Analysis of Ultra Fine Bubble Addition on Biodiesel Fuel to Reduce Emission of  Two Wheel Tractors Diesel Engine

Hanifa Farafisha; Sam Herodian; Anto Tri Sugiarto; Riesta Anggarani; Joko Pitoyo; Yogi Pramudito

doi:10.23960/jtep-l.v14i1.296-308

Authors

Hanifa Farafisha IPB University
Sam Herodian IPB University
Anto Tri Sugiarto National Research and Innovation Agency/ BRIN
Riesta Anggarani Lemigas Application for Oil and Gas Technology
Joko Pitoyo Center for Standard Testing of Agricultural Mechanization Instrument (BBPSI Mektan)
Yogi Pramudito Lemigas Application for Oil and Gas Technology

DOI:

https://doi.org/10.23960/jtep-l.v14i1.296-308

Abstract View: 158

Abstract

Diesel engines are known as high efficiency engines and are used in public transportation and agricultural sector. The exhaust gas produced by diesel engines is dangerous for human health. Ultra Fine Bubble (UFB) technology which is currently being developed is an emission reduction alternative that can enrich oxygen in fuel and has the potential to reduce emissions. This research was carried out to apply UFB technology to a variety of fuels and compare the emission results. This research method is data collection based on experimental tests. The types of fuel used in this research are biodiesel and biodiesel-diesel mixture. The research procedure starts from instrument preparation, fuel inflation which produces UFB fuel, fuel characteristics, instrument performance testing and data processing. The characteristic testing method follows the American Standard Testing and Materials (ASTM) and performance testing follows the ISO/IEC 17025:2017 standard. The research results show that fuel treated with ultra-fine bubbles can reduce exhaust emissions compared to fuel without UFB. CO content decreased by 608 parts per million (ppm) in the biodiesel-diesel blend and 306 ppm in biodiesel with UFB. The exhaust gas temperature becomes stable when the fuel contains bubbles and reduces NO and NOx content in emissions.

Keywords: Biodiesel, Diesel engine, Fuel, Ultra fine bubble

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Author Biographies

Hanifa Farafisha, IPB University

Department of Mechanical and Biosystem, IPB Univeristy

Sam Herodian, IPB University

Department of Mechanical and Biosystem, IPB Univeristy

Anto Tri Sugiarto, National Research and Innovation Agency/ BRIN

Research Center for Smart Mechatronics

Riesta Anggarani, Lemigas Application for Oil and Gas Technology

Lemigas Application for Oil and Gas Technology

Joko Pitoyo, Center for Standard Testing of Agricultural Mechanization Instrument (BBPSI Mektan)

Center for Standard Testing of Agricultural Mechanization Instrument (BBPSI Mektan)

Yogi Pramudito, Lemigas Application for Oil and Gas Technology

Lemigas Application for Oil and Gas Technology

References

Alam, H.S., Sutikno, P., Soelaiman, T.A.F., & Sugiarto, A.T. (2021). Bulk nanobubbles: Generation using a two-chamber swirling flow nozzle and long-term stability in water. Journal of Flow Chemistry, 12(10), 1–13. http://dx.doi.org/10.1007/s41981-021-00208-8

Alfath, S.F. (2023). Analisis Pengaruh Penambahan Ultra Fine Bubble Pada Bahan Bakar Biosolar B30 Terhadap Kinerja Motor Diesel Traktor Roda Dua. [Undergraduate Thesis]. IPB University Bogor.

BSN. (2005). SNI 09-7118.2-2005: Standar Emisi Gas Buang - Sumber Bergerak. Bagian 2: Cara Uji Kendaraan Bermotor Kategori M, N, dan O Berpenggerak Penyalaan Kompresi pada Kondisi Akselerasi Bebas. Badan Standardisasi Nasional, Jakarta.

Chalid, A.N., Aryadi, W., & Karnowo, K. (2021). Pengaruh temperatur bahan bakar biodiesel minyak lemak sapi terhadap performa mesin diesel multi silinder. Jurnal Inovasi Mesin, 3(2), 68–73. https://doi.org/10.15294/jim.v3i2.52797

Dwinanda, A., Kustanto, M.K., Jatisukamto, G., & Ilminnafik, N. (2023). Performance and emission characteristics of a diesel engine fueled with calophyllum inophyllum biodiesel and gasoline additives. International Journal of Application on Sciences, 1(1), 175–177.

Effendi, Y., & Syaiful. (2019). Uji daya mesin diesel dengan hot EGR menggunakan bahan bakar campuran biosolar, metanol kadar rendah, dan jatropha. Jurnal Program Studi Teknik Mesin UM Metro, 8(2), 153–156. http://dx.doi.org/10.24127/trb.v8i2.1030

Erny, A., Fatimah, D., & Muhammad, I. (2018). Fundamental characteristics of microbubbles in water and diesel fuel. MATEC Web of Conferences, 225, 05015. https://doi.org/10.1051/matecconf/201822505015

Fayad, M.A., Al-Ghezi, M.K., Hafad, S.A., Ibrahim, S.I., Abood, M.K., Al-Salihi, H.A., & Dhahad, H.A. (2022). Emissions characteristics and engine performance from the interaction effect of egr and diesel-ethanol blends in diesel engine. International Journal of Renewable Energy Development, 11(4), 992–998. https://doi.org/10.14710/ijred.2022.45051

Hakim, A.R., Wibowo, W., & Astriawati, N. (2020). Sistem pendingin mesin diesel pada wheel loader Komatsu wa120-3cs. Jurnal Teknovasi, 7(2), 77–82.

