Schultheisz and Karpati (1984) summ

Schultheisz and Karpati (1984) summarise technology
improvements relating to water use and
waste minimisation in the US up to 1977. The trend
is clearly towards the choice of processes which
reduce waste quantity and strength, particularly
improved blood recovery, dry paunch dumping and
regulated water use. Unfortunately, more recent surveys
are not available. The emergence oflow-temperature edible-rendering systems has been
especially constrained by the very strong wastewater
generated (Cooper & Russell, 1988).
Many schemes are already implemented in slaughterhouses
for the reuse of water for non-potable
uses within the plant. Most of these involve no treatment
of the water prior to its reuse. Kane &
Osantowski (1981) described a pilot-plant study in
which treated wastewater was passed through chemical
flocculation/clarification and dual media
filtration prior to further upgrading by either ion
exchange, reverse osmosis (RO) or electrodialysis.
All the latter three processes achieved greater than
90% reduction of TDS, however, the use of RO was
the most economic, with estimated capital and operating
costs for a 3.8 M1/day (1 MGD) system being
at most 40 and 68%, respectively, of those of the
other two processes. Furthermore, it required only
half the space. It is not known whether the system
has been installed at full scale.
Consideration and demonstration of the technical
feasibility of the reuse of municipal wastewater as
potable water has occurred in South Africa (Kfir &
Slabbert, 1991) and several US cities (Rogers &
Lauer, 1991). The safety and public health issues
involved have been widely discussed, but generally
pipe-to-pipe potable reuse is not favoured and most
schemes in use involve a natural intermediate step
(i.e. underground aquifer, reservoir). There are no
reports of technology development or trials for the
rehabilitation of treated wastewater from slaughterhouses
for potable reuse.
New or even improved ideas for the recovery of
valuable byproducts from slaughterhouse or rendering
plant wastewaters have received little attention,
except for high-quality water, protein, biogas and
struvite fertiliser. This may reflect the fact that the
industry is, in fact, highly efficient in achieving
product recovery prior to wastewater discharge