Experimental Evaluation of Hydrotreated Vegetable Oils as Novel Feedstocks for Steam-Cracking Process

Karaba, Adam; Němečková, Pavla; Ruskayova, Petra Dvorakova; Carmona, Héctor de Paz; Zámostný, Petr

doi:10.3390/pr9091504

Cited by 7 publications

(6 citation statements)

References 23 publications

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“…These processes fall under the general umbrella of hydroprocessing technologies, which involve the removal of the double bonds and heteroatoms from vegetable oil in the presence of a catalyst and hydrogen atmosphere [32][33][34]. Since hydroprocessed vegetable oils (HVOs) are predominantly n-paraffins, steam cracking of HVO represents an opportunity to produce the molecular building blocks of the plastic industry [35,36]. Karaba et al demonstrated the suitability of HVO for the steam cracking process by obtaining large yields of ethylene (39.9-45.6 wt%), propylene (18.7-19.2 wt%) and C 4 hydrocarbons (15.2-18.2 wt%) from a micro pyrolysis reactor [36].…”

Section: Theoretical Backgroundmentioning

confidence: 99%

“…Since hydroprocessed vegetable oils (HVOs) are predominantly n-paraffins, steam cracking of HVO represents an opportunity to produce the molecular building blocks of the plastic industry [35,36]. Karaba et al demonstrated the suitability of HVO for the steam cracking process by obtaining large yields of ethylene (39.9-45.6 wt%), propylene (18.7-19.2 wt%) and C 4 hydrocarbons (15.2-18.2 wt%) from a micro pyrolysis reactor [36].…”

Section: Theoretical Backgroundmentioning

confidence: 99%

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Fluidized bed steam cracking of rapeseed oil: exploring the direct production of the molecular building blocks for the plastics industry

Mandviwala

González-Arias

Seemann

et al. 2022

Biomass Conv. Bioref.

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Fossil-based production of plastics represents a serious sustainability challenge. The use of renewable and biogenic resources as feedstocks in the plastic industry is imminent. Thermochemical conversion enables the production of the molecular building blocks of plastic materials from widely available biogenic resources. Waste cooking oil (WCO) represents a significant fraction of these resources. This work provides insights into the thermochemical conversion of the fatty acids present in WCO, where rapeseed oil is used as the source of fatty acids. The experimental results reveal that fluidized bed steam cracking of rapeseed oil in the temperature range of 650–750 °C yields a product distribution rich in light olefins and mono aromatics. Up to 51% of light olefins, 15% of mono aromatics, and 13% of light paraffins were recovered through steam cracking. This means that up to 70% of the carbon in rapeseed oil was converted into molecular building blocks in a single step. The main conclusion from this study is that WCO and vegetable oils represent viable biogenic feedstocks for the direct production of the molecular building blocks, where the conversion is achieved through steam cracking in fluidized beds. Graphical abstract

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Section: Theoretical Backgroundmentioning

confidence: 99%

Section: Theoretical Backgroundmentioning

confidence: 99%

Fluidized bed steam cracking of rapeseed oil: exploring the direct production of the molecular building blocks for the plastics industry

Mandviwala

González-Arias

Seemann

et al. 2022

Biomass Conv. Bioref.

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“…Therefore, the use of such crude biomass oils remain a longer-term possibility. Table 1 shows the typical composition of various bio-based feedctocks that can be used for co-processing in refineries [16][17][18][19][20][21][22][23][24][25][26].…”

Section: Feedstocks For Co-processingmentioning

confidence: 99%

Tracking the Biogenic Component of Lower-Carbon Intensive, Co-Processed Fuels—An Overview of Existing Approaches

O’Connell

Ringsred³

et al. 2022

Applied Sciences

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Several methods are currently used to track the bio-component of co-processed fuels including energy/mass balance, yield methods and radiocarbon techniques. The methods used to track or estimate the bio-component of fuels produced when bio and fossil feedstocks are processed together (co-processed) in oil refineries were analysed in detail, together with their advantages and disadvantages. Some methods, such as radiocarbon methods that allow the direct measurement of the bio-content in a fuel, have been criticised due to low accuracy at low blends. However, these reservations have tended to misinterpret the options available for carbon dating and to discount recent improvements in these tests. As much higher co-pressing mixtures are anticipated if published national decarbonisation targets are to be achieved, any challenges at very low co-processing ratios affecting the accuracy of the radiocarbon methods should not be an issue. Energy/mass balance and yield methods might be supplemented with carbon-tracking to determine the real the biogenic content.

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“…The whole situation is even more complicated by the fact that C4 hydrocarbon fraction is not commonly processed by steam cracking alone, but in mixtures with heavier alkane materials with the aim to optimize the cracking capacity and to reduce the coke deposition [ 11 , 12 , 13 ]. Mutual interactions of hydrocarbons that are present in such a mixture are very essential in such situations and they are also generally important in relation to processing feedstocks that are based on renewable materials [ 14 ].…”

Section: Introductionmentioning

confidence: 99%

Co-Pyrolysis of Unsaturated C4 and Saturated C6+ Hydrocarbons—An Experimental Study to Evaluate Steam-Cracking Performance

et al. 2023

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Unsaturated C4 hydrocarbons are abundant in various petrochemical streams. They can be considered as a potential feedstock for the steam-cracking process, where they must be co-processed with C6 and higher (C6+) hydrocarbons of primary naphtha fractions. Co-pyrolysis experiments aiming at the comparison of different C4 hydrocarbon performances were carried out in a laboratory micro-pyrolysis reactor under standardized conditions: 820 °C, 400 kPa, and 0.2 s residence time in the reaction zone. C4 hydrocarbons were co-pyrolyzed with different co-pyrolysis partners containing longer hydrocarbon chain to study the influence of the co-pyrolysis partner structure on the behavior of C4 hydrocarbons. The yields of the pyrolysis products and the conversion of C4 hydrocarbons were used as the performance factors. A regression model was developed and used as a valuable tool for quantifying the inhibition or acceleration effect of co-pyrolysis on the conversion of co-pyrolyzed hydrocarbons. It was found that the performance of different C4 hydrocarbons in co-pyrolysis is substantially different from the separate pyrolysis of the individual components.

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Experimental Evaluation of Hydrotreated Vegetable Oils as Novel Feedstocks for Steam-Cracking Process

Cited by 7 publications

References 23 publications

Fluidized bed steam cracking of rapeseed oil: exploring the direct production of the molecular building blocks for the plastics industry

Fluidized bed steam cracking of rapeseed oil: exploring the direct production of the molecular building blocks for the plastics industry

Tracking the Biogenic Component of Lower-Carbon Intensive, Co-Processed Fuels—An Overview of Existing Approaches

Co-Pyrolysis of Unsaturated C4 and Saturated C6+ Hydrocarbons—An Experimental Study to Evaluate Steam-Cracking Performance

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