The present invention relates to a process for upgrading naphtha and of reducing the benzene content of reformate. The production of high octane gasoline continues to be a major objective of refinery operations worldwide. The phase-out of lead and the movement to reformulate gasoline to improve air quality in the United States, Europe, and the Pacific Rim countries present a major challenge in the refining industry.

In the United States, the recent Clean Act Amendments define reformulated gasoline in terms of properties such as RVP (Reid Vapor Pressure) and composition including oxygen, benzene, and total aromatics contents, as well as in terms of performance, measured by reductions in volatile Organic Compounds (VOC) and gaseous toxic effluents.

In most of the regulatory schemes now under consideration, limitations will be placed on the permissible level of benzene in motor gasolines. Much of the benzene in motor gasoline comes from reformate which is a major high octane contributor and therefore desirable from this point of view. Given the need for high octane fuel in current engine designs, the requirement for reforming as a source of octane will continue but only if the benzene levels can be held at permissible levels.

U.S. Patent No. 4,827,069 (Kushneric ) describes a process for alkylating the aromatic components in reformate with light olefins from FCC off gases, to produce high octane alkyl aromatics which are less toxic than benzene. The process is carried out by passing the reformate and the light olefin co-feed into a fluidized bed of catalyst, preferably ZSM-5, at a temperature which is typically in the range of

500" to 800°F. The ethylene and propylene components of the light olefin feed react to produce olefins, paraffins and aromatics which have a higher product value than the feed components. In addition, the feed components react with the aromatics in the reformate to produce alkyl aromatics which themselves may rearrange and transalkylate over the catalyst to produce a further range of products. U.S. Patent No. 4,992,607 (Harandi) also describes a process for upgrading reformate using FCC fuel gas as a source of olefins for alkylation of the aromatic components present in the reformate.

U.S. Patent No. 4,950,387 (Harandi) describes a process in which a naphtha stream is upgraded by reaction with light olefins such as FCC fuel gas.

The naphtha may be a light FCC naphtha, a heavy FCC naphtha or a heart cut of heavy naphtha drawn from the FCC column.

In all cases where a reformate is treated in these processes, the benzene content is reduced during the process by the alkylation reactions over the catalyst. It would, however, be desirable to reduce the benzene levels still further.

We have now devised a process for upgrading low octane naphthas to produce gasoline products with low levels of benzene while retaining a reasonably high pool octane. The present processing scheme uses a naphtha reformer feed which is dehexanized to provide a C_+ reformer fraction which is fed to the reformer and a C_ fraction which is fed together with the C _g fraction from the reformer effluent to a catalytic upgrading step. In this upgrading step, the low octane components from the naphtha and the benzene from the reformate are converted to light gas and a low benzene, high octane gasoline by alkylation of

the benzene and other aromatics which are present, either from the naphtha or from the reformate. The process has the advantage that benzene make in the reformer is reduced by the by-passing of the C _g benzene precursors around the reformer; in addition, improved benzene alkylation results from the presence of additional light olefins generated by the cracking of paraffins and naphthenes from the naphtha in the upgrading reaction zone. The alkylation of the benzene is preferably carried out with added olefins from an external source but the olefins may in favorable circumstances be produced in the upgrading step itself by cracking of the naphtha feed. The olefins may themselves be converted to gasoline boiling range materials.

The single figure of the accompanying drawings is a simplified process schematic showing one form of the present upgrading process Process Configuration In the present process a feedstream containing benzene and C _g paraffins and naphthenes is upgraded in the presence of a zeolite catalyst such as ZSM-5 to produce a gasoline boiling range product which is low in benzene and other aromatics but has a good pool octane rating. In addition, the upgrading process reduces RVP and may be used to reduce product sulfur levels if desulfurization has not been carried out in another step.

The figure is a simplified process schematic for carrying out the present upgrading. A naphtha feedstream, suitably of light straight run (LSR) naphtha enters the unit through line 10 and passes into a fractionator 11 operating as a dehexanizer. The C ₇ + bottoms fraction which typically contains

less than 5 weight percent ^~ _c o components is removed through line 12 and passes to reformer 13 in which the typical reforming reactions take place to produce a reformate containing benzene in effluent line 14. . The reformate from line 14 passes into a second dehexanizer 15 which separates the reformate into a heavy C_+ reformate fraction which passes out of the unit through line 16 and into the gasoline pool or to other utilization and a Co,- fraction which is sent to dehexanizer 11 through line 17, entering dehexanizer

11 at a level appropriate to its composition.

