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1. Simultaneous Ice Water Content Measurements at Multiple Locations on the NASA DC-8 Aircraft during the 2018 HIWC RADAR Flight Campaign

Author

Thomas P. Ratvasky, J. Walter Strapp, Lyle E. Lilie, Daniel B. Bouley, and Christopher P. Sivo

Subjects
Aeronautics (General)
Abstract

Ice water content measurements were made simultaneously at three locations on the NASA DC-8 in natural, glaciated conditions during the 2018 High Ice Water Content RADAR flight campaign. The purpose of these measurements was to further evaluate efficiency factors of hot-wire total water content probes in glaciated conditions and investigate the enhancement of ice crystal concentrations near fuselage surfaces due to flow field inertial effects, and ice crystals impacting the nose, breaking up, and flowing downstream. The total water content measurements were made using either Science Engineering Associates Ice Crystal Detectors or Robust Probes. Three common sensors were mounted on an underwing canister considered to be in near free-flow conditions, a standoff from a fuselage window, and the nose of the fuselage near the pitot probes. The Ice Crystal Detector concave total water content sensor and Robust Probe sensor collection and retention efficiencies were evaluated through comparisons with the underwing Ice Crystal Detector and Robust Probe measurements to the Isokinetic Probe version 2 (IKP2), which provided the reference ice water content measurement. Local ice water content at the nose position was evaluated by comparing ratios of the nose and underwing ice crystal detectors to the IKP2. Local ice water content at the window-standoff location was also evaluated by comparing total water content sensor measurements from the window probes to the measurements made with the underwing and nose probes. The key findings were: (1) the Ice Crystal Detector concave water content sensor efficiency factor to glaciated conditions was similar to previous estimates, but reduced with increased ice crystal median mass diameter; (2) the ice water content at the fuselage nose location near the DC-8 pitot probes was approximately 2.5 times the freestream values—although this estimate is affected by a higher probe efficiency factor due to smaller particles in the debris cloud from impacts upstream of the probe; and (3) the ice water content at the 17 in. standoff from the port window varied from about 50 percent to nearly three times freestream values in a complicated manner. Similar measurement locations are not uncommon on cloud research aircraft, where ice particle measurements may be subject to similar uncertainties.

Published
2021

2. Evaluations of Damaged High-Pressure Compressor Blades in Two Turbine Engines of NASA DC–8

Author

Tim P. Gabb, K.N. Lee, Peter J. Bonacuse, Kurt S. Blankenship, Thomas P. Ratvasky, Wayne D. Jennings, and Joy A. Buehler

Subjects
Aircraft Propulsion And Power
Abstract

A series of flights were performed by the NASA DC-8 for the FIREX-AQ missions to observe the effects of wildfires and agricultural fires on air quality and climate in selected locations of the United States. Borescope evaluations after these flights indicated accelerated damage had occurred over this flight series to the blades in the high pressure compressor section of all four CFM56-2C1 turbine engines. This erosion and impact damage appeared to vary in severity, and appeared most severe for engines 3 and 4 located on the right wing of the DC-8.Engine 3 had the most flight hours and cycles since last overhaul of 7,152 h and 2,502 cycles. Engine 4 had the lowest flight hours and cycles since last overhaul of 1,354 h and 369 cycles. For these reasons, three noticeably damaged blades were selected from the high pressure compressor for each of these two engines, and then evaluated at NASA GRC using optical and scanning electron microscopy. Engine 3 compressor blades had both erosion and impact damage that were observed and characterized. The erosion damage was associated with embedded particles 13 μm to 42 μm in sectioned width, composed of varied compositions ranging from SiO2 to SiO2 also containing Ca, Mg, and Al (CMAS). The impact damage was associated with the impacts of larger objects at least 650 μm to 850 μm in width, but only small fragments 5 μm to 15 μm in sectioned width were embedded in the impact surface, also composed of SiO2 to SiO2 containing Ca, Mg, and Al (CMAS). On the other hand, engine 4 blades had only impact damage that was observed and characterized. This impact damage was associated with impacts of objects at least 1,480 μm to 2,080μm in width. Small fragments 5 μm to 15 μm in sectioned width were embedded in the impact surface. For one impact, the fragments were again composed of SiO2 to SiO2 containing Ca, Mg, and Al (CMAS). For two other impacts, the fragments were often composed of Fe, and less frequently Cu.

Published
2021

3. Isokinetic Probe Total Water Content Measurements in the NASA Icing Research Tunnel with Supercooled Large Drop Conditions

Author

Thomas P Ratvasky, J Walter Strapp, and Lyle E Lilie

Subjects
Aeronautics (General)
Abstract

An Isokinetic Total Water Content Evaporator (IKP2) was used to measure liquid water content (LWC) in the NASA Icing Research Tunnel (IRT) with spray conditions that ranged in LWC and cloud drop size spectra as characterized by the median volumetric diameter (MVD). The IKP2 measurements were made as part of an international collaborative effort to investigate the measurement of supercooled large drop (SLD) conditions in several icing wind tunnels. This report focuses on the IKP2 and background water vapor (BWV) measurements made within the NASA IRT during the October 2017 test entry. The IKP2 TWC results are compared to the IRT LWC calibration values for a range of LWC and MVD values. The IRT LWC calibration is based on measurements from a multi-element hot-wire probe. In general, the IKP2 TWC values were approximately 9% greater than the IRT LWC calibration values over a range of LWC from 0.4 g/m3 to 3.0 g/m3. The ratio of IKP2 TWC to IRT LWC calibration ranged from approximately 0.9 to 1.27 over a range of MVD from 15um to 460 um. Comparisons of this data set to IKP2 data from a 2014 IRT test entry show similar results in the regions where overlaps occurred. The results support the theory and observations of water mass loss from hot-wire TWC sensors when subjected to large MVD conditions.

Published
2021

4. Test Results for the SEA Ice Crystal Detector (ICD) under SLD Conditions at the NASA IRT

Author

Lyle E Lilie, Daniel B Bouley, Christopher P Sivo, Thomas P Ratvasky, and Judith F Van Zante

Subjects
Aeronautics (General)
Abstract

The Science Engineering Associates hot-wire Ice Crystal Detector was tested under Appendix C and Supercooled Large Drop Conditions at the NASA Icing Research Tunnel, with the purpose of comparing the measurements to the tunnel LWC calibration, and to test the performance of the mixed-phase retrievals of the probe. The liquid water content measured by the total water content sensor of the probe agreed well with the tunnel calibration over a wide range of MVDs, not unexpectedly since the tunnel was calibrated with a similar Multiwire hot-wire probe. A scale factor difference of about 7% was attributed to the lack of an efficiency correction for the Ice Crystal Detector at smaller median volume diameters, and typical sample area uncertainties of liquid water content devices. In addition, the simultaneous equations that are used to retrieve liquid and ice water contents were tested under liquid and glaciated conditions. Using constant ice and water efficiencies for each wire, the equations were found to produce a large and false ice water content retrieval in large median volume diameter liquid cases. By applying a liquid efficiency to the liquid water content sensor that varied with median volume diameter, retrievals were improved such that false ice water content was less than ±10% of the total water content out to the 460 μm median volume diameter limit of the testing. The probe was also tested in glaciated conditions by freezing out a small median volume diameter spray. Using constant ice efficiencies for the two sensors provided from aircraft measurements, the retrieved ice water content was about 40% higher than expected for the case presented, likely due to the ice efficiencies that were used from aircraft measurements of natural clouds being too low for the tunnel’s glaciated sprays. Application of ice efficiencies that vary with particle size and potentially other parameters will be explored for future improvement of retrievals.

Published
2021

5. Development of a Method to Detect High Ice Water Content Environments Using Machine Learning

Author

Kristopher M. Bedka, Thomas P. Ratvasky, Allyson Rugg, Julie Haggerty, Alain Protat, J. Walter Strapp, Rodney Potts, and Alice Grandin

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Computer science, business.industry, 0211 other engineering and technologies, Ocean Engineering, 02 engineering and technology, 01 natural sciences, Ice water, Content (measure theory), Process engineering, business, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Icing
Abstract

This paper describes development of a method for discriminating high ice water content (HIWC) conditions that can disrupt jet-engine performance in commuter and large transport aircraft. Using input data from satellites, numerical weather prediction models, and ground-based radar, this effort employs machine learning to determine optimal combinations of available information using fuzzy logic. Airborne in situ measurements of ice water content (IWC) from a series of field experiments that sampled HIWC conditions serve as training data in the machine-learning process. The resulting method, known as the Algorithm for Prediction of HIWC Areas (ALPHA), estimates the likelihood of HIWC conditions over a three-dimensional domain. Performance statistics calculated from an independent subset of data reserved for verification indicate that the ALPHA has skill for detecting HIWC conditions, albeit with significant false alarm rates. Probability of detection (POD), probability of false detection (POFD), and false alarm ratio (FAR) are 86%, 29% (60% when IWC below 0.1 g m−3 are omitted), and 51%, respectively, for one set of detection thresholds using in situ measurements. Corresponding receiver operating characteristic (ROC) curves give an area under the curve of 0.85 when considering all data and 0.69 for only points with IWC of at least 0.1 g m−3. Monte Carlo simulations suggest that aircraft sampling biases resulted in a positive POD bias and the actual probability of detection is between 78.5% and 83.1% (95% confidence interval). Analysis of individual case studies shows that the ALPHA output product generally tracks variation in the measured IWC.

Published
2020
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8. Isokinetic Probe Total Water Content Measurements in the NASA Icing Research Tunnel with Supercooled Large Drop Conditions

Author

John W. Strapp, Lyle Lilie, and Thomas P. Ratvasky

Subjects
Liquid water content, Drop (liquid), Calibration, Environmental science, Atmospheric sciences, Water content, Water vapor, Evaporator, Icing, Wind tunnel
Abstract

An Isokinetic Total Water Content Evaporator (IKP2) was used to measure liquid water content (LWC) in the NASA Icing Research Tunnel (IRT) with spray conditions that ranged in LWC and cloud drop size spectra as characterized by the median volumetric diameter (MVD). The IKP2 measurements were made as part of an international collaborative effort to investigate the measurement of supercooled large drop (SLD) conditions in several icing wind tunnels. This report focuses on the IKP2 and background water vapor (BWV) measurements made within the NASA IRT during the October 2017 test entry. The IKP2 TWC results are compared to the IRT LWC calibration values for a range of LWC and MVD values. The IRT LWC calibration is based on measurements from a multi-element hot-wire probe. In general, the IKP2 TWC values were approximately 9% greater than the IRT LWC calibration values over a range of LWC from 0.4 g/m3 to 3.0 g/m3. The ratio of IKP2 TWC to IRT LWC calibration ranged from approximately 0.9 to 1.27 over a range of MVD from 15µm to 460 µm. Comparisons of this data set to IKP2 data from a 2014 IRT test entry show similar results in the regions where overlaps occurred. The results support the theory and observations of water mass loss from hot-wire TWC sensors when subjected to large MVD conditions.

Published
2021
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10. SLD Instrumentation in Icing Wind Tunnels – Investigation Overview

Author

James T. Riley, Alexei Korolev, John W. Strapp, Judith F. Van Zante, Thomas P. Ratvasky, Biagio Esposito, and David M. Orchard

Subjects
Airfoil, Liquid water content, Instrumentation, Data quality, Calibration, Environmental science, Sizing, Icing, Wind tunnel, Marine engineering
Abstract

A collaborative effort to better understand cloud characterization probes in Supercooled Large Drop (SLD) conditions, as well the ability to simulate these conditions in several icing wind tunnels, was undertaken by NASA, NRCC, CIRA, ECCC, FAA and Met Analytics, Inc. Both drop sizing and liquid water content, LWC, were measured with various probes using current to emerging technologies. To ensure the best possible data quality from the newest probes, the probe manufacturers, SEA, Inc. and Artium, Inc. were invited to support testing and data analysis efforts. A common set of probes was identified to test in each of the three participating facilities: NRCC’s Altitude Icing Wind Tunnel, NASA’s Icing Research Tunnel and CIRA’s Icing Wind Tunnel. From the common set of probes, a subset were identified to use for comparison across the three facilities. These were the CDP-2 and 2D-S for drop sizing, and the Multi-wire for LWC. The LWC value was also checked by measuring the ice accretion thickness under hard rime conditions on a NACA-0012 airfoil. A common test matrix with sweeps in both LWC and median volume diameter, MVD, was developed. Each facility achieved these conditions as determined by their own calibration. The MVD ranged from 20 to at least 200 um, and LWC ranged from 0.5 to 3 g/m3. The comparison probes tested at common conditions in each facility were intended to allow for a direct comparison, and check of potential facility bias.

Published
2021
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14. Radar Detection of High Concentrations of Ice Particles - Methodology and Preliminary Flight Test Results

Author

George F. Switzer, Chris Dumont, J. Walter Strapp, Justin K. Strickland, Steven Harrah, Thomas P. Ratvasky, Lyle Lilie, Fred H. Proctor, and Patricia J. Hunt

Subjects
Remote detection, Operational performance, Computer science, law, Range (aeronautics), Systems engineering, Process (computing), Radar, Radar detection, Flight test, Ice water, law.invention
Abstract

High Ice Water Content (HIWC) has been identified as a primary causal factor in numerous engine events over the past two decades. Previous attempts to develop a remote detection process utilizing modern commercial radars have failed to produce reliable results. This paper discusses the reasons for previous failures and describes a new technique that has shown very encouraging accuracy and range performance without the need for any hardware modifications to industry’s current radar designs. The performance of this new process was evaluated during the joint NASA/FAA HIWC RADAR II Flight Campaign in August of 2018. Results from that evaluation are discussed, along with the potential for commercial application, and development of minimum operational performance standards for a future commercial radar product.

Published
2019
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15. Ice-Crystal Icing Accretion Studies at the NASA Propulsion Systems Laboratory

Author

Jen-Ching Tsao, Juan H. Agui, Peter M. Struk, Michael C. King, Tadas P. Bartkus, and Thomas P. Ratvasky

Subjects
Ice crystals, Accretion (meteorology), Flow (psychology), Humidity, Mechanics, Physics::Geophysics, Jet engine, law.invention, Icing conditions, law, Environmental science, Relative humidity, Astrophysics::Earth and Planetary Astrophysics, Physics::Atmospheric and Oceanic Physics, Icing
Abstract

This paper describes an ice-crystal icing experiment conducted at the NASA Propulsion System Laboratory during June 2018. This test produced ice shape data on an airfoil for different test conditions similar to those inside the compressor region of a turbo-fan jet engine. Mixed-phase icing conditions were generated by partially freezing out a water spray using the relative humidity of flow as the primary parameter to control freeze-out. The paper presents the ice shape data and associated conditions which include pressure, velocity, temperature, humidity, total water content, melt ratio, and particle size distribution. The test featured a new instrument traversing system which allowed surveys of the flow and cloud. The purpose of this work was to provide experimental ice shape data and associated conditions to help develop and validate ice-crystal icing accretion models. The results support previous experimental observations of a minimum melt-ratio threshold for accretion to occur as well as the existence of a plateau region where the icing severity is high for a range of melt ratios. However, a maximum limit for melt ratio, which is suggested in the ice crystal icing literature, was not observed perhaps complicated by the potential for some supercooling of the water at these conditions.

Published
2019
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16. Analysis and Automated Detection of Ice Crystal Icing Conditions Using Geostationary Satellite Datasets and In Situ Ice Water Content Measurements

Author

Douglas A. Spangenberg, Kristopher M. Bedka, Rajendra Bhatt, Rabindra Palikonda, Benjamin R. Scarino, Christopher R. Yost, Louis Nguyen, Thomas P. Ratvasky, Konstantin V. Khlopenkov, and J. Walter Strapp

Subjects
In situ, Icing conditions, Ice crystals, Geostationary orbit, Environmental science, Ice water, Remote sensing
Published
2019
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17. Summary of the High Ice Water Content (HIWC) RADAR Flight Campaigns

Author

Justin K. Strickland, J. Walter Strapp, Patricia J. Hunt, Kristopher M. Bedka, Steven Harrah, Aaron Bansemer, T. P. Bui, Thomas P. Ratvasky, Lyle Lilie, Christopher Dumont, Glenn S. Diskin, Fred H. Proctor, and John B. Nowak

Subjects
Meteorology, Ice crystals, law, Aviation, business.industry, Convective storm detection, Environmental science, Weather radar, Radar, business, Ice water, law.invention, Icing
Abstract

NASA and the FAA (Federal Aviation Administration) conducted two flight campaigns to quantify onboard weather radar measurements with in-situ measurements of high concentrations of ice crystals found in deep convective storms. The ultimate goal of this research was to improve the understanding and develop onboard weather radar processing to detect regions of high ice water content ahead of an aircraft and enable tactical avoidance of the potentially hazardous conditions. Both High Ice Water Content (HIWC) RADAR campaigns utilized the NASA DC-8 Airborne Science Laboratory which was equipped with a Honeywell RDR-4000 weather radar and icing instruments to characterize the ice crystal clouds. The purpose of this paper is to summarize how these campaigns were conducted and highlight key results.

Published
2019
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18. Update on the NASA Glenn Propulsion Systems Lab Icing and Ice Crystal Cloud Characterization - 2017

Author

Judith F. Van Zante, Mark R. Woike, Timothy J. Bencic, Clark C. Challis, Thomas P. Ratvasky, and Emily N. Timko

Subjects
020301 aerospace & aeronautics, 010504 meteorology & atmospheric sciences, Ice crystals, business.industry, Cloud computing, 02 engineering and technology, Propulsion, Tracking (particle physics), 01 natural sciences, Plenum space, Interferometry, 0203 mechanical engineering, Environmental science, Aerospace engineering, business, Supercooling, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences, Icing
Abstract

NASA Glenn's Propulsion Systems Lab, an altitude engine test facility, generates icing clouds with a spray system. While the spray system is used mostly to create ice crystal clouds (Appendix D/P), the 2017 cloud characterization effort added the requirement to produce exactly supercooled liquid clouds in Appendix C and Appendix O. Success was demonstrated to supercool the largest drops at the warmest conditions, but not freeze out the smallest drops at the coldest conditions. This paper documents primarily the total water content characterization methodology and results from an Iso-Kinetic Probe in ice crystals and Multi-Wire sensor in supercooled liquid, along with the cloud uniformity provided by light extinction tomography. Particle size distribution results from High Speed Imaging probes and a Phase Doppler Interferometer are discussed. Also, a new numerical model for tracking the thermodynamics of the air-drop interactions in PSL from the plenum toward the cloud characterization plane are noted. Both of these latter topic are more fully documented in companion papers.

Published
2018
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19. An Initial Study of the Fundamentals of Ice Crystal Icing Physics in the NASA Propulsion Systems Laboratory

Author

Michael C. King, Jen-Ching Tsao, Thomas P. Ratvasky, Timothy J. Bencic, Tadas P. Bartkus, Peter M. Struk, and Judith F. Van Zante

Subjects
Physics, 020301 aerospace & aeronautics, Engineering, 010504 meteorology & atmospheric sciences, Ice protection system, Accretion (meteorology), Ice crystals, business.industry, Flow (psychology), Evaporation, 02 engineering and technology, 01 natural sciences, Icing conditions, 0203 mechanical engineering, Total air temperature, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Icing
Abstract

This paper presents results from an initial study of the fundamental physics of ice-crystal ice accretion using the NASA Propulsion Systems Lab (PSL). Ice accretion due to the ingestion of ice-crystals is being attributed to numerous jet-engine power-loss events. The NASA PSL is an altitude jet-engine test facility which has recently added a capability to inject ice particles into the flow. NASA is evaluating whether this facility, in addition to full-engine and motor-driven-rig tests, can be used for more fundamental ice-accretion studies that simulate the different mixed-phase icing conditions along the core flow passage of a turbo-fan engine compressor. The data from such fundamental accretion tests will be used to help develop and validate models of the accretion process. The present study utilized a NACA0012 airfoil. The mixed-phase conditions were generated by partially freezing the liquid-water droplets ejected from the spray bars. This paper presents data regarding (1) the freeze out characteristics of the cloud, (2) changes in aerothermal conditions due to the presence of the cloud, and (3) the ice accretion characteristics observed on the airfoil model. The primary variable in this test was the PSL plenum humidity which was systematically varied for two duct-exit-plane velocities (85 and 135 ms) as well as two particle size clouds (15 and 50 m MVDi). The observed clouds ranged from fully glaciated to fully liquid, where the liquid clouds were at least partially supercooled. The air total temperature decreased at the test section when the cloud was activated due to evaporation. The ice accretions observed ranged from sharp arrow-like accretions, characteristic of ice-crystal erosion, to cases with double-horn shapes, characteristic of supercooled water accretions.

Published
2017
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20. NASA Glenn Propulsion Systems Lab Ice Crystal Cloud Characterization Update 2015

Author

Judith F. Van Zante, Thomas P. Ratvasky, and Timothy J. Bencic

Subjects
020301 aerospace & aeronautics, Engineering, 010504 meteorology & atmospheric sciences, Ice crystals, business.industry, Cloud computing, 02 engineering and technology, Propulsion, 01 natural sciences, Characterization (materials science), 0203 mechanical engineering, Aerospace engineering, business, 0105 earth and related environmental sciences
Published
2016
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22. Isokinetic TWC Evaporator Probe: Development of the IKP2 and Performance Testing for the HAIC-HIWC Darwin 2014 and Cayenne Field Campaigns

Author

John W. Strapp, Craig R. Davison, Lyle Lilie, Christopher Dumont, and Thomas P. Ratvasky

Subjects
Atmosphere, Geography, Ice crystals, Meteorology, Cloud physics, Atmospheric sciences, Water content, Water vapor, Evaporator, Wind tunnel, Icing
Abstract

A new Isokinetic Total Water Content Evaporator (IKP2) was downsized from a prototype instrument, specifically to make airborne measurements of hydrometeor total water content (TWC) in deep tropical convective clouds to assess the new ice crystal Appendix D icing envelope. The probe underwent numerous laboratory and wind tunnel investigations to ensure reliable operation under the difficult high altitude/speed/TWC conditions under which other TWC instruments have been known to either fail, or have unknown performance characteristics. The article tracks the testing and modifications of the IKP2 probe to ensure its readiness for three flight campaigns in 2014 and 2015. Comparisons are made between the IKP2 and the NASA Icing Research Tunnel reference values in liquid conditions, and to an exploratory technique estimating ice water content from a bulk ice capture cylinder method in glaciated conditions. These comparisons suggest that the initial target of 20 percent accuracy in TWC has been achieved and likely exceeded for tested TWC values in excess of about 0.5 gm (exp -3). Uncertainties in the ice water content reference method have been identified. Complications are introduced in the necessary subtraction of an independently measured background water vapour concentration, errors of which are small at the colder flight temperatures, but increase rapidly with increasing temperature, and ultimately limit the practical use of the instrument in a tropical convective atmosphere to conditions colder than about 0 degrees C. A companion article in this conference traces the accuracy of the components of the IKP2 to derive estimated system accuracy.

Published
2016
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23. Current Methods Modeling and Simulating Icing Effects on Aircraft Performance, Stability, Control

Author

Billy P. Barnhart, Thomas P. Ratvasky, and Sam Lee

Subjects
Engineering, business.product_category, business.industry, Angle of attack, Longitudinal static stability, Aerospace Engineering, Flying qualities, Stall (fluid mechanics), Structural engineering, Flight control surfaces, Airplane, Icing conditions, business, Icing, Marine engineering
Abstract

Icing alters the shape and surface characteristics of aircraft components, which results in altered aerodynamic forces and moments caused by air flow over those iced components. The typical effects of icing are increased drag, reduced stall angle of attack, and reduced maximum lift. In addition to the performance changes, icing can also affect control surface effectiveness, hinge moments, and damping. These effects result in altered aircraft stability and control and flying qualities. Over the past 80 years, methods have been developed to understand how icing affects performance, stability, and control. Emphasis has been on wind-tunnel testing of two-dimensional subscale airfoils with various ice shapes to understand their effect on the flowfield and ultimately the aerodynamics. This research has led to wind-tunnel testing of subscale complete aircraft models to identify the integrated effects of icing on the aircraft system in terms of performance, stability, and control. Data sets of this nature enable pilot-in-the-loop simulations to be performed for pilot training or engineering evaluation of system failure impacts or control system design.

Published
2010
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24. Current Icing Potential: Algorithm Description and Comparison with Aircraft Observations

Author

Barbara G. Brown, Cory A. Wolff, Gary Cunning, Ben C. Bernstein, Marcia K. Politovich, Dean R. Miller, Thomas P. Ratvasky, and Frank McDonough

Subjects
Atmospheric Science, Meteorology, Aviation, business.industry, Computer science, Cloud physics, Context (language use), Lightning, Fuzzy logic, law.invention, law, Satellite, Radar, business, Algorithm, Icing
Abstract

The “current icing potential” (CIP) algorithm combines satellite, radar, surface, lightning, and pilot-report observations with model output to create a detailed three-dimensional hourly diagnosis of the potential for the existence of icing and supercooled large droplets. It uses a physically based situational approach that is derived from basic and applied cloud physics, combined with forecaster and onboard flight experience from field programs. Both fuzzy logic and decision-tree logic are applied in this context. CIP determines the locations of clouds and precipitation and then estimates the potential for the presence of supercooled liquid water and supercooled large droplets within a given airspace. First developed in the winter of 1997/98, CIP became an operational National Weather Service and Federal Aviation Administration product in 2002, providing real-time diagnoses that allow users to make route-specific decisions to avoid potentially hazardous icing. The CIP algorithm, its individual components, and the logic behind them are described.

Published
2005
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25. Naturally Aspirating Isokinetic Total Water Content Probe: Pre-flight Wind Tunnel Testing and Design Modifications

Author

John W. Strapp, Tim Rutke, Craig R. Davison, Edward Emery, and Thomas P. Ratvasky

Subjects
geography, geography.geographical_feature_category, Ice crystals, Airworthiness, Mass flow, Environmental science, Measurement uncertainty, Geotechnical engineering, Inlet, Water content, Evaporator, Marine engineering, Wind tunnel
Abstract

Airworthiness authorities have recognized that ice crystal ingestion into gas turbine engines at high altitudes can result in engine damage, operational instabilities and in-flight shutdowns. As part of a requirement for revised certification regulations to address these issues, it is important to quantify the severity of the ice crystal environment where modern aircraft operate. To accomplish this, a robust, accurate and reliable instrument is needed to define the total water content as a function of altitude and temperature. Some previous devices have suffered from measurement uncertainty and short life when exposed to a high speed erosive ice crystal environment. Measurement uncertainty can result if a device has poor capture efficiency, due to rebound of ice crystals. The National Research Council Canada (NRC), in cooperation with Environment Canada, has developed an isokinetic total water content probe (IKP) for use in sea level wind tunnels, altitude chambers and flight tests. Figure 1 shows the probe layout. The atmospheric vapour, ice, and liquid water mixture enters through the inlet, passes through the evaporator, continues into the instrumented section where the water content and mass flow are

Published
2012
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26. Naturally aspirating isokinetic total water content probe: Wind tunnel test results and design modifications

Author

Thomas P. Ratvasky, Lyle Lilie, and Craig R. Davison

Subjects
Engineering, Design modifications, NASA Glenn, Aircraft, business.industry, Ice crystals, Liquid water content, Liquids, Inlet flow, Stokes number, Ground based, Wind tunnel tests, Total water content, Power supply unit, Geotechnical engineering, Probes, Flight testing, Supercooled liquids, business, Collection efficiency, NASA, Water content, Wind tunnel test
Abstract

A total water content probe for flight and ground based testing is being completed. During operation across a range of altitudes and water content conditions, the probe has to maintain isokinetic flow, vaporize the solid and liquid water content and maintain the inlet ice free to ensure isokinetic flow. Despite achieving isokinetic operation, the collection efficiency of particles less than 30 μm can be less than 100%. A correlation of collection efficiency to Stokes number has been determined to correct the results for this effect. In preparation for flight testing an integrated data acquisition, control and power supply unit was developed and successfully tested. Results from testing at the NASA Glenn Icing Research Tunnel are presented covering both ice crystals and super cooled liquid conditions. The results correspond well to previously published work and problems encountered during previous testing of this probe are shown to have been resolved., SAE 2011 International Conference on Aircraft and Engine Icing and Ground Deicing, 13 June 2011 through 17 June 2011, Chicago, IL

Published
2011
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28. Dynamic Wind-Tunnel Testing of a Sub-Scale Iced S-3B Viking

Author

Sam Lee, Thomas P. Ratvasky, and Billy P. Barnhart

Subjects
Engineering, Ice protection system, business.industry, Angle of attack, Reynolds number, Stall (fluid mechanics), Flight control surfaces, Mechanics, Atmospheric icing, Physics::Geophysics, symbols.namesake, Thermal, symbols, Astrophysics::Earth and Planetary Astrophysics, business, Physics::Atmospheric and Oceanic Physics, Marine engineering, Wind tunnel
Abstract

The effect of ice accretion on a 1/12-scale complete aircraft model of S-3B Viking was studied in a rotary-balance wind tunnel. Two types of ice accretions were considered: ice protection system failure shape and runback shapes that form downstream of the thermal ice protection system. The results showed that the ice shapes altered the stall characteristics of the aircraft. The ice shapes also reduced the control surface effectiveness, but mostly near the stall angle of attack. There were some discrepancies with the data with the flaps deflected that were attributed to the low Reynolds number of the test. Rotational and forced-oscillation studies showed that the effects of ice were mostly in the longitudinal forces, and the effects on the lateral forces were relatively minor.

Published
2009
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29. Flight Testing an Iced Business Jet for Flight Simulation Model Validation

Author

Sam Lee, Thomas P. Ratvasky, Jon Cooper, and Billy P. Barnhart

Subjects
Aerodynamic force, Engineering, business.product_category, Elevator, Ice protection system, business.industry, Stall (fluid mechanics), Flight training, Aerospace engineering, business, Flight simulator, Flight test, Airplane
Abstract

A flight test of a business jet aircraft with various ice accretions was performed to obtain data to validate flight simulation models developed through wind tunnel tests. Three types of ice accretions were tested: pre-activation roughness, runback shapes that form downstream of the thermal wing ice protection system, and a wing ice protection system failure shape. The high fidelity flight simulation models of this business jet aircraft were validated using a software tool called "Overdrive." Through comparisons of flight-extracted aerodynamic forces and moments to simulation-predicted forces and moments, the simulation models were successfully validated. Only minor adjustments in the simulation database were required to obtain adequate match, signifying the process used to develop the simulation models was successful. The simulation models were implemented in the NASA Ice Contamination Effects Flight Training Device (ICEFTD) to enable company pilots to evaluate flight characteristics of the simulation models. By and large, the pilots confirmed good similarities in the flight characteristics when compared to the real airplane. However, pilots noted pitch up tendencies at stall with the flaps extended that were not representative of the airplane and identified some differences in pilot forces. The elevator hinge moment model and implementation of the control forces on the ICEFTD were identified as a driver in the pitch ups and control force issues, and will be an area for future work.

