Langley Research Center Turbulence Modeling Resource

Exp: NASA Juncture Flow (JF) - Turbulent Symmetric Wing Boundary Conditions

Return to: Exp: NASA Juncture Flow - Intro Page for Turbulent Symmetric Wing

This page provides information from the Juncture Flow test to help users determine appropriate boundary conditions for CFD runs. The most important information for running CFD is listed under "GENERAL" below. Some of the other data are not strictly boundary conditions, but rather may be useful for checking aspects of the CFD methodology. For example, data were collected on the model itself well upstream of the separated region of interest, with the intent that these data could serve as references for CFD comparisons (see MODEL NOSE REGION section below).

The following limited information about wind tunnel inflow characterization is provided: turbulence level, wall boundary layer thickness, and "other" (total pressure and flow angularity). Note that collecting inflow conditions is particularly difficult during a model entry in a major wind tunnel like the 14x22, so some of this was done in separate tests; analysis of much of it is still ongoing. The effects of including realistic nonuniform inflow conditions in a CFD in-tunnel run are not yet known on the quantities of interest for this case.
 

GENERAL

As described on the Exp: NASA Juncture Flow - Intro Page for Turbulent Symmetric Wing, for the purpose of maintaining some consistency between input parameters for nondimensional CFD codes, the nominal M and T were chosen to be the same between the F6 and symmetric wing because they were both well within the ranges experienced during each test. The nominal conditions were:

• Re=2.4 million based on crank chord of 580.716 mm (variation in Re was +-0.25% in Test 662).
• M=0.189 (at median dynamic pressure run); (range was 0.171 to 0.199 in Test 662).
• T=288.84 K (at median dynamic pressure run); (range was 281 to 309 K in Test 662).
• Angle of incidence in the wind tunnel varied. For the symmetric wing with horn, LDV flowfield data were taken at 0.0, 1.0, and 5.0 deg. Actual ranges were -0.04 to +0.03, +0.99 to +1.03, and +4.99 to +5.03 deg, respectively.

Description of the model tripping can be found in the notes on the Exp: NASA Juncture Flow - Turbulent Symmetric Wing Geometry) page. It is important to note that the inboard-most portion of the wing (extending roughly 25 mm away from the fuselage) is located within the fuselage's turbulent boundary layer. Information about the boundary layer on the leading edge extension (horn) is detailed in the following document: Slides Describing T662 IR Results (pdf file).

The 14x22 wind tunnel is controlled by measuring total pressure, static pressure (actually delta p between the total and the static), stagnation temperature, and dewpoint at specific locations in the tunnel and applying calibration equations. Details can be found in NASA/TM-2014-218513, NASA/TM-2018-219812, and NASA Technical Report 20190018049, 2019.

Strategies for Running Juncture Flow CFD in the Tunnel (pdf file) summarizes important information regarding in-tunnel computations.
 

MODEL NOSE REGION

Extensive flowfield data in the model nose region (near x=1168 mm), well upstream of the wing, are included in the LDV results provided on the Exp: NASA Juncture Flow (JF) - Turbulent Symmetric Wing Experimental Data page.
 

TUNNEL INFLOW TURBULENCE LEVEL

Tunnel inflow turbulence was not measured during this test. However, it was measured previously, as reported in NASA/TP-2004-213247. Using the results from that report, the presumed freestream turbulence intensity for this test is approximately 0.07% - 0.08%. Recall, however, that the model was tripped in the JF test.
 

TUNNEL WALL INCOMING BOUNDARY LAYER THICKNESS

Using wall rake data from this test, the 14x22 wall boundary layer thickness measured upstream of the model (behind the start of the test section, away from the corners) was consistent on the top and both side walls. These measures were also consistent with measurements for the earlier F6-based wing as well as with earlier unpublished measurements of the boundary layer on the floor. Therefore, it can be assumed that the tunnel wall boundary layers were roughly 4 - 5 inches (100 - 125 mm) thick at 5 - 6 feet (1.5 - 1.8 m) behind the start of the test section for the JF test. The following slides provide details from the F6-based wing testing:

Slides Describing Tunnel Wall Rake Data (pdf file)

These data are consistent with previously-measured 14x22 wall boundary layer thickness (14x22_Boundary_Layer_Summary.pdf.gz (gzipped)). Note the previous measurements also included the effect of the Boundary Layer Removal System (BLRS) on the bottom wall. The BLRS was not used in the JF test.
 

OTHER KNOWN TUNNEL INFLOW CHARACTERISTICS

Slides Describing Measured Inflow Characteristics (pdf file)

For additional 14x22 wind tunnel details, see NASA TP 3008, September 1990 and NASA TM 85662, December 1983.
 

TUNNEL SIDE AND TOP WALL PRESSURES

T662CpWallData.tar.gz (0.1 MB)
 
 

Return to: Exp: NASA Juncture Flow - Intro Page for Turbulent Symmetric Wing

Recent significant updates:
03/13/2023 - Added pdf file describing IR results for transition on the horn

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Responsible NASA Official: Ethan Vogel
Page Curator: Clark Pederson
Last Updated: 08/14/2025