Carbon capture and consumption
Could it Eliminate the Need for Wastewater Aeration?
Algal blooms have always proved a challenge for the water
industry. Yet could this organic matter,with the help of wastewater
nutrients, be turned into a biofuel and help alleviate fossil fuel
shortages? Tom Freyberg investigates the European funded All-Gas project.
First generation biofuels from crops never really bloomed into a
fruitful harvest. Opponents criticized using up valuable land to grow
crops and fuel the cars of the rich, instead of filling the stomachs of
the poor. Second generation biofuels – made from biomass - have proved a
lot harder to extract the required fuel and fully crack.
And then along came algae. Unlike first generation biofuels, algae
can be grown using land and water not suitable for plant and food
production.
Consuming solar energy and reproducing itself, algae generates a type
of oil that has a similar molecular structure to petroleum products
produced today. As if this wasn't enough – algae growth also consumes
carbon dioxide, a known major greenhouse gas (GHG).
As a result of the apparent benefits the race is on to commercialize
second and now third generation biofuels, in the case of algae.
Continents and companies are putting money where their mouths are to
find out how what we thought was simply a green weed growing in the sea
could be the answer to inevitable fossil fuel shortages.
Algal culture ponds are used to grow and harvest micro-algae using nutrients contained in wastewater |
Earlier this year US President Barack Obama announced that the
Department of Energy would make $14 million available to support
research and development into biofuels from algae. The Department has
suggested that up to 17% of the US' imported oil for transportation
could be replaced with biofuels derived from the substance.
Meanwhile Europe is going even further and mandating the gradual
replacement of fossil fuels to biofuels. An EU Directive stipulates that
by 2020 a total of 20% of energy needs should be produced by renewable
fuels. A further requirement is that 10% of biofuels need to be met
through transport related activities.
Even UK government backed agency the Carbon Trust has forecast that
by 2030, algae-based biofuels could replace more than 70 billion litres
of fossil fuels used every year around the world in road transportation
and aviation.
Nutrients: burden or blessing?
So far, so good. Yet while algae derived biofuels sound like an
answer to inevitable fossil fuel shortages, two challenges remain: space
and nutrients. The first challenge will be addressed later but on the
topic of nutrients, phosphorous and ammonia are required alongside sun
light and carbon dioxide to "feed" the algae. And with up to 30% of
operating costs at algae farms attributed to buying and adding in such
nutrients, it's a notable expense.
It is in response to this particular challenge where the wastewater
sector could play its part, with untreated effluent being a known source
of phosphorous and other nutrients. An EU funded project aims to bring
together the challenge and solution and link the water and biofuel
industries together.
The €12 million, five-year project is starting at water management
company aqualia's wastewater treatment plant in Chiclana, Southern Spain
and is backed by the European Union as part of its FP7 program –
supporting energy-related projects - with six partners.
Called All-Gas, which translates into algae in Spanish, the project
will see "algal culture ponds" being used to grow micro-algae using
nutrients contained in wastewater, such as phosphorous. A 10-hectare
site will eventually be needed for the project. Frank Rogalla, head of
R&D at aqualia, says nutrients are abundant in wastewater, so it
makes sense to incorporate the two industries.
Traditionally aeration processes at wastewater treatment plants are
heavy energy users, accounting for up to 30% of a facility's operating
costs. In the US, according to the Environmental Protection Agency,
drinking water and wastewater systems account for between 3% and 4% of
national energy consumption alone.
However, Rogalla later told Water & Wastewater International
magazine (WWi) that growing algae with wastewater can eliminate the need
for aeration, thus reducing energy use.
He said: "We have converted our treatment to anaeraobic
pre-treatment, meaning we will generate biogas from the start instead of
destroying organic matter, so no aeration will be needed. From the 0.5
kWh [kilowatt-hour] per m3 which you generally spend for
aeration, that will be completely gone. We will have a net output of
energy from algae conversion either to oils or to gas. So that's why you
get this positive output of 0.4 kWh per m3 of wastewater treated."
Rogalla added: "It will not cost more than traditional wastewater
treatment, which costs about 0.2 Euros per cubic metre. We think we will
use the same operational costs but instead of consuming energy we will
produce additional benefit, meaning we generate about 0.2 Euros per
cubic metre in additional profit from the fuel. Our aim is to be cost
neutral."
So the question has to be asked of how, technically, can the proposed
treatment eliminate the need for wastewater aeration? The answer, as
Rogalla later tells WWi, is through the initial conversion to biogas.
Compared to nitrification and dentrification to eliminate nutrients
in conventional wastewater treatment, a process Rogalla says consumes
about 5 kWh/kg Nitrogen during aeration, All-Gas will use an alternative
conversion. Firstly anaerobic pre-treatment will convert most organic
matter into biogas (CH4 and CO2). Algae will then take up the nitrogen and phosphorous.
Productive: instead of using traditional nitrification and dentrification processes, organic matter will instead be converted into biogas |
As the algae will transform most nutrients into biomass, they will also produce O2 in the process, as CO2
is taken up and oxygen released in their metabolic process. As a
result, according to Rogalla, aeration is not necessary. Most organic
carbon is transformed into energy (via biogas), nutrients are
incorporated into algae, which produce oxygen for any polishing action
necessary.
