DE69102683T3 - Use of at least one cyclopentadienyl / manganese compound in a formulated, lead-free gasoline. - Google Patents

Description

The invention relates to the use a cyclopentadienylmanganese tricarbonyl compound in an Otto engine, d. H. a gasoline engine, with gasolines that are superior in use Have properties related to the environment and performance.

International application WO 87/01384 describes lead-free gasoline compositions to which combinations of C _1-6 aliphatic alcohols, cyclopentadienyl manganese tricarbonyl as anti-knocking agents and aromatic hydrocarbons are added to improve emissions and other pollution problems.

US-A-4 139 349 describes lead-free Gasoline compositions that are a synergistic combination Bicyclopentadienyleisen- and Cyclopentadienylmangancarbonyln as Have anti-knock agents.

This invention is believed to show the most effective and efficient way to use gasolines of suitable octane number, while at the same time reducing the maximum reactivity of gasoline Combustion engine exhaust products reduce the possibility of ozone formation on the ground, smog formation and other stressful consequences of air pollution.

The invention provides the use according to claim 1 ready.

1 Fig. 4 is a scaled schematic representation of the exhaust gas dilution tunnel used in the tests described in Examples 1-4 below.

2 Figure 3 is a schematic illustration of the vehicle emissions sampling system used in accordance with the tests described in Examples 1-4 below. In the process of the present invention, the gasoline-type hydrocarbons used in the manufacture generally include saturated, olefinic and aromatic hydrocarbons; they may also contain oxidized gasoline blends such as hydrocarbyl ether. The fuels are limited in aromatic petroleum hydrocarbon content in that the aromatics are capable of producing exhaust gas species with a relatively high reactivity. Likewise, it is desirable to use gasolines that contain relatively small amounts of olefinic hydrocarbons (e.g., less than 10%, and more preferably less than 5% by volume), since these substances tend to produce high reactivity exhaust product species result.

At the moment this is the furthest Common methods of improving the octane number of the whole Gasoline based on the use of aromatic gasoline hydrocarbons in the basic mixes. Unfortunately, however, certain are aromatic Consider hydrocarbons such as benzene as carcinogens. Farther tend, as already described above, aromatic hydrocarbons (and also olefinic hydrocarbons) to be relatively reactive To result in particle-containing exhaust products, of which assumed will that she in the formation of ozone on the ground, smog and other types of Air pollution is involved.

The invention overcomes this contradiction through the use of an anti-knock agent of such a strength that already small amounts, such as 1/32 g manganese or less per gallon (3.78 l) result in a significant increase in the octane number in the fuel. Therefore, the refiner is enabled to use a gasoline with the desired one Octane number available to ask while at the same time maintain the proportion of aromatics in the base fuel or can even be reduced. As a result, the at Use of the gasoline according to the invention hydrocarbon exhaust emissions obtained have a lower maximum responsiveness on than the hydrocarbon emissions the same would have petrol, when the anti-knock agent is used to achieve the same octane number necessary amount of aromatic hydrocarbons would be replaced. Indeed surrendered the gasolines according to the invention at least in some circumstances Hydrocarbon emissions with significantly lower responsiveness than the hydrocarbon emissions of the same basic fuel without the cyclopentadienylmanganese tricarbonyl additives.

This particularly preferred embodiment according to the invention is illustrated in Example 4 below.

It can also be in accordance with preferred embodiments the invention the amount of olefinic hydrocarbons in the Gasoline composition controlled so that they are below about 10 vol .-% is (preferably less than 5 vol .-%) and additionally oxidized gasoline admixtures (e.g. hydrocarbyl ether) with suitable distillation behavior in the gasoline can be brought in. To the gasoline compositions from the aspect of environmental protection The gasoline compositions should improve even further are mixed together from the components that the vapor pressure according to Reid (ASTM test method D-323) 62.1 kPa (9.0 psi) or less and am most preferably is 55.2 kPa (8.0 psi) or less. On this way Loss of gasoline due to evaporation into the atmosphere at Storage or refueling can be effectively reduced. As is known vapor pressures according to Reid at 100 ° F (37.8 ° C) certainly.

