DE2032458B - Process for the preparation of an aromatic mixture containing deep C 8-hydrocarbons - Google Patents

Description

Co ^ -paraffin and
Naphthenic content of
Head fraction of the Be
dispatch dismantler
(Volume of liquid
percent) Octane number of the reform
mates (of course)
(ASTM D-908) 2 to 5
5 to 10
greater than 10 j2.0 to 96.0
96, C to 100.0
gK 3s than 100.0

30th

the reformate is freed from octane in a fractionation column and a fraction containing hydrocarbons with 8 or more carbon atoms is separated from a fraction with hydrocarbons with fewer than 8 carbon atoms (C ₈ fraction) and a top fraction is separated from the C _{s +} fraction in a fine fractionation column separates, which is a highly purified aromatic C ₈ hydrocarbon product.

2. The method according to claim 1, characterized in that a heavy gasoline charge fraction with a boiling range from C _e to 204 ° C is used.

Analyzes were closely cut raw material fractions within the boiling range 130 to 158 ° C · 130 to 140 ⁰ C-Frakticn were obtained ₈ aromatics of 22.2% C in reforming.

The invention is based on the finding that there is a relationship between the content of a reforming _{charge of saturated C 9+} hydrocarbons and the content of a fractionated Cg aromatic cut (which is obtained from a reformate produced from this charge) of saturated "^" + -Hydrocarbons. A separation of these C ₉ + hydrocarbons from the Cg aromatic fraction is extremely difficult. Therefore, saturated C ^ hydrocarbons, in particular n-nonane and certain isodecanes, are undesirable impurities in xylenes obtained by petrochemical means, which generally have to be removed by solvent extraction, superfractionation or other costly measures.

The invention has therefore set itself the task of finding a way to avoid such expensive cleaning measures to avoid the Cs aromatic fraction and to use reactions for this purpose, which occur in the reforming zone to remove these non-aromatic hydrocarbons Hydrocracking to lighter paraffins or to be destroyed by dehydrocyclization to aromatics.

According to the invention, this is achieved by adding a fraction of the heavy gasoline charge with an end temperature in the range from 132 to 135 ° C of a catalytic reforming at 427 to 593 ° C, 4.4 to 69 atm and a liquid space velocity of 0.1 to 20 Vol / vol / hour and subject to a severity of the conditions, expressed in parameters of the reformate, which is _{varied according to the following relationship with the C 9+} paraffin and naphthene content of the head fraqua:

Cs + 'paraffin and naphthene content of the top fraction of the
Feed separator (liquid volume percent)

2 to 5

5 to 10

greater than 10

Reformate octane number (clear) (ASTM D-908)

92.0 to 96.0
96.0 to 100.0
greater than 100, -

The invention relates to a method for producing so of a mixture containing aromatic Cg hydrocarbons by isolating a narrow fraction from a heavy fuel charge, if necessary treatment to remove impurities, catalytic reforming of the heavy gasoline fraction and separation of one of the aromatics with the desired one Fraction containing carbon number from the reformate.

In the investigation of the production of C ₉ aromatics by catalytic reforming of gasoline fractions (Neftekhimiya 7 [3] p. 392 to 397, 1967; Chemical Abstracts, Vol. 67, 1967, p. 9586; Petroleum Chem. J., 1967, P. 121 to 128) it is known that in the catalytic reforming of purified narrow fractions in addition to C _n aromatics also C _s aromatics (xylenes and ethylbenzene) are formed and the yield decreases, the heavier the fractions of the raw material used are.

the reformate is freed from octane in a fractionation column and a fraction containing hydrocarbons with 8 or more carbon atoms is separated from a fraction with hydrocarbons with fewer than 8 carbon atoms (C ₈ fraction) and the C ₈₊ fraction is separated in a fine fractionation column Separates overhead fraction, which is a highly purified aromatic C ₈ hydrocarbon product.

Preferably, in carrying out the process will be a naphtha feed fraction ₀ used according to the invention with a ^ isdebereich C to 204 ⁰ C.

The invention offers the possibility of _{obtaining aromatic C s} hydrocarbons in a purity of at least 98 percent by volume of liquid during fine fractionation. According to the invention, aromatic C ₈ hydrocarbons are preferably obtained which contain 90% of the xylene in the reformate.

