Heavy metals present in sewage sludges can be leached out, among other
processes, by a process using a consortium of sulfur oxidizing bacter
ia. The metal leaching could be combined with aerobic sludge digestion
to result in the Simultaneous Sludge Digestion and Metal Leaching (SS
DML) process. A detailed knowledge of the effect of sulfur concentrati
on on the pH variations of the sludge during the process is essential
to a complete understanding of the process kinetics. To achieve this o
bjective, SSDML experiments were conducted in Erlenmeyer flasks and 20
1 reactors and the results were analysed. The sludge pH was seen to ri
se initially, which was attributed to a lag in the activity of sulfur
oxidizing bacteria combined with the production of unidentified materi
al, which are basic in their effect on the sludge pH. The lag period w
as found to depend on (i) the surface area of sulfur available for bac
terial attachment and (ii) the number of bacteria present in the sludg
e capable of initiating bacterial colonies on these surfaces. The rate
of change of sludge pH during the lag period was found to depend on t
he sludge pH itself and the two were related using a second degree pol
ynomial. The specific growth and product formation rates of the sulfur
oxidizing bacteria were found to vary linearly with the surface area
of sulfur available when the bacterial metabolism was sulfur limited a
nd mathematical relations were developed for the same. The rate consta
nts were evaluated by calculating the instantaneous growth and sulfate
formation rates and comparing the resultant change in the sludge pH w
ith experimentally observed values. These equations were used to simul
ate the sulfate production and pH variations in the sludge for various
conditions. The simulation results matched the experimental results v
ery well, confirming the validity of the relations developed. Copyrigh
t (C) 1996 Elsevier Science Ltd