بهینه ‏سازی پارامترهای سیستم تعلیق منفعل کابین تراکتور با کمک الگوریتم ازدحام ذرات

نوع مقاله : مقاله پژوهشی

نویسنده

استادیار دانشکدۀ کشاورزی دانشگاه کشاورزی و منابع طبیعی رامین خوزستان

چکیده

این مقالۀ پژوهشی به‌منظور تعیین ضریب فنریّت و میرایی سیستم تعلیق کابین تراکتور ITM285 با هدف افزایش راحتی کاربر تراکتور انجام شد. تجزیه و تحلیل‏ها باتوجه به میانگین مربع پاسخ شتاب در باند یک‌سوم اکتاو و سازمان بین‌المللی استاندارد (ISO) انجام پذیرفت. بهینه‏سازی پارامترهای سیستم تعلیق با روش بهینه‏سازی ازدحام ذرات (PSO) روی مدل 2 درجۀ آزادی سیستم تعلیق کابین تراکتور در نرم‌افزار MatLab در محدودۀ فرکانسی از 1 تا 10 هرتز مدل انجام پذیرفت. مقادیر به‌دست‌آمده برای C1 و C2، K1، و K2 به‌ترتیب (Ns/m) 943، (Ns/m)850، (N/m) 3927، و (N/m) 26199 هستند. پارامترهای بهینه‏سازی‌شده برای سیستم تعلیق کابین تراکتور باتوجه به ISO 2631-1985 نشان از کاهش 7/16، 1/10، 5/11، و 2/12 برای زمان صعود، زمان نشت، و بیشینۀ جهش در مقایسه با مقادیر قبلی سامانۀ تعلیق دارند. درنتیجه باعث کاهش میزان ارتعاش به بدن راننده و همچنین بهبود وضعیت او می‌شود.

کلیدواژه‌ها

موضوعات


عنوان مقاله [English]

Optimization of passive tractor cabin suspension parameters using particle swarm optimization algorithm

نویسنده [English]

  • Saman Abdanan Mehdizadeh
Assistant professor, College of Agricultural Engineering, Ramin Khuzestan University of Agriculture and Natural Resources, Mollasani, Ahvaz, Khuzestan, Iran
چکیده [English]

In this paper a survey to determine the spring and damper settings of ITM285 tractor’s cabin which ensured optimal ride comfort of tractor operator was conducted. Analysis has been done in terms of root mean square acceleration response (RMSAR) in one-third-octave band and International Standard Organization (ISO). Optimization was performed using particle swarm optimization (PSO) method on a 2 DOF modeled in MatLab software for frequencies ranging from 1 to 10 Hz. Obtained results for C1, C2, K1 and K2 were 943 (Ns/m), 850 (Ns/m), 3927 (N/m)  and 26199 (N/m), respectively. Modeling tractor cabin using optimized parameters according to ISO 2631-1985, showed 16.7, 10.1, 11.5 and 12.2 % reduction in rise time, peak time, settling time and max. overshoot of tractor cabin displacement. Therefore, transmitted vibration was reduced and also improve the ride comfort of the tractor operator.  

کلیدواژه‌ها [English]

  • Tractor cabin
  • Transmitted vibration
  • Particle Swarm Optimization (PSO)
Adachi, H., Koizumi, T., Tsujiuchi, N., Kubomoto, I., & Ishida, E. (1996). Reduction of vibration and noise of tractor cabin using active mass damper. JSAE Review, 17(1), 91–98.
Anita, S., Arnautu, V., & Capasso, V. (2010). An Introduction to Optimal Control Problems in Life Sciences and Economics. New York: Springer Science and Business Media publisher.
Anonymous (2002). Agricultural wheeled tractors and field machinery – measurement of whole-body vibration of the operator. ISO 5008-2002. Geneva (Switzerland): International Organization for Standardization.
Anonymous. (1990). International Standard Organization, ISO 2631-1985 (E). Mechanical vibration and shock, 481–95.
Cao, J., Li, P., & Liu, H. (2010). An interval fuzzy controller for vehicle active suspension systems. IEEE Trans. Intelligent Transport System, 11(4), 885–895.
Chaffin, D. B., & Andersson, B. G. (1990). Occupational Biomechanics (2nd Edn.). John Wiley & Sons, Inc., New York.