Hazrat, M.A., Rasul, M.G., Khan, M.M.K. (2015) Lubricity improvement of the ultra-low sulfur diesel fuel with the biodiesel. Energy Procedia, 75, 111–117. https://doi.org/10.1016/j.egypro.2015.07.619

Kristyadi, T., Permana, D.I., Sirodz, M.P.N., Saefudin, E., & Farkas, I. (2022). Performance and emission of diesel engine fuelled by commercial bio-diesel fuels in Indonesia. Acta Technologica Agriculturae, 25(4), 221–228. https://doi.org/10.2478/ata-2022-0032

Lawang, A.T., Setyaningsih, D., & Syahbana, M. (2019). Evaluasi minyak daun cengkeh dan minyak sereh wangi sebagai bioaditif bahan bakar solar dalam menurunkan emisi gas buang pada mesin diesel. Jurnal Teknologi Pertanian, 20(2), 95–102. https://doi.org/10.21776/ub.jtp.2019.020.02.3

Lü, X.C., Yang, J.G., Zhang, W.G., & Huang, Z. (2005) Improving the combustion and emissions of direct injection compression ignition engines using oxygenated fuel additives combined with a cetane number improver. Energy & Fuels, 19(5), 1879–1880. https://doi.org/10.1021/ef0500179

Maia, J., Qadir, A., Widajati, E., & Purwanti, Y.A. (2021). Teknologi ultrafine bubbles untuk pematahan dormasi benih cendana (santalum album l.). Jurnal Perbenihan Tanaman Hutan, 9(1), 27–41.

Marui, T. (2013). An introduction to micro-bubbles and their applications. Systemics, Cybernetics and Informatics, 11(4), 68–73. ISSN: 1690-4524.

Oh, S.H., Han, J.G., & Kim, J.M. (2015). Long-term stability of hydrogen nanobubble fuel. Fuel, 158, 393–404. https://doi.org/10.1016/j.fuel.2015.05.072

Paradhiba, A.M., Febriyanti, F., Rahmadania, E., Yanisa, F., Adelina, F.U., & Mukti, R.C. (2021). Pemanfaatan teknologi nano-bubble untuk produksi Anguilla sp. pada era society 5.0. Seminar Nasional Lahan Suboptimal, Palembang, 20 October 2021.

Persulesy, P. Y., Basri, K., & Suprapto, E. (2022). pengaruh penggunaan bahan bakar biodisel berbasis biji buah nyamplung (calophyllum inophyllum) terhadap emisi gas buang mesin diesel. Lontar: Jurnal Teknik Mesin Undana, 9(1), 48–56. https://doi.org/10.35508/ljtmu.v9i01.6295

Prahmana, R., Alfian, D., Supriyadi, D., Silitonga, D., & Muhyi, A. (2020). Pengaruh komposisi campuran minyak sereh wangi dan minyak cengkeh terhadap unjuk kerja mesin diesel. Journal of Science And Applicative Technology, 4(2), 82–85. https://doi.org/10.35472/jsat.v4i2.244

Sasmita, A., Yohanes, Y., & Yolanda, K. (2022). Analisis emisi gas buang dari mesin diesel modifikasi dipengaruhi daya mesin dan bahan bakar campuran oli bekas dan dexlite. Semesta Teknika, 25(2), 170–178. https://doi.org/10.18196/st.v25i2.13748

Septiyanto, A., Maulana, S., Nugroho, A., & Sudiyono, S. (2017). Pengaruh exhaust gas recirculation (egr) terhadap performa dan emisi jelaga mesin diesel direct injection. Sainteknol: Jurnal Sains dan Teknologi, 15(2), 129–136.

Sharif, P.M., Hairuddin, A.A., As’arry, A., Rezali, K.A.M., Noor, M.M., Norhafana, M., & Shareef, S.M.. (2019). Nano gas bubbles dissolve in gasoline fuel and its influence on engine combustion performance. IOP Conference Series: Materials Science and Engineering, 469, 012062. https://doi.org/10.1088/1757-899X/469/1/012062

Siregar, S.P., Joni, J., & Ranteallo, O.T. (2024). Pemakaian sistem venturi scrubber–egr (exhaust gas recirculation) terhadap performa mesin diesel satu silinder. G-Tech: Jurnal Teknologi Terapan, 8(2), 964–974. https://doi.org/10.33379/gtech.v8i2. 4123

Song, H., Quinton, K.S., Peng, Z., Zhao, H., & Ladommatos, N. (2016). Effects of oxygen content of fuels on combustion and emissions of diesel engines. Energies, 9(1), 28. https://doi.org/10.3390/en9010028

Ushikubo, F.Y., Furukawa, T., Nakagawa, R., Enari, M., Makino, Y., Kawagoe, Y., Shiina, T., & Oshita, S. (2010). Evidence of the existence and the stability of bubbles in water. Colloids Surfaces A Physicochem. Eng. Asp, 361(103), 31– 37. https://doi.org/10.1016/j.colsurfa.2010.03.005

Wagino, W., Sugiarto, T., Yuvenda, D., Putra, R.P., &Arif, A. (2020). Pengaruh aplikasi teknologi EGRICS tipe cold terhadap emisi asap pada mesin diesel. Jurnal Inovasi Vokasional dan Teknologi, 20(2), 89–92. http://dx.doi.org/10.24036/invotek.v20i2.716

Yamamoto, K., Akai, Y., Hayashi, N. (2022). Numerical simulation of spray combustion with ultrafine oxygen bubbles. Energies, 15(22), 8467. https://doi.org/10.3390/en15228467