مجله علمی صوت و ارتعاش

مجله علمی صوت و ارتعاش

تحلیل محاسباتی اثر شدت فرسایش لبه حملۀ ایرفویل بر صوت آیرودینامیکی

نوع مقاله : مقاله پژوهشی

نویسندگان
حمیدرضا کاویانی 1
احسان بشتالم 2
1 استادیار گروه مکانیک دانشگاه ملایر
2 گروه مکانیک، دانشگاه ملایر
چکیده
فرسایش لبه حمله ایرفویل‌ها یکی از چالش‌های مهم در صنایع هوافضا و انرژی بادی است که به طور قابل توجهی بر عملکرد آیرودینامیکی و آلودگی صوتی تأثیر می‌گذارد. این پژوهش به بررسی تأثیر شدت فرسایش لبه حمله بر عملکرد و صوت مقاطع پره پرداخته است. برای این منظور از روش شبیه‌سازی گردابه‌های بزرگ[i] برای مدل‌سازی جریان آشفته و از معادلات تشابه آکوستیکی فاکس-ویلیامز و هاوکینز[ii] برای محاسبه نویز آکوستیکی استفاده شده است. ابتدا روش‌های محاسباتی با داده‌های تجربی اعتبارسنجی شدند و سپس الگوهای فرسایش واقعی بر روی مقطع پره سه‌بعدی اعمال گردیده است. نتایج نشان می‌دهد که فرسایش لبه حمله منجر به تغییرات قابل توجهی در ساختار جریان، افزایش قدرت گردابه‌ها و تأخیر در جدایش لایه مرزی می‌شود. با افزایش شدت فرسایش، افت نیروی برآ[iii] تا ۵ درصد و افزایش نیروی پسا تا ۱۰ درصد مشاهده می‌شود. همچنین، فرسایش لبه حمله باعث افزایش سطح فشار صوت[iv] در محدوده فرکانس‌های پایین می‌شود، به طوری که در حالت فرسودگی شدید، افزایش نویز آکوستیکی به 18/12 دسی‌بل در فاصله 2/19 متری رسیده است. این افزایش نویز عمدتاً ناشی از تقویت گردابه‌های بزرگ و کاهش میرایی صوت در فرکانس‌های پایین است. این مطالعه نه تنها مکانیسم‌های فیزیکی مرتبط با فرسایش لبه حمله را روشن می‌کند، بلکه راه‌حل‌هایی برای تشخیص سریع‌تر آسیب و کاهش اثرات نامطلوب آن بر عملکرد آیرودینامیکی و آلودگی صوتی ارائه می‌دهد.
 
[i]  Large Eddy Simulation, LES
[ii]  Ffowcs Williams-Hawkings, FWH
[iii]  Lift
[iv]  Sound pressure level, SPL


 


 

 
 
کلیدواژه‌ها
آیروآکوستیک
لبه حمله ایرفویل
آسیب
فرسودگی
LES
موضوعات

عنوان مقاله English

Computational Analysis of the Effect of Leading Edge Erosion Intensity on Aerodynamic Noise

نویسندگان English

Hamidreza Kaviani 1
Ehsan Bashtalam 2
1 Assistant Professor, Mechanical Engineering Department. Malayer University
2 Mechanical Engineering Department, Malayer University
چکیده English

Leading-edge erosion of airfoils is one of the major challenges in the aerospace and wind energy industries, significantly affecting aerodynamic performance and noise pollution. This study investigates the impact of leading-edge erosion severity on blade sections' aerodynamic performance and acoustic characteristics. To this end, Large Eddy Simulation (LES) is employed to model turbulent flow, while the Ffowcs Williams-Hawkings (FWH) acoustic analogy is used to compute aeroacoustic noise. The computational methods were first validated against experimental data, and then realistic erosion patterns were applied to a three-dimensional blade section. The results indicate that leading-edge erosion induces significant changes in flow structures, enhances vortex strength, and delays boundary layer separation. As erosion severity increases, lift force degradation of up to 5% and drag force augmentation of up to 10% are observed. Furthermore, leading-edge erosion leads to an increase in the Sound Pressure Level (SPL) in the low-frequency range. In cases of severe erosion, the aeroacoustic noise level rises by 12.18 dB at a distance of 19.2 meters. This noise amplification is primarily attributed to the intensification of large-scale vortices and reduced sound attenuation at low frequencies. This study not only elucidates the physical mechanisms associated with leading-edge erosion but also provides insights into early damage detection and mitigation strategies to minimize its adverse effects on aerodynamic performance and noise pollution.