Esmailzadeh, E., & Taghirad, H. D. (1996). Active vehicle suspensions with optimal state feedback control. International Journal of Mechanical Sciences, 1-18.

Etman, L. F. P., Van Campen, D. H., & Schoofs, A. J. G. (1996). Optimization of multibody systems using approximation concepts. In IUTAM Symposium on Optimization of Mechanical Systems, 81-88.
Haupt, R. L., & Haupt, S. E. (2004). Practical Genetic Algorithms, Second Edition, John Wiley & Sons, Inc., Hoboken, NJ, USA.
Khaksar, Z., Ahmadi, H., & Mohtasebi, S. S. (2013).  Whole Body Vibration Analysis of Tractor Operators Using Power Spectral Density. Journal of Mechanical Engineering and Technology, 1(1), 6-12.
Koen, D., Dimitrios, M., Jan, A., Josse, De. B., Herman, R. (2005) Improvement of vibrational comfort on agricultural vehicles by passive and semi-active cabin suspensions. Comput Electron Agric, 49, 431–40.
Kumar, A., Mahajan, P., Mohan, D., & Varghese, M. (2001). Tractor vibration severity and driver health: a study from rural India. Journal of Agricultural  Engineering Research, 80(4), 313–28.
Maleki, A., S.S. Mohtasebi, A. Akram & V. Esfahanian (2008). Investigation and Analysis of Driver Weight on His Health and Comfort in Three Commonly Used Tractors in Iran Agricultural Engineering International: the CIGR Ejournal. Manuscript MES 07 007. Vol. X.
Marzbanrad, J., Mohammadi, M., & Mostaani, S. (2013). Optimization of a passive vehicle suspension system for ride comfort enhancement with different speeds based on design of experiment method (DOE) method. Journal of Mechanical Engineering Research, 5(3), 50-59.
Marsili, A., Ragni, L., Santoro, G., Servadio, P., & Vassalini, G. (2002). Innovative systems to reduce vibrations on agricultural tractors: comparative analysis of acceleration transmitted through the driving seat. Biosystem Engineering, 81(1), 35–47.
Patil, K. M., Palanichamy, M. S., & Ghista, D. N. (1977). Dynamic response of human body seated on a tractor and effectiveness of suspension systems. Proceedings 21st Strapp Car Crash Conference SAE, Warrandala, PA, USA, 753-792.
Poli, R.,  Kennedy, J., & Blackwell, T. (2007). Particle swarm optimization-an overview. Swarm intelligence, 1, 33-57.
Scarlett, A. J., Price, J. S., & Stayner, R. M. (2007). Whole-body vibration: evaluation of emission and exposure levels arising from agricultural tractors. Journal of Terramech, 44, 65–73.
Steinwolf, A. (2006). Random vibration testing Beyond PSD Limitations. Journal of Sound and Vibration, (Dynamic Testing Reference Issue),12–21.
Tamboli, J. A., & Joshi, S. G. (1999). Optimum design of a passive suspension system of a vehicle subjected to actual random road excitations. Journal of Sound Vibration, 219(2), 193–205.
Vessonen, I., & Jarviluoma, M. (2001). Simulation based design of mobile machine vibration control and active cabin suspension prototype. Timo Holopainen and VTT Manufacturing Technology.
Zehsaz, M., Sadeghi, M.H.,  Ettefagh, M. M., & Shams, F. (2011). Tractor cabin’s passive suspension parameters optimization via experimental and numerical methods. Journal of Terramechanics, 48, 439–450.