Dehexanizer 11 separates a Co- fraction withdrawn as sidedraw in line 20; this fraction contains paraffinic and naphthenic components from the LSR feed together with benzene from the reformer. The benzene make in the reformer is, however, limited by the bypassing which occurs as a result of withdrawing C _g naphtha components through the sidedraw. The sidedraw is passed to upgrading reactor 21 in which it is reacted in a single pass reaction (no recycle) with external olefins entering through line 22. The product comprising a high octane low benzene gasoline is taken out through line 23 to the refinery gasoline pool for blending with a C ₅ -C ₈ rich gasoline withdrawn from dehexanizer 11 through line 24 and other pool gasoline components such as the heavy reformate from line 16, alkylate and straight run naphthas.

Recycle of the upgraded product may be achieved, if desired, by passing a proportion of the low benzene gasoline from line 23 through recycle line 25 to dehexanizer 15 to permit the C _? + portion of the product to be removed with the bottoms through line

16 and the unconverted Q. _c o fraction to be returned to

the upgrading reactor through line 17, dehexanizer 11 and line 20.

Hydrocarbon Feeds

The initial naphtha feed comprises a naphtha which is relatively rich in C _c o components including paraffins and naphthenes, such as cyclohexane and methyl cyclopentane, and is suitable for use as a reformer feed. Light straight run naphthas boiling from C- to about 400 ^β F (about 205 ^β C) , usually up to about 380 ^β F (about 195 ^β C) are suitable for this purpose. Straight run stocks are normally preferred as suitable feeds for the reformer but cracked stocks including catalytically cracked gasolines, e.g. FCC naphthas may also be employed. The naphtha may be pretreated to remove sulfur so that no separate pre-treatment is required after passing through the dehexanizer; sulfur may be reduced to levels appropriate for the reformer, typically to below 10 ppmw. Alternatively, the bottoms from dehexanizer 11 may be hydrotreated in pretreater 25 before entering the reformer. This achieves an economy in hydrogen consumption although at the cost of added complication. As described below, the upgrading reactor itself may be used to convert organic sulfur and nitrogen compounds from the C _g components routed into reactor 21 without the addition of hydrogen. In this case, only the reformer feed requires hydrotreating so it may be possible to reduce the size of the pretreater as well as to reduce hydrogen consumption.

A major proportion of the low octane C _g components from the naphtha feed are preferably sent to the upgrading reactor. Usually, at least 75 weight percent of these materials should be sent to the upgrading reactor in order to achieve the

greatest octane boost, coupled with the benzene reduction accruing from the by-passing of the reformer. These low octane components are converted in the upgrading reactor to light gas and a low benzene, high octane gasoline. the conversion of these components is typically from 20 to 80 percent per pass, depending on the operating severity and the supply of external olefins. Benzene conversion in the upgrading reactor is usually in the same range but normally will not exceed about 65 percent per pass due to the limited availability of light olefins and competing olefin-olefin reactions but in favorable circumstances, conversion may be higher. Benzene conversions in the range of 40 to 60 percent are typical; depending on the level of benzene reduction required, benzene conversions in the range of 40 to 50 percent may be adequate in many cases. The olefins may be supplied from an external source, as described in U.S. 4,827,069 and U.S. 4,992,607. Suitable olefins for use in the present process include ethylene and propylene from FCC light (fuel) gas as well as higher olefins such as butene and pentene. Sources of such olefins include FCC fuel gas, as mentioned, propylene and butene from the FCC USGP and pentene from light FCC naphtha. Other hydrocarbons may be mixed with the olefin feedstream, particularly paraffins in FCC fuel gas which may typically contain up to about 40 weight percent olefins, usually 10 to 40 mol percent C_-C ₃ olefins with 5 to 35 mol percent hydrogen with varying amounts of C.-C ₃ paraffins and inert gases such as nitrogen. Light FCC naphtha is also a source of higher olefins, typically Co--Co ₀ olefins, which may be used as an olefin co-feed in line 22; light FCC naphtha also provides a source of benzene and other

aromatics which are converted in the present upgrading process together with the aromatics from the reformer and those from the LSR feed.

