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{{AC|front=AC 1-01|description=Description_AC1-01|testdata=Test Data_AC1-01|cfdsimulations=CFD Simulations_AC1-01|evaluation=Evaluation_AC1 '''Application Challenge 1-01''' © copyright ERCOFTAC 2004

{{AC|front=AC 1-01|description=Description_AC1-01|testdata=Test Data_AC1-01|cfdsimulations=CFD Simulations_AC1-01|evaluation=Evaluation_AC1 '''Application Challenge 1-01''' © copyright ERCOFTAC 2004

{{AC|front=AC 4-02|description=Description_AC4-02|testdata=Test Data_AC4-02|cfdsimulations=CFD Simulation_AC4-02|evaluation=Evaluation_AC4- =='''Comparison of Test data and CFD'''==

{{AC|front=AC 3-10|description=Description_AC3-10|testdata=Test Data_AC3-10|cfdsimulations=CFD Simulations_AC3-10|evaluation=Evaluation_AC3 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 3-10|description=Description_AC3-10|testdata=Test Data_AC3-10|cfdsimulations=CFD Simulations_AC3-10|evaluation=Evaluation_AC3 ...d an approximate Reynolds number range of <math>5 x 10^{5}</math> to <math>1.2 x 10^{6}</math>.

{{AC|front=AC 1-08|description=Description_AC1-08|testdata=Test Data_AC1-08|cfdsimulations=CFD Simulations_AC1-08|evaluation=Evaluation_AC1 '''Application Challenge 1-08''' © copyright ERCOFTAC 2004

{{AC|front=AC 4-02|description=Description_AC4-02|testdata=Test Data_AC4-02|cfdsimulations=CFD Simulation_AC4-02|evaluation=Evaluation_AC4- ...t laboratory scale. In the model, the river is 54 m long and 3 m wide. The AC concerns a case with low-water discharge of 12.54 l/s which corresponds to

{{AC|front=AC 1-08|description=Description_AC1-08|testdata=Test Data_AC1-08|cfdsimulations=CFD Simulations_AC1-08|evaluation=Evaluation_AC1 '''Application Challenge 1-08''' © copyright ERCOFTAC 2004

{{AC|front=AC 3-02|description=Description_AC3-02|testdata=Test Data_AC3-02|cfdsimulations=CFD Simulations_AC3-02|evaluation=Evaluation_AC3 ...ependent on the very fine details of the geometry at the T-junction, these data are scaled by the rotation velocity near to the junction (at H/D = 3) : thi

{{AC|front=AC 3-03|description=Description_AC3-03|testdata=Test Data_AC3-03|cfdsimulations=CFD Simulations_AC3-03|evaluation=Evaluation_AC3 ...sorting and for the separation of immiscible liquids [[Evaluation_AC3-03#1|1]].

{{AC|front=AC 1-01|description=Description_AC1-01|testdata=Test Data_AC1-01|cfdsimulations=CFD Simulations_AC1-01|evaluation=Evaluation_AC1 '''Application Challenge 1-01''' © copyright ERCOFTAC 2004

{{AC|front=AC 3-08|description=Description_AC3-08|testdata=Test Case_AC3-08|cfdsimulations=CFD Simulations_AC3-08|evaluation=Evaluation_AC3 ...s flux, whereof also the global evaporation rates could be determined. The data for the different flow conditions also include the inlet conditions for air

{{AC|front=AC 4-02|description=Description_AC4-02|testdata=Test Data_AC4-02|cfdsimulations=CFD Simulation_AC4-02|evaluation=Evaluation_AC4- ...transport of sediment and the associated deformation of the bed. The input data for such a calculation are

{{AC|front=AC 6-02|description=Description_AC6-02|testdata=Test Data_AC6-02|cfdsimulations=CFD Simulations_AC6-02|evaluation=Evaluation_AC6 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 4-03|description=Description_AC4-03|testdata=Test Data_AC4-03|cfdsimulations=CFD Simulations_AC4-03|evaluation=Evaluation_AC4 ...FD evaluation. The measurements that are used here are summarised in Table 1. The internal temperature profiles within the occupied zone, Tint, were use

