This paper presents a study of the integrated management of solid wast
es generated in a high-capacity power plant, i.e., coal combustion fly
and bottom ash (BA) and flue gas desulfurization (FGD) sludges. Solid
ification/Stabilization (S/S) processes were tested by analyzing the i
nfluence of the variables: binder type, water needs, and land disposal
scenario that affect the final solid leaching characteristics. A fact
orial design of experiments was used to study the influence of these v
ariables in the final S/S solid. After characterization of the leachat
es according to European regulations, the chemical stability of the S/
S solids was analyzed using a standard dynamic leaching test (DLT). A
dynamic leaching model of the contaminants (sulfates) contained in the
S/S matrix was formulated from the research on the long-term behavior
of the solid matrix, establishing the parameters that have an effect
on the mobility of the sulfate. One parameter, the effective diffusion
coefficient [D-e (cm(2)/s)] and its logarithmic expression, the leach
ing index (LX), were evaluated for each S/S process. Values of 1.51 x
10(-11) (cm(2)/s) less than or equal to D-e less than or equal to 2.14
x 10(-9) (cm(2)/s) for 100% humidity-cured S/S wastes and 1.98 x 10(-
11)(cm(2)/s) less than or equal to D-e less than or equal to 4.36 x 10
(-11) (cm(2)/s) for water bath-cured S/S wastes were obtained for D-e,
leading to LX values of 8.67 less than or equal to LX less than or eq
ual to 10.82 and 10.36 less than or equal to LX less than or equal to
10.80, respectively. These values suggest that a high immobility was r
eached in some of the developed S/S processes. The validity of the lea
ching parameters obtained after a short-term landfill period (56 days)
was confirmed after 1 year.