6533b7d7fe1ef96bd1267b82
RESEARCH PRODUCT
Electric Field Effect on the Thermal Decomposition and Co-combustion of Straw with Solid Fuel Pellets
Maija ZakeUldis StrautinsRaimonds ValdmanisSergejs VostrikovsHarijs KalisInesa BarminaAntons Kolmičkovssubject
Flue gasControl and OptimizationMaterials science020209 energyPelletsEnergy Engineering and Power TechnologyDC electric field02 engineering and technology010501 environmental sciencesCombustion01 natural scienceslcsh:TechnologyMass transferElectric field0202 electrical engineering electronic engineering information engineeringElectrical and Electronic EngineeringComposite materialco-firingEngineering (miscellaneous)thermal decomposition0105 earth and related environmental scienceswheat strawRenewable Energy Sustainability and the Environmentlcsh:Tbog peatSolid fuelpelletsAdiabatic flame temperaturesoftwoodCombustion chamberEnergy (miscellaneous)combustiondescription
The aim of this study was to provide more effective use of straw for energy production by co-firing wheat straw pellets with solid fuels (wood, peat pellets) under additional electric control of the combustion characteristics at thermo-chemical conversion of fuel mixtures. Effects of the DC electric field on the main combustion characteristics were studied experimentally using a fixed-bed experimental setup with a heat output up to 4 kW. An axisymmetric electric field was applied to the flame base between the positively charged electrode and the grounded wall of the combustion chamber. The experimental study includes local measurements of the composition of the gasification gas, flame temperature, heat output, combustion efficiency and of the composition of the flue gas considering the variation of the bias voltage of the electrode. A mathematical model of the field-induced thermo-chemical conversion of combustible volatiles has been built using MATLAB. The results confirm that the electric field-induced processes of heat and mass transfer allow to control and improve the main combustion characteristics thus enhancing the fuel burnout and increasing the heat output from the device up to 14% and the produced heat per mass of burned solid fuel up to 7%.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-04-22 | Energies |