The main advantage of the invention is that the reformate obtained is practically free from the troublesome C ₀₄ hydrocarbons and therefore

3 4

be subjected to a simple fractionation component. Crystalline aluminosilicates can

can also be used as a catalyst support to obtain a C _{8 aromatics product of high purity,}

to win. Reforming conditions are a temperature in the

The reforming conditions to be observed range from 427 to 593 ⁰ C, preferably from 454 and

depend on the content of paraffins and naph- 5 566 ⁰ C ₁ and a pressure of 4.4 atm to 69 atm, before-

thenen in the feed to the reforming zone, preferably from 7.8 to 69 atm. The reforming zone

away. So if their content in the reforming is at an hourly liquid space velocity

charge increases, which depends on the final boiling point of the digkeit (volume of liquid charge per hour /

Charge or natural origin of the same volume of catalyst) from 0.1 to 20, preferably

depends, so more C _{e +} paraffins and naph- io from 0.5 to 15 must be operated.

thene are destroyed in order to be able to obtain a pure xylene fraction through simple fractionation. Octane remover 12, in which a hydrocarbon. This increased destruction is achieved by a fraction that contains C _e -naphthenes and lower-boiling increases in the reaction temperature or demand compounds, from a hydrocarbon reduction of the residence time on the catalyst. Another 15 fraction is separated which contains the C ₈ aromatics and higher way consists in the simple measurement of the rising boiling compounds. The octane remover severity of reforming through the increase in octane can be a conventional distillation column number of the reformate, which is an indirect indication of and is usually at a pressure of 6.4 atm the conversion and a direct indication of the and a bottom temperature u, n 149 to 177 "C ge reformate concentration of aromatics is. Hold 20. The temperature at the top is kept at 93. The invention can most clearly be kept up to 149" C by reference. The fraction which C _s -naphthenes are explained on the drawing, which contains schematically and lower-boiling hydrocarbons, a preferred embodiment of the invention is for example reproduced via line 13 to an engine, fuel blending system. The fraction, the crude oil, is introduced into the fractionating 25 C ₈ aromatics and higher-boiling hydrocarbons tower 2 via line 1. A C ₆ -204 ⁼ C- is preferably contained, is passed via line 14 into the fine fractionation heavy gasoline feed fraction from the fractionation column 15, in which a mixture of highly purified tower 2 is removed from a line 6 via the side cut take-off 5 and the aromatic Q-hydrocarbons and 7 fraction is in a pre-fractionation zone separated, the (,, -! decomposed hydrocarbons lighter hydrocarbons than the C ₆ -. 30 contains heavier hydrocarbons and the high-204'C fraction via line 3 from the purified aromatic C ₈ hydrocarbons. wer-fractionating tower 2 and heavy hydrocarbons to removed via line 17. the C ₉ -Kohlenwasserüber line 4 away materials. and heavier hydrocarbons are the Vorfraktionitrzone 7 separates an overhead fraction via line 16 is removed. It is also in the Erfindungsmit a final boiling point 132-135 ⁰ C of 30 thought that the heavy gasoline charge, which a bottom fraction and can n reaches the pre-fractionation zone 7 at a bottom temperature via line 6, work temperature from 149 to 204 ⁼ C. The bottom fraction instead in line 9 between the pre-fractionation is removed via line 8 and, for example, zone 7 and the reforming zone 10 are freed of impurities to an engine heavy oil reforming zone (not shown). The impurities of the carried. The top fraction arrives via line 9 in charge, which can be removed, for example, a catalytic reforming 10, which under reforming way sulfur compounds, nitrogen compounds, conditions a reformate with an acceptable oxygen compounds and sebum metals, which _{supplies C 9} ^ hydrocarbons . It has been found from a conventional heavy gasoline charge that if the top fraction can be 2 to 5 liquid,
by volume percentage of C ^ paraffins and naphthenes
keeps the reforming zone at such a sharpness

must work so that they can reformat with an octane.

