Attrition Studies of an Iron Fischer–Tropsch Catalyst Used in a Pilot-Scale Stirred Tank Slurry Reactor

Lin, Tiejun; Meng, Xuan; Shi, Li

doi:10.1021/ie3014428

Cited by 9 publications

(13 citation statements)

References 14 publications

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“…Attrition has been studied for many materials at room temperature, e.g., Fischer-Tropsch catalyst [19][20][21][22][23][24], coal [25,26], glass [27], oxygen carriers [3,[28][29][30], and various crystals [31][32][33]. Lin et al [21] and Bukur et al [20,22] carried out the attrition tests of an iron Fischer-Tropsch (F-T) catalyst in a stirred-tank slurry reactor. They concluded that attrition of the F-T catalyst was induced by both the mechanical stress from particles' collisions and the chemical stress due to phase transformation.…”

Section: Introductionmentioning

confidence: 99%

Influence of Temperature on Fluidized‐Bed Catalyst Attrition Behavior

Hao

Zhao

et al. 2016

Chem Eng & Technol

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Particle attrition is a prevalent problem in fluidized beds due to continuous moving of catalyst particles. It is always operated at high temperature either for lab-or industrial-scale fluidized beds. The influence of temperature on the attrition behavior of commercial methanol-to-olefins (MTO) and fluid catalytic cracking (FCC) catalysts is analyzed in a three-orifice lab-scale fluidized bed device from room temperature to 600°C. The two catalysts are found to be alike in attrition mode. Both change from a combination of abrasion and fragmentation to main abrasion with increasing temperature, but differ greatly in the variation of attrition index with temperature which may be attributed to the difference of material and particle properties. An empirical correlation of attrition index to attrition temperature for all test samples is proposed.

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Section: Introductionmentioning

confidence: 99%

Influence of Temperature on Fluidized‐Bed Catalyst Attrition Behavior

Hao

Zhao

et al. 2016

Chem Eng & Technol

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“…Physical stability issues on the other hand are mainly comprised of attrition and abrasion of catalyst pellets, especially for stirred reactors. 87 Such attrition or abrasion of the catalyst could ultimately pollute the remaining carbohydrate pulp with catalyst particles, hindering further analysis and pulp valorization. Future research should focus on maximizing the catalyst impact resistance, for instance by exploring more stable catalyst 88 supports, like niobia 89 or carbon nitrides.…”

Section: ■ Fundamental Research Questionsmentioning

confidence: 99%

“…However, more pronounced catalyst deactivation requires continuous addition, removal, and regeneration of the catalyst, for example, with slurry bubble column reactors. , The optimization of said regeneration processes for RCF purposes has not yet been tackled by the community and is ideally coupled with extensive catalyst deactivation studies, in close collaboration with the catalyst manufacturers. Physical stability issues on the other hand are mainly comprised of attrition and abrasion of catalyst pellets, especially for stirred reactors . Such attrition or abrasion of the catalyst could ultimately pollute the remaining carbohydrate pulp with catalyst particles, hindering further analysis and pulp valorization.…”

Section: Fundamental Research Questionsmentioning

confidence: 99%

“…However, this strategy demands a complicated postprocess separation of the catalyst and biomass. Alternatively, catalyst pellets can be used, which are more readily retrievable, if abrasion and attrition of these pellets can be avoided. , In jet loop reactors, there are few options to prevent abrasion other than using a highly abrasion resistant catalyst . In stirred tank reactors, the catalyst can be shielded from the rotating equipment by enclosing it in a catalyst basket mitigating physical stability issues, although it could also inflict mass transfer limitations.…”

Section: Reactor Designmentioning

confidence: 99%

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Perspective on Overcoming Scale-Up Hurdles for the Reductive Catalytic Fractionation of Lignocellulose Biomass

Cooreman

Vangeel

Aelst

et al. 2020

Ind. Eng. Chem. Res.

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In the last 5 years, reductive catalytic fractionation of lignocellulose biomass has emerged as a promising biorefinery concept that combines biomass fractionation with the preservation of chemical functionality in its products. Although significant efforts have been made in optimizing this technology on lab scale, the implementation on a larger (pilot) scale is still in its infancy. In our own search for the scale-up potential of this technology, we faced several fundamental and technical research questions that, to this day, remain unanswered. These fundamental questions are related to four main aspects of RCF, the lignocellulose feedstock, the operating pressure, the redox catalyst, and the solvent. In order to inspire future multidisciplinary research in the RCF community, these scale-up challenges are presented and discussed via multiple angles combining chemical process hurdles with more technical aspects, such as reactor design and process consequences.

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“…Owing to the incompatibility in such reaction systems, especially for biphasic reactions involving solid catalysts, vigorous stirring is required to ensure suspension of solid catalyst particles and sufficient mixing of reactants, mitigating mass‐transport resistance 2. However, such vigorous stirring not only requires a large energy input, but causes fragmentation of catalyst particles because of repeated collisions and persistent abrasion, also 3. Recently developed microfluidic and micromixing technologies open a promising avenue towards stirring‐free reactions by enforcing continuous contact between immiscible reactants and catalysts in micrometer‐sized spaces 4.…”

Section: Epoxidation Of Allylic Alcohols In (A) a Static Pickering Emmentioning

confidence: 99%

Micrometer‐Scale Mixing with Pickering Emulsions: Biphasic Reactions without Stirring

Zhang

Yang

2013

ChemSusChem

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A general strategy that avoids stirring for organic/aqueous reactions involving solid catalysts is reported. The strategy involves converting a conventional biphasic system into a Pickering emulsion phase with micrometer-scale droplets ensuring good mixing. In test reactions, nitrotoluene reduction and epoxidation of allylic alcohols, the reaction efficiency is comparable to conventional stirrer-driven biphasic catalysis reaction systems. Short diffusion distances, arising from the compartmentalization of densely packed droplets, play an important role in boosting the reaction efficiency.

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Attrition Studies of an Iron Fischer–Tropsch Catalyst Used in a Pilot-Scale Stirred Tank Slurry Reactor

Cited by 9 publications

References 14 publications

Influence of Temperature on Fluidized‐Bed Catalyst Attrition Behavior

Influence of Temperature on Fluidized‐Bed Catalyst Attrition Behavior

Perspective on Overcoming Scale-Up Hurdles for the Reductive Catalytic Fractionation of Lignocellulose Biomass

Micrometer‐Scale Mixing with Pickering Emulsions: Biphasic Reactions without Stirring

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