Computational fluid dynamics‐based steam cracking furnace optimization using feedstock flow distribution

Nonuniform temperature fields in steam cracking furnaces caused by geometry factors such as burner positions, shadow effects, and asymmetry of the reactor coil layout are detrimental for product yields and run lengths. The techniques of adjusting burner firing (zone firing) and feedstock mass flow r...

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Bibliographic Details
Published inAIChE journal Vol. 63; no. 7; pp. 3199 - 3213
Main Authors Zhang, Yu, Reyniers, Pieter A., Schietekat, Carl M., Van Geem, Kevin M., Marin, Guy B., Du, Wenli, Qian, Feng
Format Journal Article
LanguageEnglish
Published New York American Institute of Chemical Engineers 01.07.2017
Subjects
Asymmetry
Chemical industry
Coiling
Coils
Coke
Coking
Computational fluid dynamics
Computer applications
Computer simulation
Conversion
Cracking (chemical engineering)
Criteria
economics
Ethene
ethylene
Flow distribution
flow rate distribution
Fluid dynamics
Furnaces
Hydrodynamics
Lasers
Mass flow rate
Metals
Modules
Nozzles
Optimization
Raw materials
Retrofitting
Steam
steam cracking
Temperature effects
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Summary:Nonuniform temperature fields in steam cracking furnaces caused by geometry factors such as burner positions, shadow effects, and asymmetry of the reactor coil layout are detrimental for product yields and run lengths. The techniques of adjusting burner firing (zone firing) and feedstock mass flow rate (pass balancing) have been practiced industrially to mitigate these effects but could only reduce the nonuniformities between the so‐called modules (a group of many coils). An extension of the pass balancing methodology is presented to further minimize the intra‐module nonuniformities, that is, variation between the coils within a module, in floor fired furnaces. Coupled furnace‐reactor computational fluid dynamics‐based simulations of an industrial ultraselective conversion (USC) furnace were performed to evaluate four different feedstock flow distribution schemes, realizing equal values for coil outlet temperature, propene/ethene mass ratio, maximum coking rate and maximum tube metal temperature (TMT), respectively, over all the reactor coils. It is shown that feedstock flow distribution creates a larger operating window and extends the run length. Out of the four cases, the coking rate as criterion leads to the highest yearly production capacity for ethene and propene. Uniform maximum coking rates boost the annual production capacity of the USC furnace with a nameplate ethene capacity of 130 103 metric tons per year with 1000 metric tons for ethene and 730 metric tons for propene. For industrial application, achieving uniform maximum TMT is more practical due to its measurability by advanced laser‐based techniques. Most steam cracking furnaces can be retrofitted by optimizing the dimensions of venturi nozzles that regulate the feedstock flow to the coils. © 2017 American Institute of Chemical Engineers AIChE J, 63: 3199–3213, 2017
ISSN:0001-1541
1547-5905
DOI:10.1002/aic.15669