{{AC|front=AC 3-02|description=Description_AC3-02|testdata=Test Data_AC3-02|cfdsimulations=CFD Simulations_AC3-02|evaluation=Evaluation_AC3 A dedicated test rig comprising a T-junction has been tested in the Research and Development

{{AC|front=AC 5-05|description=Description_AC5-05|testdata=Test Data_AC5-05|cfdsimulations=CFD Simulations_AC5-05|evaluation=Evaluation_AC5 =='''Comparison of Test data and CFD'''==

...6-12 Quality Review|bestpractice=AC 6-12 Best Practice Advice|relatedUFRs=AC 6-12 Related ACs}} = Test Data =

{{AC|front=AC 3-11|description=Description_AC3-11|testdata=Test Data_AC3-11|cfdsimulations=CFD Simulations_AC3-11|evaluation=Evaluation_AC3 ...nd heating rates. An overview of the test cases measured is given in Table 1.

{{AC|front=AC 1-08|description=Description_AC1-08|testdata=Test Data_AC1-08|cfdsimulations=CFD Simulations_AC1-08|evaluation=Evaluation_AC1 '''Application Challenge 1-08''' © copyright ERCOFTAC 2004

{{AC|front=AC 1-05|description=Description_AC1-05|testdata=Test Data_AC1-05|cfdsimulations=CFD Simulations_AC1-05|evaluation=Evaluation_AC1 '''Application Challenge 1-05''' © copyright ERCOFTAC 2004

ERCOFTAC Knowledge Base Wiki, e.g., [[AC 1-05]] (Ahmed body), [[AC 1-08]] (L1T2 3 element ...[[AC 4-01]] (wind environment around an airport terminal building), and [[AC 4-03]] (Air flows in an open plan air conditioned office). Hence it is of h

...6-08 Quality Review|bestpractice=AC 6-08 Best Practice Advice|relatedUFRs=AC 6-08 Related ACs}} == Comparison of Test data and CFD ==

...6-10 Quality Review|bestpractice=AC 6-10 Best Practice Advice|relatedUFRs=AC 6-10 Related ACs}} ...schweig. The main objective of these investigations was to obtain accurate data for the validation of theoretical methods. The V2 cascade has a design poin

{{AC|front=AC 3-03|description=Description_AC3-03|testdata=Test Data_AC3-03|cfdsimulations=CFD Simulations_AC3-03|evaluation=Evaluation_AC3 ...erval. Each sampling operation was controlled by a ‘PET’ microcomputer and data were analysed either by fast Fourier transformation or curve fitting by a T

{{AC|front=AC 1-08|description=Description_AC1-08|testdata=Test Data_AC1-08|cfdsimulations=CFD Simulations_AC1-08|evaluation=Evaluation_AC1 '''Application Challenge 1-08''' © copyright ERCOFTAC 2004

{{AC|front=AC 1-02|description=Description_AC1-02|testdata=Test Data_AC1-02|cfdsimulations=CFD Simulations_AC1-02|evaluation=Evaluation_AC1 '''Application Challenge 1-02''' © copyright ERCOFTAC 2004

...6-10 Quality Review|bestpractice=AC 6-10 Best Practice Advice|relatedUFRs=AC 6-10 Related ACs}} = Test Data =

{{AC|front=AC 4-01|description=Description_AC4-01|testdata=Test Data_AC4-01|cfdsimulations=CFD Simulations_AC4-01|evaluation=Evaluation_AC4 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 2-07|description=Description_AC2-07|testdata=Test Case_AC2-07|cfdsimulations=CFD Simulations_AC2-07|evaluation=Evaluation_AC2 ...regions and recirculation regions (see Fig. 2 below). This is thus a good AC, since there is a relatively simple geometry (axisymmetric), and the abilit

