EP0071134B1 - Ignition improver for combustion engines - Google Patents

Ignition improver for combustion engines Download PDF

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Publication number
EP0071134B1
EP0071134B1 EP82106470A EP82106470A EP0071134B1 EP 0071134 B1 EP0071134 B1 EP 0071134B1 EP 82106470 A EP82106470 A EP 82106470A EP 82106470 A EP82106470 A EP 82106470A EP 0071134 B1 EP0071134 B1 EP 0071134B1
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EP
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Prior art keywords
curve
ignition
fuel
nitric acid
polysaccharides
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EP82106470A
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German (de)
French (fr)
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EP0071134A1 (en
Inventor
Helmut Dr. Waniczek
Herbert Dr. Bartl
Klaus Krüger
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Bayer AG
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Bayer AG
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    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10LFUELS NOT OTHERWISE PROVIDED FOR; NATURAL GAS; SYNTHETIC NATURAL GAS OBTAINED BY PROCESSES NOT COVERED BY SUBCLASSES C10G, C10K; LIQUEFIED PETROLEUM GAS; ADDING MATERIALS TO FUELS OR FIRES TO REDUCE SMOKE OR UNDESIRABLE DEPOSITS OR TO FACILITATE SOOT REMOVAL; FIRELIGHTERS
    • C10L1/00Liquid carbonaceous fuels
    • C10L1/10Liquid carbonaceous fuels containing additives
    • C10L1/14Organic compounds
    • C10L1/22Organic compounds containing nitrogen
    • C10L1/23Organic compounds containing nitrogen containing at least one nitrogen-to-oxygen bond, e.g. nitro-compounds, nitrates, nitrites
    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10LFUELS NOT OTHERWISE PROVIDED FOR; NATURAL GAS; SYNTHETIC NATURAL GAS OBTAINED BY PROCESSES NOT COVERED BY SUBCLASSES C10G, C10K; LIQUEFIED PETROLEUM GAS; ADDING MATERIALS TO FUELS OR FIRES TO REDUCE SMOKE OR UNDESIRABLE DEPOSITS OR TO FACILITATE SOOT REMOVAL; FIRELIGHTERS
    • C10L1/00Liquid carbonaceous fuels
    • C10L1/02Liquid carbonaceous fuels essentially based on components consisting of carbon, hydrogen, and oxygen only
    • CCHEMISTRY; METALLURGY
    • C10PETROLEUM, GAS OR COKE INDUSTRIES; TECHNICAL GASES CONTAINING CARBON MONOXIDE; FUELS; LUBRICANTS; PEAT
    • C10LFUELS NOT OTHERWISE PROVIDED FOR; NATURAL GAS; SYNTHETIC NATURAL GAS OBTAINED BY PROCESSES NOT COVERED BY SUBCLASSES C10G, C10K; LIQUEFIED PETROLEUM GAS; ADDING MATERIALS TO FUELS OR FIRES TO REDUCE SMOKE OR UNDESIRABLE DEPOSITS OR TO FACILITATE SOOT REMOVAL; FIRELIGHTERS
    • C10L1/00Liquid carbonaceous fuels
    • C10L1/02Liquid carbonaceous fuels essentially based on components consisting of carbon, hydrogen, and oxygen only
    • C10L1/026Liquid carbonaceous fuels essentially based on components consisting of carbon, hydrogen, and oxygen only for compression ignition
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02BINTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
    • F02B1/00Engines characterised by fuel-air mixture compression
    • F02B1/02Engines characterised by fuel-air mixture compression with positive ignition
    • F02B1/04Engines characterised by fuel-air mixture compression with positive ignition with fuel-air mixture admission into cylinder
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02BINTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
    • F02B75/00Other engines
    • F02B75/12Other methods of operation
    • F02B2075/125Direct injection in the combustion chamber for spark ignition engines, i.e. not in pre-combustion chamber
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02BINTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
    • F02B3/00Engines characterised by air compression and subsequent fuel addition
    • F02B3/06Engines characterised by air compression and subsequent fuel addition with compression ignition