The olefins may also be produced in situ by cracking of the paraffins and naphthenes in the C _g fraction of the naphtha. These cracking reactions take place along with the alkylation reactions in the presence of the acidic catalyst in the upgrading reactor. In this case, no external olefins are necessary so that the sole feed to the upgrading reactor may comprise the sidedraw from the dehexanizer comprising C _c o components from the naphtha and the reformate. The cracking reactions may in any event supply additional olefins when an olefinic co- feed is used.

The C ₅ - olefins, undergo reactions such as those described in U.S. 4,827,069 for conversion to gasoline boiling range materials. Such reactions include olefin-olefin reactions which result in C ₅ to c _g olefinic, C ₅ to C _g paraffinic and C _g . _

O gasoline components as well as alkylation reactions with Co- to Co_ aromatics, especially benzene, to produce primarily C ₇ to c _λl aromatics which may themselves rearrange and transalkyate over the catalyst in the upgrading reactor. The C _η to C.. aromatic hydrocarbons obtained in this way include lower alkyl (C. to C.) substituted aromatics such as methyl, ethyl, propyl and butyl substituted benzenes and dialkyl benzenes where the total carbons in the alkyl substituents does not exceed 5. Examples of such alkylation products include toluene, xylenes, ethylbenzene, methyl ethyl benzene, propyl benzene, methyl propyl benzene, butyl benzene, methyl butyl benzene and diethyl benzene. The incorporation of the side chain(s) into the original aronmatic

hydrocarbons improves the overall octane quality of the gasoline product as well as lowering its RVP. The effluent from the reformer will comprise benzene as well as other aromatics, unreacted paraffins and cycloparaffins. The aromatics in the reformate will principally be in the C _g - C _g range, principally benzene, toluene, xylenes and ethylbenzene, with the ratio between the various aromatics being dependent on the character of the reformer feed and reforming conditions. The paraffins in the reformate will typically be in the C ₅ - C- range. Separation of the reformate in the dehexanizer downstream of the reformer passes at least 75 and preferably at least 80 percent of the benzene produced in the reformer to the upgrading reactor together with similar boiling range paraffins and cycloparaffins which have not been converted in the reformer. When recycle is provided, the feed to the upgrading reactor will, of course, include recycled components in the appropriate boiling range. Upgrading Reactions

A number of reactions take place in the upgrading reactor between the hydrocarbons which are present. These reactions, which may take place sequentially and simultaneously include:

Feed Olefins > Equilibrated Olefin Mixture

Olefin Mixture > Aromatics + Paraffins

Benzene + Feed

Olefins > Alkylaromatics Benzene + Equilibrated

Olefins > Alkylaromatics

Paraffins > C 3, - C4, Paraffins + Olefins

Naphthenes > Aromatics, Paraffins,

Olefins

The conversion of benzene to alkyl aromatics is accompanied by both octane uplifts and gasoline yield increase resulting from the incorporation of light olefins into the product. Other reactions also occur along with benzene alkylation and alkylaromatic iso erization, including olefin oligomerization, olefin redistribution and equilibration, cyclization, and aromatization and hydrogen transfer. Under appropriate conditions, paraffin cracking is also observed, producing olefins for reaction with the aromatics in the feed or those produced from the reactions set out above. The cyclics in the naphtha feed undergo both cracking and aromatization reactions with a relatively low selectivity to benzene. The heart cut from the reformate is also rich in C _β paraffins and these components will also readily crack. These cracking reactions generate light olefins which are upgraded to higher octane products by the reactions set out above. The benefits accruing from the use of the naphtha and reformate heart cut co-feeds include:

1. conversion of low octane gasoline to higher octane gasoline without significant formation of benzene, as would take place in the reformer.