{{AC|front=AC 4-01|description=Description_AC4-01|testdata=Test Data_AC4-01|cfdsimulations=CFD Simulations_AC4-01|evaluation=Evaluation_AC4 ...y of the wind environment around a large airport terminal building (Figure 1). The building is ~300m long and is roughly rectangular in plan, with an ae

{{AC|front=AC 1-05|description=Description_AC1-05|testdata=Test Data_AC1-05|cfdsimulations=CFD Simulations_AC1-05|evaluation=Evaluation_AC1 '''Application Challenge 1-05''' © copyright ERCOFTAC 2004

{{AC|front=AC 4-03|description=Description_AC4-03|testdata=Test Data_AC4-03|cfdsimulations=CFD Simulations_AC4-03|evaluation=Evaluation_AC4 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 6-05|description=Description_AC6-05|testdata=Test Data_AC6-05|cfdsimulations=CFD_Simulation_AC6-05|evaluation=Evaluation_AC6- ...[[#Figure 16|Figure 16]] and [[#Figure 17|Figure 17]]. For each and every test case examined, results in the form of circumferential mass average span-wis

{{AC|front=AC 1-02|description=Description_AC1-02|testdata=Test Data_AC1-02|cfdsimulations=CFD Simulations_AC1-02|evaluation=Evaluation_AC1 '''Application Challenge 1-02''' © copyright ERCOFTAC 2004

{{AC|front=AC 3-08|description=Description_AC3-08|testdata=Test Case_AC3-08|cfdsimulations=CFD Simulations_AC3-08|evaluation=Evaluation_AC3 =='''Comparison of Test data and CFD'''==

...6-12 Quality Review|bestpractice=AC 6-12 Best Practice Advice|relatedUFRs=AC 6-12 Related ACs}} ...The investigation of the SE 1050 blade cascade includes experimental test data based on interferometric pictures of fluid flow and numerical simulation us

{{AC|front=AC 1-02|description=Description_AC1-02|testdata=Test Data_AC1-02|cfdsimulations=CFD Simulations_AC1-02|evaluation=Evaluation_AC1 '''Application Challenge 1-02''' © copyright ERCOFTAC 2004

{{AC|front=AC 4-04|description=Description_AC4-04|testdata=Test Data_AC4-04|cfdsimulations=CFD Simulations_AC4-04|evaluation=Evaluation_AC4 The Memorial Tunnel Fire Ventilation Test Programme consists of a series of full-scale fire tests carried out in a di

...6-08 Quality Review|bestpractice=AC 6-08 Best Practice Advice|relatedUFRs=AC 6-08 Related ACs}} = Test Data =

...ed of relevance to the [[L1T2_3_element_airfoil|Application Challenge AC 1&ndash;08]] ...to some extent, to [[Wind_environment_around_an_airport_terminal_building|AC 4&ndash;01]]

...6-10 Quality Review|bestpractice=AC 6-10 Best Practice Advice|relatedUFRs=AC 6-10 Related ACs}} == Best Practice Advice for the AC ==

{{AC|front=AC 4-04|description=Description_AC4-04|testdata=Test Data_AC4-04|cfdsimulations=CFD Simulations_AC4-04|evaluation=Evaluation_AC4 ...of Transport and Public Works and considered only cases 615B and 621A. The test case considered in this document is 615B.

{{AC|front=AC 6-02|description=Description_AC6-02|testdata=Test Data_AC6-02|cfdsimulations=CFD Simulations_AC6-02|evaluation=Evaluation_AC6 =='''Best Practice Advice for the AC'''==

...6-07 Quality Review|bestpractice=AC 6-07 Best Practice Advice|relatedUFRs=AC 6-07 Related ACs}} ...The Reynolds number ReD, based on runner diameter and average velocity is 1 750 000.