number in the range from 92.0 to 96.0 supplies (determined by the fractionation

according to ASTM test method D-908 in the division to a boiling range of 83 to 135 "C

of the refo ^r mates, which recovered the pentanes and heavy coals and through hydrodesulfurization and waste

contains hydrogen, ie the »C ₅ . -Reformat «). strip sufficiently pretreated to ensure a dry,

If the overhead fraction produces 5 to 10 volume of liquid- sulfur-free reforming feed,

percent of C ₉₊ paraffins and naphthenes must be used.

the clear target number of the C ₅₊ reformate 96.0 to borrowed from the Universal Oil Products method 273-64 and

Be 100.00. If the top fraction was greater than 10 flux 55 mass spectroscopy, this loading showed one

Liquid volume percent C ₉ + paraffins and naphthenes Content of C “+ paraffins and naphthenes of 7.1

contains, the clear target octane number of the C ₄ + -Refor- or 5.1 percent by volume, according to the invention must

mates must be greater than 100.00. An increase in this heavy gasoline fraction for the purpose of extraction

The octane number of the reformate leads to an increased C ₈ reformate of at least 98 percent by volume

Hydrocracking of the C _D + paraffins and naphthenes 60 purity sufficiently severe reforming conditions

and consequently reduces the amount of gene formed being subjected to a reformate with a

Compounds that do not achieve an aromatic C "-connection octane number of 96.0 to 100.0,

fertilize and boil in the xylene range. The heavy gasoline fraction was in a reform

The reforming zone can be a known reforming test plant on a catalyst, loading

Mierkatalysator included, which is made of heat-resistant 65 standing from platinum on halogenated alumina

inorganic oxide, -vie alumina, as a carrier, and a liquid space velocity of 1.0 h- ¹ ,

at least one metal from group VIII which has an average catalyst temperature of 480 C and

Periodic table and optionally a halogen pressure of 14.1 kg / cm ² reformed. The liquid one

Part of the reformate was then freed from aliphatic hydrocarbons in a fractionation column and showed an octane number (clear), ie, without the addition of lead, of 96.2 on analysis. _{The C 0+} non-aromatic content of the Cj aromatic fraction, measured by mass spectroscopic analysis, was 0.4%. If the reformate had been reformed to a lower total octane number, the C ₀₊ non-aromatic content _{would have been higher in the C 8} aromatic fraction.

Example 2

A reforming charge boiling in the range of 88-132 ° C was prepared from a virgin Venezuela heavy gasoline in a manner similar to that given in Example 1. The analyzes of this charge by the two analytical _{methods mentioned show a content of C 8+} paraffins and naphthenes of 9.4 and 7.9 percent by volume, respectively.

In order to obtain a C ₈ aromatic fraction of at least 98% purity, ie with less than 2% C ₀₊ paraffins and naphthenes, the heavy gasoline fraction had to be reformed to a sollocation number of 96.0 to 100.0. For this purpose, a reforming test plant with a catalyst made of platinum on halogenated alumina at a liquid space velocity of 1.9 h ^-1 , an average catalyst temperature of 482 ° C. and a

ίο reaction pressure of 22.85 kg / cm ² used. Under these conditions, a reformate freed from octane and having an octane number (clear) of 96.0 was obtained. The measured content of non-aromatics in the Cg-aromatics fraction was 1.68 percent by volume. An analysis of the C ₈ fraction of the reformate showed a content of 11.6 volume

ao percent C ₉ + paraffins and naphthenes.

1 sheet of drawings

Claims (1)

Patent claims: 1. A process for the production of a mixture containing aromatic Cg hydrocarbons by isolating a narrow fraction from a heavy gasoline charge, if necessary treatment to remove impurities, catalytic reforming of the heavy gasoline fraction and separation of a fraction containing the aromatics with the desired carbon number from the reformate, characterized in that a fraction of the Schwerbeiizin charge with a final boiling point in the range of 132 to 135 ° C of a catalytic reforming at 427 to 593 ⁰ C, 4.4 to 69 atm and a liquid space velocity of 0.1 to 20 V - '/ Vol / hour and subject to a severity of the conditions, expressed in parameters of the reformate, which is _{varied according to the following relationship with the C 9+} paraffin and naphthene content of the top fraction: