condition the residue to meet dispo

condition the residue to meet disposal acceptance regulation.
Since land application is difficult due to stringent regulations
concerning the tolerated composition [2–4], (co-)incineration is
gaining increasing interest where permits can be obtained [5].
The water purification part of a WWTP commonly comprises a
pre-treatment to remove about 50–60% of the suspended solids
and 30–40% of the BOD [6,7]. The settled primary sludge contains
mainly water (between 97% and 99%) and separates mostly
organic matter that is highly putrescible.
The pre-treatment is followed by a biological step, where
aerobic micro-organisms remove the remaining (or nearly total)
BOD and suspended solids. Nitrogen (N) and phosphorus (P) are
commonly removed simultaneously, although N is more usually
and easily targeted first. A secondary clarifier produces the
dischargeable effluent as overflow and a bottom sludge (98–99%
water), partly recycled to the biology to maintain the concentration
of the micro-organisms at the required level, and partly
evacuated to the sludge treatment units of the WWTP. If a pretreatment
is present, primary and secondary sludge are generally
combined and thickened to undergo further treatment.
This further treatment can be a combination of various steps,
as reviewed in Table 1. Anaerobic digestion (AD) is an important
step in most of the treatment routes.
All routes start with raw sludge (primary and secondary)
produced at 1–2 wt% DS. The mineral part of the DS (MDS) is
between 30 wt% and 45 wt%.
A first step is its thickening by gravity, flotation or belt
filtration. In doing so, the amount of sludge can be reduced
to as little as a third of its initial volume. The separated water
is recycled to the influent of the WWTP. Once this has
been accomplished, the sludge is subject to some form
of biochemical stabilisation, with AD playing an important
role for its abilities to further transform organic matter into
biogas (60–70 vol% of methane, CH4), thereby also reducing the
amount of final sludge solids for disposal is also reduced,
destroying most of the pathogens present in the sludge,
and limiting possible odour problems associated with residual
putrescible matter.
For these reasons, anaerobic sludge digestion optimisesWWTP
costs and is considered a major and essential part of a modern
WWTP. The potential of using the biogas as energy source is
widely recognised. Biogas is currently produced mostly by
digestion of sewage treatment sludge, with minor contributions
from fermentation or gasification of solid waste or of lignocellulosic
material (processes currently being further developed). It is
considered an important future contributor to the energy supply
of Europe, although upgrading is needed.
The annual potential of biogas production in Europe is
estimated in excess of 200 billions m3.
AD of sludge uses airtight tanks. Essentially all organic material
can be digested, except for stable woody materials since the
anaerobic micro-organisms are unable to degrade lignin. The biogas
which is formed has a high calorific value and is considered as a
renewable energy source. Clearly, it is beneficial to produce as much
biogas as possible. Despite these advantages of AD, some limitations
are inevitable, e.g. (i) only a partial decomposition of the organic
fraction, (ii) the rather slow reaction rate and associated large
volumes and high costs of the digesters, (iii) the vulnerability of the
process to various inhibitors, (iv) the rather poor supernatant
quality produced, (v) the presence of other biogas constituents such
as carbon dioxide (CO2), hydrogen sulphide (H2S) and excess
moisture, (vi) the possible presence of volatile siloxanes in the
biogas that can cause serious damage in the energy users
(generator, boiler) due to the formation of microcrystalline silica,
and (vii) the increased concentration of heavy metals and various
industrial ‘‘organics’’ in the residual sludge due to the significant
reduction of the organic fraction during digestion, leaving the
mineral and non-degradable fraction untouched.
A process flowchart of the sludge-processing steps is shown in
Fig. 1.
The present paper will attempt to extensively review the
principles of AD of sewage sludge, the process parameters and
their interaction, the design methods, the biogas utilisation, the
possible problems and potential pro-active measures, and the
recent developments to reduce the impact of the difficulties
described above.
Section 2 will review the basic principles and parameters of
the AD process, including the process description, the types of
anaerobic digesters (standard rate, high-rate, two-stage, mesophilic,
thermophilic), the current empirical design methods, the
common operating parameters and the resultant biogas yields.
Modelling and monitoring the AD process are dealt with in
Section 3: models can tentatively be divided into either simple
steady-state models or complex dynamic simulation models.
When required system performance criteria are defined, steadystate
models predict the operating parameters and lead to a
system design with reasonable accuracy. These approximate
design and operating parameters can then be used as input to
the more complex simulation models to investigate the dynamic
behaviour of the system and fine-tune the design and operating
parameters in real-time.
Having studied the dominant parameters, Section 4 will focus
on the operational vulnerability of digestion. The microbiology of
the AD is complex and delicate, involving several bacterial groups,
each of them having their own optimum working conditions. They
are sensitive to several process parameters such as pH, alkalinity,
concentration of free ammonia, hydrogen, volatile fatty acids
(VFA), etc. These parameters can be inhibiting factors to some or
all bacterial groups, and modern approaches include these
inhibiting effects in modelling, in investigating the behaviour of
the system and in controlling the process.
Section 5 will describe novel methods to accelerate the
digestion through enhancing the rate-limiting hydrolysis. Various
pre-treatments have recently been studied and include mechanical,
thermal, chemical and biological interventions. All pre-treatments
result in a lysis or disintegration of sludge cells, thus releasing
and solubilising intracellular material into the water phase and
transforming refractory organic material into biodegradable species,
therefore making more material readily available for microorganisms.
It will be shown that these pre-treatments enhance the
biogas generation. Since the degradation rate is moreover accelerated,
the dimensions of the digesters can be reduced for a given
load, thus reducing the capital requirements.