This invention relates to the production of a gasoline, in particular from petroleum material cuts obtained from an aromatic petrochemical plant.

Typical gasoline comprises 30-80 %volume of a petroleum material known as reformate. Reformate is typically produced from a crude oil petroleum refinery process.

In a crude oil petroleum refinery process, crude oil as the feed material enters a distillation tower and different products are separated according to their boiling points.

As seen in Figure 1, one of these products is heavy naphtha. Impurities in this heavy naphtha, such as sulphur, mercaptans, nitrogen, metals etc. are removed in a hydrotreater unit and the heavy naphtha then enters a reforming unit. In this unit, the naphtha linear compounds are transformed into branched and ring compounds and, as a result, the octane number of the material increases. The output of the reforming unit is known as reformate (hereinafter referred to as "refinery reformate") and is comprised of varying amounts of paraffins, olefins, napthenes and aromatics.

The American Society for Testing and Materials (ASTM) has set out the required international standards for the physical and chemical properties of a regular gasoline (RON = 91) and a premium gasoline (RON = 95) in order for it to be suitable for use in a vehicle. This set of standards ("the international ASTM standards") are set out below in Table 1 :

Table 1: the international ASTM standards for regular and premium gasoline.

*depends on the season, i.e. 12.7 Psi at 60 ⁰ F ₅ 11.0 Psi at 70 °C, 9.4 Psi at 80 ⁰ F and 8.0 Psi at 90 °C

Other specific sets of ASTM standards exist for gasolines such as European Eurosuper gasoline, European Special gasoline and European Superplus gasoline. The physical and chemical properties of refinery reformate depend on the reactor conditions and also the physical and chemical properties of the feed material. Sometimes, refinery reformate has the required physical and chemical properties to be used on its own as a gasoline conforming to the international ASTM standards. When refinery reformate does not have the required physical and chemical properties in order to be used on its own as a gasoline according to the international ASTM standards and/or in order to increase the volume of the gasoline, refinery reformate is typically mixed with other materials from the gasoline blending pool (see Fig. 1) so as to obtain the chemical and physical properties which conform to the international ASTM standards.

Aromatic petrochemical plants carry out similar production processes to crude oil pertoleum refineries (see Fig. 2) and also produce reformate (hereinafter referred to as "aromatic reformate"). In these plants, gas condensate as feed material enters a distillation tower and the light end (C1-C4) and heavy end (ClO ⁺ ) products are separated. The intermediate fraction, naphtha heart cut (C5-C10 ⁺ ) (with boiling point range 80-205 ⁰ C), is then fed into a hydrotreating unit to remove impurities and the resulting product is known as "hydrotreated" naphtha heart cut (C5-C10 ⁺ ). This product then enters a catalytic reforming unit, which is comprised of a number of reactors and catalysts, and the linear compounds are transformed into branched and ring compounds. The operating conditions of the catalytic reforming unit depend on the feed material, reactor pressure, space velocity and the type of catalyst, but under normal operating conditions, the temperature is typically in the region of 480-525 ⁰ C and the pressure is typically in the region of 3-5 bar. Higher temperatures lead to greater efficiency of the catalytic reforming unit whereas lower temperatures can lead to the undesired formation of large amounts of cokes. Accordingly, a temperature towards the higher end of the range 480-525 °C is preferably selected, preferably above 510 °C. The catalytic reforming unit is typically comprised of a number of reactors, each comprising a boiler and each boiler having a corresponding inlet temperature and outlet temperature. The control room of the aromatic petrochemical plant typically controls the temperature and pressure of the boilers via a computer. The product of the reforming unit is aromatic reformate and, like refinery reformate, it is also comprised of paraffins, olefins, napthenes and aromatics. The relative proportion of these different types of compounds varies depending on the operating conditions of the catalytic reforming unit as well as the input material.

