Investigation of combustion and emission in a DI diesel engine fueled with hydrogen-biodiesel blends

Yıl 2019, Cilt: 8 Sayı: 4, 150 - 164, 10.12.2019

Ömer Cihan İlker Temizer

https://doi.org/10.18245/ijaet.623898

Cited By: 1

Öz

The aim of this study was to determine the availability of canola oil
methyl ester as an alternative fuel in diesel engines and by adding canola oil
methyl ester and hydrogen to diesel fuel. This study was carried out
experimentally and numerically. The engine was studied at 2000 rpm speed and
full load. The analyzes carried out in the AVL-FIRE ESE Diesel part.

In-cylinder combustion and emission analyzes were examined
experimentally by adding 10% (B10) and 20% (B20) of the canola oil methyl ester
to the diesel (D100) fuel. Also, hydrogen fuel by the amount of 3% and 6% of
the mass were added to diesel and biodiesel mixture fuels to eliminate some
disadvantages of biodiesel fuels. The obtained findings in experimental and
numerical studies were similar to each other. The similarity of these results
was also validated by numerical studies using hydrogen.

The boundary conditions obtained in experimental studies were
determined, and the effect of hydrogen fuel on temperature, in-cylinder
pressure, spray distribution and CO formation were examined numerically. In the
experimental studies conducted with D100, B10 and B20 fuels, the maximum
pressures in-cylinder were measured as 87 bar, 88 bar and 89.09 bar
respectively. In numerical results, these values were recorded as 90.02, 90 and
93.8 bar respectively. Addition of 3% and 6% hydrogen to these three different
fuel mixtures increased in-cylinder pressures and temperatures. Also,
in-cylinder droplet diameters with the addition of hydrogen decreased in all
test fuels. This situation led to a reduction in CO emissions.