2. Improved benzene alkylation from the the additional light olefins generated from cracking the reformer feed.

The upgrading reactions are carried out in the presence of a solid, particulate catalyst of acidic functionality such as the preferred ZSM-5 based catalysts. The process is preferably operated in a dense phase, turbulent, fluidized bed as described in U.S. Patent No. 4,827,069 to which reference is made

for a detailed description of the operating parameters, including details of the fluidization regimes, this mode of operation is preferred because better mixing is achieved together with extended contact times. Alternatively, the process may be carried out in a riser reactor as described in U.S. Patent No. 4,992,607, to which reference is made for a detailed description of this mode of operation. In general terms, the upgrading is typically carried out in the dense phase, turbulent reactor at a temperature in the range of 500° to 900°F (about 260° to about 480"C) , more usually from 600° to 850"F (about 315" to 455°C) . Low to moderate pressure are suitable, typically from about 50 to 500 psig, total system pressure, reactor inlet (about 445 to 3550 kPaa) , preferably about 100 to 400 psig (about 790 to 2860 kPaa) . In contrast to the conditions described in U.S. 4,827,069, however, it is not necessarily preferred that cracking of the c_ to C _g paraffins should be minimized since, as described above, the cracking of these components may provide addtional olefins for reaction with the benzene. For this reason, temperatures higher than those described in U.S. 4,827,069 may be preferred, particularly when no olefin co-feed is used. Total hydrocarbon space velocity (fluid bed operation) will typically be in the range of about 0.5 to about 5 WHSV, more normally from about 0.5 to 2.0 WHSV. Catalyst regeneration may be carried out as described in U.S. 4,827,069, that is, by circulating the catalyst from the reaction zone to the regenerator in which it is regenerated by contact with air, hydrogen or other regenerating gas.

The ratio of the olefin co-feed to the C 6., fraction being fed to the upgrading reactor is

typically from about 0:1 to 10:1 (by weight) and preferably 0.2:1 to 5:1, usually about 1:1 (stream 22: stream 20). The amount of olefin fed to the upgrading reactor should be sufficient to achieve the desired benzene conversion. Ethylene is more reactive with benzene than propylene so that olefin conversion will depend upon the composition of the olefin feed; benzene conversion will similarly vary according to olefin feed composition for the same reason. The use of high olefin:aromatic ratios is desirable in order to maximize benzene alkylation.

When operating with a riser type reactor as described in U.S. 4,992,607, the conditions will be as described there, namely with a temperature in the riser section of the reactor from 350" to 900 ^β F

(about 175" to about 480 ^β C) , usually 500" to 850 ^β F (about 260" to about 455 ^β C) . Pressure in the riser section of the reactor will typically be in the range of 20 to 650 psig (about 240 to 4580 kPaa) , usually from about 50 to 420 psig (about 445 to 3000 kPaa) .

The weight ratio of catalyst to hydrocarbon feed will typicaly be from 0.5:1 to 50:1, more usually from 1:1 to 10:1, and in most cases, from 3:1 to 7:1, by weight. The other conditions appropriate for operation of the riser type reactor and the regenerator are described in detail in U.S. 4,992,607, to which reference is made for such as detailed description. As noted in U.S. 4,992,607, the olefin co-feed to the reactor may be injected at a number of spaced points along the length of the riser.

The catalytic reformer is operated under conditions appropriate to the type of unit in use (fixed bed or continuous catalytic reforming) as well as to the feed requirements and the operating

severity required. These conditions are conventional and can be adequately selected by those skilled in the art.

The products from the reaction include a major proportion in the gasoline boiling range, typically C ₅ to about 400 ^β F (about 205 ^β C), although higher end points may be encountered depending on the reaction conditions in the upgrading reactor. Normally, not more than about 10 weight percent of the liquid C ₅ product will be C..+ hydrocarbons.

The upgrading may be accompanied by desulfurization of sulfur-containing feed components. This desulfurization proceeds in the absence of added hydrogen and therefore provides an additional route to reducing gasoline product sulfur levels, with the added advantage of reducing process hydrogen requirements. Upgrading Catalysts

The acidic catalyst used in the upgrading reaction is preferably a zeolite-based catalyst, that is, it comprises an acidic zeolite in combination with a binder or matrix material such as alumina, silica, or silica-alumina, the preferred zeolites for use in the catalysts in the present process are the medium pore size zeolites, especially those having the structures of ZSM-5, ZSM-11, ZSM-22, ZSM- 23, ZSM-35, ZSM-48 or MCM-22. The medium pore size zeolites are a well-recognized class of zeolites and can be characterized as having a constraint Index of 2 to 12 (Constraint Index is determined as described in U.S. 4,016,218). Catalysts of this type are described in U.S. Patents Nos. 4,827,069 and 4,992,067, to which reference is made for further details of such catalysts, zeolites and binder or matrix materials.

