Oxygen-Containing Contaminants and Steam Cracking: Understanding their Impact Using COILSIM1D

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Muñoz G. 2, Marko R. Djokic 1, Kevin M. Van Geem 1, Guy B.

1 Oxygen-Containing Contaminants and Steam Cracking: Understanding their Impact Using COILSIM1D Ismaël Amghizar 1, Andrés E. Muñoz G. 2, Marko R. Djokic 1, Kevin M. Van Geem 1, Guy B. Marin 1 1 Laboratory for Chemical Technology, Ghent University AVGI AIChE Spring Meeting 29 th Ethylene Producers Conference San Antonio - TX, USA, March 27 th,

2 Steam Cracking Steam Cracker 2

3 Oxygen containing compounds Typical contaminants in the feed Bio based species 3

4 Steam Cracking Furnace Steam drum Quench Oil Tower Strippers Quench Water Tower Dilution Steam Generator Compressors Caustic Tower Dryers 28 C HP Steam 1.4 bar Methanol Acids Formaldehyde CO/CO 2 Gum formation Light Naphtha BF Water Dilution Steam Wash Water Caustic 38 C 14.5 bar Waste Water 10 C 13.5 bar Spent Caustic PFO Pygas HP depropanizer LP depropanizer demethanizer deethanizer C2 slpitter C3 slpitter debutanizer To Hydrogen recovery 65 C 38 bar Methane to cold box -98 C 11.8 bar 8.5 bar -37 C 36 bar 13 C -99 C -38 C -38 C propylene 32 bar 16 bar -77 C C4's 35 bar 4 bar -38 C 32 bar Quench water Ethylene Quench water 56 C steam 71 C Quench water 20 C -5 C 40 C propane 85 C C5's K. M. Van Geem, G. B. Marin, N. Hedebouin, J. Grootjans, Energy efficiency of the cold train of anethylene cracker, Oil Gas-European Magazine 34 (2008)

5 Outline Introduction Reactor and kinetic model Simulations and Results Conclusions 5

mixture The solution: COILSIM1D Detailed Chemistry 1D

6 Modeling The challenge: Complex chemistry Large number of species Large number of reactions Reactor model Unknown mixture The solution: COILSIM1D Detailed Chemistry 1D reactor model Feed reconstruction Reasonable computational times 6

7 Key elements of COILSIM1D SIMCO Furnace CRACKSIM 7

8 COILSIM1D Kinetic model 1D reactor model Broadest kinetic model for steam cracking o o o 720+ molecules 43 radicals 300,000+ reactions Based on high level Ab initio data, and validated (pilot and industrial) 8

9 CRACKSIM Free radical mechanism 3 main reaction families: 1. C C and C H scission of molecules and reverse radical radical recombination R 1 R 2 R 1 + R 2 2. H abstraction reactions (intra- and intermolecular) R 1 H + R 2 R 1 + R 2 H 3. Radical addition to olefins and reverse β-scission of radicals, both intra- and intermolecular R 1 + R 2 R 3 R 1 R 2 R 3 9

10 CRACKSIM Assumption for accurate network of manageable size μ-hypothesis: bimolecular reactions can be neglected for certain radicals (C 6+ ) PSSA for large radical species Kinetic model consists of two parts: β-network: network with elementary reactions of C 5- radicals μ-network: describes the thermal decomposition of large molecules 10

11 PRIM-O k 1 k 2 k 3 k 4 k 5 k 6 k 7 De Bruycker, R. Production of green base chemicals through conventional and emerging pyrolysis processes. Ghent University,

12 Inclusion of oxygenates Introduction of new species and radicals which can interact with hydrocarbon matrix + 12

13 Ethylene Producers Conference, San Antonio - TX, Mar 27 th 2017 Validation Pilot plant of LCT - UGent Fire-heated Furnace Reactor: 12.8 m long 7 independently heated cells Online analytics: Permanent Gas Analyzer Refinery Gas Analyzer Detailed HC Analyzer GCxGC-FID/TOF-MS Light Oxygenates Analyzer CO / CO 2 detector 13

14 Outline Introduction Reactor and kinetic model Simulations and Results Conclusions 14

15 Simulation cases Two contaminants: Methanol DME Two illustrative cases: 15

16 Naphtha composition Reconstructed from commercial indices using SIMCO Simulation cases Commercial indices of the naphtha feed Specific density [kg/m³] Reconstructed feed ASTM D86 [ C] IBP 39 50% 99 FBP 165 PIONA [wt%] Paraffins 36.5 Iso-paraffins 32.8 Olefins 0.0 Naphthenes 21.4 Aromatics

17 Results: Case I CH 3 OH H 2 CH 4 C 2 H 4 C 3 H 6 C 4 H 6 CO CO 2 CH 2 O 17

18 Results: Case II DME H 2 CH 4 C 2 H 4 C 3 H 6 C 4 H 6 CO CO 2 CH 2 O 18

19 Validation Simulated vs experimental data Temperatures: C Conc. Oxygenates: 0 2 wt% 19

20 Outline Introduction Reactor and kinetic modeling Simulations and Results Conclusions 20

21 Wrapping up CRACKSIM has been extended with the thermal decomposition of oxygenates COILSIM1D can explicitly account for the effect of oxygenates on reactor outlet yields Presence of oxygen compounds in the feed negatively impact the yields of valuable products 21

22 Wrapping up The simulated cases (methanol and DME) showed an increased yield of CO, CO 2 and formaldehyde, compared to pure HC feed Validation with pilot plant experiments showed good agreement of the model for a broad range of conditions 22

23 Acknowledgements The Long Term Structural Methusalem Funding 23

24 Questions 24

25 Oxygen-Containing Contaminants and Steam Cracking: Understanding their Impact Using COILSIM1D Ismaël Amghizar 1, Andrés E. Muñoz G. 2, Marko R. Djokic 1, Kevin M. Van Geem 1, Guy B. Marin 1 1 Laboratory for Chemical Technology, Ghent University AVGI AIChE Spring Meeting 29 th Ethylene Producers Conference San Antonio - TX, USA, March 27 th,

Full Furnace Simulations and Optimization with COILSIM1D

Full Furnace Simulations and Optimization with COILSIM1D Kevin M. Van Geem 1 Alexander J. Vervust 1 Ismaël Amghizar 1 Andrés E. Muñoz G. 2 Guy B. Marin 1 1 Laboratory for Chemical Technology, Ghent University