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Abstract

In the present work, computational fluid dynamics (CFD) simulations of a single-cylinder gasoline compression ignition (GCI) engine are performed to investigate the impact of gasoline-ethanol blending on autoignition, nitrogen oxide (NO_x), and soot emissions under low-load conditions. In order to represent the test gasoline (RD5-87), a four-component toluene primary reference fuel (TPRF)+ethanol (ETPRF) surrogate (with 10% ethanol by volume; E10) is employed. A three-dimensional (3D) engine CFD model employing finite-rate chemistry with a skeletal kinetic mechanism (including NO_x sub-mechanism), adaptive mesh refinement (AMR), and hybrid method of moments (HMOM) is adopted to capture the in-cylinder combustion phenomena and soot/NO_x emissions. The engine CFD model is validated against experimental data for three gasoline-ethanol blends: E10, E30 and E100, with varying ethanol content by volume. Model validation is carried out for a broad range of start-of-injection (SOI) timings (−21, −27, −36, and −45 crank angle degrees (°CA) after top-dead-center (aTDC)) with respect to in-cylinder pressure, heat release rate, combustion phasing, NO_x and soot emissions. For relatively later injection timings (−21 and −27 °CA aTDC), E30 yields higher amount of soot than E10; while the trend reverses for early injection cases (−36 and −45 °CA aTDC ). On the other hand, E100 yields the lowest amount of soot among all fuels irrespective of SOI timing. Further, E10 shows a non-monotonic trend in soot emissions with SOI timing: SOI-36>SOI-45>SOI-21>SOI-27, while soot emissions from E30 exhibit monotonic decrease with advancing SOI timing. NOx emissions from various fuels follow a trend of E10>E30>E100. On the other hand, NO_x emissions increase as SOI timing is advanced for all fuels, with an anomaly for E10 and E100 where NO_x decreases when SOI is advanced beyond −36 °CA aTDC. Detailed analysis of the numerical results is performed to investigate the soot/NO_x emission trends and elucidate the impact of chemical composition and physical properties on autoignition and emissions characteristics.

Keywords

Gasoline-ethanol blends soot-NOx emissions gasoline compression ignition mixture stratification computational fluid dynamics

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References

bp Energy outlook, 2023 edition –www.bp.com.

Paz

Staaden

Kokjohn

. Gasoline compression ignition operation of a heavy-duty engine at high load. SAE Technical Paper.

Yun

Reitz

. Numerical parametric study of diesel engine operation with gasoline. Combust Sci Technol 2009; 181(2): 350–378.

Sellnau

Sinnamon

Hoyer

Husted

. Gasoline direct injection compression ignition (GDCI) - diesel-like efficiency with low CO2 emissions. SAE Int J Engines 2011; 4(1): 2010–2022.

Aggarwal

Wijeyakulasuriya

. Effects of fuel reactivity and injection timing on diesel engine combustion and emissions. Int J Green Energy 2016; 13(5): 431–445.

Kolodziej

Kodavasal

Ciatti

Som

Shidore

Delhom

. Achieving stable engine operation of gasoline compression ignition using 87 AKI gasoline down to idle. SAE Technical Paper, 14 April 2015.

Kodavasal

Kolodziej

Ciatti

Som

. Computational fluid dynamics simulation of gasoline compression ignition. J Energy Resour Technol 2015; 137(3): 032212.

Kolodziej

Ciatti

Vuilleumier

Adhikary

Reitz

. Extension of the lower load limit of gasoline compression ignition with 87 AKI gasoline by injection timing and pressure. SAE Technical Paper, 1 April 2014.

Loeper

Andrie

, et al. Gasoline DICI engine operation in the LTC regime using Triple- Pulse Injection. SAE Int J Engines 2012; 5(3): 1109–1132.

10.

Pal

Probst

Pei

, et al. Numerical investigation of a gasoline-like fuel in a heavy-duty compression ignition engine using global sensitivity analysis. SAE Int J Fuel Lubricants 2017; 10(1): 56–68.

11.

Dempsey

Seiler

Svensson

. A comprehensive evaluation of diesel engine CFD modeling predictions using a semi-empirical soot model over a broad range of combustion systems. SAE Int J Engines 2018; 11(6): 1399–1420.

12.

Roberts

Chuahy

FDF

Kokjohn

Roy

. Isolation of the parametric effects of pre-blended fuel on low load gasoline compression ignition (GCI). Fuel 2019; 237: 522–535.

13.

Voice

Kumar

Zhang

. Effect of fuel reactivity on ignitability and combustion phasing in a heavy-duty engine simulation for mixing-controlled and partially-premixed combustion. In: International combustion engine division fall technical conference, 9 October 2016, vol. 50503, p.V001T02A006. American Society of Mechanical Engineers.

14.

Manente

Johansson

Tunestal

. Partially premixed combustion at high load using gasoline and ethanol, a comparison with diesel. SAE Technical Paper, 20 April 2009.

15.

Manente

Zander

Johansson

Tunestal

Cannella

. An advanced internal combustion engine concept for low emissions and high efficiency from idle to max load using gasoline partially premixed combustion. SAE Technical Paper, 25 October 2010.

16.

Zhang

Voice

Pei

Traver

Cleary

. A computational investigation of fuel chemical and physical properties effects on gasoline compression ignition in a heavy-duty diesel engine. J Energy Resour Technol 2018; 140(10): 102202.

17.

Weall

Collings

. Gasoline fuelled partially premixed compression ignition in a light duty multi cylinder engine: a study of low load and low speed operation. SAE Int J Engines 2009; 2(1): 1574–1586.

18.

Vallinayagam

Hlaing

AlRamadan

, et al. The physical and chemical effects of fuel on gasoline compression ignition. SAE Technical Paper, 2 April 2019.

19.

Kalvakala

Pal

Gonzalez

, et al. Numerical analysis of soot emissions from gasoline-ethanol and gasoline-butanol blends under gasoline compression ignition conditions. Fuel 2022; 319: 123740.

20.

Wang

Shuai

Wang

. Extension of the lower load limit in dieseline compression ignition mode. Energy Proc 2015; 75: 2363–2370.

21.

Jia

Wang

Tong

Wang

Zheng

Yao

. Experimental and numerical studies on three gasoline surrogates applied in gasoline compression ignition (GCI) mode. Appl Energy 2017; 192: 59–70.

22.

Putrasari

Lim

. A review of gasoline compression ignition: a promising technology potentially fueled with mixtures of gasoline and biodiesel to meet future engine efficiency and emission targets. Energies 2019; 12(2): 238.

23.

Fan

Duan

Liu

Han

. Effects of butanol blending on spray auto-ignition of gasoline surrogate fuels. Fuel 2020; 260: 116368.

24.

Zhou

Boot

De Goey

. Gasoline—ignition improver—oxygenate blends as fuels for advanced compression ignition combustion. SAE Technical Paper. Warrendale, PA, USA: SAE International, 2013

25.

Liu

Hua

Lee

Wang

. Experimental and kinetic investigation on soot formation of n-butanol-gasoline blends in laminar coflow diffusion flames. Fuel 2018; 213: 195–205.

26.

Inal

Senkan

. Effects of oxygenate additives on polycyclic aromatic hydrocarbons(PAHs) and soot formation. Combust Sci Technol 2002; 174(9): 1–19.

27.

Khosousi

Liu

Dworkin

, et al. Experimental and numerical study of soot formation in laminar coflow diffusion flames of gasoline/ethanol blends. Combust Flame 2015; 162(10): 3925–3933.

28.

Shao

Wang

Atef

, et al. Polycyclic aromatic hydrocarbons in pyrolysis of gasoline surrogates (n-heptane/iso-octane/toluene). Proc Combust Inst 2019; 37(1): 993–1001.

29.

Huang

Zhou

Liu

Wang

. An experimental study on the combustion and emission characteristics of a diesel engine under low temperature combustion of diesel/gasoline/n-butanol blends. Appl Energy 2016; 170: 219–231.

30.

Kalvakala

Pal

Kukkadapu

McNenly

Aggarwal

. Numerical study of PAHs and soot emissions from gasoline–methanol, gasoline–ethanol, and gasoline–n-butanol blend surrogates. Energy Fuels 2022; 36(13): 7052–7064.

31.

Kalvakala

. Effect of gasoline surrogate composition and properties on engine knock and soot emissions. Doctoral Dissertation, University of Illinois at Chicago. https://doi.org/10.25417/uic.20253768.v1.

32.

Canakci

Ozsezen

Alptekin

Eyidogan

. Impact of alcohol–gasoline fuel blends on the exhaust emission of an SI engine. Renew Energy 2013; 52: 111–117.

33.

Noh

. Effect of bioethanol on combustion and emissions in advanced CI engines: HCCI, PPC and GCI mode – a review. Appl Energy 2017; 208: 782–802.

34.

Kalvakala

Pal

Aggarwal

. Effects of fuel composition and octane sensitivity on polycyclic aromatic hydrocarbon and soot emissions of gasoline–ethanol blend surrogates. Combust Flame 2020; 221: 476–486.

35.

Woo

Kook

Hawkes

. Effect of intake air temperature and common-rail pressure on ethanol combustion in a single-cylinder light-duty diesel engine. Fuel 2016; 180: 9–19.

36.

Matti Maricq

. Soot formation in ethanol/gasoline fuel blend diffusion flames. Combust Flame 2012; 159(1): 170–180.

37.

Hua

Liu

Qiu

Qian

Meng

. Numerical study of particle dynamics in laminar diffusion flames of gasoline blended with different alcohols. Fuel 2019; 257: 116065.

38.

Pal

Kalvakala

, et al. Numerical investigation of a central fuel property hypothesis under boosted spark-ignition conditions. J Energy Resour Technol 2021; 143(3): 032305.

39.

Pal

Ren

, et al. Numerical investigation of fuel property effects on mixed-mode combustion in a spark-ignition engine. J Energy Resour Technol 2021; 143(4): 042306.

40.

Heywood

. Internal combustion engine fundamentals. New York: McGrawHill, Inc, 1988.

41.

Linstrom

Mallard

(eds.) NIST chemistry webbook, NIST standard reference database number 69. National Institute of Standards and Technology, Gaithersburg, MD.

42.

AlRamadan

Sarathy

Khurshid

Badra

. A blending rule for octane numbers of PRFs and TPRFs with ethanol. Fuel 2016; 180: 175–186.

43.

Hoth

Manchiraju

Andretti

Sinur

Kolodziej

. Towards developing an unleaded high octane test procedure (RON>100) using toluene standardization fuels (TSF). SAE Int J Adv Curr Pr Mobil 2020; 3(1): 197–207.

44.

Catania

Ferrari

Manno

Spessa

. Experimental investigation of dynamics effects on multiple-injection common rail system performance. J Eng Gas Turbine Power 2008; 130(3): 032806.

45.

Adhikary

Reitz

Ciatti

. Study of in-cylinder combustion and multi-cylinder light duty compression ignition engine performance using different RON fuels at light load conditions. SAE Technical Paper, 8 April 2013.

46.

Redlich

Kwong

JNS

. On the thermodynamics of solutions. V. An equation of state. Fugacities of gaseous solutions. Chem Rev 1949; 44(1): 233–244.

47.

CONVERGE 3.0 Theory Manual, Convergent Science Inc., Middleton, WI, 2016.

48.

Han

Reitz

. Turbulence modeling of internal combustion engines using RNG κ-ε models. Combust Sci Technol 1995; 106(4-6): 267–295.

49.

Han

Reitz

. A temperature wall function formulation for variable-density turbulent flows with application to engine convective heat transfer modeling. Int J Heat Mass Transf 1997; 40(3): 613–625.

50.

Reitz

Diwakar

. Structure of high-pressure fuel sprays. SAE Trans 1987; 96: 492–509.

51.

Patterson

Reitz

. Modeling the effects of fuel spray characteristics on diesel engine combustion and emission. SAE Trans 1998; 107: 27–43.

52.

O’Rourke

Amsden

. A spray/wall interaction submodel for the KIVA-3 wall film model. SAE Trans 2000; 109: 281–298.

53.

Kazakov

Frenklach

. Dynamic modeling of soot particle coagulation and aggregation: implementation with the method of moments and application to high-pressure laminar premixed flames. Combust Flame 1998; 114(3-4): 484–501.

54.

Kalvakala

Pal

, et al. Numerical analysis of fuel effects on advanced compression ignition using a cooperative fuel research engine computational fluid dynamics model. J Energy Resour Technol 2021; 143(10): 102304.

55.

CHEMKIN-PRO 15141, Reaction Design, San Diego, 2015.

56.

Badra

Viollet

Elwardany

Chang

. Physical and chemical effects of low octane gasoline fuels on compression ignition combustion. Appl Energy 2016; 183: 1197–1208.

57.

Agarwal

Srivastava

Dhar

Maurya

Shukla

Singh

. Effect of fuel injection timing and pressure on combustion, emissions and performance characteristics of a single cylinder diesel engine. Fuel 2013; 111: 374–383.

58.

Zhang

Qiao

Miao

Hong

Zheng

. Effects of highly dispersed spray nozzle on fuel injection characteristics and emissions of heavy-duty diesel engine. Fuel 2012; 102: 666–673.

59.

Sayin

Canakci

. Effects of injection timing on the engine performance and exhaust emissions of a dual-fuel diesel engine. Energy Convers Manag 2009; 50(1): 203–213.

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Computational study on the impact of gasoline-ethanol blending on autoignition and soot/NO x emissions under low-load gasoline compression ignition conditions

Abstract

Keywords

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