The gasolines according to the invention are lead-free in the sense that the fuel does not release any anti-knock agents organic lead compounds are added. If there are any traces of lead, these amounts are based solely on contaminants in the system in which the fuels are manufactured, mixed, stored, transported or distributed.

The one for making gasoline blends usable hydrocarbon-containing gasoline bases include distillation residues, light Naphtha fractions, from thermal or catalytic cracking processes, hydrocracking or the like Cracked gasoline bases obtained by catalytic processes Conversion or similar Process received reformate, about Polymerization or polymeric gasolines formed from olefins, by Add olefins to isobutane or other hydrocarbons via alkylation processes alkylates obtained by isomerization of linear paraffins low chain length such as n-hexane, n-heptane and the like. ä. obtained isomers and others about suitable refining processes obtained hydrocarbons in the boiling range of gasoline. if desired can appropriate amounts of suitable hydrocarbons that are superior to others Procedure like about receive the production from coal, clay slate or tar sands be included become. For example on the liquid fuels Reformates based on the Fischer-Tropsch process into the mixtures be introduced. In all cases must however the resulting gasoline reduced the requirements of the invention Exhaust hydrocarbon emissions and the typical distillation properties are sufficient commercial normal, mediocre, excellent or have super gasoline. For example, the engine gasoline generally within the parameters of ASTM D 4814 and typically initial Boiling points in the range of 21–46 ° C (70–115 ° F) and final boiling points in the range of 180-227 ° C (370-440 ° F) as measured by the ASTM standard distillation process (ASTM D 86). The hydrocarbon composition of gasolines according to the volume percentages of saturated, unsaturated and aromatic hydrocarbons is usually about ASTM test method D 1319 measured.

In general, base gasoline will be a mixture of bases available from various refining processes. The finished mixture can also contain hydrocarbons produced by other processes, such as alkylates prepared by reacting C ₄ -olefins and butanes using an acid catalyst such as sulfuric acid or hydrofluoric acid, and aromatics obtained from a reformate.

The saturated gasoline components include Paraffins and naphthenates. These saturated compound mixtures are generally obtained from: 1) crude gasoline by distillation (Straight-run gasoline), 2) alkylation processes (alkylates) and 3) Isomerization process (conversion of normal paraffins into branched ones Paraffins higher Octane). saturated Gasoline components also occur in so-called natural gasolines. In addition to the above list included thermally or catalytically cracked Basics as well as catalytic reformates certain amounts of saturated Components. According to more preferred embodiments of the invention the base gasoline mix contains a major portion of saturated gasoline components. Generally speaking, the higher the content of saturated Connections in line with the production of a fuel the needed Octane number and distillation properties, the better.

Olefinic gasoline components are commonly used by using such methods as thermal or catalytic Cracking formed. Dehydrogenation of paraffins to olefins can gaseous olefins that occur during refining to Addition material for either To win polymerizations or alkylation processes. To the greatest possible octane reactions with the addition of cyclopentadienylmanganese tricarbonyl as an anti-knock compound to achieve the olefins if they are in the fuel gene mix are used, essentially in the form of linear 1-olefins such as 1-heptene, 1-octene, 1-nonen and 1-decene. It is known to show olefins of this type excellent anti-knock reactions with regard to cyclopentadienylmanganese tricarbonyls - cf. Brown and Lovell, Industrial and Engineering Chemistry, Volume 50, No. 10, October 1958, pp. 1547-50.

The basic gasoline mixtures, with those of the cyclopentadienylmanganese tricarbonyl additive mixed according to the invention will generally contain 40-90 vol .-% saturated compounds, up to 30 (and preferably less than 10 and more preferably less than 5)% by volume olefins and up to 30% by volume aromatics, even more preferred not more than 28% by volume aromatics and most preferably not more than 25 vol.% aromatics. Preferably, the fuel mixture as a whole contains not more than 1% by volume and most preferably not more than 0.8 vol% benzene. The inventive and / or used, Particularly preferred, lead-free petrol not only meet the criteria of the invention with respect to the emission of reactive particles, but also stand out in that they (1) a maximum sulfur content of 300 ppm, (2) a maximum Bromine number of 20, (3) a maximum aromatic content of 20% by volume, (4) a maximum benzene content of 1% by volume and (5} a minimum Oxygen content in the form of at least one mono- or polyether of 1 wt .-%, in this gasoline up to 1/32 g of manganese per gallon (3.78 l) in the form of methylcyclopentadienylmanganese tricarbonyl solved is. Petrol of this type that do not contain the manganese additive are sometimes referred to as reformulated gasolines. See e.g. B. Oil & Gas Journal, April 9, 1990, pp. 43-48.

