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Demineralization of Food Waste Biochar for Effective Alleviation of Alkali and Alkali Earth Metal Species

Yoonah Jeong, Ye-Eun Lee, Dong-Chul Shin, Kwang‐Ho Ahn, Jinhong Jung, Hyo-Tae Kim

2020Processes11 citationsDOIOpen Access PDF

Abstract

Ash-related issues from a considerable amount of alkali and alkaline earth metal species in biochar are major obstacles to the widespread application of biomass in thermoelectric plants. In this study, food wastes were converted into biochar through pyrolysis at 450 °C or 500 °C and four different demineralization approaches, using deionized water, citric acid, nitric acid, and CO2 saturated water. The chemical properties of the resulting biochars were investigated, including proximate analysis, concentrations of inorganic species in biochar and ash, and the crystalline structure. All demineralization treatments produced food waste biochar with sufficient calorific value (>4000 kcal/kg) and a chlorine concentration <0.5%. Among the inorganic species in biochar, Na and K exhibited a significantly higher removal rate through demineralization, which ranged from 54.1%–85.6% and 53.6%–89.9%, respectively; the removal rates of Ca and Mg were lower than 50.0%. The demineralization method was more critical than the pyrolysis temperature in the removal of alkali and alkaline earth metals. Especially, the lower slagging and fouling tendency was expected for the biochar demineralized with citric acid. Our results suggested that food waste biochar pyrolyzed at 500 °C and demineralized with citric acid is a promising co-firing material for electric power generation in thermoelectric power plants.

Topics & Concepts

BiocharDemineralizationCitric acidPyrolysisChemistryAlkali metalAlkaline earth metalEnvironmental chemistryPulp and paper industryNuclear chemistryMaterials scienceFood scienceOrganic chemistryEnamel paintEngineeringComposite materialThermochemical Biomass Conversion ProcessesCoal and Its By-productsSustainable Development and Environmental Management