Abstract

Chemical looping combustion (CLC) of biomass is a promising technology for power generation with integrated carbon capture. In CLC, alkali content of biomass poses potential issues of bed agglomeration, as well as heat exchanger fouling and corrosion. The fate of biomass alkalis was investigated in a dual-interconnected circulating fluidized bed CLC system. Experiments were conducted in oxygen carrier aided combustion (OCAC) and CLC modes. Ilmenite and braunite oxygen carriers and three biomass fuels (wood pellets, wood char, straw pellets) were tested. Flue gas alkali emissions in the air reactor (AR) and fuel reactor (FR) were measured with a surface ionization detector (SID). Results showed that CLC operation yields gas-phase alkali emissions that are up to 15 times higher than in comparable OCAC operation. Results analysis concluded that increased alkali emissions in CLC arise from the steam atmosphere in the FR, whereby steam accelerates the decomposition of alkali compounds in the biomass. Retention of alkalis in the condensed phase was found to be >97% for ilmenite and >92% for braunite CLC operation. Up to 60–80% of the retention was attributed to fuel ash formation. The residual retention was attributed to absorption of alkalis by the oxygen carriers. Absorption likely occurred mainly through formation of alkali manganates and silicates in braunite, and formation of alkali silicates, aluminosilicates, manganates, and titanates in ilmenite. Gas-phase alkali emissions in the AR, although less than in the FR, were found to occur due to combustion of unconverted fuel carried over from the FR to the AR.

Highlights

  • Chemical looping combustion (CLC) is a novel thermal fuel conver­ sion technology with inherent carbon dioxide capture [1]

  • Oxygen carrier aided combustion (OCAC) and CLC tests were conducted with three different biomass fuels of varying alkali content, and two oxygen carrier materials

  • Results show that CLC operation results in higher gas-phase alkali release, when compared to oxygen carrier aided combustion (OCAC) operation

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Summary

Introduction

Chemical looping combustion (CLC) is a novel thermal fuel conver­ sion technology with inherent carbon dioxide capture [1]. In CLC, an oxygen carrier (OC) material, typically a metal oxide, is circulated be­ tween two interconnected reactors. Chemical looping combustion of solid fuels, whether fossil or biomass-derived, is complicated by the fact that solid fuels need to decompose to gaseous species in order to react with the oxygen carrier. The volatile fraction is devolatilized, leaving behind solid char and inorganic matter. Steam or CO2 act as a gasification agent, converting the solid char to CO and H2. The volatiles released in devolatilization and the gasification products generated from char gasification react with the oxygen carrier in a gas–solid reaction [14]

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