Box 13 Water and Sewage Management

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Boxes
The term ‘effluent sewer’ is used for a system where the household sewage solids separate 
from the sewage water and settle out in a tank on each lot. The clarified effluent in the tank 
then either gravitates or is pumped away through a network of watertight pipes to a local 
sewage treatment plant.
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When compared to a conventional gravity sewerage system, the 
benefits of a decentralized watertight effluent sewerage system are:
• 
No infiltration of stormwater into the sewers
• 
No need for sewage (plus stormwater) to bypass the treatment plant in wet weather 
nor be discharged directly to the waterway
• 
No escape of raw sewage from leaky pipes into the surrounding soil and groundwater
• 
No sewer-overflow valves that discharge raw sewage into rivers
• 
Small diameter pipes do not need to be trenched
• 
Flexible pipes can go around rocks, structures, trees and cultural sites
• 
Pipes travel short distances within the community area
• 
As the pipes carry primary treated effluent, and not raw sewage, there is less 
detrimental impact if a pipe is accidentally broken
• 
Effluent pumps use minimal electricity, thereby minimizing the generation of greenhouse 
gases, especially when local sustainable energy is used
• 
All sewage is treated and beneficially recycled
The treatment component of an effluent sewerage system is a combination of primary treat
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ment (screening and settling) in a household tank and secondary treatment (biological diges-
tion) at the community sewage treatment plant. The benefits of retaining most of the sewage 
solids in the household tank are: 
• 
The pipes are small because they are not transporting solids
• 
There is very little likelihood of pipes becoming clogged
• 
The small pipes are relatively quick and inexpensive to install
• 
The secondary treatment plant is smaller and cheaper to build and operate, because it 
does not need to process the majority of the solids
However, household interceptor tanks do need to be de-sludged every 5 to 15 years, depend
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ing on the size and characteristics of the wastewater. Through the use of remote monitoring 
(telemetry), household and decentralized systems can be efficiently and cost-effectively oper
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ated and maintained by a centralized management authority.
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The design of a local secondary sewage treatment plant for a cluster of homes, neighbourhood 
or subdivision is based on the reuse opportunities in the surrounding area. Treated effluent can 
be piped back to homes for garden watering, toilet flushing and use in the washing machine; to 
community or council land for use on sports fields, golf courses, parks, gardens, road verges, 
race courses and airfields; to agricultural land for growing pasture, fodder crops, orchards, turf, 
bamboo, essential oils, herbs, flowers and woodlots; or to mining and industrial sites. Once 
the recycling opportunities have been identified or created, the sewage treatment system can 
be designed to achieve the required effluent quality. Effluent recycling opportunities can be 
created that generate a product for consumption or sale to the community.
Where there are insufficient effluent recycling opportunities in winter or wet weather, the 
excess can be stored, transported elsewhere or, depending on the soil type, dispersed through 
the soil profile to groundwater where it later becomes beneficial baseflow in the adjacent 
rivers. Final effluent from ‘best practice’ decentralized sewage treatment systems, such as 
textile filters, sand filters and reed-beds, are safely disposed of through the soil in winter in 
New Zealand and the US.
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Through decentralized local water collection and sewage treatment and recycling systems 
that are designed to meet the needs of the local community and catchment, we can protect 
human and aquatic life and live in better balance with our environment.

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