Strength analysis of experimental crane, using proliftor 250 rope winch as an excitation of a girder

• Autorzy: Haniszewski T.

Identyfikatory

DOI

10.20858/tp.2018.13.3.12

• Języki publikacji: EN

Abstrakty

EN

The article presents the research carried out on the experimental construction of a crane, where a hoist with an AC motor without a motor control system was used as an excitation signal for the girder. The purpose of the described research is to determine the relationship between the values of the dynamic surplus factor when lifting the load with the loose rope in the initial phase of lifting and the distance of the hoist from the supporting structure. The data was obtained based on the force tests in a steel wire rope and subsequent determination of the values of stresses and deflections accompanying the selected test cases for different positions of the vibration inductor using the FE method.

Słowa kluczowe

EN

simulation; crane; dynamics; FE analysis

PL

symulacja; dźwig; dynamika; analiza elementów skończonych

• Wydawca: Wydawnictwo Politechniki Śląskiej
• Czasopismo: Transport Problems
• Rocznik: 2018
• Tom: T. 13, z. 3
• Strony: 131--142
• Opis fizyczny: Bibliogr. 17 poz.

Twórcy

autor

Haniszewski T.

• Silesian University of Technology, Faculty of Transport Krasinski 8, 40-019 Katowice, Poland

Bibliografia

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• 3. Kosucki, A & Malenta, P. The possibilities of reducing the operational load of hoisting mechanisms in case of dynamic hoisting. Maintenance and Reliability. Vol. 18(3). June 2016. P. 390-395.
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• 5. Margielewicz, J. & Haniszewski, T. & Gąska, D. & Pypno C. Badania modelowe mechanizmów podnoszenia suwnic. Katowice: Polish Academy of Science. 2013. [In Polish: Model studies of cranes hoisting mechanisms].
• 6. Oguamanam, D.C.D. & Hansen, J.S. & Heppler, G.R. Dynamic response of an overhead crane system. Journal of Sound and Vibration. Vol. 213. No. 5. 1998. P. 889-906.
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• 10. Wu Jia-Jang Transverse and longitudinal vibrations of a frame structure due to a moving trolley and the hoisted object using moving finite element. International Journal of Mechanical Sciences. Vol. 50. No. 4. 2008. P. 613-625.
• 11. Zrnić, N.Đ. &. Gašić, V.M. & Bošnjak, S.M. Dynamic responses of a gantry crane system due to a moving body considered as moving oscillator. Archives of Civil and Mechanical Engineering. Vol. 15. No. 1. 2015. P. 243-250.
• 12. PN-EN 13001-2:2013. Bezpieczeństwo dźwignic. Ogólne zasady projektowania. Część 2: Obciążenia. Warszawa: Polski Komitet Normalizacyjny. [In Polish: Security of cranes. General principles for design. Part 2: Loads. Warsaw: Polish Committee of Standardization].
• 13. REN Hui-li, WANG Xue-lin, HU Yu-jin, and LI Cheng-gang. Dynamic Response Simulation of Lifting Load System of Ship-mounted Cranes. Journal of System Simulation. 2007. Vol. 19. No. 5. P. 2665-2668.
• 14. Chen Huixian & Liu Shuang & Tang Qingtai. Dynamics Simulation and Analysis on Wire Rope of a Mine Hoist Based on SIMULINK. Mining & Processing Equipment. 2008. Vol. 36(9). P. 44-47.
• 15. Gąska, D. & Margielewicz, J. & Haniszewski, T. & Matyja, T. & Konieczny, Ł. & Chróst, P. Numerical identification of the overhead travelling crane's dynamic factor caused by lifting the load off the ground. Journal of Measurements in Engineering. 2015. Vol. 3(1). P. 1-8.
• 16. Gąska, D. & Haniszewski, T. Modelling studies on the use of aluminium alloys in lightweight load-carrying crane structures. Transport Problems. 2006. Vol. 11(3). P. 13-20.
• 17. Oguamanam, D.C.D. & Hansen, J.S. &. Heppler, G.R. Dynamic response of an overhead crane system. Journal of Sound and Vibration. 1998. Vol. 213(5). P. 889-906.

Uwagi

PL

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).