Upgrading fischer-tropsch and petroleum-derived naphthas and distillates

Abstract

A process for upgrading at least one of a Fischer-Tropsch naphtha and a Fischer-Tropsch distillate to produce at least one of a gasoline component, a distillate fuel or a lube base feedstock component. The process includes reforming a Fischer-Tropsch naphtha to produce hydrogen by-product and a gasoline component with a research octane rating of at least about 80. The process further includes upgrading a Fischer-Tropsch distillate using the hydrogen by-product to produce a distillate fuel and / or a lube base feedstock component.

Description

[0001] 1. Field of Invention[0002] The present invention is directed to the conversion of remote natural gases into saleable transportation fuels and petroleum products. More specifically, this invention is directed to upgrading by, for example, hydrotreating, hydrocracking and hydrodewaxing Fischer-Tropsch and / or petroleum-derived naphthas and distillates for use in saleable transportation fuels and petroleum products.[0003] 2. Description of Related Art[0004] The Fischer-Tropsch reaction is a well known reaction, and catalysts and conditions for performing Fischer-Tropsch reactions are well known to those of skill in the art, and are described, for example, in EP 0 921 184A1, the contents of which are hereby incorporated by reference in their entirety. The Fischer-Tropsch process converts synthesis gas into linear hydrocarbons(n-paraffins, linear olefins and minor amounts of fatty acids). Due to the linear nature of such products, once they have been subjected to removal of hetero...

AI Technical Summary

Benefits of technology

[0012] The fuel components produced by the present invention have octane values sufficient for use in conventional transportation fuels and petrochemical feedstocks. In addition, during naphtha reformation, the present invention produces hydrogen by-product that can be used in hydrotreating, hydrocracking and hydrodewaxing processes to inexpensively upgrade Fischer-Tropsch products. Thus, the present invention inexpensively provides at least a portion of the hydrogen needed for hyrdotreatment processes without having to employ expensive separation processes or separate hydrogen production facilities.

[0013] Additionally, the present invention can combine Fischer-Tropsch naphthas and distillates with petroleum-derived naphthas and distillates to obtain blended naphthas and distillates having sulphur levels of at least about 1 ppm. Thus, the present invention ensures that sulfided catalysts, used to hydrotreat naphthas and distillates, maintain adequate sulfur levels without having to add sulfur by introducing costly pure chemicals.

[0014] Finally, by combining Fischer-Tropsch naphthas and distillates with petroleum-derived naphthas and distillates, the present invention can upgrade (e.g., hydrotreat, hydrocrack or hydrodewax) petroleum hydrocarbon products, including condensates, naphthas and distillates, to obtain saleable gasoline components and petroleum feedstock products.

Problems solved by technology

However, lighter naphtha fractions are generally poorly suited for use in conventional gasolines because their linear nature causes them to exhibit a very low octane rating.

Further, although naphtha can be used as a petrochemical feedstock for ethylene production, naphtha has not been found to be suitable for transportation fuels.

More specifically, products of the Fischer-Tropsch process, in finished products, exhibit boiling ranges having unacceptable levels of oxygenates and olefins (alcohols and traces of acids).

Also, the content of linear hydrocarbons in such products is so high that the resulting products exhibit unacceptable cold climate properties including, but not limited to, jet freeze point, diesel cloud point, and lube base stock pour point.

Although such processes can upgrade Fischer-Tropsch products suffering from the above-mentioned problems to obtain saleable transportation fuels and other petroleum products, the disadvantage of these processes is that they require hydrogen.

Although hydrogen can be obtained from synthesis gases, hydrogen can only be obtained from synthesis gases by employing expensive separation processes.

Unfortunately, the construction and operation of a separate hydrogen production facility is extremely costly.

Another problem encountered during upgrading of Fischer-Tropsch distillates is that the stocks created do not contain sulfur but do contain oxygenates.

Non-sulfided catalysts for hydrotreating, hydrocracking and hydrodewaxing are available but are based on expensive noble metals including, but not limited to, platinum, palladium, combinations thereof and the like.

Unfortunately, when sulfided catalysts are in the presence of oxygenates and in the absence of sulfur, the oxygen in the feedstock replaces sulfur on the catalyst, leading to a decline in the catalyst's performance.

Unfortunately, pure chemicals are expensive to purchase and require special handling that can create safety concerns and can generate additional costs.

Images