Modeling of alkaline extraction chemistry and kinetics of softwood kraft pulp

Susanna Kuitunen; Ville Tarvo; Tiina Liitiä; Stella Rovio; Tapani Vuorinen; Ville Alopaeus

doi:10.1515/hf-2013-0225

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Modeling of alkaline extraction chemistry and kinetics of softwood kraft pulp

Susanna Kuitunen , Ville Tarvo , Tiina Liitiä , Stella Rovio , Tapani Vuorinen und Ville Alopaeus

Veröffentlicht/Copyright: 21. März 2014

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Aus der Zeitschrift Holzforschung Band 68 Heft 7

Abstract

A comprehensive model for alkaline extraction (E) of chlorine dioxide delignified (D₀) softwood kraft pulp (KP) is presented. The dynamics of the process is modeled by taking into account both irreversible and reversible chemical reactions and gas-liquid and liquid-liquid mass transfer. Equations linking molecular-scale composition (amounts of monomeric lignin and carbohydrate structures) and general engineering parameters [κ number (KN), brightness, intrinsic viscosity, total organic carbon (TOC), chemical oxygen demand (COD), etc.] are presented. The model is capable of reproducing the development of KN and brightness from the molecular-level kinetics. Reactions responsible for the darkening of chlorine dioxide bleached (D₀) pulp in alkali, brightening of pulp due to the action of hydrogen peroxide and oxygen, and reduction in KN were identified. The model predicts the chemical composition of both fiber wall and filtrate. This feature enables studies concerning the interaction of the AE chemistry with upstream (D₀ washing) and downstream (D₁ stage) processes. Quantitative physicochemical modeling approach also points out shortcoming in the present knowledge.

Keywords: alkaline extraction; brightness; chlorine dioxide; chromophore; Donnan effect; engineering parameter; hydrogen peroxide; kappa number; modeling; oxygen; pulp; reaction equilibrium; reaction kinetics; phase equilibrium; softwood

Corresponding author: Susanna Kuitunen, Department of Biotechnology and Chemical Technology, Aalto University, FI-00076 Aalto, Finland, e-mail: susanna.kuitunen@aalto.fi

Nomenclature
A₄₅₇: absorbance (at wavelength λ 457 nm) (-)
AOX: chlorine bound to organic structures in filtrate [mg Cl (kg water)^-1]
BR: brightness (%ISO)
c^F: concentration of fiber bound component in the fiber wall [mol (kg pulp)^-1]
COD: chemical oxygen demand [mg O (kg water)^-1]
D₀: chlorine dioxide delignification stage
DP: degree of polymerization (-)
E: alkaline extraction
FSP: fiber saturation point [kg water (kg o.d. pulp)^-1]
G: mass of cellulose [kg cellulose (kg polysaccharides)^-1]
H: mass of hemicelluloses [kg hemicelluloses (kg polysaccharides)^-1]
Δ_rH: change of enthalpy in reaction (J mol^-1)
k₄₅₇: overall absorption (at λ 457 nm) coefficient [m² (kg pulp)^-1]
k_457,i: component specific absorption (at λ 457 nm) coefficient [m² (mol)^-1]
K: equilibrium constant (depends on stoichiometry)
KN: κ number
k_L: acombined mass transfer coefficient (on liquid side) and mass transfer area (s^-1)
l: cuvette optical length (1 cm)
m: molality [mol (kg water)^-1]
MW: molecular weight (g mol^-1)
n: molar amount (mol)
OX: chlorine bound to organic structures in pulp [mg Cl (kg pulp)^-1]
OxEq: oxidation equivalent (mol electrons mol^-1)
p: pressure (Pa)
r: rate [mol (kg water)^-1 s^-1]
R: gas constant (8.3144 J K^-1 mol^-1)
s₄₅₇: scattering coefficient [m² (kg pulp)^-1]
Δ_r: Schange of entropy in reaction (J K^-1 mol^-1)
t: time (s)
T: temperature (K)
TOC: total organic carbon [mg C (kg water)^-1]
w: weighting factor in optimization
ε₄₅₇: molar absorptivity at light’s wavelength of 457 nm (dm³ mol^-1 cm^-1)
η: intrinsic viscosity (ml g^-1)

Superscript
E: external (to fiber wall) liquid (phase)
F: fiber wall liquid (phase)

Subscript
i, j, k: component i, j, k

Acknowledgments

Financial support from FIBIC Ltd. (EffTech and EffFibre Research Programmes) and Tekes (the Finnish Funding Agency for Innovation) is gratefully acknowledged.

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Received: 2013-11-25

Accepted: 2014-2-3

Published Online: 2014-3-21

Published in Print: 2014-10-1

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https://doi.org/10.1515/hf-2013-0225

Schlagwörter für diesen Artikel

alkaline extraction; brightness; chlorine dioxide; chromophore; Donnan effect; engineering parameter; hydrogen peroxide; kappa number; modeling; oxygen; pulp; reaction equilibrium; reaction kinetics; phase equilibrium; softwood