How recycled water could revolutionise sustainable developmentby The Conversation
Waste water is rich in carbon and nutrients and – if collected and treated properly – it could provide new water, fertiliser, and energy. A number of nations and major cities have already built sophisticated waste water treatment plants that effectively recover nutrients and bioenergy, and produce “new water” that can be reused. But more than 80% of all waste water still currently flows into natural ecosytems, polluting the environment and taking valuable nutrients and other recoverable materials with it.
While waste-water systems in large cities are often effective, they are also very expensive to construct and costly to maintain and operate. This is still better than the situation in smaller cities. There, you frequently find badly adapted systems that lack the necessary staff to perform the needed maintenance and operation.
In Latin American countries, those living in small and medium-sized cities have, at most, onsite treatment, in the form of septic tanks that lack regular and proper maintenance.
In Guatemala, only about 5% of cities with fewer than 2,000 inhabitants have centralised treatment plants; and in the Atitlan Lake Basin in Guatemala, roughly 12% of the population is not connected to any kind of sanitation system at all. If any infrastructure exists in these areas, its main goal is to collect waste water, not to treat it and reintroduce it into the water cycle.
This is even more problematic if we consider that, according to the United Nations Population Fund, the populations of small and medium-sized towns will double in Latin America over the next 15 years and double again in the coming 30 years. And yet, most efforts to improve waste-water management focus on the region’s big cities.
Using waste water to save trees
Imagine that outside one of these small cities lies a lovely piece of land: on the surface it is aesthetically pleasing and provides refuge for local wildlife. Beneath the surface is a wetland that is treats waste water and produces energy. The energy produced saves families from having to resort to using firewood collected in the wild or manure for cooking purposes. What’s more, the outflow of this wetland can be used safely in crop irrigation.
This is not a dream scenario. It is called a “constructed wetland environment” and is already in practice on a small scale worldwide.
As part of a team looking into the potential of constructed wetland environments, we have analysed 800 examples of biomass in more than 20 countries.
We found that, depending on climate and the type of plant used in the construction of this type of wetland, up to 45 hectares of land could be irrigated using waste water a daily basis. This would reduce the need for fresh water for irrigation and energy for pumping.
Under this system, a hypothetical community of 60 people would require a wetland area of about 420 square metres. And this wetland could supply the community with 630 kilograms per year of dry biomass, which could go on to produce ten gigajules per year of energy.
To put that in perspective, an average household in Ethiopia requires about seven gigajules for cooking and there are about five people per home, so the annual energy requirement for cooking in this community of 12 homes is about 84 gigajules.
The biofuel produced by the wetland can therefore supply about 12% of the cooking fuel needs of the village. And by reducing cooking fuel needs by 12%, this village can save half a hectare of forest per year on average.
We can stop wasting water
Another solution is constructing decentralised waste-water treatment plants in affected communities. Unlike city waste-water treatment plants, in decentralised plants, raw waste water is treated directly where it is produced instead of being confined in the sewer system. In rural areas, this setup can provide ready access to clean water and reduce environmental pollution.
Due to their relatively small size and low carbon footprints, the negative impact these plants have on the environment is lower than traditional plants. Another bonus is that each site can be tailor-made to suit local climatic conditions, aesthetic requirements, water quality demands, and intended use of the water.
There is no longer any good reason to waste any type of water. Collecting and exploiting waste water is both technically feasible and financially justifiable.
If properly managed, the water we have already used stops being an environmental hazard and becomes an affordable and sustainable source of energy, nutrients, and other recoverable materials.
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