O. Poukka et al., Optimal delignification degrees of cooking and oxygen alkali stage in production of ECF bleached softwood kraft, PAP PUU, 81(4), 1999, pp. 318-326
The aim of this study is to prepare, in the laboratory, ECF bleached softwo
od pulps with good yield and good quality by raising the kappa number from
cooking and extending delignification with oxygen.
Conventional softwood pulps were cooked to kappa numbers of 19.5 - 28.8 - 4
7.5 and 58.5. The pulps were further oxygen delignified in either one or tw
o stages without intermediate washing. Two-stage oxygen delignification was
improved with interstage treatment (peracetic acid or silicoperoxomolybdat
e) and by intensifying the second oxygen stage with hydrogen peroxide. The
pulps were bleached using the sequence DE,,DD. The effect of anthraquinone
was also studied at kappa numbers of 26.6 and 51.1.
The usual laboratory analyses were supplemented with computer-aided process
simulation of the pulp mill (PulpSim) so that the results could be better
understood and compared.
According to the results, the degree of delignification during oxygen delig
nification increases as the kappa number from the cook increases, even when
alkali dosage per kappa unit is lowered. Activating two-stage oxygen delig
nification by intermediate treatment with silicoperoxomolybdate or reinforc
ing the second oxygen stage with hydrogen peroxide gave promising results i
n terms of kappa reduction.
To maximize pulp yield, pulps should be cooked to high kappa and further de
lignified with oxygen. However, raising the kappa number over 30-35 is limi
ted by an increase in the amount of rejects. The viscosity of bleached soft
wood pulp is highest at kappa 45-50. Optimum beatability, expressed in term
s of beating time to achieve a tensile index of 70 Nm/g, is obtained at kap
pa 35-40. Pulps delignified in an intensified two-stage oxygen delignificat
ion process are more easily beaten than those subjected to ordinary oxygen
delignification. Pulp strength is highest at kappa 40-45 when tear indices
are compared at a tensile index of 70 Nm/g. The O-OP pulps had the best str
ength properties.
Process simulation provides an idea of how much the capacities of the cooki
ng plant and recovery boiler can be reduced by raising the kappa number om
cooking and by extending oxygen delignification. The increase in the effici
ency of washing after the oxygen stage needed to achieve the same washing l
oss (expressed in terms of Na,SO, to the bleach plant) was also calculated.
It was found, for ex ample, that on cooking to a kappa number of about 20
followed by one-stage oxygen delignification, less effective washing is nec
essary (2,85 units smaller value for washing efficiency E-k), the consumpti
on of steam in the evaporation plant is approximately 10% higher and the lo
ad to the recovery boiler is 15% higher than on cooking to a kappa number o
f about 45 followed by two-stage oxygen delignification. Greater effluent t
reatment capacity is needed when the kappa number of pulp entering the blea
ch plant is raised.