DES (ε h -DES) General approach: combine RANS model with LES in separated regime replace length scale in dissipation term with DES scale: calibration / validation with DIT case: central scheme with Matrix-dissipation low-ma preconditioning skew-symmetric flux form (energy-conserving) best results with C DES = 1.1 Decaying isotropic turbulence TAU-User Meeting 2011 Page 16

Backward-facing step with ε h -DES Re h = 37500 (Driver & Seegmiller, 1985) RANS/LES sensors: DDES, ADDES grid study: 2.6 million 8.8 million points expected and consistent improvement over RANS TAU-User Meeting 2011 Page 17 Q-criterion, colored with spanwise velocity

Conclusion overview over Reynolds-stress modelling efforts at ISM, TU Braunschweig ε h -based RSM with DNS-based near-wall modelling and non-equilibrium extensions implemented in TAU and extensively validated JHh-v2 RSM offers best compromise (but loss of accuracy at subsonic airfoil stall) Benefits: (theoretical) advantages by better representation of near-wall physics in 2D/3D and sub-/transonic testcases mostly at least as good as reference models stall prediction in 2D and 3D improved over eddy-viscosity models Drawbacks: transition tripping required (however, solutions are available) increased computational effort (awaiting optimization) moreover, potential as DES-background model demonstrated currently being implemented in central TAU-version ( release 2012) TAU-User Meeting 2011 Page 18

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback