XFOIL is a program for the design and analysis of subsonic airfoils. XFOIL was created by Mark Drela of MIT and is available for free since it was released under the GNU General Public License. It is a command prompt and menu system that performs both airfoil design and inverse design tasks. The following articles and YouTube videos will help you learn how to use this software.
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This article is an illustrated step-by-step guide on how to plot a lift polar (coefficient of lift vs angle of attack) using XFOIL.
This article is an illustrated step-by-step guide on how to plot a drag polar (coefficient of lift vs coefficient of drag) using XFOIL.
This article is an illustrated step-by-step guide on how to plot a moment polar (moment coefficient vs angle of attack) using XFOIL.
Plotting a Transition Plot (CL vs x_tr/c) in XFOIL
This article is an illustrated step-by-step guide on how to plot a transition plot using XFOIL.
This webpage is a list of the available commands in XFOIL, the parameters and parameter types for each command, and the location of the command in the menu hierarchy.
This past year I started making videos on YouTube teaching people how to use XFOIL. As you watch these videos, you will begin to master the XFOIL airfoil design software.
Engineering Design Process Used to Develop APC Propellers
CAD-CAM Computer Program
APC propeller development uses a proprietary PC based CAD-CAM system. The software is specifically tailored for model and UAV propeller design and manufacture. This system has been undergoing continuous development and improvement for over two decades.
Injection Molding Parting Line Requirements
APC propellers are injection molded using a pair of mold halves. CNC milling machines are used to create the molds. The design of the computer software used to define airfoils, and the resulting CNC motion, dominantly reflects parting line driven requirements. The parting line must be very precise and continuous around the entire perimeter of the mold cavity to allow precision molding of the very thin airfoils used on many of the APC propellers.
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Airfoils
The airfoils may have arbitrary shapes defined with either tabular data (splined cubic fits) or analytical functions typically used for NACA airfoils. The airfoil shapes may vary with span. Capability exists to smoothly 'splice' together widely different airfoil shapes. The dominant basis for the primary airfoil shape used in most APC propellers is similar to the NACA 4412 and Clark-Y airfoils, except the leading edge is somewhat lower. Also, the aft region is somewhat thicker. This alters the zero-lift angle by approximately one degree and provides greater lift without having to twist the blade more. Most blades have some washout near the tip. For applications where Mach number effects become significant near the tip, either pitch washout or camber reduction are used to minimize Mach drag rise.
Thin electric, slow-fly, and multi-rotor propellers typically blend the low Reynolds number Eppler E63 airfoil (inboard) with a Clark-Y similar airfoil near the tip.
Hub Geometry
Cross-section geometry in and near the hub region is defined with specialized algorithms. The aerodynamic-dominant airfoil must smoothly transition into a structural-dominant shape in a manner that emphasizes strength consistent with milling machine tool constraints. Hub geometry for 3 and 4 bladed propellers is very complex because of the need to match mold parting lines at all points on the mold surface perimeter.
Theoretical Basis - Aerodynamics
Vortex theory is the basis for the computational method used to calculate blade loading. For some applications, (i.e., an AT-6), the fuselage shape and/or cowling can significantly affect the airflow through the propeller. These flow field effects are computed using 3D potential flow theory. Lift-drag data are computed using the NASA TAIR code, using representative airspeed and engine RPM to set Mach number distributions. Empirical data are used to characterize minimum drag levels under low propeller loading conditions.
Current Development - Aerodynamics
The TAIR code is most appropriate for high speed conditions. This code has been heavily developed to provide very stable (numerical) performance over a broad range of environments. Stability is an essential property for batch processing described below.
APC is currently developing the ability to analyze airfoils at slower speed conditions within our design software. We expect that this improvement will substantially increase predictive accuracy of performance data at low Reynolds numbers.
Performance Data Files
APC provides Performance Data files for all propellers currently in production. These performance data provide estimates of thrust, torque and efficiency over a broad range of model speeds and engine RPM.
The performance data are all computer generated using the theoretical and computational methods described above. A batch processing system is used to update these data when improvements are made to any of the elements within the performance software. Over one week of continuous processing on a high-end workstation is required to update the performance data files.
These data are most useful when utilized on a comparative basis to identify the effects of design changes when test data exist to anchor performance of particular design. The latter is especially true for slower speed conditions where applicability of the TAIR code may be uncertain. In particular, UAV propeller design will benefit from improved performance data where a highly coupled relationship exists between aircraft drag, engine characteristics, and propeller performance.
Theoretical Basis - Structural
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A propeller-unique stress analysis package is used to compute propeller peak stress and fatigue endurance. Blade cross-section geometric properties (needed for structural analysis) are computed numerically with a very fine chord wise mesh. Steady and alternating stresses are evaluated along the entire blade considering inertia and aerodynamic loads. Stresses are evaluated in terms of bending (thrust and drag), centrifugal (inertia), and torsional (acceleration) components. Fatigue endurance margins are estimated assuming Goodman, Gerber and Smith criteria.
Natural modes (frequencies) of the propeller are computed assuming that the hub is rigid. Both published and empirically determined ranges of composite modulus of elasticity (bending) are used to calculate dynamic amplification factors. These dynamic amplification factors are used to augment (intensify) cyclic stress components.
Torsional acceleration for internal combustion is typically highly sensitive to engine fuel mixture and is therefore rather uncertain. Design parameters have been empirically developed to seek reasonable upper bounds for maximum torsional acceleration loads. However, the uncertainty with this sometimes strong (especially for racing applications) contributor to cyclic stress requires that extensive operational testing be employed to verify structural integrity for high performance applications. The component of cyclic torsional acceleration is not considered for electric motor applications.
Cyclic bending stress induced by precession during rapid loops is also included in the stress computations. However, this effect is very minor, even under extreme pitch rate conditions. In addition, precession stress is normally out-of-phase with torsional vibration effects; therefore, it does not add to peak cyclic stress magnitude.
Modulus of Elasticity
Modulus of elasticity (bending) is empirically determined using force-deflection tests with molded specimens that reflect the effects of 'skinning ' during the injection molding process. The bending modulus is sensitive to humidity.
Design Iteration
Fixed pitch propellers generally have to perform well over a large range of flight conditions. Therefore there is no single design condition that may be used to optimize a propeller shape, even if the model airplane characteristics (i.e., total drag coefficient) and engine performance characteristics (torque vs. RPM) are well known. Therefore, most (initial) propeller design iterations are verified almost exclusively with extensive flight tests.
Once a design is broadly set, interactive optimization algorithms may be used to adjust diameter, pitch and chord distributions to maximize thrust for specified model speed, engine RPM and engine torque. Two complementary methods have been used to measure engine RPM and model airspeed. (1) Telemetry provides direct in-flight measurement of engine RPM and airspeed. (2) Radar gun and (video) sound measurements are used to quantify model speed and engine RPM under specific flight conditions. These in-flight speed and RPM data are then used to evaluate the propeller performance. After a large database is developed, interpolation between existing designs is used for developing new designs.
Engine In-Flight RPM and Model Airspeed from Telemetry
The telemetry system is a computer controlled data acquisition system that can record up to 30 minutes of data in solid state memory. The data are played back after flight recovery. While many options exist within the system, it is primarily used for airspeed and RPM measurements. The airspeed and RPM measurements consistently yield data very close to that determined from radar gun and audio recordings, providing considerable confidence in data accuracy.
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Engine In-Flight RPM from Ground Based Video-Audio Recording
Engine in-flight RPM is determined using a video camera to record engine audio. Spectral analysis software is then used to determine the dominant harmonic content from the signal. Audio data are collected with the model flying both toward and away from the pilot. Differences in apparent frequency are used to identify and remove Doppler shift effects.
3 and 4 Blade Propeller Design
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Conversion to 3 and 4 bladed propellers is performed by matching the 2-blade torque for specified model speed and RPM conditions. This method allows efficient use of a rather broad data base that now exists for 2-blade propellers.