Definitions

  • the invention relates to ignition improvers in alcoholic fuels for engines which function on the principle of self-igniting internal combustion engines.
  • Methanol and ethanol can be used as fuels for petrol engines instead of the usual petroleum products.
  • this is not possible with conventional diesel engines, since the cetane number of ethanol with about 8 and methanol with about 3 is too low.
  • diesel engines require a fuel with a cetane number of at least 45 (DIN 51601; Winnacker-Küchler, Chemische Technologie, Vol. 3/1, 326 (1971)).
  • Ignition improvers are required to increase the cetane number.
  • Alkyl and cycloalkyl nitrates are known as ignition improvers for fuels made from methanol or ethanol (DE-A-2701 588, DE-A-2 039 609, Mineralöltechnik 80, 25 (4), 1 to 12), but they are expensive to produce and hydrolyze in the presence of water. This creates nitric acid, which destroys the motors through corrosion.
  • Nitric acid salts of primary, secondary and tertiary amines such as mono-, di- and triethylammonium nitrate are also known as ignition improvers for methanol and ethanol (DE-A-2 909 565); they also have corrosive properties.
  • FR-A-719 708 describes the use of nitrated sugars as an additive to alcoholic fuels. From DE-C-1646635 it is known to use alcohol with about 0.5% dinitrocellulose as a propellant for engines. These known blowing agents cannot be used for Dielsel engines.
  • ignition improvers for alcoholic fuels for diesel engines based on nitric acid esters of mono- and / or polysaccharides with a degree of nitration in the range from 1 to 3 has been found, characterized in that they are present in an amount of 2% by weight to 10% by weight .-% are contained in the alcoholic fuel.
  • the ignition improvers according to the invention are outstandingly suitable as additives for alcoholic fuels.
  • the fuels produced in this way are equivalent or superior to commercially available petroleum-based fuels.
  • the alcohol-based fuels are particularly suitable in combination with the ignition improvers for the operation of diesel engines. This is possible because with the help of the ignition improvers, the ignitability of alcoholic fuels can be increased to the level of commercially available diesel fuels (cetane number at least 45).
  • Nitric acid esters of mono- and / or polysaccharides are known per se (K. Fabel, nitrocellulose production and properties, Enke-Verlag, Stuttgart (1950)).
  • Alcoholic solutions of the nitric acid esters of polysaccharides are known from US 1 995 911, US 2 001 070 and US 2046 101.
  • Preferred monosaccharides as starting products for the nitric acid esters according to the invention are pentoses and hexoses. Examples include the following monosaccharides: ribose, glucose, mannose and galactose.
  • Polysaccharides for the nitric acid esters according to the invention are all linear, branched or cyclic polymers from monosaccharide basic building blocks. Polysaccharides for the nitric acid esters according to the invention are also di- or oligosaccharides which give at least two monosaccharide building blocks in the hydrolysis. Examples include the following polysaccharides: sucrose, lactose, maltose, raffinose, cellulose, hemicellulose, and starches such as amylose, amylopectin and dextrin.
  • degradation products of polysaccharides obtained hydrolytically or oxidatively for the nitric acid esters according to the invention are known per se (Houben-Weyl, Volume XIV / 2, pages 866 to 868 (1963)).
  • Preferred saccharides for the nitric acid esters according to the invention are degradation products of the polysaccharides. Such degradation reactions can also on the finished nitric acid esters of the polysaccharides in a conventional manner, for. B. by pressure cooking (Winnacker-kuchler. Chemische Technologie, Vol. 4/11, 737 to 738 (1960)).
  • nitric acid esters of the mono- and polysaccharides can be prepared by known processes (Houben-Weyl, Volume VI / 2, 356 (1963) and Volume XIV / 2, 868-871 and 603 (1969)).
  • the preparation can be carried out, for example, in a homogeneous and / or heterogeneous phase with nitric acid or its anhydride in the presence of dehydrating agents such as sulfuric acid, phosphoric acid, phosphorus pentoxide or acetic anhydride.
  • dehydrating agents such as sulfuric acid, phosphoric acid, phosphorus pentoxide or acetic anhydride.
  • the degree of nitration can be controlled as desired by the amount and concentration of the nitric acid or the dehydrating additives.
  • the degree of nitration affects both the alcohol solubility and the effectiveness of the claimed ignition improvers.
  • the nitric acid esters of the mono- and polysaccharides according to the invention preferably have a degree of nitration of at least one nitro group per monosaccharide unit.
  • the complete esterification of all hydroxyl groups of the corresponding carbohydrates is to be regarded as the upper limit of the degree of nitration; in these cases, however, the solubility of the nitric acid esters in the alcohol is reduced.
  • nitric acid esters of mono- and / or polysaccharides a degree of nitration of 1.5 to 2.7, particularly preferably of 2 to 2.5 as ignition improver.
  • substituents can be bonded to the saccharides in addition to the nitro group, such as. B. methoxyl, ethoxyl, carboxymethyl, hydroxyethyl, longer fatty acid residues, nitrite groups or sulfuric acid ester groups.
  • Alcoholic fuels to which the ignition improvers according to the invention are added are generally alcohols having 1 to 4 carbon atoms. Examples include methanol, ethanol, propanol, butanol and their isomers. Mixtures of these alcohols can of course also be used. Higher alcohols can also be contained in the alcoholic fuels.
  • solubilizers In order to increase the solubility of the ignition improvers according to the invention in the alcoholic fuels, it is possible to add solubilizers.
  • solubilizers As such z. B. low molecular weight ketones and esters such as acetone, methyl ethyl ketone, diethyl ketone, methyl, ethyl and butyl acetate, ethers such as diethyl, diisopropyl and dibutyl ether, tetrahydrofuran, furfurol and dioxane, ethylene glycol mono- and diethyl ether, triethylene glycol mono- and diethyl ether.
  • the claimed fuel mixtures can also contain small amounts of water, generally up to 20%.
  • a water content in the fuel mixtures according to the invention of 0.5 to 6% is particularly preferred.
  • the fuel mixtures according to the invention have proven themselves for the operation of conventional diesel engines and are characterized by high operational reliability, no misfires and excellent running properties, especially in continuous operation.
  • Nitric acid esters of mono- and / or disaccharides can be stabilized like those of the polysaccharides if their stability is not ensured by adequate purification such as recrystallization.
  • the hybrid mixtures according to the invention also have the advantage that they do not destroy the engine through corrosion. They are technically easy to manufacture and can be used without further precautionary measures.
  • the effect of the ignition enhancers and the motor properties of the alcoholic fuel mixtures according to the invention were determined on a test engine.
  • the start of injection is about 164 ° crank angle
  • the injection duration E is about 22 ° crank angle.
  • Base fuel called GK.
  • the single-cylinder diesel engine used under full load operation and correspondingly good ignition conditions still shows sufficient ignition reliability, the start of combustion, characterized by the first significant increase in dx / da, for example at the top dead center of the work cycle, as ignition delay the difference between the start of combustion and the start of injection, specified in degrees crank angle.
  • the following% figures are to be understood as% by weight.
  • the cellulose nitrate described in a) is 4% or 8% dissolved in an azeotropic mixture of 96% ethanol and 4% water. To remove suspended matter, the two solutions are filtered with a pressure filter.
  • test engine described is operated with the fuel solutions according to the invention described in b).
  • test runs are carried out with base fuel GK (cetane number 20) and diesel fuel DK (cetane number 55).
  • Figures 1 and 2 show the motor properties of DK (curve 1), GK (curve 4), the ethanolic solution with 4% (curve 3) and the ethanolic solution with 8% cellulose nitrate according to Example 1a (curve 2).
  • the ignition delay of the 8% ethanolic cellulose nitrate solution is almost the same as for diesel fuel.
  • the 5% cellulose nitrate solution has a considerably lower ignition delay than the base fuel, although pure ethanol only has a cetane number of 8.
  • a cellulose nitrate is produced as in Example 1a).
  • the cellulose nitrate described in a) is used to prepare a 4% by weight and an 8% by weight solution in technical grade methanol and the solution is filtered using a suction filter.
  • the test engine is operated with the methanolic solutions of cellulose nitrate as in Example 1) and the characteristic quantities are compared with diesel fuel DK and basic fuel GK.
  • FIG. 3 describes the pressure curve and FIG. 4 the fuel conversion when using DK (curve 1), GK (curve 4), 4% (curve 3) and 8% (curve 2) methanolic cellulose nitrate solution.
  • Figure 6 shows the fuel conversion of DK (curve 1) and the test solution (curve 2).
  • the ignition delay of the test solution is somewhat larger than with DK, but the pressure curve is very similar.
  • Arabinosetetranitrate is produced by adding 10 g arabinose in 100 cm 3 nitric acid (98%) at 0 ° C. 300 cm 3 of sulfuric acid (98% strength) are added dropwise to this solution with cooling, so that the temperature does not exceed 2 ° C.
  • reaction mixture is then poured onto 2,000 g of ice, a powdery solid substance separating out. This is filtered off, washed with water and dissolved in 50 ml of absolute ethanol at 50 ° C. When this solution cools down to -10 ° C, colorless crystals separate, which are filtered off and dried at 20 ° C in a vacuum.
  • the arabinosetetranitrate is dissolved in 4% by weight or 8% by weight in azeotropic ethanol-water (96: 4) with gentle heating.
  • the test engine is operated for comparison with DK, GK and the two test solutions.
  • Figure 7 describes the cylinder pressure curve when using DK (curve 1), GK (curve 4), the 4% ethanolic solution of arabinosetetranitrate (curve 3) and the 8% ethanolic solution of arabinosetetranitrate (curve 2).
  • FIG. 8 shows the fuel turnover, which increases with the 8% alcoholic solution (curve 2) as steeply as with DK (curve 1). With 4% arabinosetetranitrate in ethanol (curve 3) you get faster fuel conversion than with GK (curve 4).

