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Reference Number EP/S032517/1
Title BIOHEAT: Husbanding biological heat to transform wastewater treatment
Status Started
Energy Categories ENERGY EFFICIENCY(Industry) 50%;
RENEWABLE ENERGY SOURCES(Bio-Energy, Applications for heat and electricity) 50%;
Research Types Basic and strategic applied research 100%
Science and Technology Fields BIOLOGICAL AND AGRICULTURAL SCIENCES (Biological Sciences) 50%;
ENGINEERING AND TECHNOLOGY (Mechanical, Aeronautical and Manufacturing Engineering) 25%;
UKERC Cross Cutting Characterisation Not Cross-cutting 100%
Principal Investigator Dr E Heidrich
No email address given
Sch of Engineering
Newcastle University
Award Type Standard
Funding Source EPSRC
Start Date 01 December 2019
End Date 30 November 2022
Duration 36 months
Total Grant Value £304,131
Industrial Sectors Water
Region North East
Programme NC : Engineering
Investigators Principal Investigator Dr E Heidrich , Sch of Engineering, Newcastle University (100.000%)
  Industrial Collaborator Project Contact , Northumbrian Water Ltd (0.000%)
Project Contact , Helmholtz Association of German Research Centres (0.000%)
Project Contact , CentraleSupélec, France (0.000%)
Web Site
Abstract The world's population stands at 7.5 billion and the UN predicts this could rise to 11 billion by 2100 with increasing urbanisation (13). The production of human wastes and wastewaters in an unavoidable consequence of life. Treating this so it can be safely released to the environment is of paramount importance to both human health and the ecosystems we depend on. Effective technologies exist which are able to treat the large volumes of wastewater produced in urban areas, but these have changed little in the last 100 years. Activated sludge is the most prevalent method used (by volume treated) but it is energy intensive, accounting for as much as 3% of electricity consumption in developed economies (15). Furthermore 80% of the world's wastewater goes into receiving waters untreated (16). This technology is expensive and unsustainable for some, but for large parts of the world is simple unaffordable.A large proportion (roughly 50%) of the energetic costs in the activated sludge process comes from the need to bubble oxygen through the large tanks of sewage, such that the aerobic bacteria within these wastes can use the oxygen to digest the organic matter to carbon dioxide within the waste, making it safe to release to the environment. However there is energy contained within these organics in the wastewater. In activated sludge all this energy goes to the microorganisms, and we as engineers are unable to access it. Thus although effective, the activated sludge process uses substantial amounts of energy to get rid of the energy within the wastewater.If we are to move to a more sustainable form of wastewater treatment, the aerobic activated sludge process need to be replaced by an anaerobic technology. Anaerobic technologies also use naturally occurring bacteria to digest waste, but here as oxygen is not present the bacteria must produce a different waste, methane in the case of classical anaerobic digestion, or electrons in the case of Bioelectrochemical digestion. In this scenario the bacteria take only some of the energy contained in the wastewater, and we as engineers can take the rest. Anaerobic digestion has also been around for 100 years and is used on many farm and industrial waste streams as well as on the sludge produced by wastewater treatment sites. However it is not effective at treating wastewaters which are dilute, and is not effective at the lower temperatures which are typical of the UK and other countries. Bioelectrochemical systems (BES) are a newly developing technology that use specialised bacteria to grow on an electrode and produce currents as they digest the wastes, essentially acting like a biological battery. BES technologies have been shown to work with dilute wastewaters and at low temperatures, however they are not energetically efficient, with up to 90% of the total input energy going missing.Some of this energy will go to the bacteria as they metabolise, but some will be lost as heat. I hypothesise that when these bacteria live together attached to a surface in a biofilm, such as on an electrode, the heat generated is creating a localised warm environment allowing bacteria to survive and metabolise at low wastewater temperatures. Currently we do not know how much energy is going to heat, and nor do we have the ability to accurately quantify it. The aim of this grant is to develop a platform to make these critical measurements in order that we will then be able to engineer and husband the heat energy to transform wastewater treatment.
Publications (none)
Final Report (none)
Added to Database 19/08/19