THE DEVELOPMENT OF THE BIRD-IMPACTOR MODEL FOR MATHEMATICAL MODELING OF TURBOFAN ENGINE PARTS DAMAGE PROCESSES
Abstract
Keywords
Full Text:
PDF (Русский)References
Smetankina, N. V., Ivchenko, D. V. Obespechenie ptitsestoikosti rabochikh lopatok ventilyatora TRDD metodami matematicheskogo i fizicheskogo modelirovaniya. Tez. dokl. I Mezhdunar. nauch.-tekhn. konf. “Dinamika, prochnost' i modelirovanie v mashinostroenii” [Theses of 1st scientific and technical conf. “Dynamics, strength, and modeling in mechanical engineering”]. Kharkov, 2018, pp. 119–120. (In Russian).
Niering, E. Simulation of bird strikes on turbine engines. Journal of engineering for gas turbines and power, 1990, vol. 112 (4), pp. 573-578.
Moffat, Т. J., Cleghom, W. L. Prediction of bird impact pressures and damage using MSC/DYTRAN. Turbo Expo: Power for Land, Sea, and Air, 2001, 9 p. DOI: 10.1115/2001-GT-0280.
Zeng Chuana, Jiang Xiang-hua, Chai Xiang-hai, Shi Tong-cheng. TC4 Hollow Fan Blade Structural Optimi-zation Based on Bird-Strike Analysis. Procedia Engineering, 2015, vol. 99, pp. 1385-1394. DOI: 10.1016/j.proeng.2014.12.674.
Kuz'min, M. V., Kirsanov A. R. Validatsiya modeli zabrosa ptitsy na vkhod v aviatsionnyi gazoturbinnyi dvigatel' [Validation of aircraft gas-turbine engine inlet bird throw-in simulation model]. Nauchnyi vestnik MGTU GA - Civil Aviation High Technologies, 2015, no. 212, pp. 120-126.
Syed Noman Husainie. Bird Strike and Novel Design of Fan Blades. Science in the Age of Experience. Chicago, 2017, pp. 26-40.
Lukin, E. I. Zoologiya: ucheb. dlya studentov zooinzhenernykh i zooveterinarnykh vuzov i fakul'tetov [Zoology: textbook for high schools]. Moscow, Vysshaya shkola Publ., 1981. 400 p.
Reza Hedayati, Mojtaba Sadighi. Bird Strike: An Experimental, Theoretical and Numerical Investigation, Sawston, Cambridge, Woodhead Publishing, 2015. 258 p.
Smetankina, N., Ugrimov, S., Kravchenko, I., Ivchenko, D. Simulating the process of a bird striking a rigid target. Advances in design, simulation and manufacturing II. Cham, Springer, 2020, pp. 711–721.
Smetankina, N., Kravchenko, I., Merculov, V., Ivchenko, D., Malykhina, A. Modelling of bird strike on an aircraft glazing. Integrated Computer Technologies in Mechanical Engineering. Editors Mykola Nechyporuk, Vladimir Pavlikov, Dmitriy Kritskiy. Series “Advances in Intelligent Systems and Computing”, vol. 1113, Cham, Springer, 2020, pp. 289-297.
Budgey, R. The development of a substitute artificial bird by the international birdstrike research group for use in aircraft component testing. 25th International Bird Strike Committee. Amsterdam, 2000, pp. 543-550.
LS-DYNA® Keyword User's Manual. LS DYNA R8.0. LSTC, 2015, vol. II. 2482 p.
Batchelor, G. K. An Introduction to Fluid Dynamics. Cambridge, Cambridge at the University Press, 1970. (Russ. ed.: Betchelor, Dzh. Vvedenie v dinamiku zhidkosti, Moscow, Mir Publ., 1973. 760 p.)
Wilbeck J. S. Impact Behavior of Low Strength Projectiles. Air Force Materials Lab Wright-Patterson AFB OH, Ohio, 1978. 132 p. technical report: ADA060423.
Mikheev, M. A. Osnovy teploperedachi [Fundamentals of heat transfer]. Moscow, Energiya Publ., 1977. 344 p.
Idelchik, I. Y. Spravochnik po gidravlicheskim soprotivleniyam [Reference book on hydraulic resistances]. Moscow, Mashinostroenie Publ., 1992. 672 p.
Selezneva, M., Stone, P., Moffat, T., Behdinan, K., Poon, C. Modeling Bird Impact on a Rotating Fan: The Influence of Bird Parameters, 11th International LS-DYNA Users Conference. Dearborn, 2010. Available at: https://www.dynalook.com/conferences/international-conf-2010/Aerospace-1-4.pdf/@@download/file/Aerospace(1)-4.pdf (accessed 30.05.2020).
Kirsanov, A. R. Metodika ocenki povrezhdaemosti GTD na jetapah ego sozdanija, izgotovlenija i jeksplu-atacii ot porazhajushhego vozdejstvija ptic. Diss. Kand. Tehn. Nauk. [Methodology of GTE damage estimation on design, manufacture and operation stages from damaging impact of birds. Kand. Diss.]. Moscow, 2015. 229 p.
Vanin, V. A., Svetlichnyi, S. P. Chislennoe issledovanie vzaimodeistviya tela ptitsy s pregradoi na osnove setochnogo i bessetochnogo metodov [Numerical study of the interaction of bird carcasses with an obstacle on the basis of the grid and gridless methods]. Vіsnik Nats. tekhn. un-tu "KhPІ" : zb. nauk. pr. Temat. vip. : Matematichne modelyuvannya v tekhnіtsі ta tekhnologіyakh - Bulletin of National Technical University "KhPI" : coll. of sci. papers. Ser. : Mathematical modeling in engineering and technologies, 2016, no. 16, pp. 5-15.
Barber, J. P., Taylor, H. R., Wilbeck, J. S. Bird Impact Forces and Pressures on Rigid and Compliant Targets. University of Dayton Research Institute, Dayton, 1978. 88 p. technical report: ADA061313.
Wilbeck, J. S., Rand, J. L. The Development of a Substitute Bird Model. Journal of Engineering for Power, 1981, vol. 103 (4), pp. 725-730.
Ugrcic, M. Application of the Hydrodynamic Theory and the Finite Element Method in the Analysis of Bird Strike in a Flat Barrier, Scientific Technical Review, 2012, vol. 62, no. 3-4, pp. 28-37.
DOI: https://doi.org/10.32620/aktt.2020.8.11