Abstract
This paper presents a model in which “fuzzy logic multi-criteria decision-making method” is suggested to determine real-time forklift speed to reduce occupational accidents caused by operators. The model developed in the study uses the variables: the weight and height of the load carried by the forklift, the number of products on its pallet, the places with high risk of accident, and the wet-dry condition of the ground. In order to evaluate the performance of the suggested model, a data set comprises 128 different conditions in cast cobblestone production. Determined forklift speeds were compared with the forklift speeds determined by fuzzy logic using statistically analyses. Results showed that fuzzy logic model has a high accuracy and low error. Fuzzy logic modeling has proved to be a good way to decide the real-time speed of the forklifts being used in production without compromising occupational safety. Friedman test and Wilcoxon test have been used to estimate the significance of fuzzy logic method. The fuzzy logic results showed that our method achieved better results compared to beginner operator.
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References
Derrac J, García S, Molina D, Herrera F (2011) A practical tutorial on the use of nonparametric statistical tests as a methodology for comparing evolutionary and swarm intelligence algorithms. Swarm Evol Comput 1(1):3–18
Dinler G (2000) Forklift maintenance and operation manual. IOP Publishing İstanbul Medical Chamber. https://www.iyh.istabip.org.tr/sirer/im/1.pdf. Accessed 13 Feb 2017
Ersoy M (2015) A proposal on occupational accident risk analysis: a case study of a marble factory. J Hum Ecol Risk Assess Int J 21(8):2099–2125
Fan GF, Peng LL, Hong WC (2018) Short term load forecasting based on phase space reconstruction algorithm and bi-square kernel regression model. Appl Energy 224:13–33
Galal AA, Tayfour A (2012) Characteristics and prediction of traffic accident casualties in sudan using statistical modeling. Int J Transp Sci Technol 1(4):305–317
García S, Fernández A, Luengo J, Herrera F (2010) Advanced nonparametric tests for multiple comparisons in the design of experiments in computational intelligence and data mining: experimental analysis of power. Inform Sci 180(10):2044–2064
Gnoni MG, Lettera G, Bragatto PA (2012) A multi-criteria decision model for controlling knock-on risk inside chemical plants. Chem Eng Commun 199(6):798–811
Hall L (1996) Forklift fatalities. Safety Meeting Outline, SMO 96-0601. https://www.diva-portal.org/smash/record.jsf?pid=diva2%3A433488&dswid=-2103. Accessed 11 Aug 2011
Holčapek M, Turčan M (2003) A structure of fuzzy systems for support of decision making. Soft Comput 7:234–243
Hong WC, Li MW, Geng J, Zhang Y (2019) Novel chaotic bat algorithm for forecasting complex motion of floating platforms. Appl Math Model 72:425–443
Horberry T, Larsson TJ, Johnston I, Lambert J (2004) Forklift safety, traffic engineering and intelligent transport systems: a case study. Appl Ergon 35:575–581
Horberry T, Gunatilaka A, Regan M (2006) Intelligent transport systems for industrial mobile safety. J Occup Health Saf 22(4):323–334
Imriyas K, Pheng LS, Lin TA (2011) A decision support system for predicting accident risks in building projects. Archit Sci Rev 50(2):149–162
Jana DK, Pramanik S, Sahoo P, Mukherjee A (2019) Interval type-2 fuzzy logic and its application to occupational safety risk performance in industries. Soft Comput 23:557–567
Kaya G, Erkaymaz O, Sarac Z (2018) A new adaptive neuro-fuzzy solution for optimization of the parameters in the digital holography setup. Methodol Appl 2(1):1–11
Koçar O, Dizdar EN, Çetiner E (2016) Trend analysis of forklift truck accidents. 8. In: International conference on safety and health, 8–11 May, İstanbul, Turkey
Kumar P, Bauer P (2009) Progressive design methodology for complex engineering systems based on multiobjective genetic algorithms and linguistic decision making. Soft Comput 13:649–679
