Branched alkyl-aromatic sulfonic acid dispersants for dispersing asphaltenes in petroleum oils

Abstract

The present invention is a method to determine the effectiveness of an asphaltene dispersant comprising extracting the asphaltenes from an oil and determining the rate of precipitation of the extracted asphaltene in an alkane-aromatic solvent mixture in the presence and absence of the asphaltene dispersant.

Description

BACKGROUND OF THE INVENTION

[0003] The present invention relates to an additive that when blended with petroleum oils in low concentration, the tendency of the oil to foul and coke surfaces is reduced. This is achieved by increasing the solvency of the asphaltenes, the least soluble fraction, in the petroleum oil.

[0004] It is well known that petroleum crude oils and asphaltene containing oils derived from petroleum crude oils have the tendency to deposit organic solids, called foulant and coke, on refinery process equipment that contact the oil. Such process equipment includes, but is not limited to, pipes, tanks, heat exchangers, furnace tubes, fractionators, and reactors. Even small amounts of foulant or coke results in large energy loss because of much poorer heat transfer through foulant and coke as opposed to metal walls alone. Moderate amounts of foulant and coke cause high-pressure drops and interfere with and make process equipment operate inefficiently. Finally, large amounts of foulant or coke plug up process equipment to prevent flow or otherwise make operation intolerable, requiring the equipment to be shut down and cleaned of foulant and coke.

[0005] It is also well known that petroleum derived, asphaltene containing oils that have undergone reaction at high temperatures, above 350° C., have a tendency for rapidly fouling process equipment, either on cooling or by blending with a more paraffinic oil. Such processed oils include, but are not limited by, the highest boiling distillation fraction after thermally or catalytically hydro-thermally converting atmospheric or vacuum resid of petroleum crude and the highest boiling fraction of the liquid product of fluid catalytic cracking, called cat cracker bottoms or cat slurry oil or decant oil. This rapid fouling is caused by asphaltenes that become insoluble on cooling or on blending with more paraffinic oil. Here asphaltenes are defined as the fraction of the oil that is soluble when the oil is blended with 40 volumes of toluene but insoluble when the oil is blended with 40 volumes of n-heptane. If the asphaltenes become insoluble at high temperatures, above 350° C., they rapidly form toluene insoluble coke (see I. A. Wiehe, Industrial & Engineering Chemistry Research, Vol. 32, 2447-2454). However, it is not well known that the mere blending of two or more unprocessed petroleum crude oils can cause the precipitation of insoluble asphaltenes that can rapidly foul process equipment or when such crude oil blends are rapidly heated above 350° C., the insoluble asphaltenes can coke pipestill furnace tubes. If the blending of oils causes the precipitation of asphaltenes, the oils are said to be incompatible as opposed to compatible oils that do not precipitate asphaltenes on blending. Thus, incompatible blends of oils have a much greater tendency for fouling and coking than compatible oils. If a blend of two or more oils have some proportion of the oils that precipitate asphaltenes, the set of oils are said to be potentially incompatible. Fortunately, most blends of unprocessed crude oils are not potentially incompatible. It is only for that reason that many refineries can process petroleum crudes for long times without the need to shut down and clean out foulant and coke. Several crude oils have even been identified that are self-incompatible. That is they contain insoluble asphaltenes even without blending. Nevertheless, once an incompatible oil or blend of oils is obtained, the rapid fouling and coking that results usually requires shutting down the refinery process in a short time. This results in a large economic debit because while the process equipment is cleaned, large volumes of oil cannot be processed.

[0006] Therefore, it is desirable to increase the solubility of the asphaltenes in the crude oil. This can be achieved by adding asphaltene dispersants to the crude oil.