کلیدواژه‌ها English

Aeroacoustics
airfoil leading edge
damage
erosion
LES
1]   Cappugi, Lorenzo, Alessio Castorrini, Aldo Bonfiglioli, Edmondo Minisci, and M. Sergio Campobasso. "Machine learning-enabled prediction of wind turbine energy yield losses due to general blade leading edge erosion." Energy Conversion and Management 245 (2021): 114567.
[2]  Mishnaevsky Jr, Leon, Charlotte Bay Hasager, Christian Bak, Anna-Maria Tilg, Jakob I. Bech, Saeed Doagou Rad, and Søren Fæster. "Leading edge erosion of wind turbine blades: Understanding, prevention and protection." Renewable Energy 169 (2021): 953-969.
[3]  Doagou-Rad, Saeed, and Leon Mishnaevsky Jr. "Rain erosion of wind turbine blades: computational analysis of parameters controlling the surface degradation." Meccanica 55, no. 4 (2020): 725-743.
[4]  Im, Heejeon, and Bumsuk Kim. "Numerical study on the effect of blade surface deterioration by erosion on the performance of a large wind turbine." Journal of Renewable and Sustainable Energy 11, no. 6 (2019).
[5]  Gharali, Kobra, and David A. Johnson. "Numerical modeling of an S809 airfoil under dynamic stall, erosion and high reduced frequencies." Applied Energy 93 (2012): 45-52.
[6]  Ortolani, Andrea, Alessio Castorrini, and M. Sergio Campobasso. "Multi-scale Navier-Stokes analysis of geometrically resolved erosion of wind turbine blade leading edges." In Journal of Physics: Conference Series, vol. 2265, no. 3, p. 032102. IOP Publishing, 2022.
[7]  Papi, Francesco, Pier Francesco Melani, Jörg Alber, Francesco Balduzzi, Giovanni Ferrara, Christian Navid Nayeri, and Alessandro Bianchini. "Potential of mini Gurney flaps as a retrofit to mitigate the performance degradation of wind turbine blades induced by erosion." In Journal of Physics: Conference Series, vol. 2265, no. 3, p. 032046. IOP Publishing, 2022.
[8]  Fiore, Giovanni, and Michael S. Selig. "Optimization of wind turbine airfoils subject to particle erosion." In 33rd AIAA Applied Aerodynamics Conference, p. 3393. 2015. [9] M. S. Campobasso, A. Castorrini, L. Cappugi, and A. Bonfiglioli, "Experimentally validated three‐dimensional computational aerodynamics of wind turbine blade sections featuring leading edge erosion cavities," Wind Energy, vol. 25, pp. 168-189, 2022.
[10]      Ffowcs Williams, John E., and David L. Hawkings. "Sound generation by turbulence and surfaces in arbitrary motion." Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences 264, no. 1151 (1969): 321-342.
[11]      Sagaut, Pierre. Large eddy simulation for incompressible flows: an introduction. Springer Science & Business Media, 2005.
[12]      Kaviani, Hamidreza, and Ehsan Bashtalam. "Investigating the effect of SGS models in the LES method on the shape of eddies and calculating the emitted sound by implementing the Ffowcs Williams–Hawkings equation." Journal of Vibration and Sound 12, no. 23 (2023): 55-71.
[13]      Tucker, P. G. "Computation of unsteady turbomachinery flows: Part 2—LES and hybrids." Progress in Aerospace Sciences 47, no. 7 (2011): 546-569.
[14] Davidson, Lars, and Simon Dahlström. "Hybrid LES-RANS: An approach to make LES applicable at high Reynolds number." International journal of computational fluid dynamics 19, no. 6 (2005): 415-427.
[15]      Jawahar, Hasan Kamliya, S. Vemuri, and Mahdi Azarpeyvand. "Aerodynamic noise characteristics of airfoils with morphed trailing edges." International Journal of Heat and Fluid Flow 93, no. 108892 (2022): 108892.
[16]      Kaviani, Hamidreza, and Ehsan Bashtalam. "Investigating the effect of non-dimensional distances on the calculation of sound intensity in large eddy simulation method." Journal of Vibration and Sound 11, no. 22 (2023): 61-78.
