6533b823fe1ef96bd127ebf3
RESEARCH PRODUCT
Effect of Tire-Char Ash on the Extent of Synergy during CO2 Cogasification with Hydrochar from Potassium-Rich Coconut Fiber
Reza KhoshbouyFumitake TakahashiSaleem UllahDouglas HungweKunio YoshikawaLu Dingsubject
biohiiliThermogravimetric analysisChemistry020209 energyGeneral Chemical EngineeringPotassiumtechnology industry and agricultureEnergy Engineering and Power Technologychemistry.chemical_element02 engineering and technologykumicomplex mixturesjätepolttoaineetkaasutusFuel Technologykookos020401 chemical engineeringChemical engineeringsynergia0202 electrical engineering electronic engineering information engineeringbiomassa (teollisuus)FiberChar0204 chemical engineeringdescription
The influence of inherent tire char ash during co-gasification with coconut hydrochar prepared at different intensities was investigated by thermogravimetric analysis to ascertain the extent to which synergistic interaction, reactivity, and activation energy reduction were altered. High-ash tire tread (TT) and low-ash sidewall (SW) both exhibited enhanced synergy, reactivity, and activation reduction upon co-gasification with hydrochars; however, the extent of promotion was more pronounced in SW-hydrochar blends. This difference was caused by the inhibiting nature of TT inherent ash, particularly the role of Si-containing compounds. Inhibition in TT-hydrochar blends was mainly due to the promotion of alkaline and alkaline earth metal transformation into inactive silicates, and to a lesser extent, the mass transfer effect caused by accumulated ash, especially at conversions higher than 70\%. The extent of enhancement correlated well with the concentration of available alkaline and alkaline earth metals. The findings may be useful in justifying the exclusion of high ash tire char as gasification feedstock to mitigate ash-related problems. peerReviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-06-09 | Energy & Fuels |