SUMMARY OF THE INVENTION

[0007] The present invention is an asphaltene dispersant containing an aromatic group, a sulfonic acid head group, and an alkyl tail containing 16 or more carbons and at least one branch of a methyl or longer alkyl. Preferably, the aromatic group is a fused two ring aromatic and the tail a branched two tail alkyl group of 30 carbons or longer. More preferably, the dispersant is a mixture with each alkyl tail varying from one to more than 30 carbons such that there are at least a total of 30 carbons in the tail and a branched methyl or longer branch for every 12 carbons in the tail. Thus, these asphaltene dispersants need not be a pure compound but may be a mixture of compounds of the above description, such as prepared by reacting a petroleum derived aromatic stream and a mixture of olefins or alcohols in the presence of a Friedel Crafts catalyst, such as AlCl3, followed by sulfonation of the aromatic.

[0008] These asphaltene dispersants are useful because their addition at low concentrations, one weight percent or less and preferably less than 1000 parts per million, solubilize asphaltenes in petroleum or petroleum derived oils to prevent asphaltenes from either precipitating or adsorbing on metal surfaces and thereby reducing their tendency to foul or coke metal surfaces, especially heated metal surfaces, such as heat exchanger and furnace tube metal surfaces.

[0009] The invention is also directed to a method to determine the effectiveness of asphaltene dispersants.

DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 shows a schematic diagram of the structure iso-C15-C15 naphthalene acid.

[0011] FIG. 2 shows a schematic diagram of a preferred asphaltene dispersant structure of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0012] In the present invention it has been discovered that blending a member of a family of branched alkyl aromatic sulfonic acids is particularly effective at increasing the solubility of the asphaltenes in a petroleum derived oil. It is well known that alkyl benzene sulfonic acids are effective asphaltene dispersants (Chang and Fogler, Langmuir, 10, 1749-1757) and are being sold commercially for that purpose. However, both Chang and Fogler and we have found that these compounds with linear alkyl chain lengths above 16 carbons are not effective because of the lack of solubility in the oil. This led Chang and Fogler to conclude that the optimum alkyl chain length is 12 carbons. However, we have discovered that the reason for this lack of solubility is because the alkyl chains containing more than 16 carbons form wax-like crystals and promote their precipitation from the oil. This led us to alkyl chains containing branched methyls that interfere with crystal formation. The result was that branched alkyl aromatic sulfonic acids became increasingly better asphaltene dispersants, as the alkyl chain length was increased, and much better than linear alkyl aromatic sulfonic acids. Then it was discovered that two tails of branched alkyl chains attached to aromatic sulfonic acids gave an additional boost in dispersant effectiveness. Finally, in comparing alkyl aromatic sulfonic acids of different size aromatic rings, we discovered that two fused aromatic rings are better dispersants than those containing one ring (benzene) or three fused rings. This leads us to conclude that the optimum alkyl aromatic sulfonic acid dispersant for asphaltenes is one that contains branched, two alkyl tails, a two fused ring aromatic, and a sulfonic acid head. FIG. 1 shows one with two tails of 15 carbons each and one methyl branch. The preferred dispersant would be a mixture of compounds with each tail varying from 1 to 15 carbons while the total number of carbons or sum of both tails, is 30 or more and with at least one methyl branch on each tail that is longer than 12 carbons. Thus, the preferred asphaltene dispersant is better defined by FIG. 2 where R and Q are alkyl tails joined to a carbon that is attached in any position on the naphthalene ring. R and Q are alkyl chains with at least one branched methyl or longer alkyl group for every 20 carbons, and R+Q≧29.

[0013] The asphaltene dispersants are particularly useful in an oil compatibility method, which allows blending potentially incompatible petroleum oil. This oil compatibility method, which is described below, allows for determination of the effectiveness of a dispersant.

[0014] An alternate precipitation rate method for determining the effectiveness of an asphaltene dispersant is also disclosed wherein asphaltenes form a given crude oil are extracted and the rate of precipitation of the extracted asphaltenes in a aliphaltic-aromatic solvent mixture determined in the presence and absence of the dispersant.

[0015] Measurement of Dispersant Effectiveness

[0016] The Oil Compatibility Method is based upon tests with the individual oils involving blending with mixtures of a model solvent, toluene, and a model nonsolvent, n-heptane. The Oil Compatibility Method and tests provide us with a method to measure quickly the ability of a dispersant to increase the solubility of asphaltenes and to predict the improvement of the compatibility of any mixture of oils without the need for interpreting the results of thermal fouling tests. We measure the resulting increase in solubility of asphaltenes by the decrease in toluene equivalence, the percent toluene (asphaltene solvent) in heptane (asphaltene nonsolvent) required to keep asphaltenes in the oil in solution. This has enabled us to screen quickly the effectiveness of various synthetic and commercial additives as asphaltene dispersants.

