Waste water recycling-constructed wetlands-reed bed system-legislation and standards
4
Waste water recycling-constructed wetlands-reed bed system-legislation and standards
Reclaimed or recycled
water (also called wastewater reuse or water
reclamation) is the process of converting wastewater into water that
can be reused for other purposes. Reuse may include irrigation of
gardens and agricultural fields or replenishing surface water and
groundwater (i.e., groundwater recharge).
Wastewater
recycling helps customers optimise
water costs and minimise their environmental footprint.
Wastewater
recycling for municipalities:
·
Reduces
reliance on stressed fresh water sources
·
Frees up
bulk water, which can soften the need to invest in new potable plants builds
·
Protect
sensitive ecosystems and reclaim natural aquifers
Wastewater
recycling for industry:
·
Reduce
bulk water consumption = lower per-litre cost of water
·
Improve
compliance with environmental regulations
·
Harvest
valuable minerals from wastewater for secondary revenue streams
·
Work
towards Zero Liquid Discharge.
Depending on you feed water quality and required
treatment standard, wastewater recycling and reuse is often achieved by
combining numerous technologies, such as clarification, reverse osmosis,
evaporation and chemical treatment into a cohesive, high performance treatment
solution.
A constructed
wetland (CW)/ reed bed is
an artificial wetland to treat municipal or industrial
wastewater, greywater or stormwater runoff. It may also be designed
for land reclamation after mining or as a mitigation step for
natural areas lost to land development.
It uses natural functions of vegetation, soil,
and organisms to treat wastewater. Depending on the type of wastewater the
design of the constructed wetland has to be adjusted accordingly.
Similarly to natural wetlands, constructed wetlands
also act as a biofilter and/or can remove a range
of pollutants (such as organic
matter, nutrients, pathogens, heavy metals) from the water.
Constructed wetlands are a sanitation technology that have not been
designed specifically for pathogen removal, but instead, have been
designed to remove other water quality constituents such as suspended solids,
organic matter and nutrients (nitrogen and phosphorus). All types of
pathogens (i.e., bacteria, viruses, protozoan and helminths) are expected to be
removed to some extent in a constructed wetland. Subsurface wetlands provide
greater pathogen removal than surface wetlands. A biofilter has
some similarities with a constructed wetland, but is usually without plants.
Vegetation in a wetland provides a substrate
(roots, stems, and leaves) upon which microorganisms can
grow as they break down organic materials. This community of microorganisms is
known as the periphyton. The periphyton and natural chemical processes are
responsible for approximately 90 percent of pollutant removal
and waste breakdown. The plants remove about seven to ten per cent of
pollutants, and act as a carbon source for the microbes when they decay.
Different species of aquatic plants have different rates of heavy metal uptake, a
consideration for plant selection in a constructed wetland used for water
treatment. Constructed wetlands are of two basic types: subsurface flow and
surface flow wetlands.
Constructed wetlands are one example of nature-based
solutions and of phytoremediation.
Many regulatory agencies list treatment wetlands as one of their recommended
"best management practices" for controlling urban runoff.
Physical, chemical, and
biological processes combine in wetlands to remove contaminants from
wastewater. Theoretically, wastewater treatment within a constructed
wetland occurs as it passes through the wetland medium and the plant rhizosphere.
A thin film around each root hair is aerobic due to the leakage of
oxygen from the rhizomes, roots, and rootlets.
Aerobic and anaerobic micro-organisms facilitate decomposition
of organic matter. Organic
matter broken was down by micro-organisms by the mechanisms of fermentation, or
respiration and used as energy source for wetland or assimilated into biomass.
Organic particulate nitrogen (organic matter) in the effluent may settle due to
the mechanisms called sedimentation. The settled sediments may deposit in the
bottom of constructed wetlands. Nitrogen can be converted into different forms
depending on oxidation state of wetland. Microbial nitrification and
subsequent denitrification releases nitrogen as gas to the atmosphere. Phosphorus is coprecipitated with iron, aluminium and calcium compounds located in the
root-bed medium.
Suspended
solids filter out as they settle in the water column in surface flow
wetlands or are physically filtered out by the medium within subsurface flow
wetlands. Harmful bacteria and viruses are reduced by
filtration and adsorption by biofilms on the gravel or sand media in
subsurface flow and vertical flow systems.
