Abstract

Decarbonizing highly energy-intensive industrial processes is imperative if nations are to comply with anthropogenic greenhouse gas emissions targets by 2050. This is a significant challenge for high-temperature industrial processes, such as hydrocarbon cracking, and there have been limited developments thus far. The novel concept presented in this study aims to replace the radiant section of a hydrocarbon cracking plant with a novel turboreactor. This is one of the first major and potentially successful attempts at decarbonizing the petrochemical industry. Rather than using heat from the combustion of natural gas, the novel turboreactor can be driven by an electric motor powered by renewable electricity. Switching the fundamental energy transfer mechanism from surface heat exchange to mechanical energy transfer significantly increases the exergy efficiency of the process. Theoretical analysis and numerical simulations show that the ultrahigh aerodynamic loading rotor is able to impart substantial mechanical energy into the feedstock without excess temperature difference and metal temperature magnitude. A complex shockwave system then transforms the kinetic energy into internal energy over an extremely short distance. The version of the turboreactor developed and presented in this study uses a single rotor row, in which a multistage environment is achieved regeneratively by guiding the flow through a toroidal-shaped vaneless space. This configuration leads to a reduction in reactor volume by more than two orders of magnitude compared with a conventional furnace. A significantly lower wall surface temperature, supersonic gas velocities, and a shorter primary gas path enable a controlled reduction in the residence time for chemical reactions, which optimizes the yield. For the same reasons, the conditions for coke deposition on the turboreactor surfaces are unfavorable, leading to an increase in plant availability. This study demonstrates that the mechanical work input into the feedstock can be dissipated through an intense turbulent mixing process, which maintains an ideal and controlled pressure level for cracking.

Issue Section:
Research Papers
Topics:
Coke, Cracking (Materials), Energy transformation, Flow (Dynamics), Fracture (Process), Furnaces, Pressure, Rotors, Temperature, Turbulence, Chemical reactions, Turbomachinery, Heating, Design, Enthalpy, Steam, Feedstock

References

1.
Neelis
,
M.
,
Patel
,
M.
,
Blok
,
K.
,
Haije
,
W.
, and
Bach
,
P.
,
2007
, “
Approximation of Theoretical Energy-Saving Potentials for the Petrochemical Industry Using Energy Balances for 68 Key Processes
,”
Energy
,
32
(
7
), pp.
1104
1123
.10.1016/j.energy.2006.08.005
Google Scholar
Crossref
Search ADS
 
2.
International Energy Agency (IEA)
,
2013
, “
Technology Roadmap—Energy and GHG Reductions in the Chemical Industry Via Catalytic Processes
,” IEA, Paris, France.
3.
Yuan
,
B.
,
Zhang
,
Y.
,
Du
,
W.
,
Wang
,
M.
, and
Qian
,
F.
,
2019
, “
Assessment of Energy Saving Potential of an Industrial Ethylene Cracking Furnace Using Advanced Exergy Analysis
,”
Appl. Energy
,
254
, p.
113583
.10.1016/j.apenergy.2019.113583
Google Scholar
Crossref
Search ADS
 
4.
European Commission
,
2011
, “
A Roadmap for Moving to a Competitive Low Carbon Economy in 2050
,” Com
112
, European Commission, Brussels, Belgium.https://www.eea.europa.eu/policydocuments/com-2011-112-a-roadmap
5.
Linde Endineering
,
2020
, “
Linde Industrial Steam Cracking Furnace Model
,” Linde Endineering, Dublin, Ireland, accessed Oct. 15, 2020, https://www.linde-engineering.com/en/index.html
6.
Zimmermann
,
H.
, and
Walzl
,
R.
,
2000
, “
Ethylene
,”
Ullmann's Encyclopedia of Industrial Chemistry
, Wiley, Hoboken, NJ.https://onlinelibrary.wiley.com/doi/10.1002/14356007.a10_045.pub3
7.
Van Goethem
,
M. W. M.
,
2010
, “
Next Generation Steam Cracking Reactor Concept
,” Ph.D. thesis,
Delft University of Technology
, Delft, The Netherlands.
8.
Chauvel
,
A.
, and
Lefebvre
,
G.
,
2001
,
Petrochemical Processes (Volume 1: Synthesis-Gas Derivatives and Major Hydrocarbons)
,
Ophrys Editions
, Paris, France.
9.
Jambor
,
B.
, and
Hájeková
,
E.
,
2015
, “
Formation of Coke Deposits and Coke Inhibition Methods During Steam Cracking
,”
Pet. Coal.
,
57
(
2
), pp.
143
153
.
10.
Van Geem
,
K. M.
,
Heynderickx
,
G. J.
, and
Marin
,
G. B.
,
2004
, “
Effect of Radial Temperature Profiles on Yields in Steam Cracking
,”
AIChE J.
,
50
(
1
), pp.
173
183
.10.1002/aic.10016
Google Scholar
Crossref
Search ADS
 