[0017] Oil Compatibility Method

[0018] Two or more tests of each petroleum oil with a test liquid containing different proportions of a nonpolar asphaltene solvent and of a nonpolar asphaltene nonsolvent enables predicting if a given blend of oils are potentially incompatible. This is based upon determining the Insolubility Number and the Solubility Blending Number for each petroleum oil in the blend using the petroleum oil tests. Here we mean nonpolar when the molecular structure of the liquid only includes atoms of carbon, hydrogen, and sulfur. Once more, it has been learned that potentially incompatible oils can be processed with little fouling or coking as long as they are blended in the correct order, as predicted from the oil tests, and as long as certain proportions of the oils in the blend are avoided, as also are predicted by the Insolubility Number and the Solubility Blending Number of each oil in the blend as determined by the oil tests.

[0019] The first step in determining the Insolubility Number and the Solubility Blending Number for a petroleum oil is to establish if the petroleum oil contains n-heptane insoluble asphaltenes. This is accomplished by blending 1 volume of the oil with 5 volumes of n-heptane and determining if asphaltenes are insoluble. Any convenient method might be used. One possibility is to observe a drop of the blend of test liquid mixture and oil between a glass slide and a glass cover slip using transmitted light with an optical microscope at a magnification of from 50 to 600×. If the asphaltenes are in solution, few, if any, dark particles will be observed. If the asphaltenes are insoluble, many dark, usually brownish, particles, usually 0.5 to 10 microns in size, will be observed. Another possible method is to put a drop of the blend of test liquid mixture and oil on a piece of filter paper and let dry. If the asphaltenes are insoluble, a dark ring or circle will be seen about the center of the yellow-brown spot made by the oil. If the asphaltenes are soluble, the color of the spot made by the oil will be relatively uniform in color. If the petroleum oil is found to contain n-heptane insoluble asphaltenes, the procedure described in the next three paragraphs is followed for determining the Insolubility Number and the Solubility Blending Number. If the petroleum oil is found not to contain n-heptane insoluble asphaltenes, the Insolubility Number is assigned a value of zero and the Solubility Blending Number is determined by the procedure described in the section labeled, “Petroleum Oils without Asphaltenes”.

[0020] Asphaltene Containing Petroleum Oils

[0021] The determination of the Insolubility Number and the Solubility Blending Number for a petroleum oil containing asphaltenes requires testing the solubility of the oil in test liquid mixtures at the minimum of two volume ratios of oil to test liquid mixture. The test liquid mixtures are prepared by mixing two liquids in various proportions. One liquid is nonpolar and a solvent for the asphaltenes in the oil while the other liquid is nonpolar and a nonsolvent for the asphaltenes in the oil. Since asphaltenes are defined as being insoluble in n-heptane and soluble in toluene, it is most convenient to select the same n-heptane as the nonsolvent for the test liquid and toluene as the solvent for the test liquid. Although the selection of many other test nonsolvents and test solvents can be made, there use provides not better definition of the preferred oil blending process than the use of n-heptane and toluene described here.

