Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The aim of the study was to identify acoustic and structural modes in the spectrum obtained exper- imentally inside an operator’s cab in a bulldozer. Measurements were taken inside the operator’s cab in a caterpillar-track bulldozer Polremaco TD12NPH2E-2000, designed for work in underground mine enclosures. The acoustic pressure spectrum was obtained for varied rotational speeds of the engine during the free run of the machine. The reverberation time of the cab was determined basing on the pulse-type excited pressure response, followed by identification of the spectral components registered by measure- ments. Thus, identified frequencies were compared with natural acoustic frequencies registered inside the operator’s cab and with frequencies associated with the valves and ignition frequencies due to rotational speed and natural frequencies of structural vibrations of the cab’s walls. This study was conducted in an attempt to reduce the noise inside the operator’s cab using passive methods.
Słowa kluczowe
Wydawca
Czasopismo
Rocznik
Tom
Strony
653--663
Opis fizyczny
Bibliogr. 38 poz., fot., tab., wykr.
Twórcy
autor
- Institute of Machine Design Cracow University of Technology Al. Jana Pawła II 37, 31-864 Kraków, Poland
autor
- nstitute of Applied Mechanics Cracow University of Technology Al. Jana Pawła II 37, 31-864 Kraków, Poland
Bibliografia
- 1. CARLETTI E. (2013), A perception based method for the noise control of construction machines, Archives of Acoustics, 38, 2, 253-248.
- 2. ChIU M.-C. (2013), Noise elimination of a multi-tone broadband noise with hybrid Helmholtz mufflers using a simulated annealing method, Archives of Acoustics, 37, 4, 489-498.
- 3. CEMPEL CZ. (1989), Applied vibroacoustics [in Polish: Wibroakustyka stosowana], PWN, Warszawa.
- 4. DZIECHCIOWSKI Z., KOZIEŃ M.S. (2014a), Experimental investigation of acoustic parameters for machine cabine, Proceedings of the Colloquium Dynamics of Machines, Prague, 35-40.
- 5. DZIECHCIOWSKI Z., KOZIEŃ M.S. (2014b), Identification of experimentally measured acoustic modes inside bulldozer cabine, CD Proceedings of the Forum Acus- ticum, Cracow, ISSN-2221-3767, 6 pages.
- 6. DZIECHCIOWSKI Z., STOLARSKI B., WICIAK J. (2001), Sound transmission loss computation of a gantry crane cab [in Polish: Ocena izolacyjności kabin suwnic bramowych], Engineering Machine Problems, 18, 133- 141.
- 7. ENGEL Z. (2001), Protecting the environment against vibration and, noise [in Polish: Ochrona środowiska przed drganiami i halasem\, PWN, Warszawa.
- 8. FREYMANN R. (1999), Acoustic applications in vehicle engineering [in:] Fluid-structure interaction in acoustics, Habaut D. [Ed.], International Centre for Mechanical Sciences - Courses and Lectures No. 396, Springer- Verlag, Wien-New York.
- 9. HARGREAVES J.A. (1998), The use of indirect coupled boundary element analysis in vehicle NVH refinement, Proceedings of IMechE, C521/019, 213-227.
- 10. ISO 3382-2:2010, Acoustics - Measurement of Room, Acoustic Parameters - Part 2: Reverberation Time in Ordinary Rooms.
- 11. KAZIMIERSKA M., GRĘBOSZ M. (2001), The level of noise emission by the working machines with, references to European and, Polish standards [in Polish: Poziom hałasu emitowanego przez maszyny robocze w odniesieniu do norm Unii, Europejskiej i Polskich Norm], Engineering Machine Problems, 17, 127-134.
- 12. KOOPMAN G.L. (1982), Interior noise in transportation vehicles [in:] Noise generation and, control in mechanical engineering, Davies P.O.A.L., Heckl M., Koopman G.L. [Eds.], International Centre for Mechanical Sciences - Courses and Lectures No. 276, Springer-Verlag, Wien-New York.
- 13. KOZIEŃ M.S., NIZIOŁ J. (1993), Reduction of the values of the normal surface velocity for vibrating glass of the bulldozer TD20E [in Polish: Zmniejszenie wartości prędkości normalnej dla drgań szyby przedniej spycharki TD20E - analiza teoretyczna], Technical Bulletin of Rzeszów University of Technology - Mechanics, 117, 38, 71-78.
- 14. KOZIEŃ M.S., WICIAK J. (2004), Analysis of noise radiated by structural elements of operators ’ cab [in Polish: Ocena hałasu emitowanego przez elementy poszycia kabin maszyn roboczych], Engineering Machine Problems, 23, 79-90.
- 15. KOZIEŃ M.S., WICIAK J. (2004), Changing of thickness of operator’s cab as a method of increasing of the acoustic comfort of their operators, Polish Journal of Environmental Studies, 13, (Suppl. Ill), 110-113.
- 16. KOZIEŃ M.S., WICIAK J. (2008), Reduction of structural noise inside crane cage by piezoelectric actuators - FEM simulation, Archives of Acoustics, 33, 4, 643- 652.