Abstract

Nitric acid esters of monosaccharides and/or polysaccharides can be used as ignition improvers for alcoholic fuels for internal combustion engines.

Description

Die Erfindung betrifft Zündverbesserer in alkoholischen Treibstoffen für Motoren, die nach dem Prinzip von selbstzündenden Verbrennungskraftmaschinen funktionieren.The invention relates to ignition improvers in alcoholic fuels for engines which function on the principle of self-igniting internal combustion engines.

Methanol und Ethanol können anstelle der üblichen Erdölprodukte als Treibstoffe für Ottomotoren verwendet werden. Dies ist jedoch bei Dieselmotoren üblicher Bauart nicht möglich, da die Cetanzahl von Ethanol mit etwa 8 und von Methanol mit etwa 3 zu niedrig ist. Dieselmotoren benötigen für den störungsfreien Betrieb einen Treibstoff mit einer Cetanzahl von mindestens 45 (DIN 51601 ; Winnacker-Küchler, Chemische Technologie, Bd. 3/1, 326 (1971)).Methanol and ethanol can be used as fuels for petrol engines instead of the usual petroleum products. However, this is not possible with conventional diesel engines, since the cetane number of ethanol with about 8 and methanol with about 3 is too low. For trouble-free operation, diesel engines require a fuel with a cetane number of at least 45 (DIN 51601; Winnacker-Küchler, Chemische Technologie, Vol. 3/1, 326 (1971)).