{{AC|front=AC 3-03|description=Description_AC3-03|testdata=Test Data_AC3-03|cfdsimulations=CFD Simulations_AC3-03|evaluation=Evaluation_AC3 {|border="1" cell padding="20" cell spacing="3" width="600" align="center"

{{AC|front=AC 1-02|description=Description_AC1-02|testdata=Test Data_AC1-02|cfdsimulations=CFD Simulations_AC1-02|evaluation=Evaluation_AC1 '''Application Challenge 1-02''' © copyright ERCOFTAC 2004

{{AC|front=AC 1-08|description=Description_AC1-08|testdata=Test Data_AC1-08|cfdsimulations=CFD Simulations_AC1-08|evaluation=Evaluation_AC1 '''Application Challenge 1-08''' © copyright ERCOFTAC 2004

{{AC|front=AC 4-04|description=Description_AC4-04|testdata=Test Data_AC4-04|cfdsimulations=CFD Simulations_AC4-04|evaluation=Evaluation_AC4 ...ervals along the tunnel length were activated at certain times within each test. The activation of the jet fans enabled an assessment to be made of their e

{{AC|front=AC 3-02|description=Description_AC3-02|testdata=Test Data_AC3-02|cfdsimulations=CFD Simulations_AC3-02|evaluation=Evaluation_AC3 ...influence of the bulk velocity in the auxiliary pipe as indicated in Table 1, a comparison of two turbulence models and grid sensitivity studies.

{{AC|front=AC 3-08|description=Description_AC3-08|testdata=Test Case_AC3-08|cfdsimulations=CFD Simulations_AC3-08|evaluation=Evaluation_AC3 ...es of 5 mm. A description of the test case, the liquid properties, and the data is also available at:

{{AC|front=AC 3-11|description=Description_AC3-11|testdata=Test Data_AC3-11|cfdsimulations=CFD Simulations_AC3-11|evaluation=Evaluation_AC3 ...o 6000, and the Grashof number (based on heat flux) ranges from 1.1x108 to 1.4x109. Such flows with strong buoyancy influences are found in a number of

{{AC|front=AC 3-03|description=Description_AC3-03|testdata=Test Data_AC3-03|cfdsimulations=CFD Simulations_AC3-03|evaluation=Evaluation_AC3 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 2-07|description=Description_AC2-07|testdata=Test Case_AC2-07|cfdsimulations=CFD Simulations_AC2-07|evaluation=Evaluation_AC2 =='''Comparison of Test data and CFD'''==

The goal of the study on which this AC is based has been to understand and control transfer applications [[Best_Practice_Advice_AC6-14#References|[1]]], or to reduce unwanted pressure pulsations

{{AC|front=AC 4-03|description=Description_AC4-03|testdata=Test Data_AC4-03|cfdsimulations=CFD Simulations_AC4-03|evaluation=Evaluation_AC4 ...o model the temperature within the occupied zone (usually defined as up to 1.8m above floor level) given the value of the supply flow rate. Other import

{{AC|front=AC 6-02|description=Description_AC6-02|testdata=Test Data_AC6-02|cfdsimulations=CFD Simulations_AC6-02|evaluation=Evaluation_AC6 ...case is provided by Hathaway et al. (1993, 1995). A considerable amount of data including static pressure profiles, total temperature and total pressure pr

...6-12 Quality Review|bestpractice=AC 6-12 Best Practice Advice|relatedUFRs=AC 6-12 Related ACs}} ...dering shock waves, reflected shock waves, wakes (compared to experimental data using pressure distribution or field of Mach number isolines). Behind of th

{{AC|front=AC 2-06|description=Description_AC2-06|testdata=Test Data_AC2-06|cfdsimulations=CFD Simulations_AC2-06|evaluation=Evaluation_AC2 ...of the application challenge proposed by Partner 17, MTU Aero Engines. The AC is defined by the standard burner for confined natural gas flames that was

...iments carried out in a test rig at Volvo [[Best_Practice_Advice_AC2-12#1|[1,2,3]]]. Due to the simple geometry, this test case is quite attractive for verifying and validating new algorithms and mo

