Project description
Innovative low-grade waste heat harvesting
Conversion, transportation and end-use processes result in massive amounts of energy waste in the form of low-grade heat. Existing technologies for conversion of low-grade waste heat into electricity are expensive. The EU-funded EHAWEDRY project proposes an innovative conversion concept that relies on coupling charging/discharging cycles of electrochemical supercapacitors with the drying/wetting of their nanoporous electrodes. The concept exploits the proportionality of the capacitor capacity to its electrode/electrolyte contact area. The project envisages an innovative harvester prototype that reaches volumetric power densities, comparable to established waste heat recovery technologies such as Rankine cycle engines. The prototype presents design flexibility, scalability and potential for the cost-effective harvesting of low-grade waste heat.
Objective
Huge amounts of energy are wasted as low grade heat during conversion, transportation and end use. While several technologies can convert heat into electricity, none of them is cost-effective for the conversion of low-grade waste heat. EHAWEDRY proposes a radically new concept for converting low grade waste heat into electricity. EHAWEDRY will couple charging/discharging cycles of electrochemical super-capacitors with the drying/wetting of their nanoporous electrodes, exploiting the proportionality of the capacitor capacity to its electrode/electrolyte contact area. Previous attempts to couple charging/discharging cycles with changes in the electrode/electrolyte contact area aimed at harvesting the mechanical energy used to drive the change in the contact area. The power generated by these mechanical energy harvesters is relatively low, mainly because they have to use smooth capacitor plates (electrodes) to avoid generating too large capillary forces counteracting the harvested displacement. EHAWEDRY proposes a paradigm shift from the energy harvesting strategies previously used. Instead of mechanically changing the electrode/electrolyte contact area by displacing smooth electrodes, EHAWEDRY will change the electrode/electrolyte contact area by modifying the electrolyte level within nanoporous electrodes through drying/wetting cycles. The use of nanoporous electrodes will increase by many orders of magnitude the electrode/electrolyte contact area, which will translate into several orders of magnitude larger amounts of harvestable energy per cycle. Via pioneering fundamental research, EHAWEDRY targets the generation of a harvester prototype that reaches a volumetric power densities of the order of 10 kW/m3, comparable to established waste heat recovery technologies such as Rankine cycle engines, but with advantages in terms of cost, design flexibility, scalability and potential for the cost-effective harvesting of low grade waste heat without upgrading.
Fields of science
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectrical engineeringpower engineeringelectric power distribution
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectrical engineeringpower engineeringelectric power generationcombined heat and power
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectrical engineeringpower engineeringelectric power transmission
Keywords
Programme(s)
Funding Scheme
RIA - Research and Innovation actionCoordinator
08034 Barcelona
Spain