[0022] A convenient volume ratio of oil to test liquid mixture is selected for the first test, for instance, 1 ml of oil to 5 ml of test liquid mixture. Then various mixtures of the test liquid mixture are prepared by blending n-heptane and toluene in various known proportions. Each of these is mixed with the oil at the selected volume ratio of oil to test liquid mixture. Then it is determined for each of these if the asphaltenes are soluble or insoluble. Any convenient method might be used. One possibility is to observe a drop of the blend of test liquid mixture and oil between a glass slide and a glass cover slip using transmitted light with an optical microscope at a magnification of from 50 to 600×. If the asphaltenes are in solution, few, if any, dark particles will be observed. If the asphaltenes are insoluble, many dark, usually brownish, particles, usually 0.5 to 10 microns in size, will be observed. Another possible method is to put a drop of the blend of test liquid mixture and oil on a piece of filter paper and let dry. If the asphaltenes are insoluble, a dark ring or circle will be seen about the center of the yellow-brown spot made by the oil. If the asphaltenes are soluble, the color of the spot made by the oil will be relatively uniform in color. The results of blending oil with all of the test liquid mixtures are ordered according to increasing percent toluene in the test liquid mixture. The desired value will be between the minimum percent toluene that dissolves asphaltenes and the maximum percent toluene that precipitates asphaltenes. More test liquid mixtures are prepared with percent toluene in between these limits, blended with oil at the selected oil to test liquid mixture volume ratio, and determined if the asphaltenes are soluble or insoluble. The desired value will be between the minimum percent toluene that dissolves asphaltenes and the maximum percent toluene that precipitates asphaltenes. This process is continued until the desired value is determined within the desired accuracy. Finally, the desired value is taken to be the mean of the minimum percent toluene that dissolves asphaltenes and the maximum percent toluene that precipitates asphaltenes. This is the first datum point, T1, at the selected oil to test liquid mixture volume ratio, R1. This test is called the toluene equivalence test.

[0023] The second datum point can be determined by the same process as the first datum point, only by selecting a different oil to test liquid mixture volume ratio. Alternatively, a percent toluene below that determined for the first datum point can be selected and that test liquid mixture can be added to a known volume of oil until asphaltenes just begin to precipitate. At that point the volume ratio of oil to test liquid mixture, R2, at the selected percent toluene in the test liquid mixture, T2, becomes the second datum point. Since the accuracy of the final numbers increase as the further apart the second datum point is from the first datum point, the preferred test liquid mixture for determining the second datum point is 0% toluene or 100% n-heptane. This test is called the heptane dilution test.

[0024] The Insolubility Number, IN, is given by: 1$I_N=T_2-\left[\frac{T_2-T_1}{R_2-R_1}\right]R_2$

[0025] and the Solubility Blending Number, SBN, is given by: 2$S_{\mathrm{BN}}=I_N\left[1+\frac{1}{R_2}\right]-\frac{T_2}{R_2}$

[0026] Petroleum Oils Without Asphaltenes

[0027] If the petroleum oil contains no asphaltenes, the Insolubility number is zero. However, the determination of the Solubility Blending Number for a petroleum oil not containing asphaltenes requires using a test oil containing asphaltenes for which the Insolubility Number and the Solubility Blending Numbers have previously been determined, using the procedure just described. First, 1 volume of the test oil is blended with 5 volumes of the petroleum oil. Insoluble asphaltenes may be detected by the microscope or spot technique, described above. If the oils are very viscous (greater than 100 centipoises), they may be heated to 100° C. during blending and then cooled to room temperature before looking for insoluble asphaltenes. Also, the spot test may be done on a blend of viscous oils in an oven at 50-70° C. If insoluble asphaltenes are detected, the petroleum oil is a nonsolvent for the test oil and the procedure in the next paragraph should be followed. However, if no insoluble asphaltenes are detected, the petroleum oil is a solvent for the test oil and the procedure in the paragraph following the next paragraph should be followed.

[0028] If insoluble asphaltenes were detected when blending 1 volume of the test oil with 5 volumes of the petroleum oil, small volume increments of the petroleum oil are added to 5 ml of the test oil until insoluble asphaltenes are detected. The volume of nonsolvent oil, VNSO, is equal to the average of the total volume of the petroleum oil added for the volume increment just before insoluble asphaltenes are detected and the total volume added when insoluble asphaltenes were first detected. The size of the volume increment may be reduced to that required for the desired accuracy. This is called the nonsolvent oil dilution test. If SBNTO is the Solubility Blending Number of the test oil and INTO is the Insolubility Number of the test oil, then the Solubility Blending Number of the nonsolvent oil, SBN, is given by: 3$S_{\mathrm{BN}}=S_{\mathrm{BNTO}}-\frac{5\left[S_{\mathrm{BNTO}}-I_{\mathrm{NTO}}\right]}{V_{\mathrm{NSO}}}$