From the octane point of view, those gasoline base mixtures are preferred who have an ignition friendliness of (R + M) / 2 between 78-95.

A large number of cyclopentadienylmanganese tricarbonyl compounds can be used in the practice of the invention. Illustrative examples of the manganese compounds useful in this invention include Cyclopentadienymangantricarbonyl, methylcyclopentadienyl, dimethylcyclopentadienyl, Trimethylcyclopentadienylmangantricarbonyl, Tetramethylcyclopentadienylmangantricar carbonyl, Pentamethylcyclopentadienylmangantricarbonyl, ethylcyclopentadienyl, diethylcyclopentadienyl, propylcyclopentadienyl, isopropylcyclopentadienyl, Octylcyclopentadienylmaugantricarbonyl, dodecylcyclopentadienyl, Ethylmethylcyclopentadienylmangantricarbonylund Indenylcyclopentadienylmangantricarbonyl-butylcyclopentadienyl t including mixtures of two or more of these compounds. Generally, those compounds or mixtures are preferably compounds which are present at normal room temperature in liquid state such as methylcyclopentadienyl, ethylcyclopentadienyl manganese tricarbonyl, liquid mixtures of cyclopentadienyl manganese tricarbonyl and methylcyclopentadienyl manganese tricarbonyl, and mixtures of methylcyclopentadienyl manganese tricarbonyl and ethylcyclopentadienyl manganese tricarbonyl. The most preferred. Compound, because it is commercially available, and because of its excellent combination of properties and effectiveness, is methylcyclopentadienylmanganese tricarbonyl. To meet the criteria of the invention with respect to reduced emission of reactive particles, the maximum responsiveness of the C ₁ -C ₁₀ hydrocarbon particles released by the running engine is determined by that of William PL Carter of the Air Pollution Research Center, University of California at Riverside , California, developed ozone reactivity numbers.

In the case of motor vehicles, the method includes operating the vehicle on a chassis dynamometer (e.g., a Clayton model ECE-50 with a directly driven variable inertia flywheel system, the equivalent weight of vehicles from 454 to 4026 kg (1000 to 8875 pounds ) simulated in 57 kg (127 pounds) increments) according to the state test procedure (US Code of Federal Regulations, Title 40, Part 86, Subsections A and B, the sections applicable to low power motor vehicles). As schematically in the 1 and 2 , the vehicle exhaust gases are directed into a stainless steel dilution tunnel where they are mixed with filtered air. Samples of the regulated emission and samples for the determination of the C ₁ -C ₁₀ hydrocarbons are taken from the diluted exhaust gas by means of a device of the same volume (CVS - constant volume sampler) and in bags (e.g. bags made of Tedlar resin) collected in the usual way.

The state testing process uses an urban dynamometer schedule that takes 1372 seconds. This timetable is again divided into two segments. A first segment of 505 seconds (a through phase) and a second segment of 867 seconds (a stabilized phase). The process requires a cold start 505 segment and a stabilized 867 segment, followed by a ten minute suction segment and a subsequent warm start 505 segment. In the method used here, separate samples of the regulated emission and samples for determining the C ₁ -C ₁₀ hydrocarbons are collected during the cold start 505 segment, the stabilized 867 segment and the warm start 505 segment. If it is intended to collect and analyze samples for aldehydes and ketones, the sampling system will include an impinger collection system (see 2 ), which enables the continuous collection of exhaust gas samples during the desired test cycle. The exhaust gas diluted with air is passed at a rate of 4 liters per minute through a cooled glass wash bottle containing an acetonitrile solution of 2,4-dinitrophenylhydrazine and perchloric acid.

