Determination of the working energy capacity of the on-board energy storage system of an electric locomotive for quarry railway transport during working with a limitation of consumed power

Authors

DOI:

https://doi.org/10.5604/01.3001.0016.2631

Keywords:

railway transport, electric locomotive, energy storage system, traction drive, induction motor

Abstract

The use of specialized rail rolling stock which is used for transporting ore from the quarry to the crushing plant at mining enterprises is analyzed here. Electric locomotives with an asynchronous traction electric drive and an on-board energy storage system are considered for use. The calculated dependencies of the electric locomotive tractive power were analyzed and it was established that on flat sections of the track profile, the movement is carried out with a power that does not exceed 50% of the nominal one. The movement with the nominal power is carried out on the controlled uphill during the cargo half-passage. To ensure the necessary power for movement in such areas, the use of an on-board energy storage system is proposed, which should feed the traction system while limiting the power consumed from the catenary. This happens when the voltage on the pantograph drops to a minimum level. The aim of this work is to determine the on-board energy storage system parameters during the operation of the electric locomotive with limitation of the power consumed from the traction network. Mathematical models of the energy exchange processes in the electric locomotive traction system have been developed. The criteria for comparing options for calculating the parameters of the on-board energy storage system have been proposed. The criteria take into account the reduction of energy consumption during movement, the efficiency of energy storage, and the complete use of the on-board energy storage system in terms of power and working energy capacity. Based on the calculation results, it was determined that the use of an energy storage device with a power of 3,540 kW and an operating energy capacity of 63.5 kWh provides a 10% reduction in energy consumption, which is being consumed while moving along the sample section of the road. The current that can be consumed by an electric locomotive with such parameters of the on-board energy storage system is limited by 600 A.

References

A European Green Deal (2022) URL: https://ec.europa.eu/info/strategy/priorities-2019-2024/european-green-deal_en (last accessed 2022/12/21).

Postanova KMU vid 03 bereznia 2021 r. № 179 «Pro zatverdzhennia Natsionalnoi ekonomich-noi stratehii na period do 2030 roku» (Resolution of the CMU dated March 3, 2021 No. 179 "On approval of the National Economic Strategy for the period until 2030") URL: https://www.kmu.gov.ua/npas/pro-zatver-dzhennya-nacionalnoyi-eko-a179 (last accessed 2022/12/21) [in Ukrainian].

Lyadenko, T. (2019) Osoblyvosti vyrobnycho-zbutovoi diialnosti vitchyznianykh zalizorud-nykh pidpryiemstv na suchasnomu etapi yikh rozvytku (Peculiarities of production and marketing activities of domestic iron ore enterprises at the current stage of their development). Efficient economy, 4. – URL: http://www.economy.nayka.com.ua/?op=1&z=6985 (last accessed 2022/12/21). DOI: 10.32702/2307-2105-2019.4.34 [in Ukrainian].

Frolov, O., Kosenko, T. (2020) Vidkryti hirnychi roboty: Ch. I. Protsesy vidkrytykh hirnychykh robit [Elektronnyi resurs]: navch. posib. dlia stud. spetsialnosti 184 «Hirnytstvo» (Open pit mining: P. I. Processes of open pit mining [Electronic resource]: training. manual for students specialty 184 "Mining"). KPI named after Igor Sikorsky. – Electronic text data (1 file: 15.735 MB). – Kyiv: KPI named after Igor Sikorskyi, 2020. – 151 p. [in Ukrainian].

Balon, L., Bratash V., Bychuch, M. (1987). Elektropodvyzhnoi sostav promyshlennoho transporta: Spravochnyk. (Electromotive equipment of industrial transport: Reference book.) Ed. L. V. Balona. M.: Transport. 1987. [in russian].

Bratash, V. (2007). Tiahovye ahrehaty typa OPEA s asynkhronnumy tiahovumy dvyhate-liamy dlia otkrytykh hornykh razrabotok. Konstruktsyia y parametry (Traction units of the OPEA type with asynchronous traction engines for open mining. Design and parameters).