[0029] If insoluble asphaltenes were not detected when blending 1 volume of the test oil with 5 volumes of the petroleum oil, the petroleum oil is a solvent oil for the test oil. The same oil to test liquid mixture volume ratio, RTO, as was used to measure the Insolubility Number and Solubility Blending Number for the test oil is selected. However, now various mixtures of the test liquid are prepared by blending different known proportions of the petroleum oil and n-heptane instead of toluene and n-heptane. Each of these is mixed with the test oil at a volume ratio of oil to test liquid mixture equal to RTO. Then it is determined for each of these if the asphaltenes are soluble or insoluble, such as by the microscope or the spot test methods discussed previously. The results of blending oil with all of the test liquid mixtures are ordered according to increasing percent petroleum oil in the test liquid mixture. The desired value will be between the minimum percent petroleum oil that dissolves asphaltenes and the maximum percent petroleum oil that precipitates asphaltenes. More test liquid mixtures are prepared with percent petroleum oil in between these limits, blended with the test oil at the selected test oil to test liquid mixture volume ratio (RTO) and determined if the asphaltenes are soluble or insoluble. The desired value will be between the minimum percent petroleum oil that dissolves asphaltenes and the maximum percent petroleum oil that precipitates asphaltenes. This process is continued until the desired value is determined within the desired accuracy. Finally, the desired value is taken to be the mean of the minimum percent petroleum oil that dissolves asphaltenes and the maximum percent petroleum oil that precipitates asphaltenes. This is the datum point, TSO, at the selected test oil to test liquid mixture volume ratio, RTO. This test is called the solvent oil equivalence test. If TTO is the datum point measured previously at test oil to test liquid mixture volume ratio, RTO, on the test oil with test liquids composed of different ratios of toluene and n-heptane, then the Solubility Blending Number of the petroleum oil, SBN, is given by: 4$S_{\mathrm{BN}}=100\left[\frac{T_{\mathrm{TO}}}{T_{\mathrm{SO}}}\right]$

[0030] Mixtures of Petroleum Oils

[0031] Once the Solubility Blending Number is determined for each component the Solubility Blending Number for a mixture of oils, SBNmix, is given by: 5$S_{\mathrm{BNmix}}=\frac{V_1{S}_{{\mathrm{BN}}_1}+V_2{S}_{{\mathrm{BN}}_2}+V_3{S}_{{\mathrm{BN}}_3}+\cdots }{V_1+V_2+V_3+\cdots }$

[0032] where V1 is the volume of component 1 in the mixture.

[0033] The criterion for compatibility for a mixture of petroleum oils is that the Solubility Blending Number of the mixture of oils is greater than the Insolubility Number of any component in the mixture. Therefore, a blend of oils is potentially incompatible if the Solubility Blending Number of any component oil in that blend is less than or equal to the Insolubility Number of any component in that blend. Once asphaltenes precipitate, it takes on the order of hours to weeks for the asphaltenes to redissolve while it takes of the order of minutes to process the oil in refinery equipment. Thus, to prevent fouling and coking a potentially incompatible blend of oils must be blended to always keep the Solubility Blending Number of the mixture higher than the Insolubility Number of any component in the blend. Thus, both the order of blending and the final proportions of oils in the blend are important. If one starts with the oil of highest Solubility Blending Number and blends the remaining oils in the order of decreasing Solubility Blending Number and if the final mixture meets the compatibility criterion of the Solubility Blending Number of the mixture is greater than the Solubility Number of any component in the blend, then compatibility of the oils throughout the blending process is assured even though the blend of oils is potentially incompatible. The result is that the blend of oils will produce the minimum fouling and/or coking in subsequent processing.