The products and by-products of the aromatic petrochemical plant, such as aromatic reformate and hydrotreated naphtha heart cut (C5-C10 ⁺ ), are much cheaper to produce than refinery reformate but these products have not been previously mixed in order to be used in the production of gasoline. In addition, aromatic reformate has a higher RON (research octane number) than refinery reformate. However, unlike refinery reformate, aromatic reformate is not suitable for the production of gasoline according to the international ASTM standards. This is due to the large proportion of aromatic compounds contained in aromatic reformate, which is often in the region of 75-85 %volume. Whilst the presence of high levels of aromatic compounds increases the RON of a reformate (up to RON = 113 in the case of aromatic reformate), or of a gasoline containing such a reformate, it can lead to other unfavourable physical and chemical properties such as an undesired initial boiling point, final boiling point, vapour pressure or other composition and distillation properties. In addition, various health concerns are associated with aromatic compounds due to, for example, their carcinogenic nature. Therefore, in order for an aromatic reformate to be suitable for use in the production of gasoline according to the international ASTM standards, the %volume of aromatics contained therein must be reduced, preferably to below 70 %volume.

Accordingly, it is an object of the present invention to provide a method of producing a reformate from an aromatic petrochemical plant, which is suitable for use in the production of a gasoline according to the international ASTM standards. It is another object of the present invention to provide a method of producing gasoline according to the international ASTM standards, which contains a reformate obtained from an aromatic petrochemical plant. It is a further object to provide a gasoline according to the international ASTM standards when produced by these methods.

In the catalytic reforming step, the linear compounds of the hydrotreated naphtha heart cut (C5-C10 ⁺ ) are transformed into branched and ring compounds. This results in an increase in the octane number. As mentioned above, the typical operating conditions of a catalytic reforming unit of an aromatic petrochemical plant involve a temperature in the region of 480-525 ⁰ C, preferably above 510 °C, and a pressure in the region of 3-5 bar. Surprisingly, it has been found by the present inventors that by selecting the temperature of the catalytic reforming unit to be below 510 °C, the physical and chemical properties of the resultant reformate can be altered, in particular the %volume of aromatic compounds contained in the resultant reformate can be reduced whilst ensuring at least 80% efficiency of the catalytic reforming unit. Surprisingly, it has also been found by the present inventors that by adding an amount of hydrotreated naphtha heart cut (C5-C10 ⁺ ) to the reformate petroleum material, the %volume of aromatic compounds contained in the resultant reformate is reduced.

In a first aspect of the present invention, there is provided a method of producing a reformate suitable for use in the production of gasoline, comprising the steps of: obtaining naphtha heart cut (C5-C10 ⁺ ) from the distillation of gas condensate; removing undesired impurities from said naphtha heart cut (C5-C10 ⁺ ) by a hydrotreating step to produce hydrotreated naphtha heart cut (C5-C10 ⁺ ); and subjecting said hydrotreated naphtha heart cut (C5-C10 ⁺ ) to a catalytic reforming step to produce said reformate, wherein the temperature of said catalytic reforming step is selected to be in the range 485-510 ⁰ C, and/or wherein an amount of hydrotreated naphtha heart cut (C5-C10 ⁺ ) is mixed with said reformate such that said reformate contains up to 45 %volume of said hydrotreated naphtha heart cut (C5-C10 ⁺ ), so as to reduce the %volume of aromatics in said reformate.

Preferably, the reformate is suitable for the production of gasoline which meets the requirements of the international ASTM standards. More preferably, the gasoline meets the requirements of a set of ASTM standards corresponding to a gasoline selected from US Regular gasoline, US Premium gasoline, European Eurosuper gasoline, European Special gasoline and European Superplus gasoline.

The naphtha heart cut is typically obtained from an aromatic petrochemical plant and the distillation of gas condensate is typically carried out in the distillation tower of an aromatic petrochemical plant. Impurities removed from the naphtha heart cut (C5-C10 ⁺ ) by hydrotreating include sulphur, mercaptans, nitrogen and metals.

In the case that the temperature of the catalytic reforming step is selected to be in the range 485-510 ⁰ C, preferably the temperature should be selected to be in the range 490- 505 °C, more preferably, in the range 495-505 ⁰ C. Reducing the temperature in this way can reduce the %volume of aromatics in the reformate to as low as 50 %volume. The temperature of the catalytic reforming step preferably refers to the temperature of the boiler(s) within the catalytic reactor(s), more preferably the inlet temperature. The temperature of the catalytic reforming step is typically controlled by the control room of the aromatic petrochemical plant, typically by the use of a computer. Preferably, the temperature of the catalytic reforming step is selected such that the catalytic reforming unit operates at an efficiency of 80 % or higher.

