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Simulation-expertise analysis of ropes used in the horizontal belaying system

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This article deals with a dynamic simulation of the movement and fall of persons working at a height, using the rope belaying system. The input data, which are necessary for a created simulation model, were obtained from experimental measurements realised from the concrete belaying system. The simulation analyses were performed for three different values of the rope pre-load level. Consequently, the outputs from the simulations presented in this article were applied in a real design proposal of the rope anchoring arrangement for a horizontal belaying system.
Rocznik
Tom
Strony
53--67
Opis fizyczny
Bibliogr. 24 poz.
Twórcy
autor
  • Faculty of Mechanical Engineering, Technical University of Košice, Letná 9 Street, 042 00 Košice, Slovak
  • Faculty of Mechanical Engineering, Technical University of Košice, Letná 9 Street, 042 00 Košice, Slovak
  • Faculty of Mechanical Engineering, Technical University of Košice, Letná 9 Street, 042 00 Košice, Slovak
  • Faculty of Mechanical Engineering, Technical University of Košice, Letná 9 Street, 042 00 Košice, Slovak
  • Faculty of Mechanical Engineering, Institute of Transport, Technical University of Ostrava, 17. Listopadu 15/2172 Street, 708 33 Ostrava - Poruba, Czech Republic
Bibliografia
  • 1. Boroška Ján, Jozef Hulín, Oldřich Lesňák. 1982. Oceľové laná. [In Slovak: Steel ropes]. Bratislava: Alfa. Publishing of technical and economic literature.
  • 2. Boroška Ján. 2000. „Činitele ovplyvňujúce životnosť a bezpečnosť prevádzky oceľových lán”. Výskum, výroba a použitie oceľových lán. [In Slovak: “Factors affecting the service life and safety of the operation of steel ropes”. In Research, manufacture and use of wire ropes]. Faculty of Mining, Technical University, Košice, Slovakia. ISBN: 80-7099-592-0.
  • 3. Torkar M., B. Arzenek. 2002. „Failure of crane wire rope”. Engineering Failure Analysis 9(2): 227-233. ISSN 1350-6307.
  • 4. Costello George A. 2003. „Mechanics of wire rope”. In Wire & Cable Technical Symposium. 73rd annual convention: 56-63. Wire Association International, Inc. May 2003. Atlanta, Georgia, USA.
  • 5. Costello George A. Theory of wire rope. New York. Springer. ISBN 0-357-98202-7.
  • 6. Chaplin Christopher Richard. 1995. „Failure mechanisms in wire ropes”. Engineering Failure Analysis 2(1): 45-57. ISSN 1350-6307.
  • 7. Starikov Maxim, Andrey Beljatynskij, Olegas Prentkovskis, Irina Klimenko. 2011. “The use of magnetic coercivity method to diagnose crane metalware”. Transport 26(3): 255-262.
  • 8. Velinsky S.A. 1985. „General nonlinear theory for complex wire rope“. International Journal of Mechanical Sciences 27(718): 497-507. ISSN0020-7403.
  • 9. Giglio Marco, Andrea Manes. 2005. „Life prediction of a wire rope subjected to axial and bending loads”. Engineering Failure Analysis 12(4): 549-568. ISSN 1350-6307.
  • 10. Imrak C. Erdem, Erdönmez Cengiz. 2010. „On the problem of wire rope model generation with axial loading”. Mathematical and Computational Applications 15(2): 259-268. DOI: https://doi.org/10.3390/mca15020259.
  • 11. Stanova Eva, Gabriel Fedorko, Michal Fabian, Stanislav Kmet. 2011. „Computer modelling of wire strands and ropes Part I: Theory and computer implementation”. Advances in Engineering Software 42(6): 305-315. ISSN 0965-9978. DOI: https://doi.org/10.1016/j.advengsoft.2011.02.008.
  • 12. Stolle Cody S., John Douglas Reid. 2011. „Development of a wire rope model for cable guardrail simulation”. International Journal of Crashworthiness 16(3): 331-341. ISSN 1358-8265. DOI: 10.1080/13588265.2011.586609.
  • 13. Velinsky, S.A., G.L. Anderson, George A. Costello. 1984. „Wire rope with complex cross sections“. Journal of Engineerig Mechanics 110(3): 380-391. ISSN 0733-9399.
  • 14. Imanishi Etsujiro, Takao Nanjo, Takahiro Kobayashi. 2009. „ Dynamic simulation of wire rope with contact”. Journal of Mechanical Science and Technology 23(4): 1083-1088. ISSN 1976-3824.
  • 15. Paris A.J., C.C. Lin, George A. Costello. 1992. „Simple cord composites“. Journal of Engineerig Mechanics 118(9): 1939-1948. ISSN 0733-9399.
  • 16. Rudawska Anna, Hubert Debski. 2011. „Experimental and numerical analysis of adhesively bonded aluminium alloy sheets joints”. Eksploatacja i Niezawodnosc – Maintenance and Reliability 1(49): 4-10. ISSN 1507-2711.
  • 17. Gajdoš Ivan, Ján Slota, Emil Spišák, Tomasz Jachowicz, Aneta Tor-Swiatek. 2016. „Structure and tensile properties evaluation of samples produced by Fused Deposition Modeling”. Open Engineering 6(1): 86-89. ISSN 2391-5439. DOI: https://doi.org/10.1515/eng-2016-0011.
  • 18. Czech Piotr. 2011. „Diagnosing of disturbances in the ignition system by vibroacoustic signals and radial basis function - preliminary research”. Communications in Computer and Information Science 239: 110-117. 11th International Conference on Transport Systems Telematics (TST 2011). Katowice-Ustron, Poland, October 19-22, 2011. Modern Transport Telematics.
  • 19. Czech Piotr. 2012. „Determination of the course of pressure in an internal combustion engine cylinder with the use of vibration effects and radial basis function - preliminary research”. Communications in Computer and Information Science 329: 175-182. 12th International Conference on Transport Systems Telematics (TST 2012). Katowice-Ustron, Poland, October 10-13, 2012. Telematics In The Transport Environment.
  • 20. Figlus Tomasz, Marcin Stanczyk. 2016. “A method for detecting damage to rolling bearings in toothed gears of processing lines”. Metalurgija 55(1): 75-78. ISSN: 0543-5846.
  • 21. Manual to the software product COSMOS/M.S.R.A.C. Los Angeles. 2001.
  • 22. Product catalogue of steel wire ropes. Wire and rope production factory DRÔTOVŇA a.s., Hlohovec, Slovakia. 2001.
  • 23. STN EN 795: 1996. Osobné ochranné prostriedky proti pádu z výšky. Kotviace zariadenia. Bratislava. Úrad pre normalizáciu, metrológiu a skúšobníctvo Slovenskej republiky. [In Slovak: STN EN 795: 1996. Personal fall protection equipment. Anchor devices. Bratislava. Slovak Office of Standards, Metrology and Testing].
  • 24. STN EN 364+AC(832622): 1997. Osobné ochranné prostriedky proti pádu z výšky. Kotviace zariadenia. Bratislava. Úrad pre normalizáciu, metrológiu a skúšobníctvo Slovenskej republiky. [In Slovak: STN EN 364+AC(832622): 1997. Personal fall protection equipment. Testing methods. Bratislava. Slovak Office of Standards, Metrology and Testing].
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Bibliografia
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