Zur Anhebung der Cetanzahl sind Zündverbesserer erforderlich. Als Zündverbesserer für Treibstoffe aus Methanol oder Ethanol sind Alkyl-und Cycloalkylnitrate bekannt (DE-A-2701 588, DE-A-2 039 609, Mineralöl Technik 80, 25 (4), 1 bis 12), die jedoch in der Herstellung aufwendig sind und in Anwesenheit von Wasser hydrolisieren. Hierbei entsteht Salpetersäure, die die Motoren durch Korrosion zerstört.Ignition improvers are required to increase the cetane number. Alkyl and cycloalkyl nitrates are known as ignition improvers for fuels made from methanol or ethanol (DE-A-2701 588, DE-A-2 039 609, Mineralöl Technik 80, 25 (4), 1 to 12), but they are expensive to produce and hydrolyze in the presence of water. This creates nitric acid, which destroys the motors through corrosion.

Auch salpetersaure Salze von primären, sekundären und tertiären Aminen wie Mono-, Di-und Triethylammoniumnitrat sind als Zündverbesserer für Methanol und Ethanol bekannt (DE-A-2 909 565) ; sie haben ebenfalls korrosive Eigenschaften.Nitric acid salts of primary, secondary and tertiary amines such as mono-, di- and triethylammonium nitrate are also known as ignition improvers for methanol and ethanol (DE-A-2 909 565); they also have corrosive properties.

In der FR-A-719 708 wird die Verwendung von nitrierten Zuckern als Zusatz zu alkoholischen Treibstoffen beschrieben. Aus der DE-C-1646635 ist bekannt, Alkohol mit etwa 0,5% Dinitrocellulose als Treibmittel für Motoren zu verwenden. Diese bekannten Treibmittel können für Dielselmotoren nicht verwendet werden.FR-A-719 708 describes the use of nitrated sugars as an additive to alcoholic fuels. From DE-C-1646635 it is known to use alcohol with about 0.5% dinitrocellulose as a propellant for engines. These known blowing agents cannot be used for Dielsel engines.

Es wurde die Verwendung von Zündverbesserern für alkoholische Treibstoffe für Dieselmotoren auf Basis von Salpetersäureester von Mono-und/oder Polysacchariden mit einem Nitrierungsgrad im Bereich von 1 bis 3 gefunden, dadurch gekennzeichnet, daß sie in einer Menge von 2 Gew.-% bis 10 Gew.-% im alkoholischen Treibstoff enthalten sind.The use of ignition improvers for alcoholic fuels for diesel engines based on nitric acid esters of mono- and / or polysaccharides with a degree of nitration in the range from 1 to 3 has been found, characterized in that they are present in an amount of 2% by weight to 10% by weight .-% are contained in the alcoholic fuel.

Die erfindungsgemäßen Zündverbesserer eignen sich hervorragend als Additive für alkoholische Treibstoffe. Die so hergestellten Treibstoffe sind den handelsüblichen Treibstoffen auf Mineralölbasis gleichwertig oder überlegen.The ignition improvers according to the invention are outstandingly suitable as additives for alcoholic fuels. The fuels produced in this way are equivalent or superior to commercially available petroleum-based fuels.

Im besonderen eignen sich die Treibstoffe auf alkoholischer Basis in Kombination mit den Zündverbesserern für den Betrieb von Dieselmotoren. Dies ist möglich, da mit Hilfe der Zündverbesserer die Zündwilligkeit von alkoholischen Kraftstoffen auf das Niveau von handelsüblichen Dieselkraftstoffen (Cetanzahl mindestens 45) angehoben werden kann.The alcohol-based fuels are particularly suitable in combination with the ignition improvers for the operation of diesel engines. This is possible because with the help of the ignition improvers, the ignitability of alcoholic fuels can be increased to the level of commercially available diesel fuels (cetane number at least 45).

Salpetersäureester von Mono- und/oder Polysacchariden sind an sich bekannt (K. Fabel, Nitrocellulose-Herstellung. und Eigenschaften, Enke-Verlag, Stuttgart (1950)).Nitric acid esters of mono- and / or polysaccharides are known per se (K. Fabel, nitrocellulose production and properties, Enke-Verlag, Stuttgart (1950)).

Alkoholische Lösungen der Salpetersäureester von Polysacchariden sind aus der US 1 995 911, US 2 001 070 und US 2046 101 bekannt.Alcoholic solutions of the nitric acid esters of polysaccharides are known from US 1 995 911, US 2 001 070 and US 2046 101.

