Building a technological model of the exhaust gas energy recovery device for the diesel engine on a small­sized vessel

Authors

  • Olexandr Shtanko The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022, Ukraine https://orcid.org/0000-0003-3572-7915
  • Maryna Litvinova The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022, Ukraine https://orcid.org/0000-0002-4917-2132
  • Artem Andrieiev The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022, Ukraine https://orcid.org/0000-0002-6043-3700
  • Mariia Andrieieva The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022, Ukraine https://orcid.org/0000-0002-9116-4056
  • Petro Savchuk The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022, Ukraine https://orcid.org/0000-0003-3893-0644

DOI:

https://doi.org/10.15587/1729-4061.2020.194938

Keywords:

energy recuperation, diesel engine, small-sized vessels, thermoelectrical generator, exhaust gases

Abstract

Recuperation systems that utilize the energy of exhaust gases from existing diesel engines are designed for large and medium-sized vessels. There is a need to develop an appropriate system to recover the energy of exhaust gases for small-sized vessels.

We have designed a technological model of the recuperation device for small vessels in the form of a thermoelectric generator (TEG) that operates on the exhaust gas energy. Technical conditions for the TEG arrangement on a vessel have been analyzed and the components of its design have been defined. We have proposed technical solutions for improving the process of energy heat transfer from gas to a TEG, namely: the use of thermoelectric modules (TEM) with an operating temperature above 1,000 °С; the application of a square shape of the pipeline cross-section, and the arrangement of a spiral-type cylinder inside the generator pipeline.

Based on the theoretical calculations, we have examined a thermal model of the thermoelectric generator and estimated the technological parameters for using TEM in order to ensure maximum value of efficiency for a TEG. The need to divide the generator into three constituent sections has been identified, which operate as separate generators. We have shown a possibility to receive up to 0.8 kW of electric energy when using a TEG provided the rotation speed of the diesel engine shaft is 1,500 rpm.

An optimal technique for utilizing the generator electric energy has been proposed, which implies the application of a motor-wheel. A motor-wheel function is to transform the excess electrical energy from a TEG into mechanical energy (to support the main engine) within a comprehensive increase in the fuel utilization efficiency. An appropriate circuit to connect a motor-wheel to the vessel's power system has been given.

We have identified ways to improve the efficiency of a thermoelectric generator and extend the scope of its application on small vessels

Author Biographies

Olexandr Shtanko, The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022

PhD, Associate Professor

Department of Software Engineering, Physics and Mathematics

Maryna Litvinova, The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022

Doctor of Pedagogical Sciences, PhD, Associate Professor

Department of Software Engineering, Physics and Mathematics

Artem Andrieiev, The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022

PhD

Department of Heat Engineering

Mariia Andrieieva, The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022

Department of Marine Engineering and Energetics

Petro Savchuk, The Kherson branch of the National University of Shipbuilding named after Admiral Makarov Ushakova ave., 44, Kherson, Ukraine, 73022