EXAMPLE 1

[0034] The effect of 1 wt % and 5 wt % of alkyl benzene sulfonic acids on reduction of toluene equivalence of Baytown Cat Cracker Bottoms is shown in FIG. 3. While a C8 tail reduced toluene equivalence (TE) for a short time, tails much longer than 12 carbons were required for the dispersion to last for as long as a day and exhibit long term stability. However, tails longer than 16 carbons resulted in a dispersant that was only partially soluble in the oil because the tails crystallized like a wax. A branched C24 alkyl benzene sulfonic acid exhibited the best performance in terms of TE reduction and long term stability. In addition, the branched, 24 carbon tail benzene sulfonic acid used is an intermediate in the manufacture of lube oil detergents (Exxon Chemicals Paramins) and is named SA119.

a.	C8	1% reduced TE from 87 to 60, insoluble next day
		5% reduced TE from 87 to 55, insoluble next day
b.	C12	1% reduced TE from 87 to 60, insoluble next day
		5% reduced TE from 87 to 55, soluble next day
c.	C18	is a solid and partially soluble in toluene/heptane
d.	IsoC24 (5 branched methyls)
	1% reduced TE from 87 to 60, soluble next day
	5% reduced TE from 87 to 55, soluble next day

[0035] Thus, branched alkyl benzene sulfonic acids are better than linear alkyl benzene sulfonic acids as asphaltene dispersants in crude oil.

EXAMPLE 2

[0036] Table 1 contains the results of 25 synthesized dispersants. The synthesis involved alkylation of an aromatic ring, followed by sulfonation. The variables in the synthesis are the type of aromatic and the type of olefin used for alkylation. Alpha olefins give a single tail while internal olefins give two tails with a distribution of splits of the total chain length between the two tails. In addition, the total number of carbons and the degree of branching of the olefins were varied. 13C NMR was used to measure the chain length, methyl branches per molecule, percent of olefin sample that was olefin, and the percent of aromatics that was functionalized by the addition of an olefin. Elemental analysis was used to determine the percent sulfonation. Finally, reduction in the toluene equivalence of Maya crude oil after the addition of 5% dispersant was used to measure the effectiveness as an asphaltene dispersant. Results in Table 1 illustrate the salient features of our invention.

[0037] a) In comparing Entries 3, 16, and 23 with the same alpha olefin, the dispersant with naphthalene results in a lower toluene equivalence than with toluene or with phenanthrene. In addition, in comparing 7 and 8 with 24 or 9 with 25, naphthalene gives better results than phenanthrene.

[0038] (b) In comparing Entry 20 and 21 with 14 or Entry 19 with 1, it is clear that naphthalene a two fused aromatic ring structure is a superior performer compared to two aromatic rings that are connected by a C-C bond (binaphthyl) or tetralin where one ring is aromatic and the other nonaromatic.

[0039] (c) Since the best dispersants were prepared with internal olefins, two tails are more effective than single tails.

[0040] (d) Since the longest chain length internal olefins produced the best dispersants as seen by 7, 8, 10 and 11 with carbon chains of 37 to 47 on naphthalene, the alkyl tails of at least 30 carbons are most effective.

[0041] (e) In comparing 12 and 14, one sees that the more branched tail produces a better dispersant even with a low degree of functionalization.

TABLE 1
Example Synthetic Asphaltene Dispersants
				Methyls	%	Maya
		Olefin	Carbon	per	Func-	Toluene
		Internal	Chain	Mo-	tionali-	Equiva-
No.	Aromatic	or Alpha ?	Length	lecule	zation	lence
1	Toluene	Internal	23	0.15	119	34
2	Toluene	Internal	23	0.15	78	31
3	Toluene	Alpha	21	0	76	34
4	Toluene	Internal	[20-24]	[0.33]	78	32
5	Toluene	Internal	25	0	36	32
6	Toluene	Internal	33	0.99	37	23.5
7	Naphthalene	Internal	37	0.33	29	13
8	Naphthalene	Internal	37	0.33	114	11
9	Naphthalene	Internal	33	0.99	44	17
10	Naphthalene	Internal	47	0.28	85	11
11	Naphthalene	Internal	37	0.54	90	13
12	Naphthalene	Internal	25	1.9	51	17
13	Naphthalene	Internal	18	0.10	95	31
14	Naphthalene	Internal	23	0.15	89	23
15	Naphthalene	Internal	18	0.17	65	32
16	Naphthalene	Alpha	21	0	86	28
17	Naphthalene	Internal	29	0.33	60	32
18	Naphthalene	Alpha	17	0.04	40	26
19	Tetralin	Internal	37	0.33	76	>36
20	Tetralin	Internal	23	0.15	103	29
21	Binaphthyl	Internal	23	0.15	119	>30
22	Phenanthrene	Internal	23	0.15	62	30
23	Phenanthrene	Alpha	21	0	34	34
24	Phenanthrene	Internal	37	0.33	43	26.5
25	Phenanthrene	Internal	33	0.99	62	29