Larsso TJ, Rechnıtzerb G (1994) Forklift trucks—analysis of severe and fatal occupational injuries, critical incidents and priorities for preventions. Saf Sci 17:275–289
Lekka C, Okunribido O (2010) A review of workplace transport safety and HSE commissioned work on manual handling and delivery of goods. Health and Safety Laboratory, Health and Safety Executive (HSE), Workplace Transport Programme
Li DC, Liu CW, Hu SC (2011) A fuzzy-based data transformation for feature extraction to increase classification performance with small medical data sets. Artif Intell Med 52:45–52
Lifschultz BD, Donoghue ER (1994) Deaths due to forklift truck accidents. Forensic Sci Int 65:121–134
Lovested G (1997) Top ten forklift accidents. Nat Saf News 116:123–127
Lu J, Zhang G, Ruan D (2008) Intelligent multi-criteria fuzzy group decision-making for situation assessments. Soft Comput 12:289–299
Ma H, Li X, Liu Y (2019) Multi-period multi-scenario optimal design for closed-loop supply chain network of hazardous products with consideration of facility expansion. Soft Comput 24:2769–2780. https://doi.org/10.1007/s00500-019-04435-z
Milanowicz M, Budziszewski P, Kedzior K (2018) Numerical analysis of passive safety systems in forklift trucks. Saf Sci 10:98–107
Miller BC (1998) Forklift safety by desing. Prof Saf 33:18–21
Mueller SJ, Haupt RO, Haupt DG, Kempfert LA (1997) Travel speed limiting system for forklift trucks. Patent-US005652486A, USA
MUARC OHS Group (2011) Forklift literature review. IOP Publishing Dijitala Vetensapliga Arkivet. https://www.diva-portal.org/smash/get/diva2:433488/FULLTEXT01.pdf. Accessed 08 Aug 2011
Naieni JSGhR, Makui A, Ghousi R (2012) An approach for accident forecasting using fuzzy logic rules: a case mining of lift truck accident forecasting in one of the Iranian car manufacturers. Int J Ind Eng Prod Res 23(1):53–64
Naim S, Hagras H (2013) A type 2-hesitation fuzzy logic based multi-criteria group decision making system for intelligent shared environments. Soft Comput 18:1305–1319
Perttula P, Salminen S (2015) Workplace accidents in materials transfer in Finland. Int J Occup Saf Ergon 18(4):541–548
Raj A, Gautam G, Abdullah SNHS, Zaini AS, Mukhopadhyay S (2019) Multi-level thresholding based on differential evolution and Tsallis Fuzzy entropy. Image Vis Comput 91:1–14
Rebelle J, Mistrot P, Poirot P (2009) Development and validation of a numerical model for predicting forklift truck tip-over. J Veh Syst Dyn Int J Veh Mech Mobil 47(7):771–804
Rhodes C, Myrtle RA (1999) Speed controller. Patent-WO2001042868A1, USA
Saric S, Hadiashar AB (2013) Analysis of forklift accident trends within Victorian industry (Australia). Saf Sci 60:176–184
Takagi T, Sujgeno M (1985) Fuzzy identification of systems and its applications to modeling and control. IEEE Trans Syst 15:116–132
Wirgand NS (2002) Characteristics of work-related injuries involving forklift trucks. J Saf Res 18:179–190
Woldt W, Dvorak B, Dahab M (2003) Application of fuzzy set theory to industrial pollution prevention: production system modeling and life cycle assessment. Soft Comput 7:419–433
Yuen KK, Choi SH, Yang B (2010) A Full-immersive CAVE-based VR Simulation System of Forklift Truck Operations for Safety Training. J Comput Aided Des Appl 7(2):235–245
Zadeh LA (1975) Calculus of fuzzy restrictions. In: Zadeh LA, Fu KS, Tanaka K, Shimura M (eds) Fuzzy sets and their applications to cognitive and decision processes. Academic Press, New York, pp 1–39
Zhang ZC, Hong WC (2019) Electric load forecasting by complete ensemble empirical model decomposition adaptive noise and support vector regression with quantum-based dragonfly algorithm. Nonlinear Dyn 98:1107–1136. https://doi.org/10.1007/s11071-019-05252-7
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Dizdar, E.N., Koçar, O. Fuzzy logic-based decision-making system design for safe forklift truck speed: cast cobblestone production application. Soft Comput 24, 14907–14920 (2020). https://doi.org/10.1007/s00500-020-04843-6
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DOI: https://doi.org/10.1007/s00500-020-04843-6