Validation of 3-D Ice Accretion Measurement Methodology for Experimental Aerodynamic Simulation

Broeren, Andy P.; Addy, Harold E.; Lee, Sam; Monastero, Marianne C.

doi:10.2514/6.2014-2614

Cited by 36 publications

(44 citation statements)

References 19 publications

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“…Although the PolyJet method was capable of manufacturing layers of this height, its tolerance was greater than the roughness height. This was verified by the aerodynamic results shown in Broeren et al 12 that showed that the maximum lift coefficients of the SLA and PolyJet ice shapes were 6% and 11% higher than the cast shape. Figure 26 shows the comparison plots for the rime ice accretion from run ED1977.…”

Section: Figure 23 Roughness Deviation Map -Ed1974supporting

confidence: 82%

“…Artificial ice shapes were also constructed using the traditional mold/casting methods for both geometric and aerodynamic comparisons. The results of the aerodynamic comparison between the RPM shapes and the cast shapes are included in a companion paper by Broeren et al 12 This paper presents the results and analysis of the geometric comparison between the RPM shapes and the cast shapes.…”

Section: Table 2 Properties Of Rapid Prototype Methodsmentioning

confidence: 97%

“…The results and analysis of the geometric comparison between the RPM shapes and the cast shapes are included in this paper. The results of the aerodynamic comparison between the RPM shapes and the cast shapes are included in the companion paper by Broeren et al 12 The methods used for processing raw ice accretion scan data into a water-tight 3-D mesh for documentation and rapid prototype manufacturing for aerodynamic testing are described in this section. These methods were used to process data acquired with a Romer Absolute scanner using Geomagic software.…”

Section: Scan Data Processing Proceduresmentioning

confidence: 99%

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Implementation and Validation of 3-D Ice Accretion Measurement Methodology

Lee

Broeren

Kreeger

et al. 2014

6th AIAA Atmospheric and Space Environments Conference

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A research program has been implemented to develop and validate the use of a commercial 3-D laser scanning system to record ice accretion geometry in the NASA Icing Research Tunnel. A main component of the program was the geometric assessment of the 3-D laser scanning system on a 2-D (straight wing) and a 3-D (swept wing) airfoil geometries. This exercise consisted of comparison of scanned ice accretion to castings of the same ice accretion. The scan data were also used to create rapid prototype artificial ice shapes that were scanned and compared to the original ice accretion.The results from geometric comparisons on the straight wing showed that the ice shape models generated through the scan/rapid prototype process compared reasonably well with the cast shapes. Similar results were obtained with the geometric comparisons on the swept wing. It was difficult to precisely compare the scans of the cast shapes to the original ice accretion scans because the cast shapes appear to have shrunk during the mold/casting process by as much as 0.10-inch. However the comparison of the local ice-shape features were possible and produced better results. The rapid prototype manufacturing process was shown to reproduce the original ice accretion scan normally within 0.01-inch. NomenclatureCAD = Computer aided design CT = Computed tomography IRT = Icing Research Tunnel LWC = Liquid water content MVD = Median volumetric diameter RPM = Rapid prototype manufacturing SLA = Stereolithography T 0 = Total air temperature t = Icing spray time V = Tunnel airspeed α = Angle of attack Λ = Wing sweep angle *

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Section: Figure 23 Roughness Deviation Map -Ed1974supporting

confidence: 82%

Section: Table 2 Properties Of Rapid Prototype Methodsmentioning

confidence: 97%

Section: Scan Data Processing Proceduresmentioning

confidence: 99%

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Implementation and Validation of 3-D Ice Accretion Measurement Methodology

Lee

Broeren

Kreeger

et al. 2014

6th AIAA Atmospheric and Space Environments Conference

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“…The digital scans were processed and used to make RPM ice shapes to compare to the castings. A total of six ice shapes were replicated and are discussed by Broeren et al, 5 although only two of these were tested with PSP. This further testing with PSP was used to help resolve observed aerodynamic differences between the castings and RPM shapes for a horn shape ( Fig.…”

Section: A Ice Shape Acquisitionmentioning

confidence: 99%

“…The aerodynamic performance validation results are presented and analyzed by Broeren et al, 5 who concluded that the 3-D laser scanner method was valid for most of the ice shape classifications tested. However, they found that the aerodynamics for a horn shape and a fine roughness shape generated from the new method did not satisfactorily agree with the respective casting aerodynamics.…”

Section: Introductionmentioning

confidence: 99%

Validation of 3-D Ice Accretion Measurement Methodology Using Pressure-Sensitive Paint

Monastero

Bragg

2014

6th AIAA Atmospheric and Space Environments Conference

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Accurate representation of ice accretions is important to the study and understanding of aircraft icing. For research and certification purposes, replicas of ice accretions generated from an icing wind tunnel are created to perform aerodynamic tests in dry-air wind tunnels and in flight. Three-dimensional ice-shape features necessitate aerodynamic observations over the entire surface of the wing or airfoil to fully understand the flow behavior. The pressure-sensitive paint (PSP) technique allows pressure coefficient (C p ) data to be obtained over a larger area and with a greater resolution than is possible by solely using the pressure tap method. Three-dimensional C p measurements obtained as the result of this work both further the understanding of iced-airfoil aerodynamics and provide a validation for a recently developed method of recording ice accretions. Results show the ability of the PSP technique implemented in this experimental study to resolve aerodynamic differences between ice shapes made from the new 3-D ice accretion measurement methodology recently developed by the NASA Icing Research Branch and the current mold and casting method. PSP tests were performed to further investigate the aerodynamics of ice shapes that showed performance variations between the replicas made from the new and current methods. In general, the PSP results agreed with the two-dimensional data obtained from pressure taps while providing additional pressure information along the span. Aerodynamic and PSP agreement between the shapes generated from the two methods was relatively good, but not to the extent expected. Results show the general behaviors agree, with discrepancies in the quantitative data. These discrepancies are shown to be the result of geometric differences in the ice shapes made from the two methods. The 3-D ice accretion measurement methodology was validated for the two tested shapes and possible improvements to the PSP implementation are suggested.

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