Constructed wetlands have been used extensively for
the removal of dissolved metals and metalloids. Although these contaminants are prevalent in mine
drainage, they are also found in stormwater, landfill leachate and other sources
(e.g., leachate or FDG washwater at coal-fired
power plants), for which treatment wetlands have been
constructed for mines.
Typhas and Phragmites are the main species used in
constructed wetland due to their effectiveness, even though they can be invasive outside
their native range.
In North America, cattails (Typha
latifolia) are common in constructed wetlands because of
their widespread abundance, ability to grow at different water depths, ease of
transport and transplantation, and broad tolerance of water composition (including
pH, salinity, dissolved oxygen and contaminant concentrations). Elsewhere,
Common Reed (Phragmites australis)
are common (both in blackwater treatment but also in greywater
treatment systems to purify wastewater).
Plantings of reedbeds are
popular in European constructed subsurface flow wetlands, although at least
twenty other plant species are usable. Many fast growing timer plants can be
used, as well for example as Musa spp., Juncus spp., and sedges.
Plants such as Water Hyacinth (Eichhornia crassipes)
and Pontederia spp. are used worldwide.
Locally grown non-predatory fish can
be added to surface flow constructed wetlands to eliminate or reduce pests,
such as mosquitos.
Stormwater wetlands
provide habitat for amphibians but the pollutants they accumulate can affect
the survival of larval stages, potentially making them function as
"ecological traps".
Case studies
·
The total number of constructed wetlands
in Austria is 5,450 in 2015.
·
The Arcata Marsh in Arcata, California is
a sewage treatment and wildlife protection marsh
·
The Urrbrae Wetland in Australia was
constructed for urban flood control and environmental education
·
At the Ranger Uranium Mine, in Australia, ammonia
is removed in "enhanced" natural wetlands (rather than fully
engineered constructed wetlands), along with manganese, uranium and other
metals
Reed beds are natural habitats found in floodplains,
waterlogged depressions, and estuaries. Reed beds are part of
a succession from young reeds colonising open water or wet
ground through a gradation of increasingly dry ground. As reed beds age, they
build up a considerable litter layer that eventually rises above the water
level and that ultimately provides opportunities for scrub or
woodland invasion. Artificial reed beds are used to remove pollutants from grey
water
Types
Reed beds vary in the species that they can
support, depending upon water levels within the wetland system, climate,
seasonal variations, and the nutrient status and salinity of the water. Reed
swamps have 20 cm or more of surface water during the summer and
often have high invertebrate and bird species use. Reed fens have
water levels at or below the surface during the summer and are often more
botanically complex. Reeds and similar plants do not generally grow in very
acidic water; so, in these situations, reed beds are replaced
by bogs and vegetation such as poor fen.
Although common reeds are characteristic
of reed beds, not all vegetation dominated by this species is characteristic of
reed beds. It also commonly occurs in unmanaged, damp grassland and
as an understorey in certain types of damp woodland.
Wildlife
Most European reed beds mainly comprise Phragmites
australis but also include many other
tall monocotyledons adapted to growing in wet conditions – other
grasses such as reed sweet-grass (Glyceria maxima), Canary reed-grass (Phalaris
arundinacea) and small-reed (Calamagrostisspecies), large sedges
(species of Carex, Scirpus, Schoenoplectus, Cladium and
related genera), yellow flag iris (Iris pseudacorus), reed-mace
("bulrush" – Typhaspecies), water-plantains (Alismaspecies),
and flowering rush (Butomus umbellatus).
Many dicotyledons also occur, such as water mint (Mentha aquatica),
gipsywort (Lycopus europaeus), skull-cap (Scutellaria species),
touch-me-not balsam (Impatiens noli-tangere), brooklime (Veronica
beccabunga) and water forget-me-nots (Myosotis species).
Many animals are adapted to living in and around
reed-beds. These include mammals such as Eurasian otter, European
beaver, water vole, Eurasian harvest mouse and water shrew,
and birds such as great bittern, purple heron, European
spoonbill, water rail (and other rails), purple
gallinule, marsh harrier, various warblers (reed
warbler, sedge warbler etc.), bearded reedling and reed
bunting.