Published
2007
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30. Dynamic Wind-Tunnel Testing of a Sub-Scale Iced Business Jet

Author

Edward G. Dickes, Michael Thacker, Sam Lee, Thomas P. Ratvasky, and Billy P. Barnhart

Subjects
Lift coefficient, Engineering, Jet (fluid), Wing, Post stall, Ice protection system, business.industry, Mechanical engineering, Reynolds number, Mechanics, symbols.namesake, Surface roughness, symbols, Astrophysics::Earth and Planetary Astrophysics, business, Physics::Atmospheric and Oceanic Physics, Wind tunnel
Abstract

The effect of ice accretion on a 1/12-scale complete aircraft model of a business jet was studied in a rotary-balance wind tunnel. Three types of ice accretions were considered: ice protection system failure shape, pre-activation roughness, and runback shapes that form downstream of the thermal ice protection system. The results were compared with those from a 1/12-scale semi-span wing of the same aircraft at similar Reynolds number. The data showed that the full aircraft and the semi-span wing models showed similar characteristics, especially post stall behavior under iced configuration. However, there were also some discrepancies, such as the magnitude in the reductions in the maximum lift coefficient. Most of the ice-induced effects were limited to longitudinal forces. Rotational and forced oscillation studies showed that the effects of ice on lateral forces were relatively minor.

Published
2006
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31. Demonstration of an Ice Contamination Effects Flight Training Device

Author

Sam Lee, Thomas P. Ratvasky, Richard J. Ranaudo, and Kurt S. Blankenship

Subjects
Engineering, business.product_category, Flight envelope, Aeronautics, business.industry, Flight inspection, Airframe, Flight management system, Flight training, business, Flight simulator, Flight test, Airplane
Abstract

The development of a piloted flight simulator called the Ice Contamination Effects Flight Training Device (ICEFTD) was recently completed. This device demonstrates the ability to accurately represent an iced airplane s flight characteristics and is utilized to train pilots in recognizing and recovering from aircraft handling anomalies that result from airframe ice formations. The ICEFTD was demonstrated at three recent short courses hosted by the University of Tennessee Space Institute. It was also demonstrated to a group of pilots at the National Test Pilot School. In total, eighty-four pilots and flight test engineers from industry and the regulatory community spent approximately one hour each in the ICEFTD to get a "hands on" lesson of an iced airplane s reduced performance and handling qualities. Additionally, pilot cues of impending upsets and recovery techniques were demonstrated. The purpose of this training was to help pilots understand how ice contamination affects aircraft handling so they may apply that knowledge to the operations of other aircraft undergoing testing and development. Participant feedback on the ICEFTD was very positive. Pilots stated that the simulation was very valuable, applicable to their occupations, and provided a safe way to explore the flight envelope. Feedback collected at each demonstration was also helpful to define additional improvements to the ICEFTD; many of which were then implemented in subsequent demonstrations

Published
2006
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32. NASA Icing Remote Sensing System Comparisons from AIRS II

Author

Thomas P. Ratvasky, Andrew L. Reehorst, and David J. Brinker

Subjects
Geography, Lidar, Icing conditions, Radiometer, Meteorology, Liquid water content, law, Radiometry, Radar, Ceilometer, law.invention, Icing, Remote sensing
Abstract

NASA has an on-going activity to develop remote sensing technologies for the detection and measurement of icing conditions aloft. A multiple instrument approach is the current emphasis of this activity. Utilizing radar, radiometry, and lidar, a region of supercooled liquid is identified. If the liquid water content (LWC) is sufficiently high, then the region of supercooled liquid cloud is flagged as being an aviation hazard. The instruments utilized for the current effort are an X-band vertical staring radar, a radiometer that measures twelve frequencies between 22 and 59 GHz, and a lidar ceilometer. The radar data determine cloud boundaries, the radiometer determines the sub-freezing temperature heights and total liquid water content, and the ceilometer refines the lower cloud boundary. Data is post-processed with a LabVIEW program with a resultant supercooled LWC profile and aircraft hazard identification. Individual remotely sensed measurements gathered during the 2003-2004 Alliance Icing Research Study (AIRS II) were compared to aircraft in-situ measurements. Comparisons between the remote sensing system s fused icing product and in-situ measurements from the research aircraft are reviewed here. While there are areas where improvement can be made, the cases examined indicate that the fused sensor remote sensing technique appears to be a valid approach.

Published
2005
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34. Development and Utility of a Piloted Flight Simulator for Icing Effects Training

Author

Thomas P. Ratvasky, Billy P. Barnhart, Richard J. Ranaudo, Edward G. Dickes, and David R. Gingras

Subjects
Engineering, business.industry, Flight inspection, Flight management system, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Flight envelope protection, Flight simulator, GeneralLiterature_MISCELLANEOUS, Fly-by-wire, Cockpit, Aeronautics, Airframe, Flight training, business, Simulation
Abstract

A piloted flight simulator called the Ice Contamination Effects Flight Training Device (ICEFTD), which uses low cost desktop components and a generic cockpit replication is being developed. The purpose of this device is to demonstrate the effectiveness of its use for training pilots to recognize and recover from aircraft handling anomalies that result from airframe ice formations. High-fidelity flight simulation models for various baseline (non-iced) and iced configurations were developed from wind tunnel tests of a subscale DeHavilland DHC-6 Twin Otter aircraft model. These simulation models were validated with flight test data from the NASA Twin Otter Icing Research Aircraft, which included the effects of ice on wing and tail stall characteristics. These simulation models are being implemented into an ICEFTD that will provide representative aircraft characteristics due to airframe icing. Scenario-based exercises are being constructed to give an operational-flavor to the simulation. Training pilots will learn to recognize iced aircraft characteristics from the baseline, and will practice and apply appropriate recovery procedures to a handling event.

Published
2003
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35. Modeling of In-Flight Icing Effects for Flight Training

Author

Edward G. Dickes, David R. Gingras, Billy P. Barnhart, and Thomas P. Ratvasky

Subjects
Engineering, business.product_category, business.industry, Training (meteorology), Flight simulator, Airplane, Aviation safety, Icing conditions, Aeronautics, Flight training, Aerospace engineering, business, Icing, Wind tunnel
Abstract

To enhance aviation safety, NASA has initiated a simulator program, Pilot Simulator Training for Aircraft Icing Effects (PSIM), to better familiarize and train pilots for the effects of icing in flight. As part of this effort, a process for developing high-fidelity flight models of aircraft in icing conditions has been explored. The NASA DeHavilland DHC-6 Twin Otter was chosen as the subject vehicle for the work. Data for the effort were collected both from flight and wind tunnels then used to establish flight simulations for a clean airplane with no ice, an iced tail plane, and an iced wing and tail plane. Correlations of the flight models with flight data were good overall, but several areas for process improvement were identified.