- 17. KOZIEŃ M.S., WICIAK J. (2009), Choosing of optimal voltage amplitude of four pairs square piezoelectric elements for minimization of acoustic radiation of vibrating plate, Acta Physica Polonica A, A 116, 3, 348-350.
- 18. KOZIEŃ M.S., WICIAK J. (2010), Passive structural acoustic control of the smart plate - FEM simulation, Acta Physica Polonica A, 118, 6, 1186-1188.
- 19. MICHAŁOWSKI S. (1999), State of investigations on the field of vibration and, noise reduction in heavy duty machine cabs [in Polish: Stan badań związanych z redukcją drgań i hałasu w maszynach roboczych, ciężkich], Engineering Machine Problems, 14, 55-85.
- 20. MICHAŁOWSKI S., STOLARSKI B. (1998), Vibration, and noise control in heavy duty machines [in Polish: Zwalczanie wibracji i hałasu w maszynach roboczych, ciężkich], Monography, Cracow University of Technology, Cracow.
- 21. MIN S., NAGAMURA K., NAKAGAWA N., OKAMURA M. (2013), Design of compact micro-perforated membrane absorbers for polycarbonate pane in automobile, Applied Acoustics, 74, 622-627.
- 22. MlSUN S., SVANCARA P. (2001), Acoustic properties of the tractor cabin solved by using SEA method, Proceedings of the Eighth International Congress on Sound and Vibration, Hong Kong, 2335-2342.
- 23. MYUNG-HO S., JANG-MOO L., SEOCK-HYUN K., DONG-CHUL P., SEUNG-GYUN CH., JUNG-HEE K. (1993), A study on the vibration and, acoustic characteristics of a passenger car, Proceedings of Asia-Pacific Vibration Conference, Kitakyushu, 694-699.
- 24. NEFSKE D.J., WOLF J.A., HOWELL J.R. (1982), Structural acoustic finite element analysis of the automotive passenger compartment. A review of current practice, Journal of Sound and Vibration, 80, 2, 247- 266.
- 25. NELSON P.A., ELLIOTT S.P. (1993), Active control of sound, Academic Press Ltd.
- 26. Nizioł J. (Ed.) (1987), Reduction of vibration noise for cages of caterpillar bulldozer [in Polish: Obniżenie wibracji i hałasu w kabinach spycharek gąsienicowych], Technical Note for the Stalowa Wola Steelworks HSW, Cracow University of Technology, Kraków.
- 27. PLEBAN D. (2014), Definition and, measurement of the sound quality of the machine, Archives of Acoustics, 39, 1, 17-23.
- 28. RDZANEK W.P. (2002), The sound pressure from an individual mode of a clamped-free annular plate, Archives of Acoustics, 27, 2, 147-155.
- 29. RDZANEK W.P., ENGEL Z., RDZANEK W. (2003), Theoretical analysis of sound radiation of an elastically supported, circular plate, Journal of Sound and Vibration, 265, 1, 155-174.
- 30. STOEBENER U., GAUL L. (2001), Active vibration control of a car body based, on experimentally evaluated modal parameters, Mechanical Systems and Signal Processing, 15, 1, 173-188.
- 31. STOLARSKI B. (1995), Application of noise reduction method in heavy duty machines cabins, Proceedings of the Conference on Noise Control Engineering, Warsaw, 459-466.
- 32. SlJCCI G.P. (1987), The interior acoustic field, of an automobile cabin, J. Acoust. Soc. Am., 81, 6, 1688- 1694.
- 33. SUNG-HEE K., SUK-YOON H., JEE-HUN S., WON- Ho J. (2012), Interior noise analysis of a construction equipment cabin based, on airborne and, structural- borne predictions, Journal of Mechanical Science and Technology, 26, 4, 1003-1009.
- 34. SZEMELA K., RDZANEK W.P., RDZANEK W.J. (2013), Acoustic power radiated by a system of two vibrating circular membranes located at the boundary of three- wall corner spatial region, Archives of Acoustics, 37, 463-473.
- 35. TURNER W.B., TURGAY F.M. (1998), Development of coupled structure - acoustic FE models for vehicle refinement, Proceedings of IMechE, C521/026, 229-238.
- 36. XIAOFENG S., MING M., JUNFANG W. (2012), Effect of a low Mach, number flow on a semi active Helmholtz resonator, CD Proceedings of the 19th International Conference on Sound and Vibration ICSV19, Vilinus, 5 pages.
- 37. ZAWIESKA W.M., RDZANEK W.P. (2006), Low frequency approximation of natural modal radiation efficiency of some simply supported, flat plates, Archives of Acoustics, 31, 4, 123-130.
- 38. ZAWIESKA W.M., RDZANEK W.P., RDZANEK W., ENGEL Z. (2007), Low frequency estimation for the sound radiation efficiency of some simply supported, flat plates, ActaAcustica united with Acustica, 93, 3, 353- 363.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-449c3577-227d-41e3-90dc-154b3d849797