[0042] Rate of Asphaltene Precipitation Method

[0043] In this method asphaltenes are extracted from a given oil by using an extraction solvent selected from the group consisting of C3 to C16 alkanes, cyclopentane, cyclohexane and mixtures thereof. The extraction solvent is added to the oil in a ratio in the range of 10:1 to 3:1 solvent: oil by weight. The mixture of oil and solvent are mixed for a period in the range of 0.1 to 48 hours at temperatures in the range of 25° C. to 150° C. At higher temperatures mixing is conducted at suitable pressures sufficient to keep the oil and solvent in liquid state. After mixing, the insoluble solids are filtered out, washed with the extraction solvent and dried. The insoluble solids extracted or isolated by this method are the asphaltenes of the oil.

[0044] The extracted or isolated asphaltenes are dissolved in a solvent mixture. The solvent mixture is a mixture of alkanes and aromatic solvents. The alkane solvents are selected from the group consisting of C7 to C18 alkanes, cyclopentane, cyclohexane and mixtures thereof. Preferred alkane solvents are C7 to C16 n-alkanes. The aromatic solvents are selected from the group consisting of benzene, alkyl benzene wherein the alkyl group is methyl, ethyl, isopropyl and 1,2,3,4-tetrahydronaphthalene, and mixtures thereof. Preferred aromatic solvent is toluene. The solvent mixture comprising alkane and aromatic solvents are preferably in the ratio range of 0.5:1.5 to 1.5:0.5 alkane:aromatic solvent. The preferred range is a 1:1 alkane: aromatic solvent. The amount of asphaltene dissolved in the solvent mixture ranges from 0.001 to 3 wt % based on the weight of the solvent mixture. Preferred amount of asphaltene is in the range of 0.01 to 0.03 wt % based on the weight of the solvent mixture. Dissolution is achieved by mixing the solid asphaltenes and the solvent mixture between 25° C. to 80° C. for 0.1 to 48 hours.

[0045] We observed that asphaltenes precipitate from solution. This property is made use of in the rate of precipitation method. As soon as dissolution is complete the solution is analyzed for asphaltene precipitation. Then, the rate of asphaltene precipitation k1 can be determined by measuring the decrease in concentration of the asphaltene as a function of time. Since asphaltene solutions are colored the preferred analytical method is by colorimetry, measuring the decrease in absorbance of light at a fixed wavelength as a function of time. The asphaltene solution can be introduced into a 0.1 to 1 cm path length cell and the cell placed in an absorbance spectrometer and the absorbance recorded as a function of time. Absorbance is measured and recorded preferably in the visible range of the spectrum. The wavelength of monitoring is preferably between 350 to 700 nm. Decrease in light absorbance occurs due to a decrease in asphaltene concentration in solution or stated differently precipitation of the asphaltenes. Absorbance versus time plot is generated. It is preferable to plot the data as a logarithm of absorbance versus time plot and calculate the slope of the plot. The slope of this plot is defined as the rate of asphaltene precipitation and given the notation k1. The rate of precipitation can be determined in the temperature range of 25° C. to 150° C. It is preferred to determine the rate of precipitation in the range of 25° C. to 50° C.

[0046] In the next step of the method an asphaltene dispersant is added to a known quantity of the asphaltene solution, made previously to determine k1. The amount of asphaltene dispersant added can vary in the range of 0.0001 to 2 wt % based on the weight of the solvent mixture. The addition is followed by mixing between 25° C. to 80° C. for 0.1 to 48 hours. At completion of mixing the dispersant treated asphaltene solution is subject to the determination of the rate of precipitation as described above at the same temperature as determined for the asphaltene solution. The rate of precipitation of the dispersant treated asphaltene is denoted as k2.

