fbpx

Nanoparticle Technology Triples the Production of Biogas

10.22.2014

Researchers of the Catalan Institute of Nanoscience and Nanotechnology (ICN2), a Severo Ochoa Centre of Excellence, and the Universitat Autònoma de Barcelona (UAB) have developed the new BiogàsPlus, a technology which allows increasing the production of biogas by 200% with a controlled introduction of iron oxide nanoparticles to the process of organic waste treatment.

The development of BiogàsPlus was carried out by the ICN2's Inorganic Nanoparticle group, led by ICREA researcher Víctor Puntes, and by the Group of Organic Solid Waste Composting of the UAB School of Engineering, directed by Antoni Sánchez.

The system is based on the use of iron oxide nanoparticles as an additive which "feeds" the bacteria in charge of breaking down organic matter. This additive substantially increases the production of biogas and at the same time transforms the iron nanoparticles into innocuous salt.

"We believe we are offering a totally innovative approach to the improvement of biogas production and organic waste treatment, since this is the first nanoparticle application developed with this in mind. In addition, it offers a significant improvement in the decomposition of organic waste when compared to existing technologies", explains Antoni Sánchez.

According to researchers, today's biogas production is not very efficient - only 30% to 40% of organic matter is converted into biogas - when compared to other energy sources. "The first tests conducted with BiogàsPlus demonstrated that product increases up to 200% the production of this combustible gas. This translates into a profitable and sustainable solution to the processing of organic waste, thus favouring the use of this renewable source of energy", affirms Eudald Casals, ICN2 researcher participating in the project.

At the moment, BiogàsPlus has been successfully applied in cellulose and mud found in urban treatment plants, but it also can be used in different anaerobic digestions, such as agricultural, industrial or urban waste treatments.

"Now the challenge lies in extrapolating the technology to digesters with capacity for hundreds of cubic metres. This would allow using it in large-scale anaerobic digestion processes around the world, thereby greatly increasing the production of biogas, a renewable energy which is growing steadily and is accessible to everyone", Antoni Sánchez explains.

Applied Nanoparticles, a Gateway to the Market 

"Our idea is the result of many projects: you study one thing and discover another", Casals explains. "We were studying the toxicity of iron oxide nanoparticles in the waste treatment of anaerobic biological processes when we discovered that not only were they not toxic, they actually stimulated the production of biogas", he adds.

Researchers saw this discovery as the opportunity to begin a business project and make its application possible. With that in mind, they created Applied Nanoparticles, gestated at the ICN2 and currently in the process of signing a knowledge transfer agreement with the UAB.

"Our business concept focuses on the design of processes with low energy, low toxicity, minimisation of waste and reduction of contaminating emissions", Víctor Puntes affirms. "In addition, the composition of the additive can be optimised according to the waste which must be treated, in order to offer a maximum efficiency to the process." 

Acknowledged Project 

The now patented BiogàsPlus technology received in 2011 a 100,000 dollar grant from the Bill & Melinda Gates Foundation. The grant money went towards testing the capacity of iron oxide nanoparticles, which helped to verify the efficacy of its application in a pilot 100 litre digester. 

This year BiogàsPlus was one of the finalists in the third edition of the Repsol Entrepreneurs Fund. "Our product was born in an academic setting and we decided to send the proposal to the Repsol Foundation, so they could help us further develop the product and get it onto the market", all three researchers comment.

Article cited from: http://goo.gl/SZZ64S 

 

News/Events 

  1. We need to get behind Renewable Natural Gas
  2. Difference between a Turbo and Positive Displacement Blower
  3. The Difference between Methane and Natural Gas
  4. First Dairy Biogas Project in Connecticut
  5. Does Renewable Natural Gas Have a Future in Energy?
  6. Biogas Offtake Opportunities For Digesters
  7. Wisconsin Dairy Begins Production of Renewable Natural Gas
  8. Anaerobic Digestion Sector Forming a Clearer Picture
  9. Brightmark to Expand Western New York Dairy Biogas Project
  10. Biogas - The Energy Wonder That's Under Our Noses
  11. Power Generation Achieved by a Self-Assembled Biofuel Cell
  12. Less Carbon Dioxide from Natural Gas
  13. Project Uses Renewable Electricity for RNG Production
  14. Smithfield Hog Farm Provides Natural Gas to Missouri City
  15. From Waste to Gas
  16. Gas Clash Threatens Australian Export
  17. Maximizing Opportunities of Anaerobic Digestion from Wastewater
  18. Catalyst to Speed up Conversion of Biomass to Biofuel
  19. How It Works: Ethanol
  20. Anaerobic Digestion - the Next Big Renewable Energy Source
  21. Anaerobic Additions
  22. Three (3) Tech Solutions for Modern Landfills
  23. The Costs and Benefits of Anaerobic Digesters
  24. Bacteria Farts Power Wastewater Plant in Fort Wayne
  25. Europe’s First Poultry Manure Biogas Plant
  26. Electricity Using Pig Manure
  27. $38-Million Biodigester coming to Grand Rapids
  28. Biochar Could Benefit Anaerobic Digestion of Animal Manure
  29. Getting More out of Anaerobic Digestion
  30. Biogas prevents 20 million tonnes of CO2 emissions per year

 

For additonal reading, please visit us at: News Worthy

Difference between a Turbo and Positive Displacement Blower