If samples for aldehydes and ketones are taken out, the federal testing process to four Cycles for sampling aldehydes and ketones extended. Therefore comprises the sampling plan if (a) samples for regulated emission, (b) for the determination of hydrocarbons and (c) for aldehydes and ketones are withdrawn, the withdrawal for (a) during the cold start 505 segment, of the stabilized 867 segment and the warm start 505 segment. Samples for (b) are also separated from it during these three segments taken. The samples for (c), however, become continuous in the course of the cold start 505 segment taken together with the stabilized 867 segment, and one further removal is started at the beginning of the warm start 505 segment and extends to the subsequent 867 segment. If only is intended for (a) and (b) to take samples, the impinger system and the associated withdrawal procedure is not required.

The analytical procedure which for execution The hydrocarbon determination used is in example 1 described below. For the analysis of aldehydes and ketones part of the acetonitrile solution in a liquid chromatograph injected, which is equipped with a UV detector. External standards of 2,4-dinitrophenylhydrazine derivatives of aldehydes and ketones are used to quantify the results. The detection limits this process is on the order of 0.005 ppm aldehyde or ketone in the diluted Exhaust.

To measure the maximum reactivity of certain hydrocarbons, the in mg / mile expressed value for each particular colic hydrogen multiplied by the reactivity constant developed by William PL Carter. These constants, as estimated by Carter and which represent the reactivity in grams of ozone / gram of certain hydrocarbon, are given in Table 1. TABLE 1 Hydrocarbon Responsiveness g ozone / g kW methane 0.0102 Ethan 0147 propane 00:33 n-butane 0.64 n-pentane 0.64 n-hexane 0.61 n-heptane 00:48 n-octane 00:41 n-nonane 00:29 n-decane 00:25 isobutane 0.85 clumped C4-C5 alkanes 0.78 branched C5 alkanes 0.88 isopentane 0.88 neopentane 00:19 2-methyl pentane 0.91 3-methyl pentane 0.95 branched C6 alkanes 0.91 2,3-dimethylbutane 0.74 2,2-dimethylbutane 00:41 clumped C6 alkanes 0.7 2,4-dimethylpentane 1:07 3-methyl hexane 0.85 4-methylhexane 0.85 branched C7 alkanes 0.85 2,3-dimethylpentane 0.96 isooctane 0.7 4-methylheptane 0.72 branched C8 alkanes 0.72 branched C9 alkanes 0.68 4-ethylheptane 0.68 branched C10 alkanes 0.6 3 or 4-propylheptane 0.6 cyclopentane 1.6 Methylcyclopentane 1.7 C6-cycloalkanes 0.84 cyclohexane 0.84 C7-cycloalkanes 1.1 methylcyclohexane 1.17 ethylcyclohexane 1:36 C8 cycloalkanes 1:36 C9 cycloalkanes 1.6 C10 cycloalkanes 1.31 ethene 5.3 propene 6.6 1-butene 6.1 1-pentene 4.2 3-methyl-1-butene 4.2 1-hexene 3 C6-terminated alkenes 3 C7-encoded alkenes 2.4 C8 terminal alkenes 1.9 C9-terminal alkenes 1.6 C10 terminal alkenes 1:32 isobutene 4.2 2-methyl-1-butene 3.7 trans-2-butene 7.3 cis-2-butene 7.3 2-methyl-2-butene 5 C5 internal alkenes 6.2 2,3-dimethyl-2-butene 3.7 C6 internal alkenes 5.3 C7 internal alkenes 4.4 C8 internal alkenes 3.6 C9 internal alkenes 3.2 C10 internal alkenes 2.8 1,3-butadiene 7.7 isoprene 6.5 cyclopentene 4 cyclohexene 3.3 α-pinene 1.9 β-pinene 1.9 benzene 00:28 toluene 1. Ethylbenzal 1.8 n-propylbenzene 1:44 isopropylbenzene 1.5 sec-butylbenzene 1.29 C10-monoalkyl 1.28 meta-xylene 6 ortho-xylene 5.2 para-xylene 5.2 C9 dialkylbenzenes 5.3 C10 dialkylbenzenes 4.8 1,3,5-trimethyl benzene 7.5 1,2,3-trimethyl benzene 7.4 1,2,4-trimethylbenzene 7.4 C10 trialkylbenzenes 6.7 1,2,3,4-tetrahydronaphthalene 0.73 naphthalene 0.87 acetylene 00:37

