high biomass production and high co

high biomass production and high cost in terms of
energy. On the other hand, with the diminishing supply
of natural gas and other fossil fuels, bacterial conversion
of liquid (or solid) wastes to methane and stabilized byproducts
through anaerobic digestion would be beneficial
[3
/5]. These by-products could subsequently serve
as food or fertilizer and generally be disposed of with
fewer problems (easier dewatering, smaller amounts).
Also, the high temperatures and high organic load
concentrations of the effluents to be treated, as well as
the high-energy requirements of the distillery process,
are very suitable conditions for the application of
anaerobic digestion.
Anaerobic digestion has a number of advantages. For
example, it demands less energy input, anaerobic
bacteria are capable of transforming most of the organic
substances present into biogas, sludge formation is
minimal and nutrient demands are very low. The
production of biogas enables the process to generate
some energy in addition to the reduced consumption;
this can reduce operational costs by a large margin
compared with high-energy consumptive aerobic processes
[6].
For these reasons, anaerobic digestion of molasses
alcoholic fermentation wastewaters have been the subject
of a number of studies using laboratory or pilotscale
digesters [7
/12], but studies on full-scale mesophilic
plants have been reported less often. Several
related reviews have been presented and many pilotscale
investigations have been reported, using different
anaerobic reactor configurations [13
/15].
Although anaerobic digestion of most types of
distillery wastewaters is feasible and quite appealing
from an energy point of view, the presence of inhibitory
substances such as phenolic compounds severely hinders
the anaerobic process. This slows down the kinetics, and
reduces mean rates of methane production, methanogenic
activities and yield coefficients. These problems
were previously observed in anaerobic batch cultures of
wine distillery wastewaters and cane molasses stillages
[16
/18].
Many phenolic compounds are known to be toxic and
interfere with the activity of methanogenic bacteria.
There are numerous reports in the literature showing the
toxicity and the inhibitory effects of these compounds
on anaerobic digestion processes [19
/23]. In addition,
the high salinity of this waste (average conductivity of 40
mS/cm) can also cause osmotic pressure problems to the
microorganisms responsible for the anaerobic process
[24].
Therefore, although the anaerobic digestion of this
wastewater is attractive and energetically promising, the
presence of a high phenolic content slows down the
process, and hinders the removal of part of its organic
content, making the utilization of high hydraulic retention
times (HRT) necessary. Moreover, the anaerobicdigestion process does not remove the intense color from
this wastewater or an important fraction of the initial
COD, even working at organic loading rates (OLR) as
low as 2
/4 kg COD/m3 day.
Thus, the aim of this work was to study a combined
aerobic
/anaerobic treatment of beet molasses alcoholic
fermentation wastewater. In the first step of the treatment
most of the phenolic content, color and part of the
initial COD will be removed; in the anaerobic step the
remaining organic content (not previously removed) will
be eliminated. The anaerobic digestion process was
carried out in two suspended cell bioreactors operating
in continuous mode.