Optimization of the load scheme of heavy vehicle for a given flow of goods

Oliskevych, M.

Artykuł - szczegóły

Tytuł artykułu

Optimization of the load scheme of heavy vehicle for a given flow of goods

Autorzy

Oliskevych M.

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

Warianty tytułu

Języki publikacji

Abstrakty

This research is devoted to the problem of improving the usage of heavy road trains by increasing their actual loading with cargo. The present paper proves that the extremely forced road train not always fits the permissible loading from its axles and vice versa. This contradiction is reinforced by the fact that flows of general cargoes consist of different transport options packages. They are required to be arranged into a rational scheme of loading vans. There were formulated and showed an example of solving the optimization problem of placing cargo units into five-axle road train. There were used static equations of the mechanical system, which is the tractor plus van plus the general goods. First, the piece goods are considered as reduced to the centre of mass of road train. It was showed the importance to comply with accuracy of the coordinates of the centre of gravity value and its influence on the load of vehicle. The dependence of reducing of permissible loading from the centre of gravity coordinate deviation of the estimated optimal was built. The task of optimization of loading schemes was solved in three stages. In the first stage, there was defined the centre of gravity of cargo. At the second stage, there were taken into account the weight and dimensional parameters of transport packages and made a concentrated mass distribution on the wagon platform. It was found that it is advisable to choose the weight of transport packages for optimal load circuit. Each optimal loading scheme should meet the current transport scheme process of cargo delivery. To this aim, it was formulated and solved the problem of the third stage which variables are the parameters of incoming and outgoing flows such as fronts of vehicles, size of groups of cargo in packets.

Słowa kluczowe

road train loading cargo center of gravity

pociąg drogowy załadunek cargo środek ciężkości

Wydawca

Polish Academy of Sciences, Branch in Lublin

Czasopismo

ECONTECHMOD : An International Quarterly Journal on Economics of Technology and Modelling Processes

Rocznik

2017

Tom

Vol. 6, No 1

Strony

55--62

Opis fizyczny

Bibliogr. 25 poz., rys., tab., wz.

Twórcy

autor

Oliskevych M.

Myroslav@3G.ua

Department of automobile technique operation and repair, Lviv Polytechnic National University, Bandery Str., 32, Lviv, 79020, Ukraine

Bibliografia

1. Farobin Y. E., Ovcharov V. A., and Kravtseva V.A. 1981. Theory of movement of specialized rolling stock. Voronezh: Publishing house of the Voronezh State University, 160. (in Russian).
2. Qu T., Luo H., Cao N., Fang J., Zhong R., Pang A., Qiu X. and Huang G. 2012. RFID-enabled just-in-time logistics management system for 'SHIP' supply Hub in industrial park The 42nd International Conference on Computers and Industrial Engineering (CIE42), Cape Town, South Africa, In CIE42 Proceedings, v. 1. 263126319.
3. Yatskivskyy L. Y., Kunda N. T. and Shejko K. V. 2004. The problems of international cargo shipments small. Proceedings of the National Transport University. Issue 9. 162-165. (in Ukrainian).
4. Enhlezi I. P. 2011. Analysis technical development of vehicles for transportation grouped packaged unit loads in order to increase their use. Bulletin of Donetsk Academy of road transport. №1. 30-34. (in Ukrainian).
5. On measures to preserve public roads. Cabinet of Ministers of Ukraine. Kyiv. 2007. Nr. 879. (in Ukrainian) Available online of http://zakon3.rada.gov.ua/laws/show/879-2007-%D0%BF.
6. Kravchenko A. P. 2004. Methods of problems solution of operation efficiency increase of trains, Technical service of agriculture, engineering and technology in agricultural engineering Bulletin of Kharkiv State Technical University of Agriculture. (HDTUSH). Vol. 23, 274-277. (in Russian).
7. Glinchuk V. M. 2009. The choice and justification of trailer types and parts of a three-tier trains. Manuscript. The thesis for the degree of candidate of technical sciences. National Transport University. Kyiv, 23. (in Ukrainian).
8. Habrielova T. Yu. and Litvinenko S. L. 2011. Methodology and practice of loading units during transportation by air transport. Current economic problems. №6 (120), 60-66. (in Ukrainian).
9. Morabito R. and Morales S. 1998. A simple and effective recursive procedure for the manufacturer's pallet loading problem. Journal of the Operational Research Society. Vol. 49. Issue 8, 819-828.
10. Wei J., Leung S. 2011. A simulation modeling and analysis for RFIDenabled mixed product loading strategy for outbound logistics: A case study. Computers & Industrial Engineering. Vol. 61. Issue 1, 209-215.
11. Hamelyak I. P. and Raykovskyy V. F. 2014. Experimental determination of axle load vehicles. Scientific and industrial magazine. Nr 3 (239), 25-29. (in Ukrainian).
12. Fornalchyk Ye., Mohyla I. and Hilevych V. 2015. The Influence of Dynamic Characteristics of Vehicles on the Passenger Car Equivalent and Traffic Delay ECONTECHMOD. An international quarterly journal. Vol. 04. Nr 2, 45-51.
13. Oliskevych M. 2015. Optimization of information flows of logistic supply chain ECONTECHMOD. An international quarterly journal. Vol. 4. No. 4, 71-76.
14. Axle Load Calculation and Load Planning Software (Truck, Trailer, Container & Railcar). Available online of http://www.loadxpert.com/index.htm
15. Chan T. H. T., Yu L., Law S. S. and Yung T. H. 2001. Мoving force identification studies, I: Theory. Journal of Sound and Vibration. Vol. 247. Issue 1, 59-76.
16. Oliskevych M. S. 2013. Optimization of transport cycles depending on the amount of projected cargo. Bulletin of East Ukrainian National University after Volodymyr Dahl. № 5 (194). Part 1. 140-145. (in Ukrainian).
17. Amiouny V. S., Bartholdi J. J. III, Vande Vate J. H. and Zhang J. 1992. Balanced Loading. Operations Research, Vol. 40. Issue 2, 238246.
18. Eberhard E. 1991. Stability aspects of pallet loading Operations-Research-Spektrum. Vol. 13. Issue 4, 189-197.
19. Truck Loader. Available online of http://www.TLrun.com.
20. Automated cargo loading system. 1991. United States Patent 5.015.145. Available online of https://www.google.com/patents/US5015145.
21. Wilde E. D-De. 2004. Truck cargo management RFID tags and interrogators. United States Patent Application Publication Pub. Nr.: US 2004/0069850 A1. Available online of https://www.google.com/patents/US20040069850.
22. Marchuk R. N. 2011. Definition of load on the axle-train container. Herald NTU. Proceedings of the NTU, Vol. 24 (1). №29, 115-118. (in Ukrainian).
23. Vilkovskyy J. K., Oliskevych M. S. and Dorosh V. N. 2006. Method of determining the required number of vehicles on the pendulum routes. Bulletin NTU. Nr 13. Part 2, 68-72. (in Ukrainian).
24. Zhivitskaya H. 2014. Topological properties and methodology of research of complex logistic systems efficiency ECONTECHMOD. An International Quarterly Journal On Economics In Technology, New Technologies And Modeling Processes. Vol. 3. No. 3, 23-33.
25. Yuskiv V. M. 2015. The car-service company internal potential analysis in terms of logistical concept. The bulletin of transport and industry economics. Nr 52. 84-94. (in Ukrainian).

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-15c53e82-35c1-45be-a1d8-20e36aa0567a