Fluid catalytic cracking technology: current status and recent discoveries on catalyst contamination

Peng, Peng; Etim, U.J.; Zhang, Yan; Mintova, Svetlana; Zhang, Zhongdong; Zhong, Ziyi; Gao, Xionghou

doi:10.1080/01614940.2018.1549011

Cited by 92 publications

(67 citation statements)

References 256 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Fluid catalytic cracking (FCC) technology has been (and is still) one of the most important conversion processes in petroleum refinery for converting heavy fractions to more valuable fuels, such as gasoline, diesel, liquefied petroleum gas (LPG), olefinic gases, and some other products [1][2][3]. Due to the high flexibility of operation for different types of feedstocks, such as biomass-derived feedstocks, FCC technology has been long-lasting, and witnessed several stages of developments and revolutions for catalyst, feedstock, process technology, and reactor design [4][5][6]. In other words, the wider diversity of feedstocks, fluctuation of product market, and environmental emissions control have continuously proposed a number of challenges for fresh FCC catalysts, reaction conditions, and even production distribution [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

“…The modern FCC catalyst comprises four major components and additives so as to switch adaptability to change product demand and offer increasing profitability [4,11]. The new developed catalysts are supposed to own high resistance to contaminants from the heavy feedstocks, in addition to excellent hydrothermal stability due to the harsh regenerator conditions [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

“…Hydrothermal deactivation represents the equilibrium activity as a function of a regenerator bed temperature and regeneration bed flue gas water partial pressure, while metal deactivation reflects the influence of metal content on commercial equilibrium catalyst (E-Cat). Several methods are developed to simulate the E-Cat, by loading metal on the fresh catalyst in laboratory, then the artificially E-Cat can be tested on laboratory units, either with fixed bed, fixed fluid bed, the once through, or circulating pilot plant, or the Chemical Reactor Engineering Centre (CREC) Riser Simulator [4,15]. Actually, there are many standard test methods determining the activity (American Society for Testing Materials (ASTM) D3907/D3907M-19) and selectivity (ASTM D5154/D5154M-18, ASTM D7964/D7964M-19) for either E-Cat or laboratory deactivated FCC catalysts, and the microactivity test or Advanced Cracking Evaluation (ACE) test is conducted in either fixed bed (ASTM D5154/D5154M-18) or fluidized bed (ASTM D7964/D7964M-19).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Novel Method to Investigate the Activity Tests of Fresh FCC Catalysts: An Experimental and Prediction Process from Lab Scale to Commercial Scale

Liao

et al. 2021

Processes

View full text Add to dashboard Cite

The issues of feedstocks, product markets, and environmental emissions have continuously proposed a number of challenges for industrial evaluation of fresh fluid catalytic cracking (FCC) catalyst before its application in commercial units. In this work, a convenient method was proposed by comparing with the existing commercial equilibrium catalyst. A series of laboratory experiments for steam treatments and microactivity tests were established to collect reliable data, and the standalone catalyst or co-catalysts were assessed to show the evaluation process and the predicted unit performance. The results had deviation, but a consistent yield distribution than that of a commercial equilibrium catalyst. These evaluations and predictions would provide us with not only the view of hydrothermal stability and yield distribution at the unit level, but also the economic potential for fresh catalyst based on the existing industrial catalyst, which will provide refiners with industrial basis for further decisions.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Novel Method to Investigate the Activity Tests of Fresh FCC Catalysts: An Experimental and Prediction Process from Lab Scale to Commercial Scale

Liao

et al. 2021

Processes

View full text Add to dashboard Cite

show abstract

“…Una mejora realizada a las zeolitas tradicionales del proceso de FCC es la adición de tierras raras como lantano (La), que incrementa la actividad catalítica (Liu et al, 2014). Recientemente, nuevas zeolitas han sido probadas como catalizadores en el proceso de FCC, remplazando a las zeolitas tradicionales, tal es el caso de las zeolitas ITQ-7, ITQ-17, ITQ-21, ITQ-33, ITQ-39, ZSM-20, entre otras (Bai et al, 2018;Castañeda et al, 2006;Vogt et al, 2015). Dichas zeolitas presentan estructuras porosas tridimensionales, adquiriendo propiedades como fuerza ácida similar o mayor a la zeolita ZSM-5 así como una alta estabilidad térmica (Castañeda et al, 2006;Vogt et al, 2015).…”

