Method for high-temperature short-time distillation of...

Mineral oils: processes and products – Fractionation – Distillation

Reexamination Certificate

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C208S365000

Reexamination Certificate

active

06413415

ABSTRACT:

DESCRIPTION
The invention relates to a process for high-temperature flash distillation of liquid residue oil originating from processing crude oil, natural bitumen or oil sand, wherein granular, hot coke as a heat carrier (heat carrier coke) is mixed with the residue oil in a mixer whereby 60 to 90 wt. % of the residue oil is vaporized, in the mixer the non-volatile portion of the residue oil containing the metal-laden asphaltenes is converted in the mixture containing the heat carrier to oil vapour, gas and coke, from the mixer the gases and vapours and the coke are separately withdrawn, gases and vapours are cooled and a product oil as a condensate and a gas are produced, the granular coke withdrawn from the mixer is reheated and recirculated to the mixer as heat carrier.
A similar process is known from the magazine “Erdöl und Kohle-Erdgas-Petrochemie/Hydrocarbon Technology” No. 42 (1989), pages 235 to 237, where a special mixer with intermeshing, uni-directionally rotating screws is presented which permits the gases and vapours to be discharged and cooled after only a very short retention time in the high-temperature zone of the mixer, thus suppressing undesirable cracking processes in the gas phase.
The objective of the present invention is to further develop the known process and optimize the conditions for continuous process operation. This results in maximizing the product oil yield and to minimize the content of heavy metals (nickel, vanadium), Conradson carbon (CCR) and heteroatoms (S, N) in the product oil.
Using the above process, this objective is accomplished in that the liquid residue oil is mixed in the mixer with hot heat carrier coke having a temperature of 500 to 700° C. at a weight ratio of 1:3 to 1:30, at least 80 wt. % of the heat carrier coke has a grain size range of 0.1 to 4 mm, at the beginning of the mixing a liquid residue film is formed on the heat carrier coke particles, the greater part of said film (e.g. 60 to 90%) being vaporized in the mixer at as low an operating temperature as possible in the range of 450 to 600° C. and preferably 500 to 560° C., the remaining liquid residue film on the coke is subsequently converted to oil vapour, gas and coke at a retention time of 6 to 60 seconds in the mixer, the coke withdrawn from the mixer is dry, largely free from liquid components and exhibits good flow properties and the gases and vapours liberated are withdrawn from the mixer after a retention time of 0.5 to 5 seconds.
Compared to the conventional vacuum distillation process, the process of the invention raises the equivalent final boiling point from about 560° C. to about 700° C. with a marked increase in the distillation yield. At the same time, the non-distillable, contaminant-laden (heavy metals, heteroatoms, CCR) asphaltenes are converted to oil, gas and coke and the contaminants preferably remain in the coke.
The lowest possible operation temperature in the mixer, when the coke withdrawn from the mixer is just dry and has good flow properties, results in the best yield and quality of the product oil.
Mixers suitable for the process include, for example, screw mixers, rotary drum mixers, paddle mixers, plough or vibration mixers. Moreover, mixers with intermeshing, uni-directionally rotating screws, which are known and are described in German Patent 12 52 623 and the corresponding U.S. Pat. No.3,308,219 as well as in German Patent 22 13 861, can preferably be used. Due to the interaction of the screws, the formation of deposits on the screw surfaces and in the mixer housing is prevented.
Another embodiment of this process consists in passing the liquid residue oil through a first mixing section for mixing with the hot heat carrier coke and then through at least one further mixing section and hot heat carrier coke and the residue oil being fed to the mixer at the beginning of the first mixing section and gases and vapours are liberated at temperatures in the range of 450 to 600° C. in the first mixing section and further hot heat carrier coke being added to the mixture of heat carrier coke and remaining residue oil from said first section at the beginning of the second mixing section, the liberated gases and vapours being discharged from the first and/or second mixing section. This variant allows the adjustment of different temperatures within a range of 450 to 600° C. in the individual mixing sections.
If at least two mixing sections are used for mixing the residue oil with the hot heat carrier coke, the crucial first mixing section can be operated at low temperatures which promotes the capture of contaminants such as heavy metals (Ni, V), heteroatoms (S, N) and Conradson carbon (CCR) in the coke which is formed and, at the same time, suppresses undesirable cracking processes in the gas phase. These cracking processes result in increased C
4−
gas formation and hence, reduce C
5+
product oil yield and quality.
The second mixing section starts at the point where fresh heat carrier coke is added from the outside to the coke mixture coming from the first mixing section. Coke addition causes a temperature increase in the second mixing section and consequently temperature of the gases and vapours increases. Normally, the heat carrier coke is added in such a rate as to achieve a temperature increase of 5 to 50° C. This prevents dew-point underruns in the piping between the mixer and the condensing unit. At the same time, the higher temperatures accelerate the coking of the remaining, non-volatile, liquid residue components on the coke and hence, drying of the coke in the mixer so that the latter loses its stickiness. This is a prerequisite for ensuring good flowability of the coke in the heat carrier circuit. Furthermore, it is also possible to provide more than two mixing sections and add fresh coke at the beginning of each section.
When using a mixing system with several mixing sections, about 50 to 95% of the total hot heat carrier coke feed for the mixer is normally added to the first mixing section. The minimum hot coke feed rate at the beginning of the second and each further mixing section is 5%. of the total hot heat carrier coke feed. When using a mixer with only two mixing sections, the hot heat carrier coke is generally added at a weight ratio of 20:1 to 1:1 to the first and second mixing section.
Furthermore, it is possible to process in the second or a subsequent mixing section a liquid residue oil differing from that fed to the first mixing section. This allows, for example, the residue oil fed to the second mixing section to be treated at a higher temperature than the residue oil processed in the first section. Such a second residue oil may also be thermally treated in a second mixer connected partly in parallel with the first mixer and operating at higher temperatures, for example.
Moreover, it may be beneficial to preheat the liquid residue oil to temperatures of 100 to 450° C. before it is fed to the mixer. Preheating reduces both the viscosity of the residue oil and the heat requirement for valorization, so that the non-volatile proportion of the residue oil reaches the desired conversion temperature faster.
Furthermore, an oxygen-free gas or steam may be added to the mixer which offers the advantage of a reduced retention time of the liberated gases and vapours in the mixer.
The process of the invention permits about 80 to 95% of the heavy metals (Ni and V), about 50 to 70% of the Conradson carbon (CCR) and 30 to 70% of the heteroatoms (S and N) contained in the residue oil to be captured in the coke which is formed and a C
5
. product oil with a yield of 70 to 85 wt. % is recovered from the residue oil. After separation of the naphtha and, where applicable, the kerosene and gasoil fractions, this product oil is suitable for catalytic processing.


REFERENCES:
patent: 4054492 (1977-10-01), Rammler et al.
Weiss Schmalfeld “Coking of Residue oils by the LR-Process” vol. 42, No. 6, Jun. 1, 1989, pp. 235-237.

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