Methodological aspects of transportation system adaptation in open pit mines

Authors: Bakhturin Yu.A.

The role of adaptation as an interdisciplinary phenomenon and the necessity of its evolvement in engineering sciences, including mining, is stated. The notion of “open pit transportation system adaptation” is defined. The research was aimed to justify the choice of a methodology for adapting transportation systems in open pit mines, as well as to demonstrate possibility of the transportation system behavior determination and forecasting. In accordance with the definition, the state of a transportation system in the course of adaptation is described. It is shown that the theory of transportation systems for open pits and the theoretical principles are the mainframe. The theory features flexibility, is continuously developed and upgraded, meets the recent methodological standards and can serve the basis of structural and parametric adaptation. The case-studies of the efficient problem solution in mining using the universal simulation model of transportation system functioning in open pit mines developed at the Institute of Mining, Ural Branch RAS are presented. The scope of the applied research embraced: validation of parameters for loading-and-rehandling points in the dump truck– belt–rail transport flowcharts; determination of carrying capacity of rail tracks in open pits; justification of transportation system parameters for open pit mines based on the interactive modeling. The theoretical methodology framework for transportation system adaptation in open pit mines is presented, which is the joint application of the theory of transportation systems in deep open pit mines in structural and structural-and-parametric adaptation and the universal interactive simulation model of transportation system functioning in open pits in parametric adaptation.

Keywords: methodology, adapting, structural, parametric, theory of transportation systems in open pit mines, universal interactive simulation model, multi-factor experiment, carrying capacity, justification of parameters.
For citation:

Bakhturin Yu.A. Methodological aspects of transportation system adaptation in open pit mines. MIAB. Mining Inf. Anal. Bull. 2020;(3-1):568-582. [In Russ]. DOI: 10.25018/0236— 1493—2020—31-0-568-582.

Acknowledgements:

the studies were performed in the framework of the State task № GR АААА-А19-119020790025-4.

Issue number: 3
Year: 2020
Page number: 568-582
ISBN: 0236-1493
UDK: 622.68: 622.012.32
DOI: 10.25018/0236—1493—2020—31-0-568-582
Article receipt date: 21.11.2019
Date of review receipt: 10.03.2020
Date of the editorial board′s decision on the article′s publishing: 20.03.2020
About authors:

Bakhturin Yu.A., Cand. Sci. (Eng.), Leading Researcher, Laboratory of Transportation Systems and GeoEquipment for Open Pit Mines, The Institute of Mining of the Ural branch of the Russian Academy of Sciences, 620075, Ekaterinburg, Russia.

For contacts:
Bibliography:

1. Rzhevskij V.V. Nauchnye problemy gornogo proizvodstva [Scientific problems of mining production]. Sbornik statej k 80-letiyu akad. V.V. Rzhevskogo. Pod obshch. red. V.V. Istomina. Moscow: Izd-vo MGGU, 2000. 353 p. [In Russ]

2. Reshetnyak S.P. Sozdanie sistem CPT s vnutrikar’ernymi perdvizhnymi drobil’noperegruzochnymi kompleksami [Creation of CPT systems with intra-barrier perdvizhnymi crushing and reloading complexes]: Dis. d-ra tekhn. nauk/ S.P. Reshetnyak; GoI KNC RAN. Apatity, 1997. 422 p. [In Russ]

3. Rastrigin L.A. Adaptaciya slozhnyh sistem [Adaptation of complex systems]. Riga: Zinatne. 1981. 386 p. [In Russ]

4. Yakovlev V.L., Kornilkov S.V., Sokolov I.V. Innovacionnyj bazis strategii kompleksnogo osvoeniya resursov mineral’nogo syr’ya [Innovative basis of the strategy of integrated development of mineral resources]. Ekaterinburg: UrO RAN, 2018. 360 p. [In Russ]

5. Barbashin D.I., Nistyuk A.I. Adaptation of interaction means in complex technical control systems. Tekhnicheskie nauki ot teorii k praktike. 2014. no6—1. pp. 85—89. [In Russ]

6. Sokolov, B.V., Zelentsov, V.A., Brovkina, O., Mochalov, V.F., Potryasaev, S.A. Models adaptation of complex objects structure dynamics control. Advances in Intelligent Systems and Computing. 4-th Computer Science On-line Conference, CSOC 2015; Zlin; Czech Republic; 27 April 2015 through 30 April 2015. Volume 348, 2015, Springer Verlag. P.21—33.

7. Stolyarov V.F. Teoriya razvitiya gornopromyshlennyh sistem [Theory of development of mining systems]. Ekaterinburg: UrO RAN. 2009. 324 p. [In Russ]

8. Georgievskij A.B. Evolyuciya adaptacij (istorikometodologicheskoe issledovanie) [Evolution of adaptations (historical and methodological research)]. Leningrad: Nauka. 1989. 189 p. [In Russ]

9. Anton Pashchenko, Pavel Okhtilev, Semen Potrysaev, YuryIpatov, and Boris Sokolov. Methodology and Structure Adaptation Algorithm for Complex Technical Objects Reconfiguration Models. Cybernetics and Mathematics Application in Intelligent Systems: Proceedings of the 6th Computer Science On-line Conference 2017 (CSOC2017). Vol.2. Series “Advances in Intelligent Systems and Computing, Volume 574. P.319—328.

10. Doenin V.V. Modelirovanie transportnyh processov i sistem [Modeling of transport processes and systems] [Tekst]. V.V. Doenin Moscow: Izdatel’stvo «Sputnik». 2012. 288 p. [In Russ]

11. Doenin V.V. Adaptaciya transportnyh processov [Adaptation of transport processes]. Moscow: Izdatel’stvo «Sputnik», 2009. 219 p. [In Russ]

12. Bashari M., Bagheri E., DU W. Self-adaptation of service composition through product line reconfiguration. Journal of Systems and Software. 2018. Vol. 144. Pp. 84—3105. DOI: 10.1016.j.j.ss.2018.05.069.

13. Salama M., Bahsoon R. Analysing and modelling runtime architectural stability for self-adaptation software. Journal of Systems and Software. 2017. Vol. 144. Pp. 95—3-112. DOI: 10.1016.j.j.ss.2017.07.041.

14. Hussein M., Nouacer R., Radermacher A. Safe adaptation of vehicle software systems. 2017. Vol. 144. Pp. 272—286. DOI: 10.1016.j.micpro. 2017.06.014.

15. Behjati R., Nejati S. Architecture-level configuration of industrial control systems foundations for an efficient approach. Science of Computer Programming. 2018. Vol. 160. Pp. 30—47. DOI:10.1016/j.scico.2017.10.001.

16. Yakovlev V.L. Teoriya i praktika vybora transporta glubokih kar’erov [Theory and practice of choosing transport for deep quarries]. Novosibirsk: Nauka, 1989. 240 p. [In Russ]

17. Svidetel’stvo o gosudarstvennoj registracii programmy dlya EVM. 2012617844 Rossijskaya federaciya. Transportnaya sistema kar’era (TSK). Yu.A. Bahturin, A.G. ZHuravlev, L.A. Trofimenko (RF). 2012615505; zayavl. 03.07.12; opubl. 30.08.12.4.

18. Salahiev R.G., YBahturin U.A., Dedyuhin A.V., ZHuravlev A.G. Simulation modeling and automated management of mining and transport operations in quarries. Gornyj zhurnal. 2012. no 1. pp. 82–85. [In Russ]

19. Kozlov P.A., Kolokol V.S.’nikov, Sorokin V.I. Joint use of analytical methods and simulation models. Transport Urala. 2016. no 3 (50). pp. 3–8. [In Russ]

20. Ramires A., Romero J.R., Ventura S. Interactive multi-objective evolutionary optimization of software architecture. Information Sciences 2018. Vol. 463—464. Pp. 92—109. DOI:10.1016/j.ins.2018.06.034.

21. Dulin S.K., Seleckij A.S., Umanskij V.I. Razrabotka sistemy imitacionnogo modelirovaniya dvizheniya zheleznodorozhnogo transporta na osnove interaktivno zadavaemyh pravil organizacii dvizheniya [Development of a system for simulation of railway transport traffic on the basis of interactively set rules for traffic organization] [Elektronnyj resurs]. Rossijskaya associaciya iskusstvennogo intellekta. Rezhim dostupa: www.raai.org/conference/cai-08/files/cai-08_paper_283.doc. [In Russ]

22. Lel’Yu.I., Aref’ev S.A., Dunaev S.A., Glebov I.A. Development of ideas of the corresponding member of RAS V. L. Yakovlev. On accounting for the impact of mining operating conditions on the performance of quarry vehicles. Problemy nedropol’zovaniya. 2014. vypusk 3. pp. 82–85. [In Russ]

23. Kornilkov S.V., Yakovlev V.L. On the methodological approach to research in the field of subsoil development based on system, complexity, interdisciplinarity and innovation orientation. Gornyj zhurnal. 2015. no 1. pp. 4—5. [In Russ]

24. Yakovlev V.L. Features of the methodological approach to substantiating the strategy of development of complex structural deposits based on the study of transients. Geomechanical and geotechnological problems of the development of the North’s subsurface: MIAB. Mining Inf. Anal. Bull. no 7. 2015. pp. 22—35. [In Russ]

25. Yakovlev V.L., Karmaev G.D., Bersenev V.A., Glebov A.V., Semenkin A.V., Sumina I.G. On the issue of the effectiveness of cyclical-flow technology of mining operations in quarries. Fiziko-tekhnicheskie problemy razrabotki poleznyh iskopaemyh. no 1. 2016. pp. 1—10. [In Russ]

26. ZHuravlev A.G., YBahturin U.A., Bersenev V.A., CHerepanov V.A., Semenkin A.V. Substantiation of methods of adaptation of mining transport systems to changing conditions of development of complex-structured deep-lying deposits. Problemy nedropol’zovaniya. 2019. no 3. pp. 117—129. [In Russ]

27. Bahturin Yu.A. Improving the criteria base for assessing losses from environmental pollution in open-pit mining. MIAB. Mining Inf. Anal. Bull. Otdel’nyj vyp. no 11. 2011. pp. 326—329. [In Russ]

28. Bahturin Yu.A. Upravlenie rezhimami dvizheniya gornoj massy na sklade pri ciklichnopotochnoj tekhnologii Problemy nedropol’zovaniya [Management of modes of movement of rock mass in the warehouse with cyclical flow technology Problems of subsurface use»]. [elektronnyj resurs]: recenziruemoe periodicheskoe nauchnoe izdanie. Igd Uro RAN. 2015. no 4. pp. 44—49. Rezhim dostupa. trud.igduran/ru. [In Russ]

29. ZHuravlev A.G. Trends in the development of transport systems of quarries using robotic machines. Problemy nedropol’zovaniya. 2014. no 3. pp. 164—175. (DOI 10.18454/2313—1586.2014.03.164). [In Russ]

Our partners

Подписка на рассылку

Раз в месяц Вы будете получать информацию о новом номере журнала, новых книгах издательства, а также о конференциях, форумах и других профессиональных мероприятиях.