The present process may also use catalysts based on large pore size zeolites such as the synthetic faujasites, especially zeolite Y, preferably in the form of zeolite USY. Zeolite beta may also be used as the zeolite component. Other materials of acidic functionality which may be used in the catalyst.

The acidity desired in the catalyst is suitably measured by the alpha value of the catalyst. The alpha value is an approximate indication of the catalytic cracking activity of the catalyst compared to a standard catalyst. The alpha test gives the relative rate constant (rate of normal hexane conversion per volume of catalyst per unit time) of the test catalyst relative to the standard catalyst which is taken as an alpha of 1 (Rate Constant =

0.016 sec ^" ). The alpha test is described in U.S. Patent 3,354,078 and in J. Catalysis. 4., 527 (1965); 6 , 278 (1966); and £1, 395 (1980), to which reference is made for a description of the test. The experimental conditions of the test used to determine the alpha values referred to in this specification include a constant temperature of 538°C and a variable flow rate as described in detail in J. Catalysis. 61. 395 (1980) . The alpha of the catalysts used in the present process need not be more than 100 and in most cases is preferably not more than 50. For operational reasons, catalyst alpha values should preferably be in the range of 5 to 10. The particle size of the catalyst should, of course, be selected in accordance with the fluidization regime which is used in the process. Particle size distribution will be important for maintaining turbulent fluid bed conditions as described in U.S. 4,827,069. Suitable particle sizes

and distributions for operation of dense fluid bed and transport bed reaction zones are described in U.S. 4,827,069 and 4,992,607. Particle sizes in both cases will normally be in the range of 10 to 300 microns, typically from 20 to 100 microns.

EXAMPLE 1 This Example illustrates the potential for obtaining high conversion levels of paraffins, naphthenes and benzenes. A feedstream comprising a thermally cracked naphtha having the composition set out in Table 1 below was fed into a laboratory scale dense fluid bed reactor containg a fluidisable ZSM-5 catalyst with an alpha in the range of 5 to 7. The reaction was operated at 800 ^β F (about 425"C) , 190 psig, total system pressure (about 1411 kPaa) and at a total hydrocarbon space velocity of 1.0 WHSV. The total hydrocarbon feed composition and the compositions of the products at two mass balances are shown in Table 1.

EXAMPLE 1 Table 1

Temp = 800°F, Reactor Pressure = 190 psig, Total HC WHSV = 1.0

Material Balance Number Feed 1 2

Hours on Stream - 3.3 8.3

Total Balance Closure, % - 98.4 101.1

Benzene Conversion, % - 45.8 42.0

N-Hexane Conversion, % - 71.4 64.7

C Naphthene Conversion , % - 70.4 66.0

Composition. wt% of Hydrocarbon

Hydrogen 0.00 0.15 0.03

Methane 0.00 0.44 0.42

Ethane 0.00 1.17 1.16

Ethene 0.00 0.20 0.26

Propane 0.00 10.57 9.57

Propene 0.00 0.57 0.81

N-Butane 0.00 3.99 3.76

Isobutane 0.00 3.92 3.49

Butenes 0.01 1.08 1.31

Total C _s ⁺ 99.99 77.90 79.19 C. P+O+N 3.65 3.99 3.86 N-Pentane 0.41 1.15 1.18

Isopentane 0.15 1.82 1.54

Pentenes 2.64 0.83 0.92

Cyclopentane 0.44 0.19 0.23

Cg P+O+N 43.41 17.31 20.17 N-Ηexane 18.08 5.18 6.39

Isohexanes 17.38 10.29 11.70

2-Methylpentane 7.14 3.88 4.46

3-Methylpentane 8.77 5.28 6.03

2,2-Dimethylbutane 0.33 0.24 0.27

2,3-Dimethylbutane 1.14 0.89 0.95

Hexenes 4.12 0.71 0.79

Table 1 (cont.)

