with odour, corrosion and high ener

with odour, corrosion and high energy cost however restrict the
practical applications of this process. A modern method using wet
oxidation is the Vertech process, achieving 20% solubilisation and
75% complete oxidation [160].
In the nineties, the Cambi process combined thermal hydrolysis
with AD to produce a safe, storable and stable product [161].
The most frequent studies oxidative methods are ozonation
and peroxidation, belonging to the advanced oxidation processes
and based on the generation of hydroxyl (OHd) radicals which are
extremely powerful oxidants (oxidation potential 2.8 V). Due to
the oxidative power, hazardous by-products were not detected
[162].
Ozone (O3) is a powerful oxidant which is commonly used for
the disinfection of drinking water and the destruction of
pathogens. The treatment can also be applied to the destruction
of cellular material in WAS. The results of some previous studies
are reported in Table 12.
These radicals are frequently generated using hydrogen
peroxide H2O2 in combination with transition metal salts.
Generally, Fe2+-ions are used in combination with H2O2. This
reaction is referred to as the Fenton peroxidation. A major
drawback of this method is the necessity of bringing the sludge
to a very low pH (optimum at 3). For a complete review of the
chemistry behind this process, the reader is referred to Neyens
and Baeyens [165]. Its application in sludge treatment was studied
by Neyens et al. [166,167]. More recent research uses alternative
peroxidants such as peroxymonosulphate POMS and dimethyldioxirane
(DMDO) which do not require stringent reaction
conditions and significantly increase the biogas production during
the anaerobic treatment of raw secondary sludge [165]. Additional
tests are currently carried out using thickened sludge. Although
oxidative treatments are considered promising, additional research
is needed to avoid extreme reaction conditions in terms of pressures
and temperatures, or pH (Fenton). Advantages, drawbacks and
economics have been described by Neyens et al. [165–168].
5.5. Ultrasound
Sonication is no doubt the most powerful method to disrupt
sludge cells. Although cell disintegrations of 100% can be obtained
at high power levels, power consumption then becomes a serious
drawback [130]. The principle of ultrasonic treatment relies on the
induced cavitation process. Through subsequent compression and
expansion of the fluid under the effect of the ultrasonic waves,
implosions are generated which give rise to local extreme
conditions (temperatures of several thousands degrees centigrade
and pressures of up to 500 bar). The nature of cavitation and the
application of ultrasound in sludge treatment is reviewed by
Dewil et al. [169]. Other references to its use as pre-treatment for
AD are given in Table 13.
Ultrasound treatment units are commercially available in a
wide range of capacities (between 1 and 20 kW) and modular layout.
Capital costs today are roughly h 20,000/kW, with 1 kW
capable of treating sludge from a WWTP of 10,000 p.e. Operation
and maintenance costs are minimal although the ultrasound
probes need replacement every 1.5–2 years.
The use of ultrasound enhancement has been tested in several
WWTP, ranging from 50,000 to 750,000 p.e. (for a total of nearly
1.5 Mp.e.). Improved VS destruction ranged from 40% to 55%,
enhancing the biogas production by about 50%. Improvements
were also found in the dewatering plants, where cake dryness
increased by 5% in spite of using 33% less polymer.
Savings are approximately h1.5–2/p.e./year. Since the degradation
rate is accelerated, the dimensions of the digesters can
moreover be reduced for a given load, thus reducing the impact of
high capital requirements. A recent paper by Appels et al. [172]
describes the principles, application and tentative economics.
5.6. Bacterial and enzyme hydrolysis
Recently, tests have been conducted on the effect of adding
specific strains of bacteria to the sludge being anaerobically
digested. Although literature is still scarce on the subject, with
major sewage treatment companies not willing to divulge results,
the onset of the research was given by Miah et al. [173] who
measured a 210% enhanced biogas production during thermophilic
digestion (at 65 1C) caused by the protease activity of the
Geobacillus sp. strain AT1.
Biological hydrolysis with or without enzyme addition relies
on the enzymatic lysis to crack the cell-wall compounds by an
enzyme catalysed reaction. Analytic processes can be used at
ambient temperatures or external enzyme can be added [174,175].
6. Biogas enrichment, compression and storage
6.1. Perspectives
As produced by digestion, biogas is a clean and environmentally
friendly fuel, although it contains only about 55–65% of CH4.
Other constituents include 30–40% of CO2, fractions of water
vapour, traces of H2S and H2, and possibly other contaminants
(e.g. siloxanes).
Without further treatment, it can only be used at the place of
production. There is a great need to increase the energy content of
the biogas, thus making it transportable over larger distances if
economically and energy sensible. Ultimately, the compression
and use of gas cylinders or introduction into the gas network are
targets. This enrichment and enhanced potential of use, can only
be achieved after removing the CO2 and contaminants. A typical
composition of biogas from sewage sludge AD or landfill capture
and natural gas (NG) are shown in Table 14.
The heating value of biogas is determined by the CH4 content,
with the higher heating value being the energy released when
1Nm3 of biogas is combusted and the water vapour formed
within combustion is condensed. The lower heating value omits
the vapour condensation.