Objective and subjective evaluation of the physical risk factors near a conveyor system

Piňosová, Miriama; Andrejiová, Miriam; Liptai, Pavol; Lumnitzer, Ervín

doi:10.12913/22998624/94964

Artykuł - szczegóły

Tytuł artykułu

Objective and subjective evaluation of the physical risk factors near a conveyor system

Autorzy

Piňosová Miriama , Andrejiová Miriam , Liptai Pavol , Lumnitzer Ervín

Treść / Zawartość

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Identyfikatory

DOI

10.12913/22998624/94964

Warianty tytułu

Języki publikacji

Abstrakty

Currently, emphasis is still placed on risk evaluations of physical factors in workplaces. The aim of this paper was to evaluate objectively and subjectively the noise parameters and microclimate conditions near conveyor systems at the workplace for the handling and sorting postal items. Objective noise measurements were performed using the Norsonic 140 sound analyser, Class 1 and microclimatic conditions using the Testo 435 instrument. The subjective evaluation was performed by the questionnaire method (120; F: 66; M: 54). The result of the research was the assessment of health risks, depending on the sources of noise caused by conveyor systems.

Słowa kluczowe

noise risk evaluation workplaces conveyor system

hałas ocena ryzyka miejsca pracy przenośniki taśmowe

Wydawca

Lublin University of Technology
Polish Society of Ecological Engineering (PTIE), Branch of PTIE in Lublin

Czasopismo

Advances in Science and Technology. Research Journal

Rocznik

2018

Tom

Vol. 12, no 3

Strony

188--196

Opis fizyczny

Bibliogr. 26 poz., fig., tab.

Twórcy

autor

Piňosová Miriama

miriama.pinosova@tuke.sk

Technical University of Kosice, Department of Process and Environmental Engineering, Letna 9, 042 00 Kosice, Slovak Republic

autor

Andrejiová Miriam

miriam.andrejiova@tuke.sk

Technical University of Kosice, Department of Applied Mathematics and Informatics, Letna 9, 042 00 Kosice, Slovak Republic

autor

Liptai Pavol

pavol.liptai@tuke.sk

Technical University of Kosice, Department of Process and Environmental Engineering, Letna 9, 042 00 Kosice, Slovak Republic

autor

Lumnitzer Ervín

Ervin.lumnitzer@tuke.sk

Technical University of Kosice, Department of Process and Environmental Engineering, Letna 9, 042 00 Kosice, Slovak Republic

Bibliografia

1. Honus S., Bocko P., Bouda T., Ristovic I., Vulic, M. The effect of the number of conveyor belt carrying idlers on the failure of an impact place: A failure analysis. Eng. Failure. Analys., July (77), 2017, 93–101.
2. Molnár V., Fedorko G., Stehlíková B., Tomašková M., Hulínová Z. Analysis of asymmetrical effect of tension forces in conveyor belt on the idler roll contact forces in the idler housing. Meas J Int Meas Confed., 52(1), 2014, 22–32.
3. Jachowicz T., Sikora J., Dulebova L.: Investigating effects of prodegradant content on selected properties of polymer composite materials. Environ Eng Manag J, 12(6), 2017, 2879-2886.
4. Mikusova N., Millo S. Modelling conveyor belt passage with a driving drum using finite element methods. Adv Sci Technol Res J., 11(4), 2017, 239–246.
5. Debski H., Teter A., Kubiak T., Samborski S. Local buckling, post-buckling and collapse of thin-walled channel section composite columns subjected to quasi-static compression. Compos Struct., 136, 2016, 593–601.
6. Ševčíková Ľ. Hygiene – Environmental Medicine. Comenius University Publisher, editor. Bratislava, 2011, 330 p.
7. Dianat I., Vahedi A., Dehnavi S. Association between objective and subjective assessments of environmental ergonomic factors in manufacturing plants. Int J Ind Ergon., 54, 2016, 26–31.
8. Gavhed D., Toomingas A. Observed physical working conditions in a sample of call centres in Sweden and their relations to directives, recommendations and operators’ comfort and symptoms. Int J Ind Ergon., 37, 2007, 790–800.
9. Seňová A., Slaninová P., Weiss E. Evaluation of risk by point method for selected carrer in mining industry. Acta Montan Slovaca., 13(2), 2008, 278–84.
10. Hnilica R. Synergy effect of risk factors in working environment and methods their assessment. Acta Fac Tech., 17(2), 2012, 25–34.
11. Hrušková M., Buchancová J., Strýčková M., Zibolenová J., Zelník Š., Hudečková H. Sledovanie a hodnotenie zdravotného stavu zamestnancov vo vybraných prevádzkach automobilového priemyslu. Prac Lek., 67(3–4), 2015, 86–91.
12. Hnilica R., Jankovský M., Dado M., Messingerová V., Schwarz M., Veverková D. Use of the analytic hierarchy process for complex assessment of the work environment. Qual Quant., 51(1), 2017, 93–101.
13. Kapustová M. Aplikácia matematických metód pri ekologizácii pracovného prostredia v strojárskych prevádzkach. Mater Sci Technol., (2), 2004, 1–5.
14. Tolvanen K. Exposure to bioaerosols and noise at a Finnish dry waste treatment plant. Waste Manag Res., 22(5), 2004, 346–57.
15. Lumnitzer E., Piňosová M., Andrejiová M., Hricová B. Methodology of complex health risk assessment in industry 2. 1. Zręcin: MUSKA sp. z o.o., 2013, 326 p.
16. Ivaniga P., Ivaniga T. Comparison of DPSK and RZ-DPSK modulations in optical channel with speed of 10 Gbps. J Inf Organ Sci., 41(2), 2017, 185–96.
17. Slamková E., Dulina Ľ., Tabaková M. Ergonómia v priemysle. 1. GEORG, 2010, 262 p.
18. STN EN ISO 7933:2004 Ergonomics of the thermal environment - Analytical determination and interpretation of heat stress using calculation of the predicted heat strain.
19. Vyhláška Ministerstva zdravotníctva Slovenskej republiky č. 99/2016 Z. z. o podrobnostiach o ochrane zdravia pred záťažou teplom a chladom pri práci.
20. Nariadenie vlády Slovenskej republiky č. 115/2006 Z. z. o minimálnych zdravotných a bezpečnostných požiadavkách na ochranu zamestnancov pred rizikami súvisiacimi s expozíciou hluku.
21. STN EN ISO 9612:2010 Acoustics. Determination of occupational noise exposure. Engineering method.
22. Smernica Európskeho parlamentu a Rady 2003/10/ ES o minimálnych zdravotných a bezpečnostných požiadavkách, pokiaľ ide o vystavenie pracovníkov rizikám vyplývajúcim z fyzikálnych faktorov (hluk).
23. Mika D., Józwik J. Normative measurements of noise at CNC machines work station. Adv Sci Technol Res J., 10(30), 2016, 138–43.
24. Moravec M., Liptai P., Dzuro T., Badida M. Design and Effectiveness Verification of Sound Reduction Measures in Production Hall. Adv Sci Technol Res J.,11(4), 2017, 220–224.
25. Lilic N., Cvjetic A., Milisavljevic V., Pantelic U., Kolonja L. Environmental Noise Management in the Area of Opencast Mines. Tehnika, 17(1), 2017, 47–52.
26. ISO 11204:2010 Acoustics - Noise emitted by machinery and equipment - Determination of emission sound pressure levels at a work station and at other specified positions applying accurate environmental corrections.

Uwagi

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

Typ dokumentu

Bibliografia

Identyfikator YADDA

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