[0047] The difference between k1 and k2 is defined as K the effectiveness of the asphaltene dispersant at the determined temperature. When K=k1 the dispersant has maximum effectiveness. When k1=k2, K=0 and is indicative of no effectiveness.

EXAMPLE 3

[0048] In a typical experiment asphaltenes were extracted from Maya crude oil using n-heptane as the solvent and using a 10:1 solvent to crude oil ratio. The oil and solvent were mixed at 25° C. for 48 hours and the n-heptane insolubles were extracted and air dried. The extracted Maya asphaltenes were dissolved in a 1:1 hexadecane:toluene solvent mixture. A 0.025 wt % solution of the asphaltenes in the solvent mixture was made. Mixing was conducted at 25° C. for 12 hours. The asphaltene solution was placed in a 1 cm path length cell and the absorbance at 400 nm recorded over a period of 10 hours. The absorbance dropped from 3.2 to 2.6. The slope of the logarithm (absorbance) versus time plot, k1 was 0.00025.

[0049] To the 0.025 wt % asphaltene solution was added asphaltene dispersant #10 from Table 1. The amount of asphaltene dispersant was 0.001 wt % based on the weight of the solvent mixture. The dispersant treated asphaltene solution was mixed at 25C for 3 hours. The dispersant treated asphaltene solution was placed in a 1 cm path length cell and the absorbance at 400 nm recorded over a period of 10 hours. The absorbance remained at 3.2. The slope of the logarithm (absorbance) versus time plot k2=0. Therefore K=k1−k2=K1 and the dispersant exhibits maximum effectiveness.

[0050] The same experiment was then carried out using dispersant #1 from Table 1. The value of k2 was 0.00025. The value of k1=k2 and Thus the rate of precipitation method indicates that dispersant #1 was ineffective. The same result is true by the oil compatibility method as disclosed in Table 1.

Claims

1. A method to determine the effectiveness of an asphaltene dispersant in an asphaltene containing oil comprising: (a) extracting asphaltenes from said oil; (b) dissolving said extracted asphaltenes in a hydrocarbon solvent to provide a dissolved asphaltenes solution; (c) measuring the rate of precipitation, k1 of said dissolved asphaltenes; (d) dissolving said extracted asphaltenes and said asphaltene dispersant in said hydrocarbon solvent to provide a dissolved dispersant treated asphaltene solution; (e) measuring the rate of precipitation, k2 of said dissolved dispersant treated asphaltenes; (f) determining the difference K between k, and k2.

2. The method of claim 1 wherein said hydrocarbon solvent is a mixture of an alkane solvent and aromatic solvent.

3. The method of claim 2 wherein said solvent ratio is in the ratio range of alkane solvent:aromatic solvent of 0.5:1.5 to 1.5:0.5.

4. The method of claim 2 wherein said alkane solvent is selected from the group consisting of C3 to C16 alkanes, cyclopentane, cyclohexane and mixtures thereof.

5. The method of claim 2 wherein said aromatic solvent selected from the group consisting of benzene, methyl benzene, ethyl benzene, isopropyl benzene, 1,2,3,4-tetrahydronaphthalene, and mixtures thereof.

6. The method of claim 1 wherein said alkane solvent is C3 to C16 alkane.

7. The method of claim 1 wherein said alkane solvent is cyclopetane.

8. The method of claim 1 wherein said alkane solvent is cyclohexane.

9. The method of claim 5 wherein said aromatic solvent is benzene.

10. The method of claim 5 wherein said aromatic solvent is methyl benzene.

11. The method of claim 5 wherein said aromatic solvent is ethyl benzene.

12. The method of claim 5 wherein said aromatic solvent is isopropyl benzene.

13. The method of claim 5 wherein said aromatic solvent is 1,2,3,4-tetrahydronaphthalene.

14. The method of claim 5 wherein said aromatic solvent is toluene.