[17]      Menter, Florian R. "Best practice: scale-resolving simulations in ANSYS CFD." ANSYS Germany GmbH 1 (2012): 1-70.
[18]      Tucker, Paul G. Unsteady computational fluid dynamics in aeronautics. Vol. 104. Springer Science & Business Media, 2013.
[19]      Rumsey, Christopher L., and Takafumi Nishino. "Numerical study comparing RANS and LES approaches on a circulation control airfoil." International Journal of Heat and Fluid Flow 32, no. 5 (2011): 847-864.
[20] Wang, Meng, Stephane Moreau, Gianluca Iaccarino, and Michel Roger. "LES prediction of wall-pressure fluctuations and noise of a low-speed airfoil." International journal of aeroacoustics 8, no. 3 (2009): 177-197.
[21]      Wolf, William Roberto. Airfoil aeroacoustics, les and acoustic analogy predictions. Stanford University, 2011.
[22]      Solís-Gallego, Irene, Katia María Argüelles Díaz, Jesús Manuel Fernández Oro, and Sandra Velarde-Suárez. "Wall-resolved LES modeling of a wind turbine airfoil at different angles of attack." Journal of Marine Science and Engineering 8, no. 3 (2020): 212.
[23]      Seifollahi Moghadam, Zahra, François Guibault, and André Garon. "On the evaluation of mesh resolution for large-eddy simulation of internal flows using OpenFOAM." Fluids 6, no. 1 (2021): 24.
[24]      Kaviani, Hamidreza, and Ehsan Bashtalem. "Investigating the effect of modeling and simulation of vortices on aeroacoustic calculations in homogeneous shear flow." Modares Mechanical Engineering 23, no. 11 (2023): 615-626.
[25]      Chapman, Dean R. "Computational aerodynamics development and outlook." AIAA journal 17, no. 12 (1979): 1293-1313.
[26]      Tucker, Paul G., and Lars Davidson. "Zonal k–l based large eddy simulations." Computers & Fluids 33, no. 2 (2004): 267-287.
[27]      Piomelli, Ugo, Joel Ferziger, Parviz Moin, and John Kim. "New approximate boundary conditions for large eddy simulations of wall‐bounded flows." Physics of Fluids A: Fluid Dynamics 1, no. 6 (1989): 1061-1068.
[28]      Brooks, Thomas F., D. Stuart Pope, and Michael A. Marcolini. Airfoil self-noise and prediction. No. L-16528. 1989.
[29]      Han, Woobeom, Jonghwa Kim, and Bumsuk Kim. "Effects of contamination and erosion at the leading edge of blade tip airfoils on the annual energy production of wind turbines." Renewable energy 115 (2018): 817-823.
[30]      Kaviani, Hamid R., and Mohammad Moshfeghi. "Power Generation Enhancement of Horizontal Axis Wind Turbines Using Bioinspired Airfoils: A CFD Study." Machines 11, no. 11 (2023): 998.
[31]      Ladson, Charles L., Acquilla S. Hill, and William G. Johnson Jr. Pressure distributions from high Reynolds number transonic tests of an NACA 0012 airfoil in the Langley 0.3-meter transonic cryogenic tunnel. No. NASA-TM-100526. 1987.
[32]      Gregory, Nigel, and C. L. O'reilly. "Low-speed aerodynamic characteristics of NACA 0012 aerofoil section, including the effects of upper-surface roughness simulating hoar frost." (1970).
[33]      Kaviani, Hamidreza, and Ehsan Bashtalam. "Investigating the Effect of Icing on Aerodynamics and Aeroacoustics of an Airfoil." Modares Mechanical Engineering 23, no. 8 (2023): 455-465.
[34]      Hunt, Julian CR, Alan A. Wray, and Parviz Moin. "Eddies, streams, and convergence zones in turbulent flows." Studying turbulence using numerical simulation databases, 2. Proceedings of the 1988 summer program (1988).
[35]  Turner, Jacob M., and Jae Wook Kim. "Effect of spanwise domain size on direct numerical simulations of airfoil noise during flow separation and stall." Physics of Fluids 32, no. 6 (2020).
[36]      Kaviani, H. R., and A. Nejat. "Aerodynamic noise prediction of a MW-class HAWT using shear wind profile." Journal of Wind Engineering and Industrial Aerodynamics 168 (2017): 164-176.