Mechanism for Migration and Layer Growth of Biomass Ash on Ilmenite Used for Oxygen Carrier Aided Combustion

Corcoran, Angelica; Knutsson, Pavleta; Lind, Fredrik; Thunman, Henrik

doi:10.1021/acs.energyfuels.8b01888

Cited by 63 publications

(87 citation statements)

References 32 publications

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“…In comparison to real ash interaction, phosphorus from bio ash has also been observed to accumulate on the surface of the ilmenite particles used in large scale experiments. 44 …”

Section: Resultsmentioning

confidence: 99%

Understanding the Interaction of Potassium Salts with an Ilmenite Oxygen Carrier Under Dry and Wet Conditions

et al. 2020

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This study describes how potassium salts representative of those in bio ash affect the reactivity of the oxygen carrier ilmenite under moist and dry conditions. Ilmenite is a bench-mark oxygen carrier for chemical-looping combustion, a technique that can separate CO 2 from flue gases with minimal energy penalty. Different potassium salts were mixed with ilmenite to a concentration of 4 wt % potassium. The salts used were K 2 CO 3 , K 2 SO 4 , KCl, and KH 2 PO 4 . Experiments were performed at 850 °C under alternately oxidizing and reducing conditions in a dry atmosphere or in the presence of steam. Analyses of the oxygen carrier regarding changes in reactivity, structure, and composition followed the exposures. This study showed that salts such as K 2 CO 3 , K 2 SO 4 , and KCl increase the reactivity of the ilmenite. For the samples mixed with KCl, most of the salt was evaporated. KH 2 PO 4 decomposed into KPO 3 , forming layers around the ilmenite particles that lead to agglomeration. Additionally, the KPO 3 layer was more or less nonpermeable for CO and decreased the reactivity toward H 2 significantly in both dry and wet conditions. This decreased reactivity indicates that the concentration of phosphorus in biofuel may have a significant effect on oxygen carrier degradation. It was also observed that the presence of steam changed the chemistry drastically for the nonphosphorus-containing salts. Alkali salts may react with steam, forming volatile KOH that evaporates partly. KOH may also form K-titanates by reaction with the oxygen carrier, leading to segregation of iron and titanium phases in the ilmenite.

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“…In comparison to real ash interaction, phosphorus from bio ash has also been observed to accumulate on the surface of the ilmenite particles used in large scale experiments. 44 …”

Section: Resultsmentioning

confidence: 99%

Understanding the Interaction of Potassium Salts with an Ilmenite Oxygen Carrier Under Dry and Wet Conditions

et al. 2020

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“…Together with TiO 2 (rutile) it builts up KTi 8 O 16 . On the contrary, introduced calcium formed a two-layer structure around the Fe-rich outer layer with increasing operation time building up CaTiO 3 . During further experiments, Corcoran et al examined the mechanical development of sand and rock ilmenite over 15 days of OCAC operation.…”

Section: Theorymentioning

confidence: 99%

“…Nevertheless, the reactivity compared to other, e.g., Ni-based oxygen carrier is quite low, , while the reactivity with syngas is higher as for methane . The increasing porosity of the ilmenite particles during the activation process results in reduced mechanical stability and increased attrition risk in the FBC . However, ilmenite shows good fluidizability and stability in long-term tests …”

Section: Theorymentioning

confidence: 99%

“…31 The increasing porosity of the ilmenite particles during the activation process 26 results in reduced mechanical stability and increased attrition risk in the FBC. 14 However, ilmenite shows good fluidizability and stability in long-term tests. 18 The reactions ilmenite undergoes in the OCAC reactor especially depend on the temperature range applied.…”

Section: ■ Theorymentioning

confidence: 99%

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Investigation of the Oxygen Supply and Distribution in a Bubbling Fluidized Bed by Using Natural Ilmenite for Oxygen Carrier Aided Combustion

et al. 2021

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The application of oxygen carrier materials has one of its origins in the chemical looping combustion processes, which aim at inherent CO2 sequestration by realizing fuel oxidation in the absence of combustion air. This concept can be transferred to conventional fluidized bed combustion processes, the so-called oxygen carrier aided combustion. The replacement of the conventionally applied bed material with an oxygen carrier focuses mainly on large-scale circulating fluidized bed combustion plants. The main stated performance improvements include the reduction of carbon monoxide emissions even at lower excess air ratios and the enhancement of the combustion efficiency. Nevertheless, the ability of shifting oxygen in space and time is of certain interest especially in small-scale bubbling fluidized bed systems. Imperfect fuel mixing, limited residence time in the dense bed zone, as well as limited system complexity often mitigate their combustion performance. Process conditions in bubbling fluidized beds differ from those prevalent in circulating beds regarding bed material particle size distribution, fluidization velocities, or particle volume fraction in the bed. Within this study, the widely used oxygen carrier ilmenite serves as bed material in a laboratory bubbling fluidized bed combustion. The focus was on the oxygen distribution profiles and their shift by ilmenite into the bed during methane combustion. The variation of the excess air ratio, fluidization velocity, and bed height reveal a significant increase of the in-bed CO2 yield (max. 55%) within ilmenite experiments. Moreover, the oxygen conversion profile confirms the shift of the oxygen supply by ilmenite from the lower reactor part to the reduction dominated zone. The amount of shifted oxygen increases at lower excess air ratios. Thus, full conversion is not achieved as kinetics and limited residence time in the bed inhibit the fuel conversion.

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“…Experimetal observations suggest that c) is the most encountered mode of ash-OC interaction. [184,203] For example, Corcoran et al [183] reported the migration of potassium and calcium from the ash layer into the ilmenite particle, forming KTi 8 O 16.5 and CaTiO 3 , respectively. At the same time, a calcium layer mixed with other ash components (e.g., Si and P) gradually developed over the surface of the ilmenite particles.…”

Section: Interaction Between Ocs and Ashmentioning

confidence: 99%

Developing Oxygen Carriers for Chemical Looping Biomass Processing: Challenges and Opportunities

Zhou

Luo

et al. 2020

Advanced Sustainable Systems

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of global average temperature to within 2 °C compared to pre-industrial era, [2] it is necessary to rapidly reduce our reliance on fossil fuels. To this end, tremendous efforts have been put in to ramp up the capacities of renewable energy generation, including solar, wind, hydro, geothermal, tidal, etc. [3] However, non-biological renewables are available intermittenty, location-specific, and require costly infra

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Mechanism for Migration and Layer Growth of Biomass Ash on Ilmenite Used for Oxygen Carrier Aided Combustion

Cited by 63 publications

References 32 publications

Understanding the Interaction of Potassium Salts with an Ilmenite Oxygen Carrier Under Dry and Wet Conditions

Understanding the Interaction of Potassium Salts with an Ilmenite Oxygen Carrier Under Dry and Wet Conditions

Investigation of the Oxygen Supply and Distribution in a Bubbling Fluidized Bed by Using Natural Ilmenite for Oxygen Carrier Aided Combustion

Developing Oxygen Carriers for Chemical Looping Biomass Processing: Challenges and Opportunities

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