Investigating Three Different Models for Simulation of the Thermal Stage of an Industrial Split-Flow SRU Based on Equilibrium-Kinetic Approach with Heat Loss

Mohammad Hossein Kardan; Reza Eslamloueyan

doi:10.1515/cppm-2018-0025

Artikel

Investigating Three Different Models for Simulation of the Thermal Stage of an Industrial Split-Flow SRU Based on Equilibrium-Kinetic Approach with Heat Loss

Mohammad Hossein Kardan und Reza Eslamloueyan

Veröffentlicht/Copyright: 26. Oktober 2018

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Aus der Zeitschrift Chemical Product and Process Modeling Band 14 Heft 1

Abstract

Modified Claus process is the most important process that recovers elemental sulfur from H₂S. The thermal stage of sulfur recovery unit (SRU), including the reaction furnace (RF) and waste heat boiler (WHB), plays a critically important role in sulfur recovery percentage of the unit. In this article, three methods including kinetic (PFR model), equilibrium and equilibrium-kinetic models have been investigated in order to predict the reaction furnace effluent conditions. The comparison of results with industrial data shows that kinetic model (for whole the thermal stage) is the most accurate model for simulation of the thermal stage of the industrial split-flow SRU. Mean absolute percentage error for the considered kinetic model is 4.59 %. For the first time, the consequences of considering heat loss from the reaction furnace on calculated molar flows are studied. The results show that considering heat loss only affects better prediction of some effluent molar flow rates such as CO and SO₂, and its effect is not significant on the results. Eventually the effects of feed preheating on some important parameters like sulfur conversion efficiency, H₂S to SO₂ molar ratio and important effluent molar flows are investigated. The results indicate that feed preheating will reduce the sulfur conversion efficiency. It is also noticeable that by reducing the feed temperature to 490 K, H₂S/SO₂ molar ratio reaches to its optimum value of 2.

Keywords: kinetic modeling; chemical reactor; reaction engineering; sulfur recovery; thermal reactor; waste heat boiler

Nomenclature

A		Frequency factor
C_j	[mole m^-3]	Concentration of component j
C_p	[J mol^-1 K^-1]	Specific heat capacity
D	[m]	Furnace Internal diameter
E_a	[J mole^-1]	Activation energy
F_j	[mole s^-1]	Molar flow rate of component j
F_t	[mole s^-1]	Total molar flow rate
g	[m s^-2]	Acceleration of gravity
G^t	[j]	Free Gibbs energy
h	[W m^-2.K]	Heat transfer coefficient
ΔHRi	[j mole^-1]	Enthalpy of reaction i
K		Reaction rate constant
L	[m]	Characteristic length
Nu		Nusselt number
P	[pa]	Pressure
Pr		Prandtl number
q_c	[W m-1]	Rate of convection heat transfer (per unit length)
q_r	[W m-1]	Rate of radiation heat transfer (per unit length)
r	[mole m^-3 s]	Rate of reaction
rk		positive error factor
R	[j mole^-1 K^-1]	Universal gas constants
Re		Reynolds number
T	[K]	Temperature
U	[W m^-2.K]	Overall heat transfer coefficient
aik		total number of atoms of element k in component i
αG		Gas absorptivity
∈G		Gas emissivity
μm	[kg m^-1s^-1]	Gas viscosity
υij		Stoichiometric coefficient of component i in reaction j
ρ	[kg m^-3]	Gas density
σ	[W m^-2 K^-4]	Stefan-Boltzman constant

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Received: 2018-05-12

Revised: 2018-08-25

Accepted: 2018-09-15

Published Online: 2018-10-26

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Artikel in diesem Heft

https://doi.org/10.1515/cppm-2018-0025

Schlagwörter für diesen Artikel

kinetic modeling; chemical reactor; reaction engineering; sulfur recovery; thermal reactor; waste heat boiler