Use of detailed kinetic mechanism for the prediction of - - PowerPoint PPT Presentation

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

Use of detailed kinetic mechanism for the prediction of autoignitions

• F. Buda, P.A. Glaude, F. Battin-Leclerc

DCPR-CNRS, Nancy, France

• R. Porter, K.J. Hughes and J.F. Griffiths

School of Chemistry, University of Leeds, UK

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

PHENOMENA OBSERVED DURING THE REACTION BETWEEN HYDROCARBON AND OXYGEN

Cool flame Autoignition

Slow reaction

Pressure-temperature diagram in the case of 1,3-dioxan

H2C CH2 CH2 H2C

Static reactor

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

COOL FLAMES SINGLE DOUBLE

Measurement of pressure by a pressure transducer Measurement of temperature by a small thermocouple Rise below 100 °C

Formation of intermediate products (hydroperoxides)

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

PHENOMENA OBSERVED DURING THE REACTION BETWEEN HYDROCARBON AND OXYGEN

Cool flame Autoignition

Slow reaction

Pressure-temperature diagram in the case of 1,3-dioxan

H2C CH2 CH2 H2C

Static reactor

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

AUTOIGNITION

Starts like a cool flame, but does not stop Rise of temperature

• ver 500°C

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

Prevention of explosions during

• xidation processes

Prediction of the phenomena

• bserved during the
• xidation of hydrocarbons

Development of detailed chemical mechanisms for the oxidation and autoignition

• f hydrocarbons

by using an automatic generator

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

AUTOMATIC GENERATOR OF DETAILED MECHANISMS OF COMBUSTION

Primary Mechanism Generator

Reaction Model in a CHEMKIN II Format

Lumped Primary Molecules Free Radicals

Reactants

EXGAS

Kinetic Data Thermochemical Data

KINGAS

Thermochemical Data

Reaction Bases

C2-Molecules and Free Radicals

THERGAS Primary Mechanism Generator Reaction Bases Secondary Mechanism Generator Secondary Mechanism Generator THERGAS KINGAS

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

1- Initiation reactions

unimolecular initiations (ui) : ch3/ch2/ch2/ch3 2 •ch2/ch3 bimolecular initiations (bi) : ch3/ch2/ch2/ch3 + //(o)2

• o/oh + •ch(/ch3)/ch2/ch3

2- Propagation reactions

addition of free radicals on oxygen (adox) :

• ch(/ch3)/ch2/ch3 + //(o)2
• o/o/ch(/ch3)/ch2/ch3

isomerization of free radicals (is) :

• o/o/ch(/ch3)/ch2/ch3
• ch2/ch(/o/oh)/ch2/ch3

decomposition of free radicals by beta-scission (bs) :

• ch(/ch3)/ch2/ch3
• ch3 + ch3/ch//ch2

decomposition of free radicals to cycloethers (or) :

• ch2/ch(/o/oh/)ch2/ch3 c(#1)h(/ch2/ch3)/ch2/o/1 + •oh
• xidation of free radicals (ox) : •ch(/ch3)/ch2/ch3 + //(o)2 ch3/ch2/ch//ch2 + •o/oh

metathesis reactions (me) : ch3/ch2/ch2/ch3 + •oh oh2 + •ch2/ch2/ch2/ch3

3- Termination reactions

combination of free radicals (co) : •ch2/oh + •ch(/ch3)2 ch(/ch3)2/ch2/oh disproportionation of free radicals (dis) :

• o/o/ch(/ch3)2 + •o/oh ch3/ch(/o/oh)/ch3 + //(o)2

GENERIC ELEMENTARY REACTIONS IN THE PRIMARY MECHANISM OF AKKANES

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

STRUCTURE OF THE PRIMARY MECHANISM FOR ALKANES

Initial reactant

hydroperoxyalkene + •OOH

• xo - hydroperoxyalkane + •OH

hydroperoxy-cycloether + •OH di-hydroperoxyalkane + •R' di-hydroperoxyalkene + •OOH bs

O2 O2

adox

• OOR
• QOOH
• OOQOOH
• U(OOH)2

hydroperoxyalkane + •R' hydroperoxyalkene + O2 cyclic ether + •OH hydroperoxyalkane + •R' hydroperoxyalkene + •OOH

di-hydroperoxyalkane + •R' me dis

• x

me

• r

bs me

• r

bs me

conjugated olefin + •OOH aldehyde / ketone + •OH hydroperoxyalkene + •R' hydroperoxyalkene + •R'

