Hydrocracking of Fischer-Tropsch Wax

Petr Straka,Olga Pleyer,Dan Vrtiška,Jiří Hájek,Radek Černý

doi:10.35933/paliva.2020.02.01

Petr Straka, Olga Pleyer + Show 3 more

Open Access

https://doi.org/10.35933/paliva.2020.02.01

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Journal: Paliva	Publication Date: Mar 31, 2020
Citations: 2	License type: CC BY 4.0

Affiliation: University of Chemistry and Technology

Abstract

The low-temperature Fischer-Tropsch synthesis (LTFT) processing of renewable feedstocks combined with the hydrocracking of its solid product is an effective way to produce synthetic renewable engine fuels. The hydrocracking of an FT wax derived from natural gas using the LTFT synthesis was studied in this paper. The hydrocracking was carried out in a tubular fixed-bed reactor with a cocurrent flow of the feedstock and hydrogen. Reaction temperatures in the range of 305– 370 °C, a pressure of 8 MPa, an H2/feed ratio of 500 m3/m3 and weight hour space velocities (WHSV) of 1; 2 and 4 h-1 were tested. The naphtha fraction (boiling up to 200 °C) was the main product of the hydrocracking under all the tested reaction conditions. It could be used as a component into petroleum-derived gasoline in a neat form or the after processing by common refinery processes (isomerization and/or reforming). The production of low-sulfur and low-aromatic paraffinic solvent or the utilization as a feedstock for steam cracking could be some other options of the naphtha fraction utilization. The maximum yield of the gaseous products (depending on the reaction temperatures and WHSV) was 20 wt.%. They were primarily composed of n-alkanes and isoalkanes and could be, therefore, used as an optimal feedstock for steam cracking as well. The C3-C4 fraction of the gaseous products could be also utilized as an LPG fuel. Very low yields (up to 10.4 wt.%) of the middle distillates were obtained under all the tested reaction conditions. Due to their saturated nature, their densities were very low and, additionally, poor low-temperature properties can be expected.

Highlights

IntroductionThe production of liquid fuels from various sources (coal, natural gas, biomass) via the Fischer-Tropsch synthesis (FTS) process has gained renewed significance
In recent years, the production of liquid fuels from various sources via the Fischer-Tropsch synthesis (FTS) process has gained renewed significance
The reaction conditions needed for the full conversion are significantly milder when compared to the hydrocracking of petroleum vacuum distillates where a minimal temperature of around 380 °C, a pressure above 16 MPa and a weight hour space velocities (WHSV) below 1 h-1 are required [20]

Summary

Introduction

The production of liquid fuels from various sources (coal, natural gas, biomass) via the Fischer-Tropsch synthesis (FTS) process has gained renewed significance. The FTS is recognized as an industrially proven and economically competitive route to produce high-quality engine fuels. Special attention is paid to fuels made from waste biomass, because these advanced biofuels may contribute to greenhouse gas emissions reduction. FTS is a well-known and established catalytic chemical process, which was named after two German inventors, Franz Fischer and Hans Tropsch in the 1920s. During World War II, FTS was an essential source of liquid hydrocarbon fuels and necessary chemicals for the German war effort. Many modifications and adjustments of the technology have been made, including catalyst and reactor design development [1–3]

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