Investigation of glycerol doping on ignition delay times and laminar burning velocities of gasoline and diesel fuel

Jach, A.; Cieślak, I.; Teodorczyk, A.

doi:10.19206/CE-2017-230

Artykuł - szczegóły

Tytuł artykułu

Investigation of glycerol doping on ignition delay times and laminar burning velocities of gasoline and diesel fuel

Autorzy

Jach A. , Cieślak I. , Teodorczyk A.

Treść / Zawartość

Pełne teksty:

jach_cieslak_teodorczyk_investigation_ce_2_2017.pdf

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Identyfikatory

DOI

10.19206/CE-2017-230

Warianty tytułu

Języki publikacji

Abstrakty

Glycerol is a major by-product of biodiesel production. Per one tone of produced biodiesel, one hundred kilograms of glycerol is produced. Production of glycerol is increasing due to increase of demand for biodiesel. One of methods of glycerol utilization is combustion. Recent experimental studies with use of a diesel engine and a constant volume combustion chamber show that utilization of glycerol as a fuel results in lower NOx emissions in exhaust gases. It combusts slower than light fuel oil, what is explained by higher viscosity and density of glycerol. Glycerol has low cetane number, so to make combustion in a diesel engine possible at least one of the following conditions need to be fulfilled: a pilot injection, high temperature or high compression ratio. The aim of the paper is to compare glycerol to diesel and to assess influence of glycerol doping on gasoline and diesel fuel in dependence of pressure, temperature and equivalence ratio. The subject of this study is analysis of basic properties of flammable mixtures, such as ignition delay times and laminar burning velocities of primary reference fuels (diesel: n-heptane and gasoline: iso-octane). Calculations are performed with use of Cantera tool in Matlab and Python environments. Analyses of influence of glycerol on ignition delay times of n-heptane/air and iso-octane/air mixtures covered wide range of conditions: temperatures from 600 to 1600 K, pressure 10-200 bar, equivalence ratio 0.3 to 14, molar fraction of glycerol in fuel 0-1 in air. Simulations of LBV in air cover temperatures: 300 K and 500 K, pressures: 10, 40, 100, 200 bar and equivalence ratio from 0.3 to 1.9. Physicochemical properties of gasoline, diesel and glycerol are compared.

Słowa kluczowe

glycerol ignition delay time laminar burning velocities Cantera gasoline diesel

gliceryna czas opóźnienia zapłonu prędkość laminowania benzyna diesel

Wydawca

Polskie Towarzystwo Naukowe Silników Spalinowych

Czasopismo

Combustion Engines

Rocznik

2017

Tom

R. 56, nr 2

Strony

167--175

Opis fizyczny

Bibliogr. 31 poz., wykr.

Twórcy

autor

Jach A.

AJach@itc.pw.edu.pl

Faculty of Power and Aeronautical Engineering at Warsaw University of Technology

autor

Cieślak I.

ICieslak@itc.pw.edu.pl

Faculty of Power and Aeronautical Engineering at Warsaw University of Technology

autor

Teodorczyk A.

ATeod@itc.pw.edu.pl

Faculty of Power and Aeronautical Engineering at Warsaw University of Technology

Bibliografia

[1] European Biofuels Technology Platform, Fatty Acid Methyl Esters (FAME). Biofuel Fact Sheet. 2011, 1, 1-2.
[2] MINER, C., DALTON, N.N. Glycerine: an overview. Chem Soc Monogr. 1953, 117(212), 1-27.
[3] SETYAWAN, H.Y., ZHU, M., ZHANG, Z., ZHANG, D. Ignition and combustion characteristics of single droplets of a crude glycerol in comparison with pure glycerol, petroleum diesel, biodiesel and ethanol. Energy. 2016, 113, 153-159.
[4] Rychlik A., Application of glycerine for powering piston diesel engines of large power. Combustion Engines. 2015, 162(3), 644-648, 2015.
[5] MCNEIL, J., DAY, P., SIROVSKI, F. Glycerine from biodiesel: the perfect diesel fuel. Process Saf. Environ. Prot. 2012, 90(3), 180-188.
[6] STELMASIAK, Z., PIETRAS, D. Utilization of waste glycerin to fuelling of spark ignition engines. IOP Conf. Ser. Mater. Sci. Eng. 2016, 148, 12087.
[7] GRAB-ROGALINSKI, K.. SZWAJA, S. The possibility of use a waste product of biofuels production-glycerol as a fuel to the compression ignition engine. J. KONES. 2016, 23(3), 157-164.
[8] EATON, S.J. et al. Formulation and combustion of glyceroldiesel fuel emulsions. Energy and Fuels. 2014, 28(6), 3940-3947.
[9] ARBAB, M.I., MASJUKI, H.H., VARMAN, M. et al. Fuel properties, engine performance and emission characteristic of common biodiesels as a renewable and sustainable source of fuel. Renew. Sustain. Energy Rev. 2013, 22, 133-147.
[10] KESLING, H.S., KARAS, L.J., LIOTTA, F.J. Diesel fuel. 1994.
[11] RANZI, E. et al. Chemical kinetics of biomass pyrolysis. Energy & Fuels. 2008, 22(6), 4292-4300.
[12] DUPONT, C. et al. Biomass pyrolysis: kinetic modelling and experimental validation under high temperature and flash heating rate conditions. J. Anal. Appl. Pyrolysis. 2009, 85(1-2), 260-267.
[13] CALONACI, M., GRANA, R., BARKER HEMINGS, E. et al. Comprehensive kinetic modeling study of bio-oil formation from fast pyrolysis of biomass. Energy & Fuels. 2010, 24(10), 5727-5734.
[14] HEMINGS, E.B., CAVALLOTTI, C., CUOCI, A. et al. A detailed kinetic study of pyrolysis and oxidation of glycerol (propane-1,2,3-triol). Combust. Sci. Technol. 2012, 184(7-8), 1164-1178.
[15] CORBETTA, M. et al. Pyrolysis of centimeter-scale woody biomass particles: kinetic modeling and experimental validation. Energy & Fuels. 2014, 28(6), 3884-3898.
[16] DEE, V., SHAW, B.D. Combustion of propanol–glycerol mixture droplets in reduced gravity. Int. J. Heat Mass Transf. 2004, 47(22), 4857-4867.
[17] RANZI, E. et al. Hierarchical and comparative kinetic modeling of laminar flame speeds of hydrocarbon and oxygenated fuels. Prog. Energy Combust. Sci. 2012, 38(4), 468-501.
[18] HARTMANN, M., GUSHTEROVA, I., FIKRI, M. et al. Auto-ignition of toluene-doped n-heptane and iso-octane/air mixtures: high-pressure shock-tube experiments and kinetics modeling. Combust. Flame. 2011, 158(1), 172-178.
[19] ZHANG, K. et al. An updated experimental and kinetic modeling study of n-heptane oxidation. Combust. Flame. 2016, 172, 116-135.
[20] GOODWIN, D.G., MOFFAT, H., SPETH, R.L. Cantera: an object-oriented software toolkit for chemical kinetics, thermodynamics, and transport processes. 2017.
[21] JERZEMBECK, S., PETERS, N., PEPIOT-DESJARDINS, P., PITSCH, H. Laminar burning velocities at high pressure for primary reference fuels and gasoline: experimental and numerical investigation. Combust. Flame. 2009, 156(2), 292-301.
[22] LIU, Y., JIA, M., XIE, M., PANG, B. Improvement on a skeletal chemical kinetic model of iso-octane for internal combustion engine by using a practical methodology. Fuel. 2013, 103, 884-891.
[23] BARABÁS, I., TODORUŢ, I.A. Predicting the temperature dependent viscosity of biodiesel-diesel-bioethanol blends. Energy and Fuels. 2011, 25(12), 5767-5774.
[24] KUMAR, P., KISHAN, P.A., DHAR, A. Numerical investigation of pressure and temperature influence on flame speed in CH4-H2 premixed combustion. Int. J. Hydrogen Energy. 2016, 41(22), 9644-9652.
[25] CHENG N.-S. Formula for the viscosity of a glycerol−water mixture. Ind. Eng. Chem. Res. 2008, 47(9), 3285-3288.
[26] GRAB-ROGALINSKI, K., SZWAJA, S. The combustion properties analysis of various liquid fuels based on crude oil and renewables. IOP Conf. Ser. Mater. Sci. Eng. 2016, 148, 12066.
[27] KANAVELI, I.-P., ATZEMI, M., LOIS, E. Predicting the viscosity of diesel/biodiesel blends. Fuel. 2017, 199, 248-263.
[28] STEIN, R.A. et al. Effect of heat of vaporization, chemical octane, and sensitivity on knock limit for ethanol – gasoline blends. SAE Int. J. Fuels Lubr. 2012, 5(2), 2012-01-1277.
[29] QUISPE, C.A.G., CORONADO, C.J.R., CARVALHO, J.A. Glycerol: production, consumption, prices, characterization and new trends in combustion. Renew. Sustain. Energy Rev. 2013, 27, 475-493.
[30] P. Information 3. Chemical and Physical Information 3.1, 1990.
[31] ALPTEKIN, E., CANAKCI, M. Characterization of the key fuel properties of methyl ester-diesel fuel blends. Fuel. 2009, 88(1), 75-80.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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