Benzene 23.45 12.71 13.61

Toluene 3.10 6.83 6.24

Ethylbenzene 0.20 5.81 5.99

Xylenes 0.49 4.15 3.47

Cg Aromatics 0.68 5.75 5.18 Trimethylbenzenes 0.46 0.94 0.57

Methylethylbenzenes 0.14 2.15 1.79

N-Propylbenzene 0.05 1.63 1.79

Isopropylbenzene 0.01 1.03 1.05

C,Q Aromatics 0.56 2.34 1.92 C-.7. Unknowns 2.36 6.09 4.99

CJT — Properties

R+O/M+0 80.5/74.6 95.6/85.5 93.3/85.1

Molecular Weight 88.2 95.7 94.3

Density @ 60F, g/ml 0.73 0.77 0.76

RVP, psi 4.8 4.1 4.2

EXAMPLES 2-3

These Examples illustrate the process using a light olefin co-feed (ethylene, propylene) in combination with the naphtha feed. The processing was carried out in the manner described in Example 1 but at 800"F (about 425"C) , 190 psig (about 141 kPaa) and at a WHSV of 0.74 (total HC) , 0.08 (olefin) and 0.70 overall (6.2 wt. percent N ₂ ) . The results are given in Tables 2 and 3 below.

EXAMPLE 2 Table 2

Temp = 800 ^β F WHSV: Total HC = 0.74

Press = 190 psig Olefin = 0.08

TOS = 4 hrs Overall (6.2 wt% N ₂ ) « 0.79

Composition. HC wt% Feed Product Conversion

Hydrogen 0 0.1

Methane 0 0.4

Ethane 0 0.7

Ethene 0.9 0.2 83

Propane 0 10.7

Propene 5.0 0.5 90

N-butane 0 3.9

I-butane 0 4.6

Butenes 0 0.8

Total C5+ 94.1 78.3 83.2 wt% (77.8 vol%)

C ₅ PON 2.1 3.5

N-pentane 0.2 1.0

I-pentane 0.1 1.9

Pentenes 1.8 0.6

Cyclopentane 0 0

Cg PON 44.9 21.8 N-hexane 10.5 2.6 75

Total Aromatics 36.3 47.1

Benzene 33.2 19.4 42

Toluene 2.0 6.0

Ethylbenzene 0.2 7.4

Xylenes 0.3 2.8

C _g Aromatics 0.3 5.7 C- ₀ + Aromatics 0.4 5.9

Table 2 (cont. )

C5+ Properties

RON+0 86.9 99.9 Δ=13

MON+0 79.3 87.7 Δ= 8

SG § 60F 0.741 0.794

MW 84.6 91.6

RVP, psia 5.23 4.61 Δ=-0.62

MB HC Closure, wt% - 98.8

EXAMPLE 3 Table 3

Temp = 800°F WHSV: Total HC = 0.74

Press = 190 psig Olefin = 0.08

TOS = 9 hrs Overall (6.2 wt% N ₂ ) = 0.79

Composition. HC wt% Feed Product Conversion

Hydrogen 0 0.1

Methane 0 0.4

Ethane 0 0.8

Ethene 0.9 0.2 79

Propane 0 9.6

Propene 4.6 0.6 86

N-butane 0 3.5

I-butane 0 3.8

Butenes 0 1.0

Total C5+ 94.5 80.0 84.6 wt% (79.5 vol%)

C ₅ PON 2.2 3.3

N-pentane 0.3 0.9

I-pentane 0.1 1.6

Pentenes 1.8 0.8

Cyclopentane 0 0

C ₆ PON 45.1 23.8 N-hexane 10.5 3.2 69

Methyl pentane 19.3 10.9 43

Di ethylbutane 10.5 8.5 19

Cg olefins 2.5 0.4 C _g naphthenes 2.2 0.8 64 C _? PON 7.9 3.9

N-heptane 1.4 0.4 72

MeCg + EtC ₅ 3.7 1.8 51 Dimethylpentanes 1.6 1.3 18

C- olefins 1.0 0.2 C ₇ naphthenes 0.2 0.2 0

Cg PON 2.6 2.1

NCg paraffins 0.1 0 ICg paraffins 2.2 2.0 Cg olefins 0.1 0 C. naphthenes 0.2 0.1

C _q PON 0.3 0.1

^C 10 ^P0N 0 0

Total Aromatics 36.5 46.7

Benzene 33.3 20.4 39

Toluene 2.0 6.1

Ethylbenzene 0.2 7.5

Xylenes 0.3 2.8

C _Q Aromatics 0.3 5.4 C '1.0_+ Aromatics 0.4 4.5

Table 3 (cont.)

