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Determination of the end-point of the cook is based on a combination of empirical
cooking models and color analysis of the cooking liquor. The empirical models
used for sulfite pulping are called either the S- or the H-factors [3]. The S-factor
includes both the temperature and the partial pressure of SO2. It is generally
accepted that the rate of delignification is proportional to the ion product of
[H+].[HSO3
– ]n, with n most likely being 0.75, and the rate of cellulose degradation
(equals viscosity loss) to [H+], both being proportional to the partial pressure of
SO2 [3]. Thus, the S-factor (SF) is developed from the following expression:
430 4 Chemical Pulping Processes
rL _ _
dL
dt _ kL _ _ L a _ pSO 2 n
_174_
where L is the lignin concentration, kL the rate constant, pSO2 the partial pressure
of SO2, and a and n are constants, with a assumed to be unity. The SF calculates
to the expression:
SF _ _
tfinal
tT _100_ C
dL
L _
tfinal
tT _100_ C
Exp
EA _ L
R _ 373 _
EA _ L
T _ __ pSO 2 n
_ dt _175_
The SF also correlates with the viscosity, provided that the activation energy is
adjusted to a value determined for the carbohydrate degradation, EA,C.
The energy of activation for delignification, EA,L, has been found to be 67 kJ mol–1
in the beginning of delignification, and 95 kJ mol–1 at the final phase [4]. The energy
of activation for the dissolution of the carbohydrates, EA,C, changed only
slightly in the course of cooking from about 80 kJ mol–1 in at the start of the cook to
90 kJ mol–1 at the end of the cook [4]. For cellulose degradation during acid sulfite
pulping, higher values for EA,C (e.g., 125 kJmol–1 and 176 kJmol–1) havebeenreported,
respectively [5,6]. Pressure regulation clearly has an impact on the velocity of cellulose
degradation, and thus on the calculated value for the activation energy.
According to Eq. (175), the partial pressure of SO2 must be considered, though
this is barely measurable. To estimate a value for the partial pressure of SO2 it has
been assumed that the total digester pressure, ptot, is primarily a combination of
the partial pressure of SO2 and the partial pressure of water, pH2O, at the specified
temperature [Eq. (176)][7].
pSO 2 __ ptot _ pH 2 O _ _176_
It is, however, common practice that pressure and temperature are adjusted to
preset values during the cooking phase (and deviate from the preset values only
during the heating-up period), which therefore would maintain a rather constant
partial pressure of SO2 when calculated according to Eq. (176). In view of this situation,
a simple H-factor concept in combination with a color analysis of the cooking
liquor would be sufficient for correct end-point determination. The activation
energy for cellulose degradation, EA,C, during acid sulfite pulping of beech wood
with pressure control at a level of 8.5 bar, has been calculated by nonlinear regression
analysis using the following approximation for H-factor determination [8].
For practical reasons, cellulose degradation is measured as loss in intrinsic viscosity.
HS _ C _
tF
t 0
Exp _
EA _ C
R _ __
T _
373_15 _ _ ___ dt _177_
4.3 Sulfite Chemical Pulping 431
where HS,C is the H-factor for cellulose degradation during acid sulfite pulping.
Based on a total of 155 laboratory cooks, an activation energy for cellulose degradation,
EA,C, of 110 kJ mol–1 has been determined. Inserting this activation energy
leads to the following expression for the HS,C:
H _
tfinal
tT _100_ C
Exp 35_47 _
T _ _ dt _178_
The dissolving pulp viscosity cannot be adjusted with sufficiently high precision
by only using H-factor control. Cellulose degradation is additionally influenced by
the composition of the cooking liquor – for example, the amounts of combined
and free SO2 and the liquor-to-wood ratio. H-factor control is, however, well-suited
for the precalculation of cooking times which enables the optimization of digester
sequencing, steam supply and thus the prediction of production output. The real
end-point determination of a sulfite cook – particularly a sulfite-dissolving cook –
is very difficult for two main reasons. The first reason is that, to date, there is no
capability of analyzing a representative sample from the entire cook to determine
the target pulp properties. Examples include the pulp viscosity of a dissolving
pulp or the residual lignin content (kappa number) for a paper grade-pulp, to be
assessed either within a very short time or even on-line, such that the process
operator is still in a position to adjust the process conditions accordingly. The second
reason is that a sulfite cook accelerates towards the end of the process, and
reactions cannot be stopped immediately at a predetermined time. Consequently,
the whole process of terminating the cook including the relief of digester pressure
and cold displacement – must be controlled with regard to the viscosity (or kappa
number) development. Currently, only cooking liquor analysis is applied to monitor
the reaction medium of the cook towards the end of the process. Although
they are only indirect methods, cooking liquor tests have the advantage that the
samples – which preferably are removed from the liquor circulation – represent
the entire digester content, and the analysis can be carried out rapidly and even
recorded on-line. Among a wide variety of possible methods listed in Table 4.56,
color determination of the cooking liquor is the most important parameter for
end-point determination, at least for dissolving pulp production.
Absorbance at 280 nm, which is characteristic for the lignin and furfural concentrations
of the liquor, changes during the final period of dissolving pulp cook
due to condensation reactions. Therefore, absorbance at this wavelength is not
well-suited to measure the lignin concentration of the cooking liquor. However,
absorbance in the visible region – preferably between 400 and 500 nm – correlated
well with the acidity prevailing in the cooking liquor. The liquor color, which converts
from light yellow to brown and finally to dark-brown, most likely originates
from condensation reactions involving carbonyl groups from lignin structures
induced by a lack of hydrogen sulfite ion concentration and the development of
acidity [11]. In industrial practice, the color is measured at 430 nm against pure
water. Development of the color is carefully monitored during the whole final
432 4 Chemical Pulping Processes
cooking phase (from the beginning of the pressure relief until the blow). Thus,
absorbency at 430 nm shows a reasonably good correlation to pulp viscosity
(Fig. 4.158). [13].
Tab. 4.56 Cooking liquor analysis methods used for end-point
determination of acid sulfite cooks.
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