Constructed wetlands are artificial swamps
(sometimes called reed fields) using reed or other marshland plants
to form part of small-scale sewage treatment
systems. Water trickling through the reed bed is cleaned
by microorganisms living on the root system and in the litter. These
organisms utilize the sewage for growth nutrients, resulting in a
clean effluent. The process is very similar to aerobic conventional sewage
treatment, as the same organisms are used, except that conventional treatment
systems require artificial aeration.
Treatment ponds
Treatment ponds are small versions of constructed
wetlands which uses reed beds or other marshland plants to form an even
smaller water treatment system. Similar to constructed wetlands, water
trickling through the reed bed is cleaned by microorganismsliving on the
root system and in the litter. Treatment ponds are used for the water treatment
of a single house or a small neighbourhood.
Recycling
treated wastewater for irrigation
The use of
treated wastewater in agriculture benefits human health, the environment and
the economy. This use represents an alternative practice that is being adopted
in different regions confronted with water shortages and growing urban
populations with increasing water needs, especially given the decline in
surface and groundwater resources caused by climate variability (CV) and
climate change (CC). The availability of water resources is also affected by
wastewater-sourced pollution, as such water is not always treated before
reaching surface channels, and by associated aquifer pollution
One of the
most recognized benefits of wastewater use in agriculture is the associated
decrease in pressure on freshwater sources. Thus, wastewater serves as an
alternative irrigation source, especially for agriculture, the greatest global
water user, which consumes 70% of available water. Furthermore, wastewater
reuse increases agricultural production in regions experiencing water
shortages, thus contributing to food safety. Approximately 805 million people,
one-ninth of the global population, suffer from hunger. However, according to
FAO’s latest estimations, a decreasing trend in hunger supports the possibility
of halving the number of undernourished people. However, to be successful, it
is first necessary to adopt a comprehensive approach that includes public and
private investment aimed at increasing agricultural productivity, in addition
to increasing and improving the availability of water resources and protecting
vulnerable groups. Depending on the local situation, another benefit associated
with agricultural wastewater reuse could be the avoided cost of extracting
groundwater resources. In this regard, it is worth noting that energy required
to pump groundwater can represent up to 65% of the costs of irrigation
activities
Additionally,
the nutrients naturally present in wastewater allow savings on fertilizer
expenses to be realized, thus ensuring a closed and environmentally favorable
nutrient cycle that avoids the indirect return of macro- (especially nitrogen
and phosphorous) and microelements to water bodies. Depending on the nutrients,
wastewater may be a potential source of macro- (N, P and K) and micronutrients
(Ca, Mg, B, Mg, Fe, Mn or Zn). Indeed, wastewater reuse has been proven to
improve crop yield and result in the
reduced use of fertilizers in agriculture. Therefore, eutrophication conditions
in water bodies would be reduced, as would the expenses for agrochemicals used
by farmers. The prevention of water pollution would be another benefit
associated with wastewater reuse in agriculture. A decrease in wastewater
discharge helps improve the source quality of receiving water bodies. Moreover,
groundwater reservoirs are preserved, as agricultural wastewater reuse
recharges these sources with higher-quality water. Additionally, an increased
use of wastewater could contribute to the installation and optimization of
treatment facilities to produce effluent of a desired quality for irrigation
purposes, representing an economic benefit to sanitation projects. In those areas
where climatic and geographic characteristics allow, low-cost wastewater
treatment systems might also be a viable option, achieved using certain
technological options that fulfill the objective of agricultural reuse.
Wastewater use in agriculture helps liberate capital resources through the
payment of economic instruments by the actors of different countries
Limitations
Associated with Agricultural Wastewater Reuse
The use of treated or untreated wastewater in
agriculture is not exempt from adverse effects on the environment, especially
on soil. The scientific literature includes evidence of alterations in the
physicochemical parameters of soil. Variations have been observed in the
structure and magnitude of microbial biomass in soil, as well as an increase in
microbial activity caused by agricultural wastewater reuse. Altering
physicochemical parameters and soil microbiota can affect fertility and
productivity, thus disturbing soil sustainability from inadequate irrigation
with wastewater. A review follows on the effects of wastewater reuse in
agriculture and the impact on physicochemical parameters such as pH, organic
matter, nutrients, salinity and contaminants, as well as on microbial
diversity.