Published
2002
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36. Simulation Model Development for Icing Effects Flight Training

Author

Thomas P. Ratvasky, David R. Gingras, Billy P. Barnhart, and Edward G. Dickes

Subjects
Engineering, Icing conditions, business.product_category, Aeronautics, business.industry, Training (meteorology), Flight training, business, Flight simulator, Flight test, Icing, Airplane, Wind tunnel
Abstract

A high-fidelity simulation model for icing effects flight training was developed from wind tunnel data for the DeHavilland DHC-6 Twin Otter aircraft. First, a flight model of the un-iced airplane was developed and then modifications were generated to model the icing conditions. The models were validated against data records from the NASA Twin Otter Icing Research flight test program with only minimal refinements being required. The goals of this program were to demonstrate the effectiveness of such a simulator for training pilots to recognize and recover from icing situations and to establish a process for modeling icing effects to be used for future training devices.

Published
2002
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37. Iced Aircraft Flight Data for Flight Simulator Validation

Author

Kurt S. Blankenship, Thomas P. Ratvasky, William J. Rieke, and David J. Brinker

Subjects
Aircraft flight mechanics, Engineering, Tailplane, Elevator, business.industry, Stall (fluid mechanics), Flight control surfaces, Aerospace engineering, business, Flight simulator, Flight test, Fly-by-wire
Abstract

NASA is developing and validating technology to incorporate aircraft icing effects into a flight training device concept demonstrator. Flight simulation models of a DHC-6 Twin Otter were developed from wind tunnel data using a subscale, complete aircraft model with and without simulated ice, and from previously acquired flight data. The validation of the simulation models required additional aircraft response time histories of the airplane configured with simulated ice similar to the subscale model testing. Therefore, a flight test was conducted using the NASA Twin Otter Icing Research Aircraft. Over 500 maneuvers of various types were conducted in this flight test. The validation data consisted of aircraft state parameters, pilot inputs, propulsion, weight, center of gravity, and moments of inertia with the airplane configured with different amounts of simulated ice. Emphasis was made to acquire data at wing stall and tailplane stall since these events are of primary interest to model accurately in the flight training device. Analyses of several datasets are described regarding wing and tailplane stall. Key findings from these analyses are that the simulated wing ice shapes significantly reduced the C , max, while the simulated tail ice caused elevator control force anomalies and tailplane stall when flaps were deflected 30 deg or greater. This effectively reduced the safe operating margins between iced wing and iced tail stall as flap deflection and thrust were increased. This flight test demonstrated that the critical aspects to be modeled in the icing effects flight training device include: iced wing and tail stall speeds, flap and thrust effects, control forces, and control effectiveness.

Published
2002
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38. Ice accretion formations on a NACA 0012 swept wing tip in natural icing conditions

Author

Mario Vargas, Thomas P. Ratvasky, and Julius A. Giriunas

Subjects
Airfoil, Engineering, Icing conditions, business.industry, Swept wing, Ice accretion, business, Geomorphology, NACA airfoil, Marine engineering, Icing
Abstract

An experiment was conducted in the DeHavilland DHC-6 Twin Otter Icing Research Aircraft at NASA Glenn Research Center to study the formation of ice accretions on swept wings in natural icing conditions. The experiment was designed to obtain ice accretion data to help determine if the mechanisms of ice accretion formation observed in the Icing Research Tunnel are present in natural icing conditions. The experiment in the Twin Otter was conducted using a NACA 0012 swept wing tip. The model enabled data acquisition at 0 deg, 15 deg, 25 deg, 30 deg, and 45 deg sweep angles. Casting data, ice shape tracings, and close-up photographic data were obtained. The results showed that the mechanisms of ice accretion formation observed in-flight agree well with the ones observed in the Icing Research Tunnel. Observations on the end cap of the airfoil showed the same strong effect of the local sweep angle on the formation of scallops as observed in the tunnel.

Published
2002
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43. Flying Qualities Evaluation of a Commuter Aircraft with an Ice Contaminated Tailplane

Author

Thomas P. Ratvasky, Richard J. Ranaudo, and Judith F. Van Zante

Subjects
business.product_category, Tailplane, Elevator, Computer science, Aviation, business.industry, Airspeed, Flying qualities, Thrust, Airplane, Aeronautics, Aerospace engineering, business, Icing
Abstract

During the NASA/FAA (Federal Aviation Administration) Tailplane Icing Program, pilot evaluations of aircraft flying qualities were conducted with various ice shapes attached to the horizontal tailplane of the NASA Twin Otter Icing Research Aircraft. Initially, only NASA pilots conducted these evaluations, assessing the differences in longitudinal flight characteristics between the baseline or clean aircraft, and the aircraft configured with an Ice Contaminated Tailplane (ICT). Longitudinal tests included Constant Airspeed Flap Transitions, Constant Airspeed Thrust Transitions, zero-G Pushovers, Repeat Elevator Doublets, and Simulated Approach and Go-Around tasks. Later in the program, guest pilots from government and industry were invited to fly the NASA Twin Otter configured with a single full-span artificial ice shape attached to the leading edge of the horizontal tailplane. This shape represented ice formed due to a 'Failed Boot' condition, and was generated from tests in the Glenn Icing Research Tunnel on a full-scale tailplane model. Guest pilots performed longitudinal handling tests, similar to those conducted by the NASA pilots, to evaluate the ICT condition. In general, all pilots agreed that longitudinal flying qualities were degraded as flaps were lowered, and further degraded at high thrust settings. Repeat elevator doublets demonstrated reduced pitch damping effects due to ICT, which is a characteristic that results in degraded flying qualities. Pilots identified elevator control force reversals (CFR) in zero-G pushovers at a 20 deg flap setting, a characteristic that fails the FAR 25 no CFR certification requirement. However, when the same pilots used the Cooper-Harper rating scale to perform a simulated approach and go-around task at the 20 deg flap setting, they rated the airplane as having Level I and Level II flying qualities respectively. By comparison, the same task conducted at the 30 deg flap setting, resulted in Level II flying qualities for the approach portion, and Level III for the go-around portion.The results of this program indicate that safe and acceptable flying qualities with an ICT condition, can be effectively assessed by task-oriented pilot maneuvers. In addition, other maneuvers such as repeat elevator doublets provide good qualitative and quantitative assessments of pitch damping and elevator effectiveness, which are characteristics that correlate well with pilot task ratings. The results of this testing indicate that the FAR 25 zero-G pushover maneuver, which requires no CFR during its execution, may be an overly conservative pass/fail criteria for aircraft certification.

