2020
DOI: 10.1016/j.apcatb.2019.118329
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Fine structural changes of fluid catalytic catalysts and characterization of coke formed resulting from heavy oil devolatilization

Abstract: Coke formation from heavy oil cracking and the associated change in the porous structure of fluid catalytic cracking (FCC) catalysts has been studied using a comprehensive range of techniques, including 2D and 3D imaging and carbon/coke characterization techniques. The carbon/coke formed from heavy oil devolatilization has been investigated with a range of oilto-FCC catalyst ratios (1:3, 1:2, 1:1, 2:1 and 3:1) to simulate the ageing of FCC catalysts in an operating oil refinery. Carbon/coke was formed on all u… Show more

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Cited by 37 publications
(18 citation statements)
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“…The X-ray nano-CT image also shows that, while the interior porous structure of the pelleted catalyst is slightly affected by the coking, the exterior is significantly modified by coke formation. This is in agreement with the coke deposition from heavy oil devolatilization by using Fluid Catalytic Cracking (FCC) catalyst reported by Zhang et al [35]. The structural changes in the pellets near the exteriors due to coke deposition leading to pore-mouth blockage is behind the rapid deactivation reflected in the API gravity with TOS shown in Figure 2.…”
Section: Coke Formationsupporting
confidence: 90%
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“…The X-ray nano-CT image also shows that, while the interior porous structure of the pelleted catalyst is slightly affected by the coking, the exterior is significantly modified by coke formation. This is in agreement with the coke deposition from heavy oil devolatilization by using Fluid Catalytic Cracking (FCC) catalyst reported by Zhang et al [35]. The structural changes in the pellets near the exteriors due to coke deposition leading to pore-mouth blockage is behind the rapid deactivation reflected in the API gravity with TOS shown in Figure 2.…”
Section: Coke Formationsupporting
confidence: 90%
“…X-ray nano-CT imaging was used to examine coke deposition within the microstructure of the pelleted spent catalyst in full 3D. This imaging technique was utilized by Lomas et al [34] to study metallurgical coke fracture, and Zhang et al [35] to examine coke deposition resulting from catalytic heavy oil devolatilization. The interior reconstruction of the catalyst structure can be obtained, providing details of the microstructural changes that have taken place after reaction.…”
Section: Coke Formationmentioning
confidence: 99%
“…In the first mechanism, at low coke contents, the active site of the catalyst material is covered by coke, which causes catalyst deactivation by preferential blocking of the strongest acid sites. In the second mechanism at high coke contents, pore-clogging causes reduced diffusion in micro-pores [48] (pore sizes < 2 nm [37] ) hindering mass transport of products and feedstock, in turn reducing catalyst efficiency.…”
Section: Introductionmentioning
confidence: 99%
“…It can be concluded from the previous discussion that the heterogeneity in the sulfur spatial distribution can be attributed in part to the fabrication process of the catalyst pellets/extrudates (granular form) as well as the uneven metal-catalyst dispersion. It is to be noted that the pore sizes in the catalyst are below the resolution currently possible to image directly with hard x-ray tomography [31] , [32] and the sample volumes it is possible to probe by electron microscopy are statistically unrepresentative in this case, and therefore gas adsorption was used to further characterize the pore structure.…”
Section: Resultsmentioning
confidence: 99%