The implementation of this invention and the results that can be achieved are shown in the following examples 1–4 explained. This Examples are not intended to limit the invention and are not intended to limit the same thought.

example 1

Two four-seater Ford Crown Victoria, built in 1988, with essentially the same kilometer (66578 and 67096 miles: ie 107147 and 107980 km) were tested under the same test conditions by a chassis dynamometer with dynamometer specifications of 1814 kg (4000 lb) inertia and a road load of 11.4 HP (8.5 hydrocarbons) at 50 mph ( 80.5 kmh) make use of, operated. For this comparison test pair, a commercially available lead-free gasoline was procured and divided into two portions. Methylcyclopentadienylmanganese tricarbonyl was mixed into one portion in an amount equivalent to approximately 1/32 g manganese per gallon (3.78 L), and then the octane number, (R + M) / 2, of the finished fuel ("MMT fuel ") certainly. Xylenes were mixed into the other portion in an amount necessary to achieve the octane number of the MMT-containing gasoline. In addition, n-butane was added to the latter gasoline ("Xy fuel) to achieve the Reid vapor pressure of the MMT fuel. Control data of these two test fuels and the base gasoline are summarized in Table 2, in which" - "for" not measured " stands.

TABLE 2 TEST FUEL CONTROL DATA

A vehicle was run on the MMT fuel, the other is powered by the Xy fuel. Before the test, each Vehicle subjected to a federal 3-bag test procedure (US Code of Federal Regulations, Title 40, Part 86, Section A and B, the smaller on motor vehicles. Performance applicable sections), to measure regulated emissions. The vehicles then doubled measured at two speed accumulation points, by using the extended version of the state described above Test procedure was applied to separate samples for (a) regulated Emission, (b) hydrocarbon determination and (c) for aldehydes and withdraw ketones. Therefore, the test schedule did not match only the procedure described in the Code of Federal Regulations, but at the same time presented a method with four cycles for determination of aldehydes and ketones. Exhaust gas emission rates for hydrocarbons total, carbon monoxide, and nitrogen oxides are reported in grams / mile.

The same volume sampling device (CVS constant volume sampler) used for the determination was connected to a stainless steel dilution tunnel that was 18 inches (45.7 cm) in diameter and 16 feet (4.9 m) long (cf. , 1 ), and operated at a flow rate of 320 scfm (9062 l / min). This flow rate provided temperatures in the tunnel's sampling zone during the state testing process that generally did not exceed 110 ° F (34 ° C). A cooling fan with an output of 5000 cfm (142 m ³ / min) was used in front of the vehicle during all cycles. The closure flap was kept fully open during all cycles and was only closed during the intake periods. The exhaust gas sampling was carried out using a system that was used in accordance with the guidelines developed in the following publications and reports:
Urban et al., "Regulated and Unregulated Exhaust Emissions from Malfunctioning Automobiles", Paper 790696, presented at the 1979 SAE Passenger Car Conference, Dearborn, Michigan, June 1979;
Urban et al., "Exhaust Emissions from Malfunctioning Three-way Catalystequipped Automobiles", Paper 800511, presented at the SAE Congress and Exhibition, Detroit, Michigan, February 1980;
Urban, "" Regulated and Unregulated Exhaust emissions from Malfunctioning Non-Catalyst and Oxidation Catalyst Gasoline Automobiles ", EPA Report 460 / 3-80-003, 1980; and
Smith et al., "Characterization of Emissions from Motor Vehicles Designed for Low NO _x Emissions", final report EPA 600 / 2-80-176 created under contract no. 68-02-2497, July 1980.