Bevorzugte Monosaccharide als Ausgangsprodukte für die erfindungsgemäßen Salpetersäureester sind Pentosen und Hexosen. Beispielsweise seien die folgenden Monosaccharide genannt : Ribose, Glucose, Mannose und Galactose.Preferred monosaccharides as starting products for the nitric acid esters according to the invention are pentoses and hexoses. Examples include the following monosaccharides: ribose, glucose, mannose and galactose.

Polysaccharide für die erfindungsgemäßen Salpetersäureester sind alle linearen, verzweigten oder cyclischen Polymere aus Monosaccharid-Grundbausteinen. Polysaccharide für die erfindungsgemäßen Salpetersäureester sind auch Di- bzw. Oligosaccharide, die bei der Hydrolyse mindestens zwei Monosaccharid-Bausteine ergeben. Beispielsweise seien die folgenden Polysaccharide genannt : Saccharose, Lactose, Maltose, Raffinose, Cellulose, Hemicellulose, und Stärken wie Amylose, Amylopectin und Dextrin.Polysaccharides for the nitric acid esters according to the invention are all linear, branched or cyclic polymers from monosaccharide basic building blocks. Polysaccharides for the nitric acid esters according to the invention are also di- or oligosaccharides which give at least two monosaccharide building blocks in the hydrolysis. Examples include the following polysaccharides: sucrose, lactose, maltose, raffinose, cellulose, hemicellulose, and starches such as amylose, amylopectin and dextrin.

Selbstverständlich ist es auch möglich, für die erfindungsgemäßen Salpetersäureester hydrolytisch oder oxidativ gewonnene Abbauprodukte von Polysacchariden zu verwenden. Solche Abbauprodukte sind an sich bekannt (Houben-Weyl, Band XIV/2, Seiten 866 bis 868 (1963)). Bevorzugte Saccharide für die erfindungsgemäßen Salpetersäureester sind Abbauprodukte der Polysaccharide. Solche Abbaureaktionen können auch an den fertigen Salpetersäureestern der Polysaccharide in an sich bekannter Weise, z. B. durch Druckkochen (Winnacker-Küchler. Chemische Technologie, Bd. 4/11, 737 bis 738 (1960)) durchgeführt werden.It is of course also possible to use degradation products of polysaccharides obtained hydrolytically or oxidatively for the nitric acid esters according to the invention. Such degradation products are known per se (Houben-Weyl, Volume XIV / 2, pages 866 to 868 (1963)). Preferred saccharides for the nitric acid esters according to the invention are degradation products of the polysaccharides. Such degradation reactions can also on the finished nitric acid esters of the polysaccharides in a conventional manner, for. B. by pressure cooking (Winnacker-Küchler. Chemische Technologie, Vol. 4/11, 737 to 738 (1960)).

Die Salpetersäureester der Mono- und Polysaccharide können nach bekannten Verfahren hergestellt werden (Houben-Weyl, Band VI/2, 356 (1963) und Band XIV/2, 868-871 und 603 (1969)).The nitric acid esters of the mono- and polysaccharides can be prepared by known processes (Houben-Weyl, Volume VI / 2, 356 (1963) and Volume XIV / 2, 868-871 and 603 (1969)).

Die Herstellung kann beispielsweise in homogener und/oder heterogener Phase mit Salpetersäure oder dessen Anhydrid in Anwesenheit von wasser entziehenden Mitteln wie Schwefelsäure, Phosphorsäure, Phosphorpentoxid oder Essigsäureanhydrid erfolgen. Der Nitrierungsgrad kann durch die Menge und Konzentration der Salpetersäure bzw. der wasserentziehenden Zusätze beliebig gesteuert werden.The preparation can be carried out, for example, in a homogeneous and / or heterogeneous phase with nitric acid or its anhydride in the presence of dehydrating agents such as sulfuric acid, phosphoric acid, phosphorus pentoxide or acetic anhydride. The degree of nitration can be controlled as desired by the amount and concentration of the nitric acid or the dehydrating additives.

Der Nitrierungsgrad beeinflußt sowohl die Alkohollöslichkeit als auch die Wirksamkeit der beanspruchten Zündverbesserer. Bevorzugt haben die erfindungsgemäßen Salpetersäureester der Mono- und Polysaccharide ein Nitrierungsgrad von mindestens einer Nitrogruppe pro Monosaccharide Einheit. Als obere Grenze des Nitrierungsgrades ist die vollkommene Veresterung aller Hydroxygruppen der entsprechenden Kohlehydrate anzusehen ; in diesen Fällen ist allerdings die Löslichkeit der Salpetersäureester in dem Alkohol herabgesetzt.The degree of nitration affects both the alcohol solubility and the effectiveness of the claimed ignition improvers. The nitric acid esters of the mono- and polysaccharides according to the invention preferably have a degree of nitration of at least one nitro group per monosaccharide unit. The complete esterification of all hydroxyl groups of the corresponding carbohydrates is to be regarded as the upper limit of the degree of nitration; in these cases, however, the solubility of the nitric acid esters in the alcohol is reduced.

