Hidrojen ile Yakıt Zenginleştirmenin Dizel Motorun Motor Performansı ve Emisyon Özelliklerine Etkisi
Hava kirliliğinin giderek artışı ve motor performansı arttırmaya yönelik arayışlar hidrojen gibi ek yakıtlara olan ihtiyacı artırmıştır. Bu çalışmada, bir sıkıştırma ateşlemeli motorun çalışma karakteristikleri üzerine atık kızartma yağından üretilen biyodizel yakıtına (AKY) hidrojen ilavesinin etkileri deneysel olarak incelenmiştir. Hidrojen, giriş havasına belli bir debide verilmiştir. Yapılan testte dizel motorunun performans ve emisyon değerleri incelenmiştir. Katkısız dizel yakıt, motorun çeşitli yakıtlara göre operasyonel özelliklerini karşılaştırmak için referans yakıt olarak seçilmiştir. Sonuç olarak hidrojen ilavesinin motor performansını artırdığını gözlemlenmiştir. Hidrojen gazı motor silindirlerine verildiğinde CO ve CO2 emisyonları azalmış ve NOx emisyonları ise artmıştır.
Effect of Fuel Enrichment with Hydrogen on Engine Performance and Emission Characteristics of Diesel Engine
Increase in air pollution and seeking to improve engine performance has increased the need for additional fuels such as hydrogen. In this study, the effects of hydrogen addition on biodiesel fuel produced from waste frying oil on the operating characteristics of an ignition engine have been experimentally investigated. Hydrogen is introduced into the inlet air at a certain flow rate. Performance and emission values of the diesel engine were examined. Pure diesel fuel is selected as the reference fuel to compare the operational characteristics of the engine with respect to various fuels. As a result, it has been observed that the hydrogen addition increases the engine performance. When hydrogen gas is supplied to engine cylinders, CO and CO2 emissions are reduced and NOx emissions are increased.
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- 1. Hoseini, S.S., Najafi, G., Ghobadian, B.,
Mamat, R., Sidik, N.A.C., Azmi, W.H., 2017.
The Effect of Combustion Management on
Diesel Engine Emissions Fueled with Biodieseldiesel
Blends. Renewable and Sustainable
Energy Reviews, 73, 307–331.
- 2. Çalık, A., 2018. Determination of Vibration
Characteristics of a Compression İgnition
Engine Operated by Hydrogen Enriched Diesel
and Biodiesel Fuels. Fuel, 230, 355–358.
- 3. Çalık, A., 2017. Pamuk Yağı Biyodizelinin
Motor Ses Seviyesine Olan Etkilerinin
İncelenmesi. Çukurova Üniversitesi
Mühendislik-Mimarlık Fakültesi Dergisi, 32(4),
147–152.
- 4. Tüccar, G., 2018. Environmental Effects Effect
of Hydroxy Gas Enrichment on Vibration,
Noise and Combustion Characteristics of a
Diesel Engine Fueled with Foeniculum Vulgare
oil Biodiesel and Diesel Fuel. Energy Sources,
Part A: Recovery, Utilization, and
Environmental Effects, 40(10), 1257–1265.
- 5. Musa, I.A., 2016. The Effects of Alcohol to Oil
Molar Ratios and the Type of Alcohol on
Biodiesel Production Using Transesterification
Process. Egyptian Journal of Petroleum, 25(1),
21–31.
- 6. Uludamar, E., Yildizhan, Ş., Aydin, K., Özcanli,
M., 2016. Vibration, Noise and Exhaust
Emissions Analyses of an Unmodified
Compression Ignition Engine Fuelled with Low
Sulphur Diesel and Biodiesel Blends with
Hydrogen Addition. International Journal of
Hydrogen Energy, 41(26), 11481–11490.
- 7. Zhou, J.H., Cheung, C.S., Leung, C.W., 2014.
Combustion, Performance, Regulated and
Unregulated Emissions of a Diesel Engine with
Hydrogen Addition. Applied Energy, 126, 1–12.
- 8. Ramadhas, A.S., Jayaraj, S., Muraleedharan, C.,
Padmakumari, K., 2006. Artificial Neural
Networks Used for the Prediction of the Cetane
Number of Biodiesel. Renewable Energy,
31(15), 2524–2533.
- 9. Yildizhan, Ş., Uludamar, E., Çalık, A., Dede,
G., Özcanlı, M., 2017. Fuel Properties,
Performance and Emission Characterization of
Waste Cooking Oil (WCO) in a Variable
Compression Ratio (VCR) Diesel Engine.
European Mechanical Science, 1(2), 56–62.
- 10. Zareh, P., Zare, A.A., Ghobadian, B., 2017.
Comparative Assessment of Performance and
Emission Characteristics of Castor, Coconut and
Waste Cooking Based Biodiesel as Fuel in a
Diesel Engine. Energy, 139, 883–894.
- 11. Senthur Prabu, S., Asokan, M.A., Roy, R.,
Francis, S., Sreelekh, M.K., 2017. Performance,
Combustion and Emission Characteristics of
Diesel Engine Fuelled with Waste Cooking Oil
Bio-diesel/diesel Blends with Additives.
Energy, 122, 638–648.
- 12. Rehan, M., Gardy, J., Demirbas, A., Rashid, U.,
Budzianowski, W.M., Pant, D., Nizami, A.S.,
2017. Waste to Biodiesel: A Preliminary
Assessment for Saudi Arabia. Bioresource
Technology.
- 13. Atabani, A.E., Silitonga, A.S., Ong, H.C.,
Mahlia, T.M.I., Masjuki, H.H., Badruddin, I.A.,
Fayaz, H., 2013. Non-edible Vegetable Oils: A
Critical Evaluation of Oil Extraction, Fatty Acid
Compositions, Biodiesel Production,
Characteristics, Engine Performance and
Emissions Production. Renewable and
Sustainable Energy Reviews, 18, 211–245.
- 14. Hwang, J., Bae, C., Gupta, T., 2016. Application
of Waste Cooking Oil (WCO) Biodiesel in a
Compression İgnition Engine. Fuel, 176, 20–31.
- 15. Tan, Y.H., Abdullah, M.O., Nolasco-Hipolito,
C., Zauzi, N.S.A., Abdullah, G.W., 2017.
Engine Performance and Emissions
Characteristics of a Diesel Engine Fueled with
Diesel-biodiesel-bioethanol Emulsions. Energy
Conversion and Management, 132, 54–64.
- 16. Attia, A.M.A., Hassaneen, A.E., 2016.
Influence of Diesel Fuel Blended with Biodiesel
Produced from Waste Cooking Oil on Diesel
Engine Performance. Fuel, 167, 316–328.
- 17. Cheung, C.S., Man, X.J., Fong, K.W., Tsang,
O.K., 2015. Effect of Waste Cooking Oil
Biodiesel on the Emissions of a Diesel Engine.
Energy Procedia, 66, 93–96.
- 18. Elshaib, A.A., Kamal, M.M., Elahwany, A.A.,
2014. Performance of a Diesel Engine Fueled by
Waste Cooking Oil Biodiesel. Journal of the
Energy Institute, 87(1), 11–17.
- 19. Arat, H.T., Sürer, M.G., 2017. State of Art of
Hydrogen Usage as a Fuel on Aviation.
European Mechanical Science, 2(1), 20–30.
- 20. Du, Y., Yu, X., Liu, L., Li, R., Zuo, X., Sun, Y.,
2017. Effect of Addition of Hydrogen and
Exhaust Gas Recirculation on Characteristics of
Hydrogen Gasoline Engine. International
Journal of Hydrogen Energy, 42(12),
8288–8298.
- 21. Çelebi, K., Uludamar, E., Özcanlı, M., 2017.
Evaluation of Fuel Consumption and Vibration
Characteristic of a Compression Ignition Engine
Fuelled with High Viscosity Biodiesel and
Hydrogen Addition. International Journal of
Hydrogen Energy, 42(36), 23379–23388.
- 22. Nguyen, T.A., Mikami, M., 2013. Effect of
Hydrogen Addition to Intake Air on
Combustion Noise from a Diesel Engine.
International Journal of Hydrogen Energy,
38(10), 4153–4162.
- 23. Chiriac, R., Apostolescu, N., 2013. Emissions of
a Diesel Engine Using B20 and Effects of
Hydrogen Addition. International Journal of
Hydrogen Energy, 38(30), 13453–13462.
- 24. Bhasker, J.P., Porpatham, E., 2017. Effects of
Compression Ratio and Hydrogen Addition on Lean Combustion Characteristics and Emission
Formation in a Compressed Natural Gas Fuelled
Spark Ignition Engine. Fuel, 208, 260–270.
- 25. Tüccar, G., Uludamar, E., 2017. Emission and
Engine Performance Analysis of a Diesel
Engine Using Hydrogen Enriched Pomegranate
Seed Oil Biodiesel. International Journal of
Hydrogen Energy, 43, 18014-18019.
- 26. Uludamar, E., 2018. Effect of Hydroxy and
Hydrogen Gas Addition on Diesel Engine
Fuelled with Microalgae Biodiesel.
International Journal of Hydrogen Energy,
43(38), 18028-18036.
- 27. Baltacioǧlu, M.K., Arat, H.T., Kenanoǧlu, R.,
2017. Exergy and Performance Analysis of a CI
Engine Fuelled with HCNG Gaseous Fuel
Enriched Biodiesel. International Journal of
Exergy, 24, 39-56.
- 28. Rimkus, A., Matijošius, J., Bogdevičius, M.,
Bereczky, Á., Török, Á., 2018. An Investigation
of the Efficiency of Using O2 and H2
(hydrooxile gas -HHO) Gas Additives in a ci
Engine Operating on Diesel Fuel and Biodiesel.
Energy, 152, 640–651.
- 29. Chelladorai, P., Varuvel, E.G., Martin, L.J.,
Bedhannan, N., 2018. Synergistic Effect of
Hydrogen Induction with Biofuel Obtained
from Winery Waste (Grapeseed Oil) for CI
Engine Application. International Journal of
Hydrogen Energy, 43(27), 12473–12490.
- 30. Serin, H., Yildizhan, Ş., 2018. Hydrogen
Addition to Tea Seed Oil Biodiesel:
Performance and Emission Characteristics.
International Journal of Hydrogen Energy, 43,
18020-18027.
- 31. Canakci, M., Ozsezen, N., 2005. Evaluating
Waste Cooking Oils as Alternative Diesel Fuel.
G.U. Journal of Science, 18(1), 81–91.
- 32. Rocha, H.M.Z., Pereira, R. da S., Nogueira,
M.F.M., Belchior, C.R.P., Tostes, M.E. de L.,
2017. Experimental Investigation of Hydrogen
Addition in the Intake Air of Compressed
Ignition Engines Running on Biodiesel Blend.
International Journal of Hydrogen Energy,
42(7), 4530–4539.