Efficiency of fuel gas supply on LNG-fueled vessels

The widespread use of LNG as a fuel for marine internal combustion engines makes to pay attention to the quality of gas fuel supply systems and its specifics. The objective of this paper is to review modern gas fuel supply systems and analyze their efficiency. The goal is to determine the most important parameters of gas fuel that affect the stability of the working process of marine dual-fuel engines and ways to maintain them within the specified limits. Evaluation of the gas fuel preparation efficiency is carried out on the basis of operational data obtained on the gas carrier vessel board. Data collection is carried out under non-standard operating conditions, which makes it possible to evaluate the quality of the resulting gas fuel with a time-varying composition of the initial natural gas. To analyze the obtained data, modern software, which is used by leading developers of marine diesel engines, is used (Wartsila Methane Number Calculator, AVL BoostTM and Python 3 statistic libraries). The analysis results are approximated for gas fuel supply systems for gas-fueled vessels, but not being gas carriers. This approximation is made taking into account the design features of gas fuel supply systems, since the specificity of the design imposes certain restrictions on the applicability of the conclusions obtained as a result of the previous analysis. Also, attention is paid to the accumulation of residual heavy hydrocarbons in bunker tanks, the excess of which can adversely affect the quality of gas fuel. Since there is no universal way to solve this problem, only general assumptions about possible ways to dispose of them have been made. 

1. LNG bunker fuel prices. Web. 30 Apr. 2023 <https://sea-lng.org/lng-bunker-fuel-prices/>.

2. Emission Control Areas (ECAs) designated under MARPOL Annex VI. Web. 30 Apr. 2023 <https://www.imo.org/en/OurWork/Environment/Pages/Emission-Control-Areas-(ECAs)-designated-under-regulation‑13‑ofMARPOL-Annex-VI-(NOx-emission-control).aspx>.

3. International Code of Safety for Ship Using Gases or Other Low-flashpoint Fuels (IGF Code). Web. 30 Apr. 2023 <https://www.imo.org/en/ourwork/safety/pages/igf-code.aspx>.

4. Global fleet. Web. 30 Apr. 2023 <https://sea-lng.org/why-lng/global-fleet/>.

5. 2021 was a record year for LNG fueled ships, says DNV. Web. 30 Apr. 2023 <https://safety4sea.com/2021‑wasa-record-year-for-lng-fueled-ships-says-dnv/>.

6. Tomasz Wlodek MSc, P. E. “Safety aspects of different composition liquefied natural gas storage processes.” International Multidisciplinary Scientific GeoConference: SGEM 4 (2016): 167–174.

7. Operational experience of the 51/60DF from MAN Diesel &Turbo. Web. 30 Apr. 2023 <https://dl-manual. com/doc/operation-manual-mz7811jprpo7>.

8. Rosemount™ 700XA Gas Chromatograph. Web. 30 Apr. 2023 <https://www.emerson.com/en-us/catalog/rosemount‑700xa-gas-chromatograph>.

9. Pirson’s correlation. Web. 30 Apr. 2023 <https://www.codecamp.ru/blog/pearson-correlation-coefficient/>.

10. seaborn.PairGrid. Web. 30 Apr. 2023 <https://seaborn.pydata.org/generated/seaborn.PairGrid.html>.

11. Wärtsilä Methane Number Calculator. Web. 30 Apr. 2023 <https://www.wartsila.com/marine/products/gas-solutions/methane-number-calculator>.

12. BOOSTTM. Users Manual Version 2017. AVL List GmbH Graz, Austria, 2017. (License Agreement for Use of the Simulation Software AVL BOOSTTM between Admiral Makarov SUMIS and AVL List GmbH, 2019).

13. DH-FGSS MEGI/XDF/DFDE. Web. 30 Apr. 2023 <https://www.dh.co.kr/ebook/leaflet_marine_DH-FGSS/index.html#page/1>.

14. The sophisticated world of LNG. Web. 30 Apr. 2023 <https://www.man-es.com/docs/default-source/document-sync/lng-gas-supply-and-bunker-systems-eng.pdf?sfvrsn=b32d2eb5_1>.

15. LNG Fuel Gas Supply System. Web. 30 Apr. 2023 <https://www.kongsberg.com/contentassets/63bb1708808b4ece9f2bd9190edd49ac/468252_lng-fuel-gas-supply-system_091020.pdf>.

16. LNG fuel gas supply system (FGSS). Web. 30 Apr. 2023 <https://marine-service-noord.com/en/products/alternative-fuels-and-technologies/lng/fuel-gas-supply-system/>.

17. LNG fuel gas supply system (LNG FGSS): components. Web. 30 Apr. 2023 <https://www.mhi.com/products/ship/fgss_components.html>.

18. Wärtsilä LNGPac. Web. 30 Apr. 2023 <https://www.wartsila.com/marine/products/gas-solutions/lng-asfuel/lngpac>.

19. Ott, Marcel, Ingemar Nylund, Roland Alder, Takayuki Hirose, Yoshiyuki Umemoto, and Takeshi Yamada. “The 2‑stroke low-pressure dual-fuel technology: from concept to reality.” The 28th CIMAC World Congress 2016, Helsinki, Finland. CIMAC, 2016. Paper No. 233.

20. ME-GA — The latest dual-fuel MAN B&W two-stroke engine. Web. 30 Apr. 2023 <https://www.man-es.com/docs/default-source/document-sync/me-ga-eng.pdf?sfvrsn=b8afb1ad_3>.

21. Dual fuel engines. Web. 30 Apr. 2023 <https://www.wartsila.com/marine/products/engines-and-generatingsets/dual-fuel-engines>.

22. Providing the flexibility needed for reliable power generation. Web. 30 Apr. 2023 <https://www.man-es.com/energy-storage/products/dual-fuel-engines>.