In the case that hydrotreated naphtha heart cut (C5-C10 ⁺ ) is mixed with the reformate, preferably the amount of hydrotreated naphtha heart cut (C5-C10 ⁺ ) added is such that the reformate contains between 5-45 %volume hydrotreated naphtha heart cut (C5- ClO ⁺ ), more preferably between 5-25 %volume hydrotreated naphtha heart cut (C5- ClO ⁺ ). The hydrotreated naphtha heart cut (C5-C10 ⁺ ) contains lower amounts of aromatic compounds than the reformate. Therefore, the addition of the hydrotreated naphtha heart cut (C5-C10 ⁺ ) reduces the %volume of aromatics in the reformate without the need to reduce the temperature of the catalytic reforming step. This alters the physical and chemical properties of the reformate such that it can now be used in the production of a gasoline according to the international ASTM standards. As the temperature does not need to be reduced, this has the advantage that the operation of the aromatic petrochemical plant is not affected. As mentioned above, reducing the temperature of the catalytic reforming step reduces the efficiency of the catalytic reforming unit and also leads to increased formation of undesired cokes. Hydrotreated naphtha heart cut (C5-C10 ⁺ ) has not been mixed with aromatic reformate in order to be used in the production of gasoline before. An advantage of this feature is that hydrotreated naphtha heart cut (C5-C10 ⁺ ) is cheaper to produce than other petroleum material cuts which comprise the gasoline blending pool. Therefore, the present invention provides a method of producing a reformate suitable for use in the production of a gasoline according to the international ASTM standards, which is cheaper to produce than refinery reformate.

Hydrotreated naphtha heart cut (C5-C10 ⁺ ) has a lower RON than aromatic reformate. Therefore, the addition of hydrotreated naphtha heart cut (C5-C10 ⁺ ) to aromatic reformate will reduce the RON of aromatic reformate. However, due to the high RON of aromatic reformate, the addition of hydrotreated naphtha heart cut (C5-C10 ⁺ ) does not reduce the RON below a level such that the aromatic reformate cannot be used in the production of gasoline according to the international ASTM standards.

Within the specified range of up to 45 %volume, the amount of said hydrotreated naphtha heart cut (C5-C10 ⁺ ) added to said reformate depends on the desired physical and chemical properties of the reformate. The hydrotreated naphtha heart cut (C5-C10 ⁺ ) added to said reformate is typically obtained from an aromatic petrochemical plant or an oil refinery. As an alternative to hydrotreated naphtha heart cut (C5-C10 ⁺ ), naptha and heavy S.R.G (C5-C10), with boiling points in the range 75-210 °C, obtained from a crude oil refinery process can be used. This is because these cuts have similar chemical and physical properties to hydrotreated naphtha heart cut (C5-C10 ).

In a second aspect of the present invention, there is provided a method of producing gasoline comprising the steps of: producing a reformate according to the method of the first aspect of the present invention; and blending said reformate with at least one other petroleum material cut to produce gasoline. The addition of other petroleum material cuts alters the physical and chemical properties of the resultant gasoline.

Preferably, the at least one other petroleum material cut is other petroleum materials in a gasoline blending pool.

Preferably, the gasoline meets the requirements of the international ASTM standards. More preferably, the gasoline meets the requirements of a set of ASTM standards corresponding to a gasoline selected from US Regular gasoline, US Premium gasoline, European Eurosuper gasoline, European Special gasoline and European Superplus gasoline.