Changes in
soil pH due to treatment of effluent using constructed wetland technology are
correlated with three factors: (i) type of soil cover; (ii) soil texture; and
(iii) period of irrigation. The changes in soil pH influence the availability
of nutrients and metals, the cation exchange capacity (CEC) and the
mineralization of organic matter. Additionally, different researchers consider
pH incidence to be a decisive factor in determining the number of species and
variety of soil microorganisms, as an increase in free metals is not related to
changes in the soil pH, and the concentration and availability of metals have
the potential to affect the substrate of the microbial communities
Moreover,
organic matter is critical for nutrient storage and soil structure. Through the
formation and stabilization of aggregates (sand, lime and clay), the organic
matter content contributes to the capacity of the soil to retain water,
affecting drainage properties and compaction resistance. Organic matter also
constitutes a deposit of important macro- and micronutrients (N, P and S) for
plant growth, contributing to the cation exchange capacity (CEC) and,
consequently, to soil fertility. Depending on the amount of organic matter
contributed, different studies have reported an increase in total organic
carbon (TOC) and nitrogen (N) in those soils irrigated with domestic
wastewater. This phenomenon also causes the availability of organic matter to
increase. As a consequence, the presence of specific bacteria populations may
be favored in the soil. Between 40% and 70% of soil bacteria are associated
with stable aggregates (clay particles)
The stability
of aggregates in the soil and the water retention capacity from the organic
matter contributed by wastewater irrigation depend on the concentration levels,
the composition of organic matter and soil texture. Thus, sandy-clay soils
irrigated with wastewater increase the stability of their aggregates.
Conversely, soils with a clayey texture diminish the stability of their
aggregates. Additionally, the use of wastewater in prolonged irrigation (more
than 20 years) can result in negative changes in soil structure due to the
accumulation of sodium in the exchange complex.
A study on
sugarcane irrigated with treated wastewater for 12 months found an increase in
the content of organic matter in the soil that, according to the authors,
favored the reuse of wastewater in the areas under study. Different research
studies have noted an increase in the different forms of nitrogen (N-NO3,
NH4-N or Total N) after irrigation with wastewater for periods
ranging from one to 20 years. However, despite existing benefits in
agricultural production and a reduction in chemical agents (fertilizers) from
the increase in N and P contributed by wastewater, soil microbial communities
can be affected, particularly the activities associated with the cycle of these
elements
More than
ninety percent of the soil’s nitrogen is in organic form. Ammonium and nitrate
are the main forms of absorption by plants, in addition to some organic
nitrogen compounds. It is generally believed that nitrite is an intermediate
product in the conversion of Ammonium to Nitrate in the soil, where the
conversion of Nitrite to Nitrate is important, since relatively small amounts
may have toxic effects on plant growth. These intermediate products of complex
organic substances of nitrogen can be absorbed by the plants. Organic nitrogen
nutrition can affect the quality of the plant product and the metabolism of the
plan. Similarly, under excessive application of nitrogen (by fertilizer,
sewage, or other source), vegetables can accumulate high levels of nitrate and,
when consumed by living things, can pose serious health hazards.
Another effect
is the accumulation of inorganic N in the soil that can affect the
biodegradation of carbon compounds. Additionally, the excessive supply of
nutrients in the soil may have adverse effects. Nutrients such as phosphorus
and nitrate can be included in the runoff or can be leached towards
groundwater, thus causing the eutrophication or toxicity of other habitats.
Irrigated wastewater can promote soil salinization (an increase in the
concentration of soluble salts) or sodification (an excess of interchangeable
sodium in relation to other cations).
Salinity
problems occur when the soluble salts are concentrated in the root zone, thus
causing osmotic stress that limits the capacity of plants to absorb water and
nutrients. Sodicity therefore negatively affects the stability of aggregates
and soil structure, as high interchangeable sodium content causes a decrease in
permeability. Sodicity is caused by expansive and dispersive processes on clays
as a consequence of the destruction of aggregates due to high Na+
concentrations. Different research studies noted that changes in sodicity
generate an increase in soil compaction and reduce the infiltration rate of
water. As a result, soil microbiota is affected by variations in soil salinity
or sodicity.
The effects on
microbial communities are primarily related to changes in soil structure and
decreases in osmotic potential. Another study assessed the effects of salinity
on the structure, activity and community of soil microorganisms. Their results
suggest that higher salinity content metabolically stresses soil microbiota.
Additionally, the Carbon Nitrogen relation of the biomass tends to be lower in
higher salinity soils, which reflects the predominance of bacteria in the
microbial biomass of saline soils. Furthermore, soil degradation increases due
to the disposal of pollutants (metals and pharmaceutical compounds) through different
media such as wastewater, which accumulate in the soil as a result of
irrigation.
Typically,
metal concentrations in soils not subjected to anthropogenic activities depend
primarily on the parental material (stone) and can be present in the soil at
non-toxic levels for living beings. However, population growth and
industrialization have resulted in an increase in the presence of such
polluting agents in wastewater and, consequently, in irrigated soils. Metals
such as Fe, Cr, Zn, Pb, Ni, Cd and Cu, which are abundant in wastewater, lead
the list of possible polluting agents that have accumulated in soil as a result
of wastewater irrigation. The presence of these elements in the soil can limit
fertility and/or modify soil microbial communities; they also affect a soil’s
phytotoxicity potential with consequent effects on plant growth and pollution.
Other
ecosystem functions affected due to metal pollution include organic matter
mineralization, changes in soil enzyme activity, litter decomposition, microbial
biomass reduction and changes in microbial structure. Additionally, the metals
accumulated in a soil can interact with pharmaceutical products or other ECs,
exacerbating the potential effects on the soil. Several studies have also noted
strong co-occurrence patterns between the metals in a soil and a resistance to
antibiotics in certain environmental conditions. The fate and effect of these
compounds (emerging metals and/or polluting agents) depend on several factors
such as the chemical properties of the pollutant type, the species and age of
the vegetation cover, the composition of the rhizosphere microorganisms and
soil characteristics (temperature, pH of the nutritional environment, soil
texture and structure).
Researchers
have noted that low-mobility compounds accumulate in soils with an irrigation
period ranging from one to 100 years, in contrast with high-mobility compounds.
Additionally, researchers worldwide have highlighted the risks posed by
high-mobility compounds, given the possible leaching that may pollute
groundwater sources. For example, in some amoxicillin-degradation products, it
was observed that high-mobility compounds polluted the groundwater of
wastewater-irrigated agricultural fields. Another study concluded, after
discovering low retention rates for ibuprofen in soils, that this compound has
a high potential to percolate through soil and pollute groundwater sources
Specific
ion toxicity
Toxicity due
to a specific ion occurs when that ion is taken up by the plant and accumulates
in the plant in amounts that result in damage or reduced yield. The ions of
most concern in treated wastewater are sodium, chloride, and boron. The source
of boron is usually household detergents or discharges from industrial plants.
Chloride and sodium also increase during domestic usage, especially where water
softeners are used. For sensitive crops, toxicity is difficult to correct
without changing the crop or the water supply. The problem is usually
accentuated by severe (hot) climatic conditions Soil permeability In addition
to their effects on the plant, sodium in irrigation water may affect soil
structure and reduce the rate at which water moves into the soil as well as
reduce soil aeration. If the infiltration rate is greatly reduced, it may be impossible
to supply the crop or landscape plant with enough water for good growth. A
permeability problem usually occurs in the surface few centimeters of the soil
and is mainly related to a relatively high sodium or very low calcium content
in this zone or in the applied water. At a given SAR, the infiltration rate
increases as salinity increases or decreases as salinity decreases. Therefore,
SAR and ECw should be used in combination to evaluate the potential
permeability problem. Sometimes, treated wastewaters are relatively high in
sodium and the resulting high SAR is a major concern in planning wastewater
reuse projects. Chemical or biological amendments are needed over time to
prevent soil structural degradation when irrigating exclusively with sodic water.
On calcareous soils that contain appreciable amounts of precipitated or native
calcite (CaCO3), the dissolution of calcite in the root zone is
enhanced by adding acid formers and by the actions of plant roots that increase
the levels of carbon dioxide, thereby providing soluble calcium to offset
sodium effect
Clogging
problems with sprinkler and drip irrigation systems have been reported when
treated municipal wastewater is used. The most frequent clogging problems occur
with drip irrigation systems. In drip irrigation, vortex emitters were more
sensitive to clogging than labyrinth emitters and no significant difference was
observed between the same kind of emitter placed on soil or sub-soil; in
filters, gravel media and disk filters assured better performance than screen
filters. Another possible problem of the wastewater reuse is the excessive
residual chlorine in treated effluent. Residual chlorine causes plant damage
when sprinklers are used if the high chlorine residual exists at the time the
effluent is sprinkled on plant foliage. Residual chlorine less than 1 mg/l
should not affect plant foliage, but when chlorine residual is in excess of 5
mg/l, severe plant damage can occur.