{{AC|front=AC 3-01|description=Description_AC3-01|testdata=Test Data_AC3-01|cfdsimulations=CFD Simulations_AC3-01|evaluation=Evaluation_AC3 The topic chosen for study as the Application Challenge (AC) is that of 2-dimensional buoyancy-opposed plane wall jet penetrating into

{{AC|front=AC 4-01|description=Description_AC4-01|testdata=Test Data_AC4-01|cfdsimulations=CFD Simulations_AC4-01|evaluation=Evaluation_AC4 ...Fluid Mechanics Ltd, on behalf of WS Atkins Consultants. A subset of this data is presented in this Application Challenge, namely the runway wind environm

century, the studies providing quantitative data on this type of flow (see [[UFR_2-11_Description#table1|Table 1]]).

...6-07 Quality Review|bestpractice=AC 6-07 Best Practice Advice|relatedUFRs=AC 6-07 Related ACs}} = Test Data =

{{AC|front=AC 3-02|description=Description_AC3-02|testdata=Test Data_AC3-02|cfdsimulations=CFD Simulations_AC3-02|evaluation=Evaluation_AC3 =='''Best Practice Advice for the AC'''==

{{AC|front=AC 5-05|description=Description_AC5-05|testdata=Test Data_AC5-05|cfdsimulations=CFD Simulations_AC5-05|evaluation=Evaluation_AC5 ...ed data generated by Trombetti et al (1991), see [[#Measured data|Measured data]]. The free-stream velocity, U₀, was 4m/s so that the Reynolds n

{{AC|front=AC 6-02|description=Description_AC6-02|testdata=Test Data_AC6-02|cfdsimulations=CFD Simulations_AC6-02|evaluation=Evaluation_AC6 ...ens. Next, the air passes through a specially designed bellmouth with a 10:1 area contraction. From there it flows into the compressor and exits through

{{AC|front=AC 5-05|description=Description_AC5-05|testdata=Test Data_AC5-05|cfdsimulations=CFD Simulations_AC5-05|evaluation=Evaluation_AC5 ...three hills and a corresponding set of three valleys (not covered in this AC document) were studied. A neutrally stable atmospheric boundary layer of he

...6-12 Quality Review|bestpractice=AC 6-12 Best Practice Advice|relatedUFRs=AC 6-12 Related ACs}} == Best Practice Advice for the AC ==

{{AC|front=AC 1-05|description=Description_AC1-05|testdata=Test Data_AC1-05|cfdsimulations=CFD Simulations_AC1-05|evaluation=Evaluation_AC1 '''Application Challenge 1-05''' © copyright ERCOFTAC 2004

...6-10 Quality Review|bestpractice=AC 6-10 Best Practice Advice|relatedUFRs=AC 6-10 Related ACs}} ...de surface pressure data and wake profiles were compared with experimental data from exit plane traverses. Calculations were performed using two sheared H-

...6-10 Quality Review|bestpractice=AC 6-10 Best Practice Advice|relatedUFRs=AC 6-10 Related ACs}} ...repancy is for case 9, for which there is some doubt over the experimental data (see below). Overall pressure loss is low for both meshes, although closer

{{AC|front=AC 5-05|description=Description_AC5-05|testdata=Test Data_AC5-05|cfdsimulations=CFD Simulations_AC5-05|evaluation=Evaluation_AC5 ...r details are now summarised but it should be noted there are no available data files containing the computational results.

{{AC|front=AC 2-06|description=Description_AC2-06|testdata=Test Data_AC2-06|cfdsimulations=CFD Simulations_AC2-06|evaluation=Evaluation_AC2 =='''Best Practice Advice for the AC'''==

{{AC|front=AC 2-01|description=Description_AC2-01|testdata=Test Data_AC2-01|cfdsimulations=CFD Simulations_AC2-01|evaluation=Evaluation_AC2 ...circular bluff-body with an orifice at its centre for the main fuel Figure 1. The diameters are 3.6 mm for the fuel nozzle and 50mm for the bluff-body.