11.
Symoens
,
S. H.
,
Olahova
,
N.
,
Munoz Gandarillas
,
A. E.
,
Karimi
,
H.
,
Djokic
,
M. R.
,
Reyniers
,
M.-F.
,
Marin
,
G. B.
, and
Van Geem
,
K. M.
,
2018
, “
State-of-the-Art of Coke Formation During Steam Cracking Anti-Coking Surface Technologies
,”
Ind. Eng. Chem. Res.
,
57
(
48
), pp.
16117
16136
.10.1021/acs.iecr.8b03221
Google Scholar
Crossref
Search ADS
 
12.
Coolbrook Oy
,
2020
, “Coolbrook Oy,” Coolbrook Oy, Helsinki, Finland, accessed Oct. 15, 2020, https://coolbrook.com
13.
Bushuev
,
V. A.
,
2007
, “
Process for Producing Low-Molecular Olefins by Pyrolysis of Hydrocarbons
,” U.S. Patent Application No. 7232937B2.
14.
Sixsmith
,
H.
, and
Altmann
,
H.
,
1977
, “
A Regenerative Compressor
,”
ASME J. Eng. Ind.
,
99
(
3
), pp.
637
647
.10.1115/1.3439291
Google Scholar
Crossref
Search ADS
 
15.
Gao
,
G.-Y.
,
Wang
,
M.
,
Ramshaw
,
C.
,
Li
,
X.-G.
, and
Yeung
,
H.
,
2009
, “
Optimal Operation of Tubular Reactors for Naphtha Cracking by Numerical Simulation
,”
Asia-Pacific J. Chem. Eng.
,
4
(
6
), pp.
885
892
.10.1002/apj.351
Google Scholar
Crossref
Search ADS
 
16.
Denton
,
J. D.
,
1983
, “
An Improved Time Marching Method for Turbomachinery Flow Calculation
,”
ASME J. Eng. Power
, 105(3), pp. 514–521.10.1115/1.3227444
Google Scholar
Crossref
Search ADS
 
17.
Denton
,
J. D.
,
1986
, “
The Use of a Distributed Body Force to Simulate Viscous Effects in 3D Flow Calculations
,”
ASME
Paper No. 86-GT-144.10.1115/86-GT-144
Google Scholar
Crossref
Search ADS
 
18.
Denton
,
J. D.
,
1992
, “
The Calculation of Three-Dimensional Viscous Flow Through Multistage Turbomachines
,”
ASME J. Turbomach.
,
114
(
1
), pp.
18
26
.10.1115/1.2927983
Google Scholar
Crossref
Search ADS
 
19.
Klostermeier
,
C.
,
2008
, “
Investigation Into the Capability of Large Eddy Simulation for Turbomachinery Design
,” Ph.D. thesis,
University of Cambridge
, Cambridge, UK.
20.
Rosic
,
B.
,
Denton
,
J. D.
, and
Pullan
,
G.
,
2006
, “
The Importance of Shroud Leakage Modeling in Multistage Turbine Flow Calculations
,”
ASME J. Turbomach.
,
128
(
4
), pp.
699
707
.10.1115/1.2181999
Google Scholar
Crossref
Search ADS
 
21.
Jeong
,
J.
, and
Hussain
,
F.
,
1995
, “
On the Identification of a Vortex
,”
J. Fluid Mech.
,
285
, pp.
69
94
.10.1017/S0022112095000462
Google Scholar
Crossref
Search ADS
 
22.
Bai
,
D.
,
Zong
,
Y.
,
Zhou
,
M.
, and
Zhao
,
L.
,
2020
, “
Turbulent Mixing Enhancement of Thermal Cracking Coil by Hollow Cross Disk Internal
,”
Chem. Eng. Process.-Process Intensif.
,
147
, p.
107726
.10.1016/j.cep.2019.107726
Google Scholar
Crossref
Search ADS
 
23.
Schietekat
,
C. M.
,
Van Cauwenberge
,
D. J.
,
Van Geem
,
K. M.
, and
Marin
,
G. B.
,
2014
, “
Computational Fluid Dynamics-Based Design of Finned Steam Cracking Reactors
,”
AIChE J.
,
60
(
2
), pp.
794
808
.10.1002/aic.14326
Google Scholar
Crossref
Search ADS
 
24.
Schlichting
,
H.
, and
Gersten
,
K.
,
2016
,
Boundary-Layer Theory
,
Springer
, Berlin.
Copyright © 2022 by ASME
You do not currently have access to this content.