Possible
solutions of problems associated with the sewage and industrial effluents
To exploit the sewage waters as a potential
source of irrigation and maintain environment the sewage waters must be diluted
either with canal or underground water to a avoid the excessive accumulation of
soluble salts in the soils. It will help in maintaining the productivity of
agricultural crop without any harmful effect on soil properties.
Entry of heavy metals into food chain can be
reduced by adopting soil and crop management practices, which immobilize these
metals in soils and reduce their uptake by plants.
Heavy
phosphate application and also the application of kaolin / zeolite to soils can
reduce the availability of heavy metals.
Application of organic manures can mitigate
the adverse effect of the toxic metals on crops. Thus in the soil contaminated
with high amount of toxic metals, application of organic manures is recommended
to boost the yield potentials as well as decrease the metal availability to
plants.
Raising hyper accumulator plants
(mustard/trees) in toxic metals contaminated soils is recommended to avoid the
entry of toxic metal in the food chain.
Permissible
limits for land application
|
S.No. |
Parameters |
Maximum permissible limit |
|
1 |
Color and
odor |
- |
|
2 |
Suspended
Solids, mg/L |
200 |
|
3 |
Particle
size of Suspended solid |
- |
|
4 |
Dissolved
solids (inorganic) mg/L |
2100 |
|
5 |
pH value |
5-9 |
|
6 |
Temperature |
- |
|
7 |
Oil &
Grease, mg/L |
10 |
|
8 |
Biochemical
Oxygen Demand (3 days at 27 0C), mg/L |
100 |
|
9 |
Chemical
Oxygen Demand, mg/L |
- |
|
10 |
Arsenic (as
As), mg/L |
0.2 |
|
11 |
Mercury (as
Hg), mg/L |
0.01 |
|
12 |
Chlorides
(mg L-1) |
600 |
|
13 |
Sulphates
(mg L-1) |
1000 |
|
14 |
Total Cr (mg
L-1) |
- |
|
15 |
Cr (VI) (mg
L-1) |
- |
|
16 |
Fluoride (mg
L-1) |
- |
|
17 |
Faecal
coliforms |
- |
Case study
It's been called
"toilet-to-tap" – much to the chagrin of water
experts and managers. In some parts of the world, the
wastewater that flows down the drain – yes,
including toilet flushes – is now being filtered
and treated until it's as pure as spring water, if not more so.
It might not sound
appealing, but recycled water is safe and tastes like any
other drinking water, bottled or tap. "If anything,
recycled wastewater is relatively sweet," says Anas Ghadouani,
an environmental engineer at the University of Western Australia in Crawley.
Still, for some people, the
prospect of drinking recycled wastewater is literally hard to swallow.
But spurred by drought
and growing populations, many cities are already
incorporating recycled wastewater into the water supply. Not only is
recycling becoming a necessity, a sustainable water
future will demand it.
So if you
aren't already drinking recycled wastewater,
you soon will be. "It's a no-brainer," Ghadouani says.
"It's what's going to happen."
Wastewater
is much more than toilet water, of course. Think of all the
water that goes down the drain every time you rinse an apple or hose
off your car. That water is an untapped resource, and there's a
lot of it. "It is cheaper; it is a guaranteed
resource," says Peter Scales, a chemical engineer at the
University of Melbourne in Australia. If an average city recycled all
its wastewater, he says, it could reduce how much water it
needed by 60%.
Recycling
wastewater for irrigation and other non-drinkable uses is
already commonplace. It’s actually the same technology used to treat
drinking water supplies that have become contaminated – and it’s been
around for years.
For some people, no matter how
much you tell them the water is safe to drink, the feeling of
disgust is too much to overcome
First, you have to filter out
all of the solids and other gunk in the water. Then, in a process called
reverse osmosis, you filter out the tiniest of particles. And as an extra
precaution, the water is often flashed with ultraviolet light to sterilise
pathogenic microbes. "We can supply water in a very pure state – purer
than what they currently get out of reservoirs and rivers,"
Scales says.