{{AC|front=AC 3-02|description=Description_AC3-02|testdata=Test Data_AC3-02|cfdsimulations=CFD Simulations_AC3-02|evaluation=Evaluation_AC3 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 3-01|description=Description_AC3-01|testdata=Test Data_AC3-01|cfdsimulations=CFD Simulations_AC3-01|evaluation=Evaluation_AC3 =='''Best Practice Advice for the AC'''==

{{AC|front=AC 4-04|description=Description_AC4-04|testdata=Test Data_AC4-04|cfdsimulations=CFD Simulations_AC4-04|evaluation=Evaluation_AC4 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 3-11|description=Description_AC3-11|testdata=Test Data_AC3-11|cfdsimulations=CFD Simulations_AC3-11|evaluation=Evaluation_AC3 =='''Comparison of Test data and CFD'''==

{{AC|front=AC 6-06|description=Description_AC6-06|testdata=Test Data_AC6-06|cfdsimulations=CFD Simulations_AC6-06|evaluation=Evaluation_AC6 ...nd Reynolds number. The test case is represented by the blade shown in Fig 1-b. This profile is the nozzle guide vane of a highly loaded transonic turbi

{{AC|front=AC 6-05|description=Description_AC6-05|testdata=Test Data_AC6-05|cfdsimulations=CFD_Simulation_AC6-05|evaluation=Evaluation_AC6- ...rameters (PDPs) are the tip-clearance size and the rotating hub speed. The test cases are summarized in [[#Table EXP-A|Table EXP-A]].

{{AC|front=AC 2-07|description=Description_AC2-07|testdata=Test Case_AC2-07|cfdsimulations=CFD Simulations_AC2-07|evaluation=Evaluation_AC2 <math>k = \frac{1}{2}\left(u^{\prime\;2} +

...6-08 Quality Review|bestpractice=AC 6-08 Best Practice Advice|relatedUFRs=AC 6-08 Related ACs}} ...ial gas compression applications (HVAC and industrial gas processing). The test case is thus representative of extremely highly loaded compressor applicati

{{AC|front=AC 3-01|description=Description_AC3-01|testdata=Test Data_AC3-01|cfdsimulations=CFD Simulations_AC3-01|evaluation=Evaluation_AC3 '''Flow loop and test section'''

{{AC|front=AC 4-03|description=Description_AC4-03|testdata=Test Data_AC4-03|cfdsimulations=CFD Simulations_AC4-03|evaluation=Evaluation_AC4 ...flow rates equivalent to 1.5, 2.0 and 3.0 air changes per hour (Scenarios 1, 2 and 3, respectively).

{{AC|front=AC 3-11|description=Description_AC3-11|testdata=Test Data_AC3-11|cfdsimulations=CFD Simulations_AC3-11|evaluation=Evaluation_AC3 ...ear-wall treatments, namely standard wall functions; a low-Reynolds-number 1-equation near-wall model, and the low-Reynolds-number Launder-Sharma k-ε s

{{AC|front=AC 6-05|description=Description_AC6-05|testdata=Test Data_AC6-05|cfdsimulations=CFD_Simulation_AC6-05|evaluation=Evaluation_AC6- ...rs ('''“Advanced Civil Core Compressor Aerodynamics''',” AER2-CT92-0039, 1/1/1993-30/9/1996).

{{AC|front=AC 6-05|description=Description_AC6-05|testdata=Test Data_AC6-05|cfdsimulations=CFD_Simulation_AC6-05|evaluation=Evaluation_AC6- =='''Best Practice Advice for the AC'''==

{{AC|front=AC 4-01|description=Description_AC4-01|testdata=Test Data_AC4-01|cfdsimulations=CFD Simulations_AC4-01|evaluation=Evaluation_AC4 {|border="1" cell padding="25" cell spacing="3" align="center" width="700"

|area=1 |number=1

{{AC|front=AC 6-06|description=Description_AC6-06|testdata=Test Data_AC6-06|cfdsimulations=CFD Simulations_AC6-06|evaluation=Evaluation_AC6 ...ing of the valve allows the pressurised and heated gas to flow through the test section providing constant freestream conditions (total temperature, total