TABLE SAMPLING AND ANALYSIS PROCEDURE FOR KW DETERMINATION

The analytical procedures performed to determine the hydrocarbons for C _1-3 hydrocarbons and benzene and toluene, as well as the C ₄ - (1,3-butadiene) procedure are described in detail in the following reports from the United States Environmental Protection Agency:
Smith et al., "Analytical Procedures Characterizing Unregulated Pollutant Emissions from Motor Vehicles", Report EPA 600 / 2-79-17, created under contract No. 68-02-2497, February 1979; and
Smith, "Butadiene Measurement Methodology", final report EPA 460 / 3-88-005, prepared under instruction B-1 of contract no. 68-03-4044, August 1988.

The individual analysis methods were as follows:

C ₁ -C ₃ hydrocarbons, benzene and toluene

The diluted exhaust gases were collected in teddy bags and analyzed using gas chromatography (GC) with a flame ionization detector. The compounds examined included Me than, ethane, ethylene, acetylene, propane, propylene, benzene and toluene. The GC apparatus was equipped with four separately packed columns, which were used to analyze the individual compounds. A system of timers, electromagnetic valves and gas sampling valves directed the flow of the sample through the system. The carrier gas is helium. Peak areas are compared to those of an external calibration mixture and the hydrocarbon concentrations obtained using a Hewlett-Packard 3353 computer system. The lowest detection limits for C ₁ -C ₃ compounds, benzene and toluene are 0.05 ppmC.

C ₄ hydrocarbon including 1,3-butadiene

The process used results in a separation and concentration information for seven C ₄ compounds, namely: isobutane, butane, 1-butene, isobutene, cis-2-butene, trans-2-butene and 1,3-butadiene. Samples from standard bags of a constant volume sampling device (CVS) and from bags with emissions from evaporation were examined for C ₄ compounds by means of a GC equipped with an FID. The GC system used was a Perkin-Elmer Model 3920B gas chromatograph with an FID, two pneumatically operated and electrically controlled Seiscor valves and an analytical column. This column measures 9 ft × 1/8 in (2.7 m × 3 mm), is made of stainless steel and contains 80/100 Carbopack C with 0.19% picric acid. The carrier gas is helium, which flows through the column at a rate of 27 ml / min. For analysis, the column temperature is kept at 40 ° C. External standards in clean air (zero air) were used to quantify the results. The detection limits of the method are of the order of 0.03 ppmC.

(C ₅ -C ₁₀ hydrocarbon

This procedure allows quantitative Determination of more than 80 individual hydrocarbon species in Car exhaust. The GC system uses a Perkin-Elmer model 3920B Gas chromatograph with the subambient possibilities, a capillary column and equipped with an FID is. The capillary column used in the system is a Perkin-Elmer F-50 Versilube column with the dimensions 150 ft × 0.02 in (46 m × 0.5 mm) made of WCOT stainless steel. At the beginning, this column becomes a sample injection Chilled to -139 ° F (-95 ° C). With The injection is at a temperature of 185 ° F (85 ° C) with an increase of 7 ° F (4 ° C) per minute programmed. The column temperature will be at 185 ° F in about 15 minutes Kept at (85 ° C), around the flush the pillar to end. To the flow rate of the helium carrier gas A flow control device is used to maintain at 1.5 ml / min. A sample volume of 10 ml allows the detection of 0.1 ppmC using the flame ionization detector.

Using the in Table 1 Given the maximum ozone reactivity data, the maximum responsiveness total hydrocarbons specified for each Car intended for both the accumulation point after 500 (800 km) as well as for those after 1000 miles (1600 km). Table 4 summarizes the data determined in this way the maximum responsiveness together.

TABLE 4 - Maximum reactivity of the specified hydrocarbons

The data given in Table 4 show that with this fuel, methylcyclopentadienylmanganese tricarbonyl reduced total hydrocarbon emissions by 15.5% after 500 test miles (800 km) and by 4% after 1000 test miles ( 1600 km). Of even greater importance is the fact that at the accumulation points, both after 500 miles and after 1000 miles, the maximum total reactivity of the emitted hydrocarbons, as described above, with the MMT-containing fuel is approximately 30% (29% and 31%) was lower than the maximum responsiveness of the total emissions with the same fuel that contained the amount of xylenes required to achieve the octane number of the MMT-containing fuel.