Hirn. electromechanics and automation: Scientific and technical coll, 79, 93-98.

Riabov, Ie., Mosin, S., Overianova, L., Konratieva, L., Demydov, O., Goolak, S. (2022a). Otsinka tekhnichnykh parametriv lokomotyva dlia zaliznychnoho kariernoho transportu (Evaluation of technical parameters locomotive for railway career transport). Transport Systems and Technologies, 39, 83-100. DOI:10. 32703/2617-9040-2022-39-9 [in Ukrainian].

Sydorenko, A., Yatsko, S. (2022). Otsinka vplyvu rezhymiv roboty systemy elektrychnoi tiahy na vtraty vid nerivnomirnosti spozhyvannia elektroenerhii ta zakhody shchodo yikh znyzhennia (Assessment of the influence of the operating modes of the electric traction system on losses from unevenness of electricity consumption and measures to reduce them). Transport Systems and Technologies, 39, 115-127. DOI: 10.32703/2617-9040-2022-39-11 [in Ukrainian].

Khozia, P., Sulym, A. (2021). Kontseptsii keruvannia enerhetychnymy protsesamy na elektrorukhomomu skladi z nakopychuvachamy enerhii (Management strategies for energy processes in electric rolling stock with on-board energy storage devices). Transport Systems and Technologies, 38, 63-79. DOI: 10.32703/2617-9040-2021-38-63-6 [in Ukrainian].

Fedele, E., Iannuzzi, D., del Pizzo, A. (2021). Onboard energy storage in rail transport: Review of real applications and techno-economic assessments / IET Electr. Syst. Transp., 11(4), 279– 309. DOI: 10.1049/els2. 12026.

Wang, Y.; Liu, C.; Cai, C.; Ma, Z.; Zhou, M.; Dong H.; Li, F (2022). Bi-Level Planning Model for Urban Energy Steady-State Optimal Configuration Based on Nonlinear Dynamics. Sustainability, 14, 6485-6516.

Zhang, Y.; Diao, L.; Xu, C.; Zhang, J.; Wu, Q.; Pei, H.; Huang, L.; Li, X.; Qi, Y. (2022). An Optimization of New Energy Hybrid Configuration Parameters Based on GA Method. J.Mar. Sci. Eng., 10, 1747-1764. DOI: 10.3390/jmse10111747.

Yang, Y.; Zhang, W.; Wei, S.; Wang, Z. (2020) Optimal Sizing of On-Board Energy Storage Systems and Stationary Charging Infrastructures for a Catenary-Free Tram. Energies, 13, 6227-6247. DOI: 10.3390/en1323 6227.

Graber, G., Galdi, V., Calderaro, V., Piccolo, A. (2016). Sizing and energy management of on-board hybrid energy storage systems in ur-ban rail transit. 2016 International Conference on Electrical Systems for Aircraft, Railway, Ship Propulsion, and Road Vehicles & International Transportation Electrification Conference (ESARS-ITEC), 1-6, DOI: 10.1109/ ESARS-ITEC.2016.7841408.

Herrera Pérez, V.I. (2017). Optimized energy management strategies and sizing of hybrid storage systems for transport applications. Doctoral Thesis, 224 p.

Spiryagin, M., Wu, Q., Wolfs, P., Sun, Y., Cole, C. (2017). Comparison of locomotive energy storage systems for heavy-haul operation. International Journal of Rail Transportation, 6(1), 1-15. DOI: 10.1080/23248378.2017.132 5719.

Poline, M., Pouget, J., Gerbaud, L. (2015). De-sign of Energy Storage Systems by Optimization Applied to Hybrid Electric Locomotive. 2015 IEEE Vehicle Power and Propulsion Conference (VPPC), 1-5. DOI:10.1109/vppc. 2015.7352926.