In one embodiment of the second aspect, the at least one other petroleum material cut is selected from butane (C4), light naphtha (C4-C5), pentane (C5), light straight run gasoline (S.R.G) (C5-C6), heavy components (C7-C10 ^" ) and hydrotreated naphtha heart cut (C5-C10 ⁺ ). Butane (C4) is added in order to increase the pressure of the resultant gasoline. Light naphtha (C4-C5), pentane (C5) and light S.R.G (C5-C6) are added to increase the pressure, to decrease the initial boiling point and to reduce the %volume of aromatics in the resultant gasoline. Throughout the specification, the term "pentane" is deemed to include all geometric isomers of pentane, including normal pentane and isopentane as well as combinations thereof. Heavy components (C7-C10 ^" ), which includes heavy naphtha (C7-C8), have high boiling points, and are added to increase the initial and final boiling points of the resultant gasoline. Hydrotreated naphtha heart cut (C5-C10 ⁺ ), which has a low %volume of aromatics, is added to reduce the %volume of aromatics in the resultant gasoline. These other petroleum material cuts have a lower RON than the reformate, meaning that their addition reduces the RON of the resultant gasoline. However, due to the high RON of the reformate, it is still possible to make the RON of the resultant gasoline acceptable under the international ASTM standards.

Preferably, the gasoline contains up to 60 %volume of light S.R.G (C5-C6) and/or up to 25 %volume pentane (C5) and/or up to 5 %volume butane (C4) and/or up to 15 %volume light naphtha (C4-C5) and/or up to 5.0 %volume heavy components (C7-C10 ^" ) and/or up to 45 %volume hydrotreated naphtha heart cut (C5-C10 ⁺ ) and/or between 30-98 %volume of the reformate. More preferably, the gasoline contains 5-60 %volume of light S.R.G (C5-C6) and/or 2-5 %volume butane and/or 5-25 %volume hydrotreated naphtha heart cut (C5-C10 ⁺ ) and/or 2-3 %volume heavy naphtha and/or 50-90 %volume of the reformate. Even more preferably, the gasoline contains 2-4 %volume butane and/or 10-40 %volume light S.R.G. Preferably, the amount of the other petrochemical material cut added is selected depending on the desired physical and chemical properties of the resultant gasoline.

Further additives can be added to the gasoline. Examples of such additives include, but are not restricted to, octane enhancers, metal deactivators, anti-oxidants, anti-knock agents, gum and rust inhibitors, detergents, etc. These are added during and/or after blending to achieve the desired chemical and physical properties of the resultant gasoline. Preferably, the additive is an octane enhancer and more preferably is methyl tertiary butyl ether (MTBE). Even more preferably, the gasoline contains up to 9 %volume of MTBE. It is not essential to add MTBE to the gasoline. This is because, although the RON of a gasoline produced according to the present invention will depend on the composition of the feed material, typical gasolines produced according to the present invention have an RON of approximately 87-99.5. However, if MTBE is added, the RON of a gasoline produced according to the present invention can be increased.

The gasoline can be mixed with other refinery gasolines in a gasoline blending pool. This has the effect of altering the physical and chemical properties of the gasoline and also increasing the volume of the gasoline. The gasoline can be mixed with the other refinery gasolines in order to increase their octane number.

In another embodiment of the second aspect, the at least one other petroleum material cut is selected from butane (C4), direct distillation gasoline, FCC hydrocracked gasoline, isomerate gasoline, alkylate gasoline and MTBE.

Typically, such other petroleum materials are obtained from an oil refinery.

Preferably, the gasoline comprises 30-80 %volume of said reformate, 10-40 %volume of FCC hydrocracked gasoline, up to 5 %volume of butane (C4), up to 10 %volume of direct distillation gasoline, up to 8 %volume isomerate gasoline, up to 20 %volume alkylate gasoline and up to 9 %volume MTBE. Even more preferably, the gasoline comprises up to 4 % volume butane and, still even more preferably, the gasoline comprises 2-4 %volume butane.

Preferably, the gasoline is European Eurosuper gasoline or European Superplus gasoline.

In a third aspect of the present invention, there is provided a gasoline produced according to the methods of the first and second aspects.

Preferred embodiments of the method of the first aspect (1) are as follows:

(2) A method according to (1), wherein said reformate contains 5-45 %volume of hydrotreated naphtha heart cut (C5-C10 ⁺ ).

(3) A method according to (2), wherein said reformate contains 5-25 %volume of hydrotreated naphtha heart cut (C5-C10 ⁺ ). (4) A method according to (l)-(3), wherein said naphtha heart cut (C5-C10 ⁺ ) is obtained from an aromatic petrochemical plant.

(5) A method according to (l)-(4), wherein said an amount of hydrotreated naphtha heart cut (C5-C10 ⁺ ) which is mixed with said reformate is obtained from an aromatic petrochemical plant or an oil refinery.

Preferred embodiments of the method of the second aspect are as follows:

(6) A method of producing gasoline comprising the steps of: producing a reformate according to (2)-(5); and blending said reformate with at least one other petroleum material cut to produce gasoline.

(7) A method according to (6), wherein said at least one other petroleum material cut is selected from butane (C4), light naphtha (C4-C5), pentane (C5), light straight run gasoline (S.R.G) (C5-C6), heavy components (C7-C10 ^" ) and hydrotreated naphtha heart cut (C5-C10 ⁺ ).

(8) A method according to (7), wherein said gasoline contains up to 60 %volume light S.R.G (C5-C6).

(9) A method according to (7) or (8), wherein said gasoline contains up to 5 %volume butane (C4).

(10) A method according to (7)-(9), wherein said gasoline contains up to 5.0 %volume heavy components (C7-C10 ^" ).

(11) A method according to (7)-(10), wherein said gasoline contains up to 45 %volume hydrotreated naphtha heart cut (C5-C10 ⁺ ). (12) A method according to (7)-(ll), wherein said gasoline contains up to 25

%volume pentane (C5).

(13) A method according to (7)-(12), wherein said gasoline contains up to 15 %volume light naphtha (C4-C5).

(14) A method according to (6)-(13), wherein said gasoline contains between 30-98 %volume of said reformate.

(15) A method according to (6)-(14), wherein the method further comprises a step of adding MTBE to the gasoline.

(16) A method according to (15), wherein said gasoline contains up to 9 %volume MTBE. (17) A method according to (6), wherein said at least one other petroleum material cut is selected from butane (C4), direct distillation gasoline, FCC hydrocracked gasoline, isomerate gasoline, alkylate gasoline and MTBE.

(18) A method according to (17), wherein said gasoline comprises 30-80 %volume of said reibrmate, 10-40 %volume FCC hydrocracked gasoline, up to 5

%volume butane (C4), up to 10 %volume of direct distillation gasoline, up to

8 %volume isomerate gasoline, up to 20 %volume alkylate gasoline and up to

9 %volume MTBE.

(19) A method according to (17) or (18), wherein said gasoline is Eurosuper gasoline or Superplus gasoline.

(20) A method according to (1)-(19), wherein said gasoline meets the requirements of the international ASTM standards.

(21) A method according to (1)-(19), wherein said gasoline meets the requirements of a set of ASTM standards corresponding to a gasoline selected from US Regular gasoline, US Premium gasoline, European Eurosuper gasoline,

European Special gasoline and European Superplus gasoline.

A preferred embodiment of the gasoline according to the third aspect is:

(22) A gasoline produced according to the method of (6)-(21).

The invention will next be described by reference to the following figures, in which:

Fig. 1 is a schematic of a typical oil refinery.

Fig. 2 is schematic of a typical aromatic petrochemical plant. Fig. 3 is a schematic of both a typical oil refinery and a typical aromatic petrochemical plant, indicating the processes the present invention.

Fig. 4 is a graph showing a typical distillation curve for motor gasoline, northern winter grade.

Fig. 5 is a graph showing typical distillation curves for heavy and light components.

Fig. 3 contains schematics of the production methods of both refinery reformate and aromatic reformate. In addition, a schematic of the methods of the present invention are shown. It can be seen that the reformate produced according to the present invention (in tank (I)) can be used to produce gasoline according to the international ASTM standards by blending it with other petroleum material cuts such as butane (C4), light naphtha (C4-C5), light S.R.G (C5-C6) and heavy components (C7-C10 ^" ) and additives such as MTBE (tank (2)). Alternatively, the reformate can be blended with other petroleum material cuts such as butane (C4), direct distillation gasoline, FCC hydrocracked gasoline, isomerate gasoline and alkylate gasoline and additives such as MTBE to produce gasolines such as Eurosuper gasoline or Superplus gasoline (tank (3))-

EXAMPLES

Example 1:

Tables 2 and 3 list laboratory test results for samples of a typical refinery reformate and a typical aromatic reformate, respectively:

Table 2: laboratory test results for a typical refinery reformate.

