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Erschienen in:
Impact of Flowfield on Pollutants’ Emission from a Swirl-Assisted Distributed Combustor Kapitel lesen Erstes Kapitel lesen

2021 | OriginalPaper | Buchkapitel

Experimental Investigation on a Compression Ignition Engine with Blends of Plastic Oil and Diesel as Fuel

verfasst von : Manoj Kumar, J. M. Mallikarjuna

Erschienen in: Advances in IC Engines and Combustion Technology

Verlag: Springer Singapore

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Abstract

Waste plastic is a conventional source of energy. It can be transformed into oil by thermal degradation method such as pyrolysis. In this work, pyrolysis plastic oil (PPO) was prepared by microwave pyrolysis method using waste plastic. The plastic oil was analysed, tested and used as the properties of it were similar to that of diesel. The single cylinder direct injection diesel engine was fuelled with different blends at different loads from no load to full load condition. The performance, combustion characteristics and emissions were recorded and compared with that of diesel. Based on the results, it is found that the brake thermal efficiency for blends PPO20, PPO40, PPO60, PPO80 and PPO100 at 90% of full load condition were lower by 3.9, 6.8, 8.3, 9 and 9.7%, respectively, with respect to diesel when the engine was operated at a constant speed of 1500 rpm. Specific fuel consumption for blends PPO20, PPO40, PPO60, PPO80 and PPO100 at 90% of full load were higher by 0.4, 1.2, 2, 3.6 and 6%, respectively, as compared to diesel at constant speed (1500 rpm). The NOx emissions for blends PPO20, PPO40, PPO60, PPO80 and PPO100 at 90% of full load were higher by 7.65, 13, 17, 23 and 24.2%, respectively, as compared to diesel while engine was running in constant speed (1500 rpm). The CO emissions for PPO blends PPO20, PPO40, PPO60, PPO80 and PPO100 at 90% of full load were lower by 6.5, 17.4, 26, 30.4 and 7.6%, respectively, as compared to diesel at constant speed (1500 rpm). The UHC emissions for PPO blends PPO20, PPO40, PPO60, PPO80 and PPO100 at 90% of full load were lower by 6.5, 17.4, 26, 30 and 39%, respectively, as compared to diesel at constant speed (1500 rpm). It can be concluded that the plastic oil could be used as a substitute fuel in diesel engine.

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Vorheriges Kapitel Experimental Investigation of Aromatic Blended Binary Fuel on Pollutant Emissions from Compression Ignition Engine
Nächstes Kapitel Combustion Characteristics of Conventional Diesel Engine and Low Heat Rejection Diesel Engine with Biodiesel Blends
Literatur
1.
Mani M, Nagarajan G, Sampath S (2010) An experimental investigation on a DI diesel engine using waste plastic oil with exhaust gas recirculation. Fuel 89:1826–1832CrossRef
2.
Wongkhorsub C, Chindaprasert N (2013) A comparison of the use of pyrolysis oils in diesel engine. Energy and Power Eng 5:350–355
3.
Guntur R, Kumar D, Reddy V (2011) Experimental evaluation of a diesel engine with blends of diesel-plastic pyrolysis oil. Int J Eng Sci Technol 6:5033–5040
4.
Mani M, Nagarajan G, Sampath S (2011) Characterisation and effect of using waste plastic oil and diesel fuel blends in compression ignition engine. Energy 36:212–219CrossRef
5.
Kumar S, Singh RK (2011) Recovery of hydrocarbon liquid from waste high density polyethylene by thermal pyrolysis. Braz J Chem Eng 28(04):659–667CrossRef
6.
Kumar S, Prakash R, Murugan S, Singh R (2013) Performance and emission analysis of blends of waste plastic oil obtained by catalytic pyrolysis of waste HDPE with diesel in a CI engine. Energy Convers Manage 74:323–331CrossRef
7.
Mani M, Subash C, Nagarajan G (2009) Performance, emission and combustion characteristics of a DI diesel engine using waste plastic oil. Appl Therm Eng 29:2738–2744CrossRef
8.
Pratoomyod J, Laohalidanond K (2013) Performance and emission evaluation of blends of diesel fuel with waste plastic oil in a diesel engine. Int J Eng Sci Technol 2:57–63
9.
Consea JA, Font R, Marcilla A, Garcia AN (1994) Pyrolysis of polyethylene in a fluidized bed reactor. Energy Fuel 8:1238–1246CrossRef
10.
Panda AK, Singh RK (2011) Catalytic performances of kaoline and silica alumina in the thermal degradation of polypropylene. J Fuel Chem Technol 39(3):198–202CrossRef
11.
Park JW, Kim JH, Seo G (2002) The effect of pore shape on the catalytic performance of zeolites in the liquid-phase degradation of HPDE. Polym Degrad Stability 76(3):495–501CrossRef
12.
Frigo S, Seggiani M, Puccini M, Vitolo S (2014) Liquid fuel production from waste tyre pyrolysis and its utilisation in a diesel engine. Fuel 116:399–408CrossRef
13.
Murugan S, Ramaswamy M, Nagarajan G (2008) The use of tyre pyrolysis oil in diesel engines. Waste Manage 28:2743–2749CrossRef
14.
Kaimal VK, Vijayabalan P (2015) A detailed study of combustion characteristics of a di diesel engine using waste plastic oil and its blends. Energy Convers Manage 105:951–956CrossRef
15.
Heywood JB (1988) Internal combustion engine fundamentals. McGraw-Hill Inc
16.
Kidoguchi Y, Yang C, Kato R, Miwa K (2000) Effects of fuel cetane number and aromatics on combustion process and emissions of a direct-injection diesel engine. JSAE Rev 21:469–475CrossRef
17.
Semerjian H, Vranos A (1977) NOx formation in premixed turbulent flames. Symp (International) Combustion 16(1):166–179
18.
Greeves G, Khan IM, Wang CHT, Fenne I. Origins of hydrocarbons emissions from diesel engines. SAE Technical Paper (770259)
19.
Mendez S, Kashdan JT, Bruneaux G, Thirouard B, Vangraefschepe F. Formation of unburned hydrocarbons in low temperature diesel combustion. SAE Technical Paper (2009-01-2729)
Metadaten
Titel
Experimental Investigation on a Compression Ignition Engine with Blends of Plastic Oil and Diesel as Fuel
verfasst von
Manoj Kumar
J. M. Mallikarjuna
Copyright-Jahr
2021
Verlag
Springer Singapore
Buch
Advances in IC Engines and Combustion Technology

Print ISBN: 978-981-15-5995-2

Electronic ISBN: 978-981-15-5996-9

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-981-15-5996-9_7

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