But inevitably, there's a "yuck"
factor. Recently, psychologist Paul Rozin of the University of
Pennsylvania in the US and a team of researchers surveyed
2,000 Americans, finding that while 49% were willing to try
recycled wastewater, 13% refused, and the rest weren't sure. For some
people, no matter how much you tell them the water is safe to drink, the feeling
of disgust is too much to overcome – even in the direst of
situations.
Political problem
In 2006, for
example, a drought-stricken city in eastern Australia named Toowoomba
tried to implement wastewater recycling. But the effort was a
political disaster, as 62% of voters rejected the plan in a
referendum. "Water recycling is enormously powerful, but
it's politically a real problem," says Scales.
Dwindling water supplies
forced Toowoomba officials into a desperate situation, and they
tried to introduce wastewater recycling without giving people time to get used
to the idea, says Clare Lugar, a spokesperson for the Water
Corporation, the water company for Perth and Western
Australia – a region that's been experiencing drought
for 15 years. The corporation has been integrating wastewater
recycling into its own supply. But it's taking a lesson from
Toowoomba and going slowly.
Western Australia is already
one of the driest places on Earth, and climate change has likely made
it worse. "It's sort of a hotspot for drought," Ghadouani says.
"That's what the models predicted, and that's exactly what's
happening." Last year, for example, Perth's dams received only 72.4
billion litres of water – less than a third of what's needed.
To alleviate the drought,
the Water Corporation turned to desalination in 2006, using
offshore plants to convert salt water into fresh. Desalination
is expensive, but effective. Today, desalination accounts for
39% of the region's water supply. Groundwater provides 43%, and
reservoirs supply the rest. But with continuing drought and an
increasing population, recycled wastewater would provide extra security at less
cost.
Eventually, recycled
wastewater could provide 20% of Perth's water supply
The corporation
is modelling its approach on what Orange County,
California, is doing: pumping recycled wastewater into aquifers to replenish
the ground supply. The aquifers provide free storage, which would
otherwise be expensive, and act as a psychological buffer
to minimise the "yuck" factor. Even though the
water is already drinkable, some people feel the water gets
naturally purified through the ground.
In 2012, Water
Corporation finished a three-year trial in which it recycled millions of
litres of water and tried to change hearts and minds about the process. It
built a visitor's centre and representatives gave tours of the water
recycling plant and spoke to various local government, community, and
Aboriginal groups. This grassroots approach appears to be working, as
surveys consistently show 70% support. "Our success has been
more about the community engagement and getting that right," Lugar says.
They're now ramping
up their capabilities, having recycled 10 billion litres in
Perth from 2013 to 2014. Next year, the Water Corporation will
unveil a full-scale plant that can routinely recycle 14 billion
litres of water annually, and up to 28 billion if needed.
Eventually, recycled wastewater could provide 20% of Perth's
water supply.
Riches of rain
The combination of recycling,
desalination, and – perhaps most importantly – conservation
is helping to make Perth drought-proof. "We've become a case study
internationally for other countries in terms of how we've managed our response
to the drying climate," Lugar says.
That kind
of multi-faceted approach is crucial. For example, Scales says,
another untapped water source is rain, and if you recycle wastewater
and collect all the storm-water that drains into the gutter, you
could provide water for an entire city.
But making people comfortable
with recycling and building the infrastructure to
collect storm-water would take years or even decades. "Trying
to do augmentation from something like wastewater or storm-water in the middle
of a drought is not going to get you there," he says. "You
need to actually do it across a period of time where the population assimilates
to it. And then they just use it."
Places like Singapore,
Belgium, Windhoek in Namibia, and Wichita Falls in Texas have all begun
recycling wastewater. Eventually, due to growing
populations, so must the rest of the
world – regardless of drought or climate change. "There's no
choice," Scales says.
Treating contaminated water
uses the same process as recycling wastewater
In most of
the world's largest cities, such
as the metropolises of Asia and South
America, the lack of drinkable tap water leads to
diseases. "It's because their surface water supplies are contaminated
with wastewater," he says. But
treating contaminated water uses the
same process as recycling wastewater. Technologically speaking, then,
the problems are identical.
So whatever you
call the process – purification, recycling, or
"toilet-to-tap" – it amounts to the same thing: clean water
for all.
posted by Dr.C.Prabakaran @ October 27, 2022
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