Department of Marine Engineering and Energetics

References

  1. Gohari, A., Matori, A. N., Yusof, K. W., Toloue, I., Sholagberu, A. T. (2018). The effect of fuel price increase on transport cost of container transport vehicles. International Journal of GEOMATE, 15 (50), 174–181. doi: https://doi.org/10.21660/2018.50.30814
  2. Budashko, V. V. (2017). Design of the three-level multicriterial strategy of hybrid marine power plant control for a combined propulsion complex. Electrical Engineering & Electromechanics, 2, 62–72. doi: https://doi.org/10.20998/2074-272x.2017.2.10
  3. Girgin, I., Ezgi, C. (2017). Design and thermodynamic and thermoeconomic analysis of an organic Rankine cycle for naval surface ship applications. Energy Conversion and Management, 148, 623–634. doi: https://doi.org/10.1016/j.enconman.2017.06.033
  4. Ji, D., Tseng, K. J., Wei, Z., Zheng, Y., Romagnoli, A. (2016). A Simulation Study on a Thermoelectric Generator for Waste Heat Recovery from a Marine Engine. Journal of Electronic Materials, 46 (5), 2908–2914. doi: https://doi.org/10.1007/s11664-016-5038-8
  5. Kumar, S., Heister, S. D., Xu, X., Salvador, J. R., Meisner, G. P. (2013). Thermoelectric Generators for Automotive Waste Heat Recovery Systems Part I: Numerical Modeling and Baseline Model Analysis. Journal of Electronic Materials, 42 (4), 665–674. doi: https://doi.org/10.1007/s11664-013-2471-9
  6. Politicin, B. M., Shtanko, O. D., Litvinova, M. B., Karpova, S. O. (2017). Energy recovery device for the internal combustion engine. Naukovyi visnyk Natsionalnohо hirnychnoho universytetu, 3, 82–89.
  7. Anatychuk, L. I., Kuz, R. V. (2016). Thermoelectric generator for trucks. Journal of Thermoelectricity, 3, 43–48.
  8. Nour Eddine, A., Chalet, D., Faure, X., Aixala, L., Chessé, P. (2018). Optimization and characterization of a thermoelectric generator prototype for marine engine application. Energy, 143, 682–695. doi: https://doi.org/10.1016/j.energy.2017.11.018
  9. Onishchenko, D. O., Pankratov, S. A., Zotov, A. A., Osipkov, A. S., Poshekhonov, R. A. (2017). Study of Influence of Hydraulic Thermoelectric Generator Resistance on Gasoline Engine Efficiency. International Journal of Applied Engineering Research, 12 (5), 721–727.
  10. Vikhor, L. N., Anatychuk, L. I. (2009). Generator modules of segmented thermoelements. Energy Conversion and Management, 50 (9), 2366–2372. doi: https://doi.org/10.1016/j.enconman.2009.05.020
  11. Golubev, M. V. (2013). Automatisation of the ship system for exhaust gases cleaning. Electrotechnic and computer systems, 10 (86), 74–79.
  12. Sudovye dizel'nye dvigateli: Seriya Iveco. Available at: http://www.brizmotors.ru/equipment/marine_engines/commercial/
  13. Sudovye dvigateli: Seriya YC4D. Available at: http://www.yuchai.ru/13-sudovye-dvigateli
  14. Nanni diesel. Available at: https://suddiesel.ru/catalog/666/
  15. Leontiev, A. I., Kavtaradze, R. Z., Onishchenko, D. O., Golosov, A. S., Pankratov, S. A. (2016). Improvement of piston engine operation efficiency by direct conversion of the heat of exhaust gases into electric energy. High Temperature, 54 (1), 105–112. doi: https://doi.org/10.1134/s0018151x16010053
  16. Yanov, S. (2014). Teplovaya effektivnost' parovyh kotlov. Moscow: Inostrannaya literatura, 152.
  17. Wolfram Support. Available at: https://support.wolfram.com/kb/27134
  18. Sizov, V. G. (2008). Teoriya korablya. Odessa: Feniks, Moscow: TransLit, 464.
  19. Datasheet: LTC3802 – Dual 550kHz Synchronous 2-Phase DC/DC Controller with Programmable Up/Down Tracking. Available at: https://www.analog.com/media/en/technical-documentation/data-sheets/3802f.pdf
  20. Datasheet: LTC3810 – 100V Current Mode Synchronous Switching Regulator Controller. Available at: https://www.alldatasheet.com/view.jsp?Searchword=Ltc3810&gclid=EAIaIQobChMIsr_2wfj-5gIVjZIYCh3q7Ax4EAAYASAAEgKNgPD_BwE

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Published

2020-02-29

How to Cite

Shtanko, O., Litvinova, M., Andrieiev, A., Andrieieva, M., & Savchuk, P. (2020). Building a technological model of the exhaust gas energy recovery device for the diesel engine on a small­sized vessel. Eastern-European Journal of Enterprise Technologies, 1(8 (103), 35–42. https://doi.org/10.15587/1729-4061.2020.194938

Issue

Vol. 1 No. 8 (103) (2020): Energy-saving technologies and equipment

Section

Energy-saving technologies and equipment

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Copyright (c) 2020 Olexandr Shtanko, Maryna Litvinova, Artem Andrieiev, Mariia Andrieieva, Petro Savchuk

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