Kapetanović, M., Vajihi, M., Goverde R.M.P. (2021) Analysis of Hybrid and Plug‐In Hybrid Alternative Propulsion Systems for Regional Diesel‐Electric Multiple Unit Trains. Energies, 14, 5920-5948. DOI: 10.3390/en1 4185920.

Liu, F., Wang, C., Luo, Y. (2021) Parameter Matching Method of a Battery-Supercapacitor Hybrid Energy Storage System for Electric Vehicles. World Electr. Veh. J., 12, 253-263. DOI: 10.3390/wevj12040253.

Wang, Y., Moura, S.J., Advani S.G., Prasad, A.K. (2019). Optimization of power plant component size on board a fuel cell/battery hybrid bus for fuel economy and system durability. International Journal of Hydrogen Energy, 44, 33, 18283-18292, DOI: 10.1016/j.ijhydene. 2019.05.160.

Omelyanenko, V. , Riabov, Ie. , Overianova, L., Omelianenko, H. (2021). Traction electric drive based on fuel cell batteries and on-board inertial energy storage for multi unit train. Electrical engineering and electromechanics, 4, 64-72. DOI: 10.20998/2074-272X. 2021.4.08.

Corlu, C., de la Torre R., Serrano-Hernandez A., Juan A.; Faulin, J. (2020). Optimizing Energy Consumption in Transportation: Literature Review, Insights, and Research Opportunities. Energies, 13, 1115-1147. DOI: 10.3390/ en13051115.

Hryshechkina T. (2021) Improvement of the system of maintenance of technical objects of railway transport taking into account the dependent failures of their elements: diss. ... candidate technical Sciences: 05.22.20. Dnipro, 164 p. [in Ukrainian].

Syvenko, M.., Miroshnyk, O., Sereda, A. (2021). Rozrakhunok optymalnykh parametriv nakopichuvachiv ta vidnovliuvalnykh dzherel enerhii v izolovanykh enerhosystemakh (Calculation of optimum parameters of storage and renewable energy sources in isolated energy systems). Bulletin of the National Technical University "KhPI". Series: Energy: Reliability and Energy Efficiency, (1 (2), 91-95. DOI: 10.20998/2224-0349.2021.01.13). [in Ukrainian].

Riabov, Ie., Liubarskyi, B., Overianova, L., Goolak, S., Kondratieva, L. (2022b) Mathemat-ical Model of the Electric Traction System of Quarry Railway Transport. Proceedings of 26th International Scientific Conference. Transport Means 2022, 330-335.

Kuznetsov, V., Kardas-Cinal, E., Gołębiowski, P., Liubarskyi, B., Gasanov, M. Riabov, I., Kondratieva, L., Opala, M. (2022) Method of Selecting Energy-Efficient Parameters of an Electric Asynchronous Traction Motor for Die-sel Shunting Locomotives-Case Study on the Example of a Locomotive Series ChME3 (ЧMЭ3, ČME3, ČKD S200). Energies, 2022, 15, 317-335. DOI: 10.3390/en15 01031.

Sablin, O., Bosyi, D., Kuznetsov, V., Lewczuk, K., Kebal, I., Myamlin, S., (2022). Efficiency of energy storage control in the electric transport systems. Archives of Transport, 62(2), 105-122. DOI: 10.5604/01.3001.0015. 9569.

Buriakovskyi, S., Maslii, A., Pomazan D. (2019) Searching of The Optimum Configuration of The Traction Electric Transmission of The Shunting Locomotive. 2019 IEEE International Conference on Modern Electrical and Energy Systems (MEES), 22-25, DOI: 10.1109/MEES.2019.8896525.

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Published

2023-03-31

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Original articles

How to Cite

Kondratieva, L., Bogdanovs, A., Overianova, L., Riabov, L., & Goolak, S. (2023). Determination of the working energy capacity of the on-board energy storage system of an electric locomotive for quarry railway transport during working with a limitation of consumed power. Archives of Transport, 65(1), 119-154. https://doi.org/10.5604/01.3001.0016.2631

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