Media Release
19 November 2009
World first in bio-crude oil
World’s largest wastewater algae to bio-crude oil demonstration puts CO2 to good use.
This week will see the Minister of Energy Hon Gerry Brownlee open the largest wastewater algae to bio-crude oil
demonstration project in the world.
The bio-crude from wastewater algae system is a technology for the future – it enables renewable fuel production while
achieving low cost, energy efficient wastewater treatment, nutrient recovery, and greenhouse gas abatement.
The project combines NIWA’s scientific expertise on advanced wastewater treatment and algal production pond technology
with Solray’s bio-crude oil conversion technology and is hosted by Christchurch City Council at the Christchurch
Wastewater Treatment Plant.
“The reality is that no one in the world has done anything on this scale. Our trial aims to show that this complete
process can be cost effective and efficient”, says pioneering NIWA Algal Pond Scientist, Dr Rupert Craggs.
The process creates value at every step - it treats wastewater, recovers wastewater nutrients as fertiliser, removes
carbon dioxide from flue gas, and creates biofuel.
The Christchurch wastewater treatment plant has 230 hectares of polishing ponds that are currently used to provide
disinfection of the treated wastewater prior to discharge.
It is in one of these ponds that five hectares have been cordoned off by NIWA and converted into a series of specially
designed High Rate Algal Ponds with carbon dioxide (CO2) addition.
“Adding CO2 into the ponds enhances wastewater treatment and doubles algal production – biofuel production could be a
great co-benefit for the community from its wastewater treatment” says Dr Craggs.
Another advantage of High Rate Algal Ponds is that the algae growing in these systems can be easily harvested by simple
gravity settling – the harvested algal biomass can then be used as either a fertiliser or feed for livestock and
aquaculture, or, as is this case with this demonstration, be converted to biofuel and the residue used as fertiliser.
The algae is collected from the harvesters and pumped to Solray’s specially designed “Super Critical Water Reactor”
where pressure and heat converts it to bio-crude oil. The bio-crude, like fossil crude oil, can then be refined into
LPG, petrol, kerosene, diesel, bitumen, and other oil based products.
“This process is essentially the same as nature used many millions of years ago to create the oilfields of the world we
are currently rapidly depleting”
says Chris Bathurst, Solray Energy Ltd.
The Foundation for Research Science and Technology funded three year trial is in its first year and may in time generate
fuel that the Christchurch City Council can use to power facilities in the city.
The aim of the project is for NIWA to produce between 150 and 300 tonnes of algae per year from the 5 hectares of
wastewater treatment High Rate Algal Ponds. After harvesting and dewatering, this algae could potentially be converted
into 45,000 - 90,000 litres (275 - 550 barrels) of bio-crude oil by Solray.
This bio-crude oil would normally be converted into a variety of products such as LPG, petrol, kerosene, diesel and
bitumen, but if this amount were completely converted to petrol, it would power between 22 and 45 cars per year.
Christchurch City Council, Unit Manager City Water and Waste, Mark Christison says “The City Council is very interested
in the project, both in terms of how the High Rate Algal Ponds can remove nutrients from the wastewater and the energy
efficiency of Super Critical Water Reactor conversion of algal biomass into bio-crude oil.”
This trial is the culmination of over twelve years of research into High Rate Algal Pond wastewater treatment by NIWA
and will demonstrate the commercial feasibility of algal biofuel production from these advanced wastewater treatment
ponds which are a cost-effective way to upgrade the oxidation ponds currently used to treat the wastewater from many New
Zealand communities.
The bio-crude oil opening is this Friday 20th November 1.45 - 2.30 pm.
ENDS