{{AC|front=AC 1-02|description=Description_AC1-02|testdata=Test Data_AC1-02|cfdsimulations=CFD Simulations_AC1-02|evaluation=Evaluation_AC1 '''Application Challenge 1-02''' © copyright ERCOFTAC 2004

=Test Data= ...ms, Erlangen, Germany). Even though the MRI measurements presented in this AC are new, the phantom setup used is the same and the sinusoidal pulsatile fl

{{AC|front=AC 2-08|description=Description_AC2-08|testdata=Test Data_AC2-08|cfdsimulations=CFD Simulations_AC2-08|evaluation=Evaluation_AC2 == Overview and Boundary Data ==

cubical enclosure ([[UFR_4-20_Description#figure1|Fig.&nbsp;1]]). (e.g. [[UFR_4-20_References#1|Awbi&nbsp;2003,&nbsp;2007]]).

{{AC|front=AC 2-08|description=Description_AC2-08|testdata=Test Data_AC2-08|cfdsimulations=CFD Simulations_AC2-08|evaluation=Evaluation_AC2 Validation data exists for the reacting and non-reacting cases using the same velocity boun

{{AC|front=AC 5-05|description=Description_AC5-05|testdata=Test Data_AC5-05|cfdsimulations=CFD Simulations_AC5-05|evaluation=Evaluation_AC5 =='''Best Practice Advice for the AC'''==

...6-07 Quality Review|bestpractice=AC 6-07 Best Practice Advice|relatedUFRs=AC 6-07 Related ACs}} == Comparison of CFD Results and Test data ==

{{AC|front=AC 2-06|description=Description_AC2-06|testdata=Test Data_AC2-06|cfdsimulations=CFD Simulations_AC2-06|evaluation=Evaluation_AC2 ...) that are of particular interest for the validation of combustion models. Data were obtained for different swirl numbers and equivalence ratios. The setup

...6-08 Quality Review|bestpractice=AC 6-08 Best Practice Advice|relatedUFRs=AC 6-08 Related ACs}} == Best Practice Advice for the AC ==

{{AC|front=AC 3-03|description=Description_AC3-03|testdata=Test Data_AC3-03|cfdsimulations=CFD Simulations_AC3-03|evaluation=Evaluation_AC3 =='''Best Practice Advice for the AC'''==

...6-07 Quality Review|bestpractice=AC 6-07 Best Practice Advice|relatedUFRs=AC 6-07 Related ACs}} == Best Practice Advice for the AC ==

{{AC|front=AC 4-01|description=Description_AC4-01|testdata=Test Data_AC4-01|cfdsimulations=CFD Simulations_AC4-01|evaluation=Evaluation_AC4 =='''Best Practice Advice for the AC'''==

{{AC|front=AC 6-02|description=Description_AC6-02|testdata=Test Data_AC6-02|cfdsimulations=CFD Simulations_AC6-02|evaluation=Evaluation_AC6 ...ameters are compared with experimental data. Comparisons with experimental data, including blade surface static pressure, and pitch-averaged static and tot

{{AC|front=AC 4-04|description=Description_AC4-04|testdata=Test Data_AC4-04|cfdsimulations=CFD Simulations_AC4-04|evaluation=Evaluation_AC4 =='''Best Practice Advice for the AC'''==

{{AC|front=AC 2-07|description=Description_AC2-07|testdata=Test Case_AC2-07|cfdsimulations=CFD Simulations_AC2-07|evaluation=Evaluation_AC2 An overview of the experimental test cases is provided here. The values of the [[DOAPs#PDPs:_Problem_Definition_

{{AC|front=AC 2-08|description=Description_AC2-08|testdata=Test Data_AC2-08|cfdsimulations=CFD Simulations_AC2-08|evaluation=Evaluation_AC2 The measurements outlined in the 'Test Data' section are well suited to assess whether they are reproduced by the simul