unclassified

“…Uno de los principales inconvenientes presentes durante el empleo de catalizadores heterogéneos industriales es la desactivación inminente e inevitable con el transcurso del tiempo de los sitios activos, acompañada de la pérdida de actividad catalítica y disminución de la selectividad del producto deseado (Zhou et al, 2020). Por ejemplo: a) el catalizador del proceso FCC se desactiva por la formación de coque depositado sobre la superficie del catalizador (Al-Khattaf, 2002;Bai et al, 2018;Ino et al, 1996); b) el proceso de desactivación de los catalizadores de hidrodesulfuración (HDS) se realiza en tres fases: una desactivación rápida debido a la formación de coque en la superficie del catalizador; una desactivación lenta debida al recubrimiento de la superficie de los catalizadores por metales, como Ni, Va, Na, entre otros, y, una desactivación rápida causada por el bloqueo de los poros del catalizador debida a la deposición de metales y coque (Kallinikos et al, 2008;Seki et al, 2001). Aunado a esto, el proceso HDT genera un subproducto azufrado de reacción, el H 2 S, el cual debe ser eliminado antes de entrar en otras etapas del proceso de refinación, tal es el caso del proceso de hidrogenación para incrementar el número de cetano del diésel, ya que el H 2 S desactiva fácilmente los catalizadores de hidrogenación a base de metales como el Ni y metales nobles, Pt y Pd (Song, 1999;Song y Schmitz, 1997).…”

unclassified

Mecanismos de desactivación de catalizadores heterogéneos

Romero

Sarabia-Bañuelos

Hernández-González

et al. 2020

View full text Add to dashboard Cite

La desactivación catalítica es un problema serio en las diferentes secciones del proceso de refinación del petróleo, que causa la pérdida de actividad catalítica con respecto al tiempo de operación. La presente revisión está enfocada en los mecanismos de desactivación de catalizadores, tales como envenenamiento, ensuciamiento, degradación térmica y sinterización, degradación química y fallas mecánicas como el desgaste y el aplastado del catalizador, en el craqueo catalítico fluidizado (FCC), la hidrodesulfuración (HDS) y el reformado catalítico. Las causas de estos mecanismos de desactivación catalítica son químicos, térmicos y mecánicos. Se revisan las características y consideraciones clave para cada uno de estos tipos de mecanismos de desactivación. Además, el costo total por la desactivación catalítica aumenta gradualmente cada año debido al remplazo del catalizador gastado, generando miles de toneladas de desechos industriales.

show abstract

Dealumination of Y zeolite through an economic and eco‐friendly defect‐engineering strategy

Dong

Zhang

et al. 2023

AIChE Journal

View full text Add to dashboard Cite

A sustainable defect‐engineering strategy for the dealumination of Y zeolite is described. This strategy includes the green synthesis of a well‐crystallized Y zeolite with point defects arising from the incorporation of Fe atoms by using Fe‐containing perlite and the subsequent preparation of ultra‐stable Y (USY) zeolite by efficient steaming dealumination. The systematic characterizations verify that Fe atoms originally existing in the perlite are incorporated into the as‐synthesized Y zeolite and function as point defects, leading to the distortion of framework Al. The step‐by‐step investigation of dealumination process shows that vacancies are formed by the extraction of framework Fe in ammonium exchange, and the framework dealumination is promoted under the combined effect of the distorted framework Al and the formed vacancies during steaming treatment. The resulting USY zeolite owns excellent features in (hydro)thermal stability, pore structure and acid property, and exhibits outstanding catalytic performance in the cracking of n‐octane and 1,3,5‐triisopropylbenzene.

show abstract

Fluid catalytic cracking technology: current status and recent discoveries on catalyst contamination

Cited by 92 publications

References 256 publications

A Novel Method to Investigate the Activity Tests of Fresh FCC Catalysts: An Experimental and Prediction Process from Lab Scale to Commercial Scale

A Novel Method to Investigate the Activity Tests of Fresh FCC Catalysts: An Experimental and Prediction Process from Lab Scale to Commercial Scale

Mecanismos de desactivación de catalizadores heterogéneos

Dealumination of Y zeolite through an economic and eco‐friendly defect‐engineering strategy

Contact Info

Product

Resources

About