Vorteilhafterweise verwendet man Salpetersäureester von Mono- und/oder Polysacchariden mit einem Nitrierungsgrad von 1,5 bis 2,7, insbesondere bevorzugt von 2 bis 2,5 als Zündverbesserer.It is advantageous to use nitric acid esters of mono- and / or polysaccharides a degree of nitration of 1.5 to 2.7, particularly preferably of 2 to 2.5 as ignition improver.

Zur Verbesserung der Alkohollöslichkeit können neben der Nitrogruppe auch andere Substituenten an die Saccharide gebunden sein, wie z. B. Methoxyl, Ethoxyl, Carboxymethyl, Hydroxyethyl, längere Fettsäurereste, Nitritgruppen oder Schwefelsäureestergruppen.In order to improve alcohol solubility, other substituents can be bonded to the saccharides in addition to the nitro group, such as. B. methoxyl, ethoxyl, carboxymethyl, hydroxyethyl, longer fatty acid residues, nitrite groups or sulfuric acid ester groups.

Alkoholische Treibstoffe, denen die erfindungsgemäßen Zündverbesserer zugesetzt werden, sind im allgemeinen Alkohole mit 1 bis 4 Kohlenstoffatomen. Beispielsweise seien Methanol, Ethanol, Propanol, Butanol und deren Isomere genannt. Selbstverständlich können auch Gemische dieser Alkohole verwendet werden. Es können auch höhere Alkohole in den alkoholischen Treibstoffen enthalten sein.Alcoholic fuels to which the ignition improvers according to the invention are added are generally alcohols having 1 to 4 carbon atoms. Examples include methanol, ethanol, propanol, butanol and their isomers. Mixtures of these alcohols can of course also be used. Higher alcohols can also be contained in the alcoholic fuels.

Um die Löslichkeit der erfindungsgemäßen Zündverbesserer in den alkoholischen Treibstoffen zu erhöhen, ist es möglich Lösungsvermittler zuzusetzen. Als solche seien z. B. niedermolekulare Ketone und Ester wie Aceton, Methylethylketon, Diethylketon, Methyl-, Ethyl-und Butylacetat, Ether wie Diethyl-, Diisopropyl-und Dibutylether, Tetrahydrofuran, Furfurol und Dioxan, Ethylenglykolmono- und -diethylether, Triethylenglykolmono- und -diethylether genannt.In order to increase the solubility of the ignition improvers according to the invention in the alcoholic fuels, it is possible to add solubilizers. As such z. B. low molecular weight ketones and esters such as acetone, methyl ethyl ketone, diethyl ketone, methyl, ethyl and butyl acetate, ethers such as diethyl, diisopropyl and dibutyl ether, tetrahydrofuran, furfurol and dioxane, ethylene glycol mono- and diethyl ether, triethylene glycol mono- and diethyl ether.

Die beanspruchten Treibstoffgemische können auch geringe Mengen Wasser, im allgemeinen bis zu 20 %, enthalten. Besonders bevorzugt ist ein Wassergehalt in den erfindungsgemäßen Treibstoffgemischen von 0,5 bis 6 %.The claimed fuel mixtures can also contain small amounts of water, generally up to 20%. A water content in the fuel mixtures according to the invention of 0.5 to 6% is particularly preferred.

Die erfindungsgemäßen Treibstoffgemische haben sich für den Betrieb von konventionellen Dieselmotoren bewährt und zeichnen sich aus durch hohe Betriebssicherheit, keine Zündaussetzer und hervorragende Laufeigenschaften insbesondere im Dauerbetrieb. Von den erfindungsgemäßen Zündverbesserern werden jene Salpetersäureester von Mono- und/oder Polysacchariden bevorzugt verwendet, welche bei Raumtemperatur ausreichende Stabilität aufweisen. Dies ist vor allem bei Salpetersäureestern von Polysacchariden der Fall, die z. B. durch Druckkochen (Houben-Weyl, Band XIV/2, Seite 870 (1963)) oder durch Zusatz von geeigneten Stabilisatoren stabilisiert wurden. Derartige Stabilisatoren sind bekannt. So wird in US-A-2404887 Nitrocellulose durch Verrühren mit verdünnter, wäßriger Ammoniak-Lösung stabilisiert. Eine Reihe anderer Stabilisatoren wie Ethylacetat, Amylacetat, Aceton, Anilin, Diphenylamin oder Diethyldiphenylharnstoff sind von H. Brunswig in « Die Explosivstoffe VIII", « Das rauchlose Pulver auf den Seiten 368 bis 378 (1926) beschrieben.The fuel mixtures according to the invention have proven themselves for the operation of conventional diesel engines and are characterized by high operational reliability, no misfires and excellent running properties, especially in continuous operation. Of the ignition improvers according to the invention, preference is given to using those nitric acid esters of mono- and / or polysaccharides which have sufficient stability at room temperature. This is especially the case with nitric acid esters of polysaccharides, e.g. B. were stabilized by pressure cooking (Houben-Weyl, Volume XIV / 2, page 870 (1963)) or by adding suitable stabilizers. Stabilizers of this type are known. In US-A-2404887 nitrocellulose is stabilized by stirring with dilute, aqueous ammonia solution. A number of other stabilizers such as ethyl acetate, amylacetate, acetone, aniline, diphenylamine or diethyldiphenylurea are described by H. Brunswig in "The Explosives VIII", "The Smokeless Powder" on pages 368 to 378 (1926).

Salpetersäureester von Mono- und/oder Disacchariden können wie jene der Polysaccharide stabilisiert werden, wenn nicht ihre Stabilität durch ausreichende Reinigung wie Umkristallisieren gewährleistet ist.Nitric acid esters of mono- and / or disaccharides can be stabilized like those of the polysaccharides if their stability is not ensured by adequate purification such as recrystallization.

Die erfindungsgemäßen Treifstoffgemische haben weiterhin den Vorteil, daß sie den Motor nicht durch Korrosion zerstören. Sie lassen sich technisch leicht herstellen und können ohne weitere Vorsichtsmaßnahmen eingesetzt werden.The hybrid mixtures according to the invention also have the advantage that they do not destroy the engine through corrosion. They are technically easy to manufacture and can be used without further precautionary measures.

BeispieleExamples

Die Wirkung der Zündwilligkeitverbesserer und die motorischen Eigenschaften der erfindungsgemäßen alkoholischen Treibstoffgemische wurden an einem Testmotor ermittelt. Verwendet wurde ein luftqekühlter 1-Zylinder 4-Takt-Dieselmotor mit einem Hubraum von Vh = 1,6 dm3 und einem Verdichtungsverhältnis von E = 18,2 bei einem Betriebsdruck von 7 bar effektivem Mitteldruck und einer mittleren Motordrehzahl von n = 1 600 min-1.The effect of the ignition enhancers and the motor properties of the alcoholic fuel mixtures according to the invention were determined on a test engine. An air-cooled 1-cylinder 4-stroke diesel engine with a displacement of V h = 1.6 dm 3 and a compression ratio of E = 18.2 was used at an operating pressure of 7 bar effective mean pressure and an average engine speed of n = 1,600 min- 1 .

Bei diesem Betriebsdruck und einer dem Serienbetrieb entsprechenden Motoreinstellung sowie entsprechenden Bauteil- und Öltemperaturen liegen Selbstzündungsbedingungen vor, wie sie bei serienmäßigen Direkteinspritzmotoren im Vollastbetrieb üblich und damit repräsentativ sind. Figur 1, 3, 5 und 7 zeigen beispielhaft den Zylinderdruck p [bar] in Abhängigkeit von der jeweiligen Stellung des Hubkolbens, angegeben in a = Grad Kurbelwinkel (im folgenden auch kurz °KW genannt). Ein Kurbelwinkel von 180° entspricht dem oberen Totpunkt des Hubkolbens.At this operating pressure and with an engine setting corresponding to series operation, as well as corresponding component and oil temperatures, there are auto-ignition conditions as are common with standard direct injection engines in full-load operation and are therefore representative. FIGS. 1, 3, 5 and 7 show, by way of example, the cylinder pressure p [bar] as a function of the respective position of the reciprocating piston, indicated in a = degree crank angle (also referred to below as ° KW). A crank angle of 180 ° corresponds to the top dead center of the reciprocating piston.

Figur 2, 4, 6 und 8 zeigen beispielhaft den normierten Brennstoffumsatz (dx)/(da) [rad-'] in Abhängigkeit von a = Grad Kurbelwinkel [°KW].Figures 2, 4, 6 and 8 show an example of the standardized fuel conversion (dx) / (da) [rad- '] as a function of a = degree crank angle [° KW].

Der Einspritzbeginn liegt bei ca. 164° Kurbelwinkel, die Einspritzdauer E beträgt ca. 22° Kurbelwinkel.The start of injection is about 164 ° crank angle, the injection duration E is about 22 ° crank angle.

Als Vergleichsbasis zur Beurteilung der Zündwilligkeit der erfindungsgemäßen Treibstoffgemische diente der Zylinderdruckverlauf, der Zündverzug und der Brennverlauf bei Verwendung eines handelsüblichen Dieselkraftstoffes DK nach DIN 51 601 und bei Verwendung eines Gemisches aus 20 % Cetan (Hexadecan) und 80 % a-Methylnaphthalin, im folgenden als Grundkraftstoff GK bezeichnet.The cylinder pressure curve, the ignition delay and the combustion curve when using a commercially available diesel fuel DK according to DIN 51 601 and when using a mixture of 20% cetane (hexadecane) and 80% a-methylnaphthalene, hereinafter served as a basis for comparison for assessing the ignitability of the fuel mixtures according to the invention Base fuel called GK.

Bei Verwendung von GK mit einer Cetanzahl von 20 zeigt der verwendete Einzylinder-Dieselmotor bei Vollastbetrieb und entsprechend guten Zündbedingungen eine noch ausreichende Zündsicherheit, der Brennbeginn, gekennzeichnet durch den ersten deutlichen Anstieg von dx/da, etwa bei dem oberen Totpunkt des Arbeitstaktes Als Zündverzug wird die Differenz von Brennbeginn und Einspritzbeginn bezeichnet, angegeben in Grad Kurbelwinkel. Die folgenden %-Angaben sind als Gew.-% zu verstehen.When using GK with a cetane number of 20, the single-cylinder diesel engine used under full load operation and correspondingly good ignition conditions still shows sufficient ignition reliability, the start of combustion, characterized by the first significant increase in dx / da, for example at the top dead center of the work cycle, as ignition delay the difference between the start of combustion and the start of injection, specified in degrees crank angle. The following% figures are to be understood as% by weight.