An overview of aqualia's wastewater treatment plant in Chiclana, Southern Spain |
"It only seems logical to use the wastewater nutrients to grow algae
biomass; on the one hand saving the aeration energy, on the other hand
the algae fertilizer and cleaning wastewater without the occurrence of
useless sludge, but producing biofuels and added value instead," Rogalla
adds.
CROATIAN CENTER of RENEWABLE ENERGY SOURCES (CCRES)
special thanks to U.S. Department of Energy | USA.gov
and WaterWorld, Industrial WaterWorld
Space challenges
Addressing the second challenge of space requirements to harness
algae ponds, for a commercial scale operation it's estimated that a 10
hectare site is required (roughly 10 football pitches). Yet when
compared to the oil yields of other crops, algae still proves
favourable.
Data from US-based National Renewable Energy Laboratory (NREL) show
that oil yields from soybeans work out at 400 litres/hectare/year, which
compares to 6,000 for palm oil and theoretically, a potential 60,000
for microalgae. For barrels/hectare/year, the same comparison yields 2.5
for soybeans, 36 for palm oil and a minimum of 360 for microalgae.
As predictions go, the production of 60,000 litres of biofuel from
only one hectare of algae is optimistic compared aqualia's aims for the
Europe project. If a target set by the EU is reached, then each hectare
should produce 20,000 litres of biodiesel. This, the firm says, compares
to 5000 litres of biofuel per hectare per year for biofuels such as
alcohol from sugar cane or biodiesel from palm oil.
The Spanish project also hopes to use produced biogas from the
anaerobic pre-treatment and raw wastewater organic matter as car fuel,
with each hectare touted to treat about 400 m3 per day.
Statistics to one side, the challenge of space remains. Booming urban
populations are expanding closer to rural wastewater treatment plants
but at the same communities insist on an 'out of sight, out of mind'
rule when it comes to infrastructure that treats their waste. Rogalla
does not think the land issue could impede the development of algae
ponds to the majority of wastewater treatment plants. "Algae ponds of
course can be put on marginal lands, or even on rooftops," he adds. "In
rural areas extensive oxidation ponds for wastewater treatment are not
uncommon, not to mention the often unused land areas as buffer zones
around wastewater treatment plants.
Biogas generated from wastewater could mean the 0.5 kWh per m3 usually spent on aeration won't be required |
"As we do not claim that all fuel can be made from biofuel on land,
but only where possible wastewater should be turned into biofuel
(excluding mostly big cities), the land issue seems secondary."
Carbon capture and consumption
One further benefit that has made algae growth attractive compared to
other fuels is its consumption of Greenhouse Gases (GHG), namely CO2,
in order to grow. While captured carbon consumed by algae will
inevitably be released later when used as a fuel in cars, it could still
be a step in the right direction in reducing the impact of a world
still firmly grasping CO2 emitting fuel sources.
An article entitled Algal Biofuels: The Process from NREL in a
Society for Biological Engineering journal suggests that over two
billion tons of CO2 could be captured by growing algae on the space equivalent to the entire U.S. soybean crop of 63.3 million acres.
Power plants and cement kilns appear to be an ideal match for algae
growth, then. Yet, in order for All-Gas to attract seven million Euros
worth of funding for its project, the CO2 had to come from
renewable sources. Any fossil fuel burning plants were not permitted, as
Denise Green, manager of biofuels across Europe and Africa from Hart
Energy Consulting tells WWi.
"This particular call was restricted to projects in which the carbon
dioxide supply for the algae cultivation was provided by renewable
applications, excluding carbon dioxide from fossil fuel installations,"
she says.
"However I see no reason why future funding for algae projects could
not be provided for research into algae as part of the solution for CO2
capture for zero emission power generation. If there are objections to
using algae from fossil fuel installations for transportation fuels,
there are other industries for which algae can be used where this may
not be an issue."
Project roll out and commercialisation
The project will be implemented in two stages, with a prototype
facility being used to confirm the scale of the full-size plant during
the first two years. Once the concept has been proven in full-scale
ponds, a 10 hectare site will be developed and operated at commercial
scale during the next three years.
Rogalla suggests the project could be rolled out among aqualia's
existing facilities along the Mediterranean belt, including Italy,
Portugal, Egypt and even South America, all of which have "favourable
conditions, meaning the climate is advantageous and the land is
available".
Clearly, the conversion of algae to fuel is possible and has been
demonstrated on a laboratory scale. It could hold the potential to turn a
new leaf for biofuels haunted by their unsuccessful and much criticized
first generation brothers. The real interest for the water sector
should be the pipe dream of the project to eliminate aeration and turn
existing wastewater treatment facilities into biofuel production
centres.
The pivotal outcome of the project will be cost. This was proved in
the well documented closure of the US Department of Energy's algae
research programme in 1996 after nearly 20 years of work. At the time it
was estimated that the $40-60/bbl cost of producing algal oil just
couldn't compete with petroleum for the foreseeable future.
However, it is the additional methane extracted from raw wastewater
and algae residue that differentiates this project. It's not just
reliant upon biodiesel produced from the algae. All-Gas has the chance
to spearhead Europe into proving that algae biofuel, through the help of
wastewater, could eventually be more competitive on a per barrel price
with traditional oil.
CCRES ALGAE PROJECT
part of
Croatian Center of Renewable Energy Sources (CCRES)
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