{{AC|front=AC 2-01|description=Description_AC2-01|testdata=Test Data_AC2-01|cfdsimulations=CFD Simulations_AC2-01|evaluation=Evaluation_AC2 ...e presented. For reacting flows, instantaneous temperature and composition data files are made available. Listings of the fluid mixtures used are given in:

...tion=UFR 3-07 Description|references=UFR 3-07 References|testcase=UFR 3-07 Test Case|evaluation=UFR 3-07 Evaluation|qualityreview=UFR 3-07 Quality Review|b = Test Case =

In the current application challenge (AC), ''in vitro'' velocity measurements using particle image velocimetry (PIV) ...n in the human upper airways” and provides the corresponding flow velocity data. The investigations were performed for steady-state inhalation at a flow ra

...6-07 Quality Review|bestpractice=AC 6-07 Best Practice Advice|relatedUFRs=AC 6-07 Related ACs}} Two international workshops, focused on this test case, have been organised: Turbine-99 - Workshop on Draft Tube Flow, Porjus

{{AC|front=AC 6-05|description=Description_AC6-05|testdata=Test Data_AC6-05|cfdsimulations=CFD_Simulation_AC6-05|evaluation=Evaluation_AC6- ...urbo_3D''' code, which was developed at UPMC/LEMFI, on fine grids of about 1.5 million points using the Launder-Sharma new-wall low-Reynolds-number k-ε

...6-08 Quality Review|bestpractice=AC 6-08 Best Practice Advice|relatedUFRs=AC 6-08 Related ACs}} ...one; border-bottom: solid windowtext 1.0pt; border-right: solid windowtext 1.0pt; padding: 0cm 2.8pt 0cm 2.8pt" width="89" valign="top" |

...publications). The boundary conditions applied at the inlet came from the data acquired during the experiment (2D cine PC-MRI). ...metry used in the calculation is the same as the one presented in the test data section. The computational domain has one inlet and one single outlet, so t

{{AC|front=AC 3-01|description=Description_AC3-01|testdata=Test Data_AC3-01|cfdsimulations=CFD Simulations_AC3-01|evaluation=Evaluation_AC3 ...1 of this report. The preliminary computational studies described in issue 1 had considered only the isothermal case. This enabled an early evaluation o

{{AC|front=AC 2-01|description=Description_AC2-01|testdata=Test Data_AC2-01|cfdsimulations=CFD Simulations_AC2-01|evaluation=Evaluation_AC2 ...conditions are specified with the same approach described in the previous test. The Flamelet database is obtained from the same reduced mechanism of the p

(shown in Fig.1) is a widely used test case for that the Sandia D Flame is not a demanding test case it seems to be

{{AC|front=AC 6-06|description=Description_AC6-06|testdata=Test Data_AC6-06|cfdsimulations=CFD Simulations_AC6-06|evaluation=Evaluation_AC6 =='''Best Practice Advice for the AC'''==

...vice. ''Access the Knowledge Base to find the UFRs associated with your AC''. In the present AC, experiments and simulations were conducted at a flowrate of 60 L/min throu

{{AC|front=AC 3-01|description=Description_AC3-01|testdata=Test Data_AC3-01|cfdsimulations=CFD Simulations_AC3-01|evaluation=Evaluation_AC3 ...predictions as well as through comparisons with the available experimental data.

{{AC|front=AC 1-05|description=Description_AC1-05|testdata=Test Data_AC1-05|cfdsimulations=CFD Simulations_AC1-05|evaluation=Evaluation_AC1 '''Application Challenge 1-05''' © copyright ERCOFTAC 2004

{{AC|front=AC 2-01|description=Description_AC2-01|testdata=Test Data_AC2-01|cfdsimulations=CFD Simulations_AC2-01|evaluation=Evaluation_AC2 =='''Best Practice Advice for the AC'''==