Revista de la Facultad de Ingeniería

As for the problem of low efficiency and difficulty of the operation of block, a method of modeling and simulation of the operation scheduling process of block stockyard based on Petri net is proposed. Firstly, based on the analysis of the operation scheduling process of block yard, the operation scheduling mode of virtual flow line is presented; Secondly, a virtual flow line model according to the operation scheduling model of block stockyard based on hierarchical-timed Petri net is established and the feasibility of the virtual flow line is proved with the method of invariant; Finally, a block stockyard operation scheduling simulation model based on the digital factory strategy is established and the digital simulation analysis of block yard operation scheduling is carried out. The results show that the mode of virtual flow line operation and the Petri net contribute to improving efficiency of the block stockyard operation scheduling and resources using, the virtual flow line can also avoid the blocking. The effective method and theoretical support are provided in this paper for the block stockyard scheduling.

Babu S.A.K., Pratap S., Lahoti Geet. (2015). Minimizing delay of ships in bulk terminals by simultaneous ship scheduling, stockyard planning and train scheduling, Maritime Economics & Logistics, 17(4): 464-492.

Bish E.K., Leong T.Y., Li C.L., Ng J.W.C., Simchi Levi D. (2001). Analysis of a new vehicle scheduling and location problem, Naval Research Logistics, 48(5):363-385. Doi: 10.1002/nav.1024.

Boland N., Gulczynski D., Savelsbergh M. (2012). A stockyard planning problem, European Journal of Transportation and Logistics, 1(3):197-236.

Bruzzone A., Signorile R. (1998). Simulation and genetic algorithms for ship planning and shipyard layout, Simulation, 71(2): 74-83.

Chen T. (2016). A utility-driven scheduling algorithms in cloud computing, Revista Tecnica de la Facultad de Ingenieria Universidad del Zulia, 39(2): 282-287.

Dong F., Parvin H., Van Oyen M.P., Singer D.J. (2009). Innovative ship block assembly production control using a flexible curved block job shop, Journal of Ship Production, 25(4): 206-213.

Lee S.K. Kim B., Huh M., Cho S., Park S., Lee D. (2013). Mining transportation logs for understanding the after-assembly block manufacturing process in the shipbuilding industry, Expert Systems with Applications, 40(1):83-95.Doi: 10.1016/j.eswa.2012.07.033.

Li C., Zhang Z.Y., Mao Z.J. (2008). Research on Production Scheduling of Curved Block and Modeling based on Virtual Flow Line, Industrial Engineering and Management, 2:39-43.

Lorenzini, G.L., Helbig D., Da Silva C.C., De Vasconcellos Real M., Dos Santos E.D., Isoldi L.A., Rocha L.A.O. (2016). Numerical evaluation of the effect of type and shape of perforations on the buckling of thin steel plates by means of the constructal design method, International Journal of Heat and Technology, 34: S9-S20.Doi: 10.18280/ijht.34S102.

Mei J.P., Cao J.X., Zhang X., Hu L.H. (2014). Design Method of High-Speed Robot Fruit-Milk Packaging Line Based on Petri Net. Journal of Tianjin University (Science and Technology), 47(2):138-142. DOI: 10.11784/tdxbz201206036.

Park C., Seo J. (2009). Genetic Algorithm of the Planar Storage Location Assignment Problem, Journal of the Korean Institute of Industrial Engineers, 35(2):129-140. Doi: 10.1016/j.cie.2009.04.010.

Park C., Seo J. (2009). On the Assembly Block Storage Location Assignment Problem, Industrial Engineers Interfaces, 22(2):116-125. Doi: 10.1080/09537280902803056.

Park C., Seo J., Kim J. Lee S., Baek T.H., Min S.K. (2007). Assembly block storage location assignment at a shipyard: a case of Hyundai Heavy Industries, Production Planning & Control, 18(3):180-189. Doi:10.1080/09537280601009039.

Park C., Seo J.y. (2009). Assembly block storage location assignment problem: revisited, Production Planning & Control, 20(3):216-226. Doi: 10.1080/09537280902803056.

Park C., Seo J.y. (2009). Mathematical modeling and solving procedure of the planar storage location assignment problem, Computers & Industrial Engineering, 57(3):1062-1071. Doi: 10.1016/j.cie.2009.04.010.

Pratap S., Kumar M.B., Saxena D., Tiwari M.K. (2016). Integrated scheduling of rake and stockyard management with ship berthing: a block based evolutionary algorithm, International Journal of Production Research, 54(14):4182-4204.Doi: 10.1080/00207543.2015.1111535.

Suri G., Saif B. (2004). Modeling and analysis of flexible queueing systems. Naval Research Logistics, 51(5): 755-782.Doi: 10.1002/nav.20020.

Zhang Z.Y., Jiang Z.B. (2004). Research on Modeling Based on Petri Net of Virtual Flow-line production System. Journal of Jiangsu University of Science and Technology(Natural Science Edition), 18(4):32-36.

Zhang Z.Y., Shen G., Liu X.R., Hu X.C. (2012). Block storage yard scheduling of shipbuilding based on shortest-path algorithm. Computer Integrated Manufacturing Systems, 18(9):1982-1990.