Restricted accessResearch articleFirst published online 2023-6
An experimental investigation into the combustion stability and emissions of an n-butanol/diesel blended fueled partially premixed compression ignition (PPCI) engine
Higher cyclic variability in internal combustion engines (ICE) increases driveability problems, specific fuel consumption, and exhaust emissions. Consequently, quantification of the combustion stability in different combustion parameters is essential for the design of closed-loop control for a partially premixed combustion (PPC). This research examines the impacts of a PPC strategy on the spectral features of IMEP combustion parameters for early, and late injection timings of a 4-cylinder CRDI engine using wavelet transforms (WT). Furthermore, operating points were optimized based on the combustion and emissions characteristics of the partially premixed compression ignition engine. Results indicated that the early start of injection (SOI) timing of 12° CA BTDC has a lower standard deviation in the time-series data of IMEP than the late SOI timing. Moreover, when the amount of n-butanol in diesel fuel was increased from 0% to 20% at a load of 2 bar BMEP, COVIMEP decreased from 3.1% to 2.75% at early SOI timing. The WT results reveal that the continuous strong intensity band pattern changes irregularly when the injection timing is advanced. It was also found that at lower cyclic variability conditions (SOI = 12°CA BTDC), CO and smoke emissions decreased, and there was a noticeable increase in NOx emissions.
KumarPSharmaMPDwivediG. Impact of ternary blends of biodiesel on diesel engine performance. Egypt J Pet2016; 25: 255–261.
2.
KumarPSandhuSSSinghM, et al. Potential assessment of methanol to reduce the emission in LTC mode diesel engine. In: AgarwalAKValeraHPexaMČedíkJ (eds) Methanol. Energy, environment, and sustainability. Singapore: Springer, 2021, pp. 271–292.
3.
KumarPSharmaMPDwivediG. Impact of biodiesel on combustion, performance and exhaust emissions of diesel engines. J Integr Sci Technol2014; 2: 57–63.
4.
SinghTSRajakUSamuelOD, et al. Optimization of performance and emission parameters of direct injection diesel engine fuelled with microalgae Spirulina (L.) – response surface methodology and full factorial method approach. Fuel2021; 285: 119103.
5.
KumarPSinghMSandhuSS. Wavelet analysis for cyclic combustion dynamics of a multi-cylinder CRDI diesel engine fuelled with a blending of argemone biodiesel–diesel oil. Chaos2022; 32: 043107.
6.
SinghASaxenaMRMauryaRK. Investigation of bifurcations in cyclic combustion dynamics of a CNG-diesel RCCI engine. Fuel2022; 320: 123871.
7.
TunerMJohanssonTAulinH, et al. Multi cylinder partially premixed combustion performance using commercial light-duty engine hardware. SAE technical paper 2014-01-2680, 2014. DOI: 10.4271/2014-01-2680.
8.
QiuLChengXLiuBDongSBaoZ. Partially premixed combustion based on different injection strategies in a light-duty diesel engine. Energy2016; 96: 155–165.
9.
KalghatgiGTHeadRA. Combustion limits and efficiency in a homogeneous charge compression ignition engine. Artic Int J Engine Res2006; 7: 215–236.
10.
El ShenawyEAElkelawyMBastawissiHAE, et al. Investigation and performance analysis of water-diesel emulsion for improvement of performance and emission characteristics of partially premixed charge compression ignition (PPCCI) diesel engines. Sustain Energy Technol Assess2019; 36: 100546.
11.
KumarPSingh SandhuS. An attempt to implement partially premixed combustion strategy in a multi-cylinder CRDI engine: A detailed experimental and wavelet transform analysis. Fuel2022; 323: 124372.
12.
KumarPSingh SandhuS. Impact analysis of partially premixed combustion strategy on the emissions of a compression ignition engine fueled with higher octane number fuels: A review. Mater Today Proc2021; 45: 5772–5777.
13.
DuraisamyGRangasamyMGovindanN. A comparative study on methanol/diesel and methanol/PODE dual fuel RCCI combustion in an automotive diesel engine. Renew Energy2020; 145: 542–556.
14.
NanthagopalKAshokBSaravananB, et al. Study on decanol and Calophyllum inophyllum biodiesel as ternary blends in CI engine. Fuel2019; 239: 862–873.
15.
AoyamaTHattoriYMizutaJ. An experimental study on premixed- charge compression ignition gasoline engine. Tech rep. SAE technical paper 960081, 1996.
16.
DimitrakopoulosNBelgiornoGTunerM, et al. PPC operation with low ron gasoline fuel. A study on load range on a euro 6 light duty diesel engine. In: COMODIA 2017 - 9th Int conf model diagnostics advanced engine syst, 2017. DOI: 10.1299/jmsesdm.2017.9.c308.
17.
SaxenaMRMauryaRK. Effect of diesel injection timing on peak pressure rise rate and combustion stability in RCCI Engine. SAE technical paper2018, pp.1–16.
18.
ZhangMHongWXieF, et al. Effects of diluents on cycle-by-cycle variations in a spark ignition engine fueled with methanol. Energy2019; 182: 1132–1140.
19.
ShamunSBelgiornoGDi BlasioG. Engine parameters assessment for alcohols fuels application in compression ignition engines. Energy Environ Sustain2020; 125–139.
20.
AjovalasitMGiacominJ. Analysis of variations in diesel engine idle vibration. Proc IMechE, Part D: J Automobile Engineering2003; 217: 921–933.
21.