Example 2

The procedure of Example 1 was followed using a commercially available regular unleaded gasoline another domestic oil company repeated. Table 5 summarizes the most important test results of the two mixed Test fuels together - d. H. of the MMT fuel and the Xy fuel.

The results of the comparison test with these fuels are summarized in Table 6.

The data from Table 6 show that that at these fuels the MMT not only the total amount emitted Hydrocarbons compared to the Xy fuel around 5.5 and 15.8% decreased, but more importantly, the maximum responsiveness of the specified hydrocarbons in total for the MMT fuel 19 and Was 29% lower than the maximum responsiveness of the emissions the same basic fuel (manganese-free), but the one to achieve the octane number of the MMT-containing fuel Contained xylenes.

TABLE 5 TEST FUEL CONTROL DATA

TABLE 6 MAXIMUM REACTIVITY OF SPECIFIED CARBON HYDROGEN

example 3

The procedure of Example 1 was followed repeated, this time using a commercially available unleaded regular gasoline from another domestic oil company was used, the 1 wt .-% oxygen in the form of an ether additive contained (presumably methyl t-butyl ether). The main research results of the two test fuels mixed from this base gasoline - d. H. the MMT fuel and the Xy fuel - are summarized in Table 7.

TABLE 7 - TEST FUEL CONTROL DATA

TABLE 8 - Maximum reactivity of the specified hydrocarbons

The data from Table 8 show that with this fuel the maximum responsiveness of the specified Exhaust hydrocarbons in the MMT fuel are approximately 23% lower (25 and 21% lower) than the maximum responsiveness the emissions of the same basic fuel (manganese-free), which Achieve the necessary octane number of the fuel containing MMT Amount of xylenes contained. Although the total amount of hydrocarbons emitted for both Test fuels approximately was the same, the MMT fuel according to the invention therefore gave essentially less reactive hydrocarbon exhaust and consequently pointed a lower potential for the formation of ozone on the ground.

Overall, the emitted with the Vehicles powered by MMT fuels lower amounts of hydrocarbons, Carbon monoxide and nitrogen oxides than those under the same conditions vehicles powered by xy fuels. As detailed above explains was the maximum responsiveness of the total hydrocarbons used by MMT fuels Vehicles were emitted, much less than the total maximum responsiveness of the hydrocarbons used by the Xy fuels Vehicles were emitted. Moreover was observed using the above test carried out according to Examples 1-3, that the with the "MMT fuel vehicles generally lower emissions of aldehydes such as formaldehyde, acetaldehyde and benzaldehyde produced as that vehicles powered by xy fuels. The economic performance of the fuel was for the vehicle powered by MMT fuel decreased slightly (1–2%).

Example 4

Using the procedure of Example 1 was a comparison between the maximum responsiveness total of the specified hydrocarbons with the MMT fuel from example 1 and with the same basic fuel that no "additional xylenes or other aromatics have been added. In short, compare this measurement shows the base fuel from Example 1 with the same base fuel, the MMT at a concentration of approximately 1/32 g manganese per gallon (3.78 l) contains. Table 9 shows the averaged results obtained in these test runs Results.

TABLE 9 - Maximum reactivity of the specified hydrocarbons

From the data given in Table 9 it can be seen that the MMT fuel according to the invention not only produces less hydrocarbon exhaust emissions, but that of what is even more important the maximum responsiveness of the specified hydrocarbons for the one with the MMT fuel vehicle operated much lower (28% lower) than that specified hydrocarbon emissions of the pure basic fuel (free of manganese). As can be seen from Table 2, the The octane number of the MMT fuel is significantly higher than that of the pure one Base fuel, d. H. (R + M) / 2 of 92.9 vs. 92.2.

The fuels according to the invention can or contain several other additives, provided these others Additives or combinations of additives reduce performance not drastic - especially the improved performance in terms of exhaust emissions as they are shown in Examples 1-4 - that of up to 1/32 grams Base fuel containing manganese per gallon (3.78 L) without this other Additive or which has additives. Antioxidants, additives for Control of deposits (e.g. additives to keep the supply system free, Carburetor detergents and ORI-controlling additives), anti-corrosion agents, Metal deactivators and oxidized admixtures such as dihydrocarbyl ether and polyethers are typical examples of those commonly used in gasolines Additives that are used in the fuels according to the invention under the above proviso can be used. In short, the invention allows the introduction of any auxiliary additive or any combination of additives that improve the Fuel or its performance and not that of it Invention enabled Performance benefits negated or severely compromised.