Anahtar Kelimeler

Diesel Engine, Hydrogen, Canola oil methyl ester, CO emission, AVL Fire

Kaynakça

• 1. K R Patil, P M Khanwalkar, S S Thipse, K P Kavathekar, S D Rairikar, Development of HCNG blended fuel engine with control of NOx emissions, 2nd International Conference on Emerging Trends in Engineering & Technology (ICETET-09), TII - 423 (2009), 1068-1074.
• 2. A A Taha, T Abdel-Salam, M Vellakal, Hydrogen, biodiesel and ethanol for internal combustion engines: a review paper, Proceedings of the ASME 2015 Internal Combustion Engine Division Fall Technical Conference, ICEF2015, 1-11.
• 3. C M White, R R Steeper, A E Lutz, The hydrogen-fueled internal combustion engine: a technical review, International Journal of Hydrogen Energy, 31 (2006), 1292 – 1305.
• 4. N K Patil, S V Prayagi, CFD analysis of single cylinder HCNG engine: a review, International Research Journal of Engineering and Technology (IRJET), 4:5 (2017), 2632-2636.
• 5. P Dimiriou, T Tsujimura, A review of hydrogen as a compression ignition engine fuel, International Journal of Hydrogen Energy, 42 (2017), 24470 – 24486.
• 6. B A Çeper, Use of hydrogen-methane blends in internal combustion engines, Chapter 7, Hydrogen Energy - Challenges and Perspectives Book, http://dx.doi.org/10.5772/50597, 01.17.2017. 175-200.
• 7. Fulton J, Lynch F, Marmora R. Hydrogen for reducing emissions from alternative fuel vehicle, SAE Technical Paper, 1993; No. 931813.
• 8. K Nanthagopal, R Subbarao, T Elango, P Baskar, K Annamalai, Hydrogen enriched compressed natural gas (HCNG) – A futuristic fuel for internal combustion engines, Thermal Science 15:4 (2011),1145-1154.
• 9. H Köse, M Ciniviz, An experimental investigation of effect on diesel engine performance and exhaust emissions of addition at dual fuel mode of hydrogen, Fuel Processing Technology 114 (2013) 26–34.
• 10. A Mariani, B Morrone, A Unich, A review of hydrogen-natural gas blend, fuels in internal combustion engines, Fossil Fuel and the Environment, (2012), 17-36.
• 11. F Halter, C Chauveau, N Djebaili-Chaumeix, I, Gökalp, Characterization of the effects of pressure and hydrogen concentration on laminar burning velocities of methane–hydrogen–air mixtures, Proceedings of the Combustion Institute 30 (2005), 201–208.
• 12. Z Chen, Effects of hydrogen addition on the propagation of spherical methane/air flames: A computational study, International Journal of Hydrogen Energy, 34 (2009), 6558 – 6567.
• 13. G P McTaggart-Cowan, S R Munshi, S N Rogak, P G Hill, W K Bushe, Hydrogen-methane blend fuellıng of a heavy-duty, dırect-ınjectıon engıne, 2007 ASME International Mechanical Engineering Congress and Exposition, Proceedings of IMECE2007, 1-10.
• 14. B Morrone, A Unich, Numerical investigation on the effects of natural gas and hydrogen blends on engine combustion, International Journal of Hydrogen Energy, 34 (2009), 4626 – 4634.
• 15. S Tangöz, S O Akansu, N Kahraman, Effects of compression ratio on performance and emissions of a modified diesel engine fueled by HCNG, International Journal of Hydrogen Energy, 40 (2015), 15374 – 15380.
• 16. S Reddy, M Dutta, K V K Reddy, Effect of Compression Ratio on Performance of a Hydrogen Blended CNG-Diesel Dual Fuel Engine, Journal of Mechanical Engineering, 44:2 (2014), 87-93.
• 17. S O Akansu, Z Dulger, N Kahraman, T N Veziroğlu, Internal combustion engines fueled by natural gas—hydrogen mixtures, International Journal of Hydrogen Energy, 29 (2004), 1527 – 1539.
• 18. J Xu, X Zhang, J Liu, L Fan, Experimental study of a single-cylinder engine fueled with natural gas–hydrogen mixtures, International Journal of Hydrogen Energy, 35 (2010), 2909 – 2914.
• 19. J Wang, Z Huang, Y Fang, B Liu, K Zeng, H Miao, D Jiang, Combustion behaviors of a direct-injection engine operating on various fractions of natural gas–hydrogen blends, International Journal of Hydrogen Energy, 32 (2007), 3555 – 3564.
• 20. H T Arat, K Aydın, E Baltacıoğlu, E Yaşar, M K Baltacıoğlu, Ç Conker, A Burgaç, A review of hydrogen-enriched compressed natural gas (HCNG)-fuel in diesel engines, A Journal of Macro Trends in Energy and Sustainability, 1:1 (2013), 115-122.
• 21. M S Kumar, S V Karthic, P Pradeep, Investigations on the influence of ethanol and water injection techniques on engine's behavior of a hydrogen - biofuel based dual fuel engine, International Journal of Hydrogen Energy, 43 (2018), 21090 – 21101.