C5+ Properties

RON+0 86.9 98.8 Δ=12

MON+0 79.3 87.3 Δ= 8

SG § 60F 0.741 0.789

MW 84.6 90.7

RVP, psia 5.23 4.64 Δ=-0.59

MB HC Closure, wt% 100.1

EXAMPLES 4 - 5 These two Examples were carried out as described in Examples 2-3 above but at a temperature of 750 ^β F (about 400 ^β C) . The results are given in Tables 4 and 5 below.

EXAPLE 4

Table 4

Temp = 750 ^β F WHSV: Total HC = 0.74

Press = 190 psig Olefin = 0.08

TOS = 4 hrs Overall ( 6.2 wt% N ₂ ) — 0.79

Composition. HC wt% Feed Product Conversion

Hydrogen 0 0

Methane 0 0.1

Ethane 0 0.2

Ethene 0.9 0.1 94

Propane 0 6.2

Propene 4.4 0.3 94

N-butane 0 3.7

I-butane 0 4.2

Butenes 0 0.5

Total C5+ 94.7 84.8 89.5 Wt% (85.3 vol%)

C PON 2.2 4.0

N-pentane 0.3 1.5

I-pentane 0.1 2.1

Pentenes 1.8 0.4

Cyclopentane 0 0

C ₆ PON 45.2 28.3 N-hexane 10.5 2.9 73

Total Aromatics 36.5 45.0

Benzene 33.4 22.3 33

Toluene 2.0 3.9

Ethylbenzene 0.2 6.0

Xylenes 0.3 1.5

C_ Aromatics 0.3 6.6 C. ₀ + Aromatics 0.4 4.7

Table 4 (cont.)

C5+ Properties

RON+0 86.9 97.3 Δ=10

MON+0 79.3 87.1 Δ= 8

SG @ 60F 0.741 0.778

MW 84.6 90.1

RVP, psia 5.23 4.94 Δ=-0.29

MB HC Closure, % - 94.6

EXAMPLE: 5

Table 5

Temp = 750 ^β F WHSV: Total HC = 0.73

Press = 190 psig Olefin = 0.07

TOS = 10 hrs Overall ( 6.2 wt% N ₂ ) = 0.78

Composition. HC wt% Feed Product Conversion

Hydrogen 0 0

Methane 0 0.1

Ethane 0 0.2

Ethene 0.9 0.1 92

Propane 0 4.6

Propene 3.7 0.3 91

N-butane 0 2.8

I-butane 0 2.9

Butenes 0 0.6

Total C5+ 95.4 88.4 92.7 Wt% (88.5 vol%)

C ₅ PON 2.2 3.4

N-pentane 0.3 1.3

I-pentane 0.1 1.6

Pentenes 1.8 0.6

Cyclopentane 0 0

C ₆ PON 45.6 32.3 N-hexane 10.6 4.7 66

Methyl pentane 19.5 15.6 20

Dimethylbutane 10.6 10.2 4

Cg olefins 2.6 0.5 C _g naphthenes 2.3 1.3 42 C ₇ PON 7.9 5.3

N-heptane 1.4 0.5 65

MeC O. + EtCD,. 3.7 2.8 25

Dimethylpentanes 1.6 1.6 3

C ₇ olefins 1.0 0.2 C ₇ naphthenes 0.2 0.2 0

C _g PON 2.6 2.4

NCg paraffins 0.1 0 ICg paraffins 2.2 2.3 C _g olefins 0.1 0 C _R naphthenes 0.2 0.2

C _Q PON 0.3 0.4

CZ _n PON 0 0

10

Total Aromatics 36.8 44.7

Benzene 33.6 22.5 33

Toluene 2.0 3.7

Ethylbenzene 0.2 5.5

Xylenes 0.3 1.5

C _q Aromatics 0.3 7.3 C ₁₀ + Aromatics 0.4 4.2

Table 5 (cont. )

C5+ Properties

RON+0 86.9 95.3 Δ= 8

MON+0 79.3 86.1 Δ= 7

SG @ 60F 0.741 0.777

MW 84.6 90.0

RVP, psia 5.23 4.85 Δ=-0.38

MB HC Closure , % - 101. 0