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Bio4Energy researchers are behind a breakthrough innovation that can be used to make bio-based and biodegradable hydrogels. Hydrogels are key components in materials used to restore or maintain human health such as wound healing, tissue engineering, artificial organs or everyday contact lenses. The ingenuity of hydrogels lies in a dichotomy: While they are able to […]
Bio4Energy wants to wish its members and followers a Merry Christmas and a Happy New Year! What have you got coming for 2023? Bio4Energy has more research and development, a new course in the Bio4Energy Graduate School, as well as a continued aim for excellence and usefulness of results produced. We hope that you will […]
While a part of the research community is trying to develop plastics from bio-based materials; as an alternative to petrochemicals; a group of Bio4Energy researchers are looking at how to reuse or recycle traditional plastic using bio-based processes. Two projects were granted last month, one by the national funders Swedish Research Council and more recently […]
A Bio4Energy research leader has been appointed Innovator of the Year by his employer Luleå University of Technology, Sweden, for developing energy-efficient technology for biogas upgrading for use as vehicle fuel. Professor Jonas Hedlund and his team on Bio4Energy Catalysis and Separation have a history of developing and perfecting membranes from zeolites. The latter are microporous, crystalline aluminosilicate materials commonly used as commercial […]
Bio4Energy researchers have won funds from the Swedish Research Council for multi-annual projects on “upcycling” of plastic waste, evaluation of carbon nano materials for use in electrodes and photothermal imaging of fatty acids and droplets. The projects and their participants are acknowledged as follows:
A project consortium including research groups, technology development companies, plant owners and iron and steel industry; is about to take a large step toward phasing out the use of fossil coal in the iron and steel industries in Sweden.
Thanks to a substantial grant from the Swedish Energy Agency, the partners will be able to deliver a reactor concept and a roadmap detailing the way in which to implement a switch from fossil coal to biocarbon in existing district-heating plants, using fluidised-bed gasification technology.
Whereas fossilised coal is extracted from the Earth’s interior in mining operations, oftentimes transported over long distances and a potent source of greenhouse gas emissions; biocarbon is high-temperature treated biomass from woody residue or industrial bio-based waste that will be sourced regionally by the partners.
In fact, when treated at a temperature range of 500 – 900 degrees Celsius, biomass becomes almost pure solid carbon and earns the name “biocarbon”. It is seen as carbon “neutral” under the current regulatory framework and so the expectation is that the new technology will deliver net zero emissions of carbon dioxide, the greenhouse gas.
Seven-to-nine per cent of global emissions of carbon dioxide hail from iron and steel making operations. In Sweden, where the sector is both an important employer and provider of exports, this figure is 12 per cent.
Bio4Energy’s role in the four-year project is to map out what conditions are needed for biocarbon to be a cost-effective alternative to fossil coal, via modeling and laboratory trials. Notably, the research results will show which biomass properties and mixing behavior inside the reactors are optimal. Professor Kentaro Umeki of Luleå University of Technology will lead these efforts, starting now.
“The reaction [inside the reactor or boiler] has to be precisely controlled for the quality and productivity of the steel to be high”, Umeki said in a conference call with Bio4Energy Communications.
“We have been working for six-seven years to optimise the biocarbon properties and yield”, he added, with reference to other projects, running or concluded.
For all the talk about climate change and fossil fuel phase out, Umeki said, there was an important point that tended to be overlooked in the societal debate.
“It is extremely important to know that carbon is still needed as the transition happens. Almost the only source of renewable carbon is biomass.
“Quite many processes for instance in the petrochemical industry still need carbon, even if you do not see it [as a consumer]. The carbon gotten from biomass is the most cost effective”, he said.
A recent estimate for total biocarbon production needed to replace fossil coal in the sector, put the total to between 200,000 and 300,000 tonnes of biocarbon during the years 2030 – 2045, according to background documentation to the consortium’s grant application.
“At the end of the project, there will be a new reactor concept ready to implement and which will provide the industrial partners with up to 80,000 tonnes per annum of biocarbon and a reduction of CO2 emission of about 290,000 tonnes per year”, it said;
“Thus it becomes clear that the proposed technology can deliver future needs of biocarbon to the iron and steel industries on a national level”.
Consortium partners are: Chalmers University of Technology (lead), Luleå University of Technology, RISE Research Institutes of Sweden, BioShare, E.ON, Höganäs and SSAB.
The Bio4Energy research environment is celebrating its 100th thesis defence by a PhD student. Mojtaba Nobandegani, Luleå University of Technology (LTU) receives the honour of being the 100th advanced student to pass his doctoral degree as part of the Bio4Energy cluster. His thesis Adsorption and mass transport in zeolite membranes is part of the research efforts of the platform Bio4Energy Chemical Catalysis and […]
Bio4Energy
Umeå University
SE-90187 UMEÅ
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