• 22. G Tüccar, E Uludamar, Emission and engine performance analysis of a diesel engine using hydrogen enriched pomegranate seed oil biodiesel, International Journal of Hydrogen Energy, 43 (2018), 18014 – 18019.
• 23. H Serin, Ş Yıldızhan, Hydrogen addition to tea seed oil biodiesel: Performance and emission characteristics, International Journal of Hydrogen Energy, 43 (2018), 18020 – 18027.
• 24. M A Akar, E Kekilli, O Bas, S Yıldızhan, H Serin, M Ozcanli, Hydrogen enriched waste oil biodiesel usage in compression ignition engine, International Journal of Hydrogen Energy, 43 (2018), 18046 – 18052.
• 25. M Parthasarathy, J I J R Lalvani B Dhinesh, K Annamalai, Effect of hydrogen on ethanol–biodiesel blend on performance and emission characteristics of a direct injection diesel engine, Ecotoxicology and Environmental Safety,134 (2016), 433–439.
• 26. M S Kumar, A Ramesh, B Nagalingam, Use of hydrogen to enhance the performance of a vegetable oil fuelled compression ignition engine, International Journal of Hydrogen Energy, 28 (2003), 1143 – 1154.
• 27. R Chiriac, N Apostolescu, Emissions of a diesel engine using B20 and effects of hydrogen addition, International Journal of Hydrogen Energy, 38 (2013), 13453 – 13462.
• 28. M Aldhaidhawi, R Chiriac, V Badescu, G Descombes, P Podevin, Investigation on the mixture formation, combustion characteristics and performance of a Diesel engine fueled with Diesel, Biodiesel B20 and hydrogen addition, International Journal of Hydrogen Energy, 42 (2017), 16793 – 16807.
• 29. S Imran, D R Emberson, B Ihracska, D S Wen, R J Crookes, T Korakianitis, Effect of pilot fuel quantity and type on performance and emissions of natural gas and hydrogen based combustion in a compression ignition engine, International Journal of Hydrogen Energy, 39 (2014), 5163 – 5175.
• 30. S Imran, T Korakianitis, R Shaukat, M Farooq, S Condoor, S Jayaram, experimentally tested performance and emissions advantages of using natural-gas and hydrogen fuel mixture with diesel and rapeseed methyl ester as pilot fuels, Applied Energy, 229 (2018), 1260–1268.
• 31. T Korakianitis, A M Namasivayam, R J Crookes, Diesel and rapeseed methyl ester (RME) pilot fuels for hydrogen and natural gas dual-fuel combustion in compression–ignition engines, Fuel, 90 (2011), 2384–2395.
• 32. S Imran, D R Emberson, A Hussain, H Ali, B Ihracska, T Korakianitis, Performance and specific emissions contours throughout the operating range of hydrogen-fueled compression ignition engine with diesel and RME pilot fuels, Alexandria Engineering Journal, 54 (2015), 303–314.
• 33. S Imran, D R Emberson, A Diez, D S Wen, R J Crookes, T Korakianitis, Natural gas fueled compression ignition engine performance and emissions maps with diesel and RME pilot fuels, Applied Energy, 124 (2014), 354–365.
• 34. S Imran, D R Emberson, D S Wen, A Diez, R J Crookes, T Korakianitis, Performance and specific emissions contours of a diesel and RME fueled compression-ignition engine throughout its operating speed and power range, Applied Energy, 111 (2013), 771–777.
• 35. B Alpgiray, Kanola yağının diesel motorunun performansına ve emisyon karakteristiklerine etkilerinin belirlenmesi, Ankara University, Master’s thesis, Institute of science and technology, 2006.
• 36. S Wei, F Wang, X Leng, X Liu, K Ji, Numerical analysis on the effect of swirl ratios on swirl chamber combustion system of DI diesel engines, Energy Conversion and Management, 75 (2013), 184–190.
• 37. B V V S U Prasad, C S Sharma, T N C Anand, R V Ravikrishna, High swirl-inducing piston bowls in small diesel engines for emission reduction, Applied Energy, 88:7 (2011) 2355–2367.
• 38. F Payri, J Benajes, X Margeo, A Gil, CFD modeling of the in-cylinder flow in direct-injection diesel engine, Computers & Fluids, 33:8 (2004), 995–1021.
• 39. H Köten, Performans analysis of a diesel engine within a multi-dimensional framework, Journal of Thermal Engineering, 4:4 (2018), 2075-2082.
• 40. S M Hosseini, R Ahmadi, Performance and emissions characteristics in the combustion of co-fuel diesel-hydrogen in a heavy duty engine, Applied Energy, 205 (2017) 911–925.
• 41. N Boz, M Kara, O Sunal, E Alptekin, N Değirmenbaşı, Investigation of the fuel properties of biodiesel produced over an alumina-based solid catalyst, Turkish Journal of Chemistry, 33:3 (2009), 433-442.