Jump to navigation Jump to search
No edit summary
m (Removed semantic markup.)
 
(12 intermediate revisions by 5 users not shown)
Line 1: Line 1:
[[Description]]    [[Test Data]]  [[CFD Simulations]]  [[Evaluation]]  [[Quality Review]]  [[Best Practice Advice]]  [[Related UFRs]]
{{AC|front=AC 1-01|description=Description_AC1-01|testdata=Test Data_AC1-01|cfdsimulations=CFD Simulations_AC1-01|evaluation=Evaluation_AC1-01|bestpractice=Best Practice Advice_AC1-01}}
 
== Application Area 1: External Aerodynamics ==
== Application Area 1: External Aerodynamics ==
=== Application Challenge AC1-01 ===
=== Application Challenge AC1-01 ===
Line 25: Line 26:
----
----
''Contributors: Fred Mendonca; Richard Allen - Computational Dynamics Ltd''
''Contributors: Fred Mendonca; Richard Allen - Computational Dynamics Ltd''
{{AC|front=AC 1-01|description=Description_AC1-01|testdata=Test Data_AC1-01|cfdsimulations=CFD Simulations_AC1-01|evaluation=Evaluation_AC1-01|bestpractice=Best Practice Advice_AC1-01}}

Latest revision as of 11:32, 14 January 2022

Front Page

Description

Test Data

CFD Simulations

Evaluation

Best Practice Advice

Application Area 1: External Aerodynamics

Application Challenge AC1-01

Abstract

This application challenge is proposed by Computational Dynamics, Partner 34 of the QNET-CFD Thematic network.

The test case is derived from testing of the M219 cavity model and formed part of a joint BAe/DERA (now BAE SYSTEMS and QinetiQ, respectively) programme at the ARA transonic wind tunnel at Bedford. The wind tunnel model configuration is shown in Figure 1 (section 1.4) and consists of an empty, rectangular cavity, with an L/D ratio of 5, set into the flat surface of the rig.

Cavity flows are of general interest in both low and high-speed environments, for from the point of view of comfort (passengers experiencing acoustic buffeting in automotive cabins) and component reliability (equipment in aircraft cavities). This poses a significant challenge to the modellers insofar as it is a multi-physics problem; fluid flow modelling needing to be carefully specified to fulfil the requirements for dipole and quadrupole acoustic source prediction. The modeller’s challenges are towards building and understanding of the effects of, and minimum requirements related to;

• Space and time discretisation (and associate CFD solver methodologies).

• Using appropriate turbulence modelling (suitability of RANS, LES and combinations thereof).

• Achieving reasonable run times for three-dimensional geometries of industrial interest.

This test case from the M219 study, although simple in geometry, contains all the factors relevant to the modelling of aeroacoustic dipole and quadrupole sources. Prediction of the tonal, high-energy narrow-band modes are of particular interest in structural design (fatigue), and at high flow speeds the mechanisms that generate broad-band modes need to be understood from the viewpoint of noise attenuation. Also, knowledge of the flow patterns within and around the cavity give an improved indication of the behaviour or acoustic perception by objects in the cavity volume.

This application challenge represents an ideal assessment of the ability of CFD codes to predict the detailed flow physics and acoustic nature of a simple cavity within industrially acceptable run times.

The means by which the CFD is validated against measurements is point-wise pressure histories. These data, processed via Fourier Transforms, allow the analysis of the acoustic tone signatures; in particular the power spectral density, RMS pressure and sound pressure level.


Contributors: Fred Mendonca; Richard Allen - Computational Dynamics Ltd


Front Page

Description

Test Data

CFD Simulations

Evaluation

Best Practice Advice