In Table 3, P = parafins, O = olefins, N = naphthas and A = aromatics. It can be seen that the physical and chemical properties of both samples do not allow them to be used as a gasoline on their own according to the international ASTM standards. For example, among others, the Reid vapour pressure (RVP) is too low, the final boiling point (FBP) is too low and the %volume of aromatics is too high. Therefore, in order to produce such a gasoline, this refinery reformate must be mixed with other materials from the gasoline blending pool according to the desired physical and chemical properties of the resultant gasoline. However, due to the high levels of aromatic compounds in aromatic reformate (72.22 %volume in this sample), it is not possible to substitute refinery reformate with aromatic reformate in the conventional production of gasoline according to the international ASTM standards.

Example 2:

Table 4 lists laboratory test results for a sample of reformate produced according to the first aspect of the present invention wherein an amount of hydrotreated naphtha heart cut (C5-C10 ⁺ ) is mixed with the reformate:

Table 4: laboratory test results for a reformate produced according to the first aspect of the present invention

In this sample, the reformate contains 90 %volume of aromatic reformate (the sample of table 3) and 10 %volume hydrotreated naphtha heart cut (C5-C10 ⁺ ). It can be seen that the addition of hydrotreated naphtha heart cut (C5-C10 ⁺ ) results in the physical and chemical properties of the reformate being closer to those of the refinery reformate. In particular, the aromatic content is reduced. Accordingly, the reformate is suitable for use in the production of gasoline according to the international ASTM standards.

Example 3:

Table 5 lists values corresponding to the production of reformate according to one embodiment of the first aspect of the present invention when the inlet temperature of the catalytic reforming unit is selected to be in the range 485-510 °C and the reactor is operating at 80 % efficiency:

Table 5: laboratory test results corresponding to the production of reformate according to the first aspect of the present invention wherein the inlet temperature of the catalytic reforming unit is selected to be in the range 485-510 ⁰ C

It can be seen that, when selecting the inlet temperature of each reactor in the catalytic reforming unit to be in the range 485-510 °C (in this case 503 °C), the %volume of aromatics in the resultant reformate is significantly lower than in typical aromatic reformate.

Example 4: Table 6 lists the compositions for an example of a reformate produced according to the first aspect of the present invention and a gasoline containing this reformate produced according to embodiments of the second aspect of the present invention and their corresponding RONs:

Table 6: compositions of an example of a reformate and an example of a gasoline produced according to the methods of the present invention.

Reformate

Component %vol RON Pressure / psi

Aromatic reformate 94.3 98.2 -

Hydrotreated 5.7 50 naphtha heart cut

Final results 100 96 4.8

Gasoline (RON = 95.1)

Component %vol

Reformate 76.8

Light S.R.G 11

Butane 3.2

Heavy naphtha 0

MTBE 9

Total volume 100

Total Pressure @ 100 ^{c 3} F / psi 8

Table 7 lists test results for the gasoline shown in Table 6:

Table 7: laboratory test results for a sample of gasoline produced according to the present invention.

The test results show that the gasoline meets the requirements of the international ASTM standards for a premium gasoline.

Example 5:

Table 8 lists test results for a typical sample of hydrotreated naphtha heart cut after it has left the hydrotreating unit of an aromatic petrochemical plant:

Table 8: laboratory test results for a typical sample of hydrotreated naphtha heart cut (1) and a typical sample of gas condensate feed for comparison (2).

As with Table 3, P = parafmes, O = olefins, N = naphthas and A = aromatics. It can be seen that the %volume of aromatics contained in hydrotreated naphtha heart cut is significantly lower than in typical aromatic reformate.