• x

is is is is is is

O2 O2

adox bs

+ HO2 ui bi

• R'

me

conjugated olefin + •OOH

• R

+ O2

• lefin + •R'

bs

• x

is

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

KINETIC DATA OF THE PRIMARY MECHANISM OF LINEAR ALKANES AT HIGH TEMPERATURE

• Combust. Flame, 114:81 (1998) Ph. D. Thesis of P.A. Glaude (1999)

(k=AxTb x exp(-E/RT), Units : cm3, mol, s, kJ)

H-abstraction (per H atom) Primary H (i.e. R-CH3) Secondary H (i.e. R1-CH2-R2) lg A b E lg A b E Initiation with O2 112.6 205 12.00 201 Oxidation 11.37 20.9 11.90 20.9 H-atom abstraction by

• O•

13.23 32.8 13.11 21.7

• H

6.98 2 32.2 6.65 2 20.9

• OH

5.95 2 1.88 6.11 2

• 3.20
• CH3
• 1

4 34.3 11.0 39.8

• OOH

11.30 71.1 11.30 64.8 Other reactions lg A b E Addition of a free radical on O2 19.34

• 2.5

Beta-scission

to •CH3 + molecule

13.30 130.0

• f a free

to •R + molecule

13.30 120.0 radical

to •OOH + molecule

12.92 108.7

to •OH + molecule

9.00 31.3 Cyclic 3 members ring 12.00 69.0 ether 4 members ring 11.30 64.8 formation 5 members ring 10.77 37.6 6 members ring 10.00 25.1 Disproportionation of •OOR and

• OOH

11.30

• 5.43

Isomerizations and unimolecular initiations Calculated according to the methods proposed by S.W. Benson

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

Examples of predictions using detailed kinetic mechanisms generated by EXGAS

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

0.0 0.5 1.0 1.5 2.0 2.5 550 600 650 700 750 800 2-stage ignition

T / K % n-C4H10 by volume in air

slow reaction cool flame slow reaction single stage ignition

N-butane Prediction of a composition – temperature ignition diagram

mixture in air, at 0.2 MPa in a closed vessel 0.5 dm3 Color lines : Experiments (M.R. Chandraratna and J.F. Griffiths, 1994, Combust. Flame)

Simulations

Black lines : Simulations performed in Leeds with a mechanism generated in Nancy

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

N-butane Simulated two-stage ignition profile

1.45 % in air, at 0.2 MPa and 600 K

1.0 1.5 2.0 2.5 600 800 1000 1200 1400 1600

T / K t / s

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions Rapid compression machine of Lille (R. Minetti and M. Ribaucour)

N-heptane Modeling of the reaction in a rapid compression machine

Tafter compression = 706 K, Pafter compression = 3.2 bar, Φ = 1

1.2x10

6

1 0.8 0.6 0.4 Pressure (bar) 40x10

• 3

30 20 10 Residence time (s) 200x10

• 6

150 100 50 Mole fraction Ignition delay time Pressure OH mole fraction H2O2 mole fraction /2500

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

N-heptane Modeling the autoignition delay times in a shock tube (ST) and in a rapid compression machine (RCM)

ST : Ciezki H.K. and Adomeit G., 1993, Combust. Flame RCM : Minetti R., Carlier M., Ribaucour M., Therssen E. and L.R. Sochet, 1995, Combust. Flame

Points are experiments, lines simulations, Φ = 1

0.1 1 10 100 1000 Ignition delays times (ms) 1.4 1.2 1.0 0.8 1000/T (K) 3.2 bar : (RCM) (ST) 13.5 bar : (ST), 42 bar : (ST)

1000K 800K 700K

Negative temperature coefficient (NTC) region

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

N-decane Modeling the autoignition in a shock tube

Pfahl U., Fieweger K. and Adomeit, G., IDEA-EFFECT, Final Report, 1996

Points are experiments, lines simulations, Φ = 1

0.1 1 10 100 Ignition delay times (ms) 1.4 1.2 1.0 0.8 1000/T (K)

12 bar 50 bar

1000K 800K 700K NTC region displaced towards the higher temperatures when the pressure increases

5th International Symposium on Hazard Prevention and Mitigation of Industrial Explosions

Detailed chemical mechanisms for the oxidation and autoignition

• f alkanes

automatically generated

Semi quantitative prediction of the experimental conditions

• f the different oxidation phenomena (cool flame, ignition)

Quantitative modeling of autoignition delay times in given conditions Prediction of the formation of intermediate products