Preferred oxygenated materials, in the fuels of the invention can be mixed in are ethers with a suitably low volatility such as methyl t-butyl ether, Ethyl t-butyl ether, t-amyl methyl ether and 2,2-diethyl-1,3-propanediol. Can continue Mixtures of over the catalytic methoxylation of olefinic components in Gasoline-produced methyl hydrocarbyl ethers can be used efficiently. Methods for producing such mixtures are known and in the Literature described. See, for example, US-A-4,746,761 and WO 89/11463 and the references mentioned therein. Can also be used soluble in petrol Suitable low volatility esters and alcohols such as t-butyl acetate, 1-hexanol, 2-hexanol, 3-hexanol and polyethoxyethanols. Usually such oxygenated compounds are used in an amount which is sufficient up to 3 to 4 wt .-% oxygen in the fuel to disposal to provide, provided that such use with valid or proposed legislation. Other suitable oxygen-containing mixing agents include p-cresol, 2,4-xylene, 3-methoxyphenol, 2-methylfuran, cyclopentanone, isovaleraldehyde, 2,4-pentanedione and the like Compounds containing oxygen.

Preferred antioxidants for the fuels according to the invention are sterically hindered phenolic antioxidants such as 2,6-di-t-butylphenol, 2,4-dimethyl-6-t-butylphenol, 4-methyl-2,6-di-t-butylphenol, 4- Ethyl-2,6-di-t-butylphenol, 4-butyl-2,6-di-t-butylphenol and mixtures of phenols with t-butyl groups with predominantly 2,6-dit-butylphenols. In some cases, aromatic amines can be useful as antioxidants either alone or in conjunction with a phenolic antioxidant. Antioxidants are typically used in amounts of up to 25 pounds per thousand barrels (0.07 kg / m ³ ), the actual amount used depending on the stability of the gasoline (e.g. the olefin content).

Another type of additives preferably used in the fuels according to the invention are ashless detergents such as polyetheramines, polyallcenylamines, alkenylsuccinimides and polyetheramide amines. These materials can range from 50 to 500 pounds per thousand barrels (0.14 to 1.4 kg / m ³ ) and more often in the range of 100 to 200 pounds per thousand barrels (0.28 to 0.55 kg / m ³ ) ³ ) can be used.

The cyclopentadienylmanganese tricarbonyl compounds like the other supporting ones Additives or admixtures can with the base fuel using a conventional mixing device over known Procedures are mixed.

Claims (6)

Use of at least one cyclopentadienylmanganese tricarbonyl compound in an amount corresponding to up to 1/32 gram of manganese per gallon (3.78 l), in a formulated, unleaded petrol, which is a Variety of hydrocarbons with a boiling point in the range that of gasoline and not more than 30 vol .-% aromatics for Decrease in responsiveness of the exhaust gas products that come from the combustion of this gasoline in an Otto combustion engine. Use according to claim 7, where the hydrocarbons have a boiling point in the range of that saturated with gasoline, include olefinic and aromatic hydrocarbons. Use according to claim 8, where the hydrocarbons of gasoline with a boiling point in the range of that of gasoline 40-80 vol .-% saturated and up to 25 vol% aromatic hydrocarbons and less than 1% by volume of benzene. Use according to a of claims 7, 8 or 9, in which the hydrocarbons with the boiling point of Gasoline contain less than 10 vol .-% olefins. Use according to a of claims 7-10, in which the gasoline is mixed with at least one oxygenated gasoline contains. Use according to a of claims 7-11, in which the cyclopentadienylmanganese tricarbonyl compound in Essentially consists of methylcyclopentadienylmanganese tricarbonyl and in the gasoline containing the manganese after a vapor pressure Reid (ASTM test method D-323) of 55.2 kPa (8.0 psi) or less Has.