YangLZareABodiscoTANabiNLiuZBrownRJ. Analysis of cycle-to-cycle variations in a common-rail compression ignition engine fuelled with diesel and biodiesel fuels. Fuel2021; 290: 120010.
22.
SenAKLongwicRLitakGGórskiK. Analysis of cycle-to-cycle pressure oscillations in a diesel engine. Mech Syst Signal Process2008; 22: 362–373.
23.
BoguśPMerkiszJ. Misfire detection of locomotive diesel engine by non-linear analysis. Mech Syst Signal Process2005; 19: 881–899.
24.
YangLPDingSLLitakGSongEZMaXZ. Identification and quantification analysis of nonlinear dynamics properties of combustion instability in a diesel engine. Chaos2015; 25: 013105.
25.
YangLPBodiscoTAZareAMarwanNChu-VanTBrownRJ. Analysis of the nonlinear dynamics of inter-cycle combustion variations in an ethanol fumigation-diesel dual-fuel engine. Nonlinear Dyn2019; 95: 2555–2574.
26.
MauryaRKAgarwalAK. Experimental study of combustion and emission characteristics of ethanol fuelled port injected homogeneous charge compression ignition (HCCI) combustion engine. Appl Energy2011; 88: 1169–1180.
27.
JinCYaoMLiuHLeeCFFJiJ. Progress in the production and application of n-butanol as a biofuel. Renew Sustain Energ Rev2011; 15: 4080–4106.
28.
AbdallaANAliOMAwadOITaoH. Wavelet analysis of an SI engine cycle-to-cycle variations fuelled with the blending of gasoline -fusel oil at a various water content. Energy Convers Manag2019; 183: 746–752.
29.
YusriIMMamatRAkasyahMKJamlosMFYusopAF. Evaluation of engine combustion and exhaust emissions characteristics using diesel/butanol blended fuel. Appl Therm Eng2019; 156: 209–219.
30.
SaxenaMRMauryaRK. Combustion instability analysis of dual-fuel stationary compression ignition engine using statistical method and wavelet transform. SAE technical paper, 2022.
31.
QiG. Wavelet-based AE characterization of composite materials. NDT E Int2000; 33: 133–144.
32.
OrdAHobbsBDeringGGessnerK. Nonlinear analysis of natural folds using wavelet transforms and recurrence plots. Philos Trans R Soc A Math Phys Eng Sci2018; 376: 20170257.
33.
SharmaPSharmaAK. Statistical and continuous wavelet transformation-based analysis of combustion instabilities in a biodiesel-fueled compression ignition engine. J Energy Resour Technol2022; 144: 032304.
34.
TorrenceCCompoGP. A Practical Guide to Wavelet Analysis. Bull Am Meteorol Soc1998; 79: 61–78.
35.
SolakaHAronssonUTunerM, et al. Investigation of partially premixed combustion characteristics in low load range with regards to fuel octane number in a light-duty diesel engine. SAE technical paper, 2012. DOI: 10.4271/2012-01-0684.
36.
LiJYuWYangW. Evaluating performance and emissions of a CI engine fueled with n-octanol/diesel and n-butanol/diesel blends under different injection strategies. Fuel2021; 284: 119085.
37.
ChengXLiSYangJLiuB. Investigation into partially premixed combustion fueled with N-butanol-diesel blends. Renew Energy2016; 86: 723–732.
38.
LiuBChengXLiuJ, et al. Combustion and particulate matter emission characteristics for diesel engine run by partially-premixed low-temperature combustion mode. SAE technical paper, 2017. DOI: 10.4271/2017-01-2398.
39.
KitamuraTItoTSendaJFujimotoH. Mechanism of smokeless diesel combustion with oxygenated fuels based on the dependence of the equivalence ration and temperature on soot particle formation. Int J Engine Res2002; 3: 223–248.
40.
Rajesh KumarBSaravananS. Effects of iso-butanol/diesel and n-pentanol/diesel blends on performance and emissions of a di diesel engine under premixed LTC (low temperature combustion) mode. Fuel2016; 170: 49–59.
41.
AshokBNanthagopalKAnandVAravindKMJeevananthamAKBalusamyS. Effects of n-octanol as a fuel blend with biodiesel on diesel engine characteristics. Fuel2019; 235: 363–373.
42.
Susanth KishnaRNanthagopalKAshokBSrinathRPranava KumarMBhowmickP. Investigation on pilot injection with low temperature combustion of Calophyllum inophyllum biodiesel fuel in common rail direct injection diesel engine. Fuel2019; 258: 116144.
43.
ShahbakhtiMKochCR. Characterizing the cyclic variability of ignition timing in a homogeneous charge compression ignition engine fuelled with n-heptane/iso-octane blend fuels. Int J Engine Res2008; 9: 361–397.
44.
AliOMMamatRMasjukiHHAbdullahAA. Analysis of blended fuel properties and cycle-to-cycle variation in a diesel engine with a diethyl ether additive. Energy Convers Manage2016; 108: 511–519.
45.
SenAKLitakGEdwardsKDFinneyCEDawCSWagnerRM. Characteristics of cyclic heat release variability in the transition from spark ignition to HCCI in a gasoline engine. Appl Energy2011; 88: 1649–1655.
46.
SenAKLitakGTaccaniRRaduR. Wavelet analysis of cycle-to-cycle pressure variations in an internal combustion engine. Chaos Solitons Fractals2008; 38: 886–893.
47.
YasinMHMMamatRAliOM, et al. Study of diesel-biodiesel fuel properties and wavelet analysis on cyclic variations in a diesel engine. Energy Proc2017; 110: 498–503.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