Published
2000
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44. In-flight aerodynamic measurements of an iced horizontal tailplane

Author

Judith Foss VanZante and Thomas P. Ratvasky

Subjects
Aircraft flight mechanics, Engineering, Tailplane, Elevator, business.industry, Angle of attack, Longitudinal static stability, Stall (fluid mechanics), Flight control surfaces, Aerospace engineering, business, Marine engineering, Slip (aerodynamics)
Abstract

The effects of tailplane icing on aircraft dynamics and tailplane aerodynamics were investigated using, NASA's modified DHC-6 Twin Otter icing research aircraft. This flight program was a major element of the four-year NASA/FAA research program that also included icing wind tunnel testing, dry-air aerodynamic wind tunnel testing, and analytical code development. Flight tests were conducted to obtain aircraft dynamics and tailplane aerodynamics of the DHC-6 with four tailplane leading-edge configurations. These configurations included a clean (baseline) and three different artificial ice shapes. Quasi-steady and various dynamic flight maneuvers were performed over the full range of angles of attack and wing flap settings with each iced tailplane configuration. This paper presents results from the quasi-steady state flight conditions and describes the range of flow fields at the horizontal tailplane, the aeroperformance effect of various ice shapes on tailplane lift and elevator hinge moment, and suggests three paths that can lead toward ice-contaminated tailplane stall. It was found that wing, flap deflection was the most significant factor in driving the tailplane angle of attack toward alpha(tail stall). However, within a given flap setting, an increase in airspeed also drove the tailplane angle of attack toward alpha(tail stall). Moreover, increasing engine thrust setting also pushed the tailplane to critical performance limits, which resulted in premature tailplane stall.

Published
1999
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45. NASA/FAA Tailplane Icing Program overview

Author

Thomas P. Ratvasky, James T. Riley, and Judith F. Van Zante

Subjects
Engineering, Ice formation, Tailplane, Code development, Aeronautics, business.industry, Aerodynamics, business, Wind tunnel, Icing
Abstract

The effects of tailplane icing were investigated in a four-year NASA/FAA Tailplane Icing, Program (TIP). This research program was developed to improve the understanding, of iced tailplane aeroperformance and aircraft aerodynamics, and to develop design and training aides to help reduce the number of incidents and accidents caused by tailplane icing. To do this, the TIP was constructed with elements that included icing, wind tunnel testing, dry-air aerodynamic wind tunnel testing, flight tests, and analytical code development. This paper provides an overview of the entire program demonstrating the interconnectivity of the program elements and reports on current accomplishments.

Published
1999
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46. Investigation of dynamic flight maneuvers with an iced tailplane

Author

Thomas P. Ratvasky and Judith F. Van Zante

Subjects
Engineering, Leading edge, Tailplane, Elevator, Aeronautics, business.industry, Deflection (engineering), Flapping, Stall (fluid mechanics), business, Stabilizer (aeronautics), Icing
Abstract

A detailed analysis of two of the dynamic maneuvers, the pushover and elevator doublet, from the NASA/FAA Tailplane Icing Program are discussed. For this series of flight tests, artificial ice shapes were attached to the leading edge of the horizontal stabilizer of the NASA Lewis Research Center icing aircraft, a DHC-6 Twin Otter. The purpose of these tests was to learn more about ice-contaminated tailplane stall (ICTS), the known cause of 16 accidents resulting in 139 fatalities. The pushover has been employed by the FAA, JAA and Transport Canada for tailplane icing certification. This research analyzes the pushover and reports on the maneuver performance degradation due to ice shape severity and flap deflection. A repeatability analysis suggests tolerances for meeting the required targets of the maneuver. A second maneuver, the elevator doublet, is also studied.

Published
1999
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47. Wind tunnel measured effects on a twin-engine short-haul transport caused by simulated ice accretions

Author

Thomas P. Ratvasky, Brenda Gile Laflin, Mark G. Potapczuk, and Andrew L. Reehorst

Subjects
Flow visualization, Airfoil, Leading edge, Drag, business.industry, Environmental science, Aerospace engineering, business, Atmospheric icing, Marine engineering, Wind tunnel, Icing, Landing gear
Abstract

A series of wind tunnel tests were conducted to assess the effects of leading edge ice contamination upon the performance of a short-haul transport. The wind tunnel test was conducted in the NASA Langley 14 by 22 foot facility. The test article was a 1/8 scale twin-engine short-haul jet transport model. Two separate leading edge ice contamination configurations were tested in addition to the uncontaminated baseline configuration. Several aircraft configurations were examined including various flap and slat deflections, with and without landing gear. Data gathered included force measurements via an internal six-component force balance, pressure measurements through 700 electronically scanned wing pressure ports, and wing surface flow visualization measurements. The artificial ice contamination caused significant performance degradation and caused visible changes demonstrated by the flow visualization. The data presented here is just a portion of the data gathered. A more complete data report is planned for publication as a NASA Technical Memorandum and data supplement.

Published
1996
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48. Close-up analysis of inflight ice accretion

Author

Andrew L. Reehorst, Thomas P. Ratvasky, and James Sims

Subjects
Geography, Drop size, Meteorology, Drag, Video tape, Ice accretion, Snow, Droplet size, Atmospheric icing, Icing
Abstract

The objective of this effort was to validate in flight, data that has been gathered in the NASA Lewis Research Center's Icing Research Tunnel (IRT) over the past several years. All data was acquired in flight on the NASA Lewis Research Center's Twin Otter Icing Research Aircraft. A faired 3.5 in. diameter metal-clad cylinder exposed to the natural icing environment was observed by a close-up video camera. The grazing angle video footage was recorded to S-VHS video tape and after the icing encounter, the resultant ice shape was documented by 35 mm photography and pencil tracings. The feather growth area was of primary interest; however, all regions of the ice accretion, from the stagnation line to the aft edge of run back were observed and recorded. After analysis of the recorded data several interesting points became evident: (1) the measured flight feather growth rate is consistent with IRT values, (2) the feather growth rate appears to be influenced by droplet size, (3) the feathers were straighter in the lower, spottier LWC of flight in comparison to those observed in the IRT, (4) feather shedding and ice sublimation may be significant to the final ice shape, and (5) the snow encountered on these flights appeared to have little influence on ice growth.

Published
1994
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