Beispiel 1example 1 a) Herstellung des Zündverbesserersa) Manufacture of the ignition improver

Gebleichte Baumwollinters werden in an sich bekannter Weise bei 20 °C unter Rühren mit der 50-fachen Menge einer Nitriersäure, bestehend aus

  • 79,6 % Schwefelsäure
  • 11,4% Salpetersäure
  • 9,0 % Wasser

behandelt. Nach 2 Stunden Nitrierzeit trennt man das entstandene Cellulosenitrat von der Säure ab, wäscht mit destilliertem Wasser neutral und kocht das Produkt 3 Stunden in der 20-fachen Menge 3 %iger wässriger NaHCOa-Lösung zur Stabilisierung. Das Cellulosenitrat trennt man wieder von der Flüssigkeit ab, wäscht mit Wasser neutral, und trocknet das faserige Produkt bei 30 °C im Vakuum.Bleached cotton sinters are made in a manner known per se at 20 ° C. while stirring with 50 times the amount of a nitrating acid
  • 79.6% sulfuric acid
  • 11.4% nitric acid
  • 9.0% water

treated. After 2 hours of nitriding, separate the resulting cellulose nitrate is washed off from the acid, washed neutral with distilled water and boiled for 3 hours in 20 times the amount of 3% aqueous NaHCO a solution for stabilization. The cellulose nitrate is separated from the liquid again, washed neutral with water, and the fibrous product is dried at 30 ° C. in vacuo.

Die Elementaranalyse dieses Cellulosenitrats ergibt

Figure imgb0001
The elemental analysis of this cellulose nitrate shows
Figure imgb0001

b) Formulierung des Treibstoffgemischesb) formulation of the fuel mixture

Das in a) beschriebene Cellulosenitrat wird zu 4 % bzw. 8 % in einem azeotropen Gemisch von 96 % Ethanol und 4 % Wasser gelöst. Um Schwebestoffe zu entfernen werden die beiden Lösungen mit einer Druckfilternutsche filtriert.The cellulose nitrate described in a) is 4% or 8% dissolved in an azeotropic mixture of 96% ethanol and 4% water. To remove suspended matter, the two solutions are filtered with a pressure filter.

c) Motorischer Testc) Motor test

Mit dem in b) beschriebenen erfindungsgemäßen Treibstofflösungen wird der beschriebene Testmotor betrieben. Zum Vergleich werden Testläufe mit Grundkraftstoff GK (Cetanzahl 20) und Dieseltreibstoff DK (Cetanzahl 55) durchgeführt.The test engine described is operated with the fuel solutions according to the invention described in b). For comparison, test runs are carried out with base fuel GK (cetane number 20) and diesel fuel DK (cetane number 55).

Figuren 1 und 2 zeigen die motorischen Eigenschaften von DK (Kurve 1), GK (Kurve 4), der ethanolischen Lösung mit 4 % (Kurve 3) und der ethanolischen Lösung mit 8% Cellulosenitrat nach Beispiel 1a (Kurve 2).Figures 1 and 2 show the motor properties of DK (curve 1), GK (curve 4), the ethanolic solution with 4% (curve 3) and the ethanolic solution with 8% cellulose nitrate according to Example 1a (curve 2).

Druckverlauf (Figur 1)Pressure curve (Figure 1)

Bei Verwendung von DK steigt der Druck nach dem Einspritzbeginn steil an und beginnt bei etwa 1900KW wieder abzufallen. Nahezu identisch ist der Druckverlauf bei Betrieb des Motors mit Ethanol und 8 % des Cellulosenitrat. Bei Betrieb mit Grundkraftstoff findet der Druckanstieg erst wesentlichspäter statt, während 4 % des Cellulosenitrats nach 1a in Ethanol bereits eine wesentliche Verbesserung bringen.When using DK, the pressure rises steeply after the start of injection and begins to drop again at around 1900 kW. The pressure curve is almost identical when the engine is operated with ethanol and 8% of the cellulose nitrate. When operating with base fuel, the pressure rise takes place much later, while 4% of the cellulose nitrate after 1a in ethanol already brings about a significant improvement.

Brennstoffumsatz (Figur 2)Fuel turnover (Figure 2)

Der Zündverzug der 8 %igen ethanolischen Cellulosenitratlösung ist nahezu gleich gering wie bei Dieseltreibstoff. Die 5%ige Cellulosenitratlösung weist einen erheblich geringeren Zündverzug als der Grundkraftstoff auf, obwohl reines Ethanol nur eine Cetanzahl von 8 besitzt.The ignition delay of the 8% ethanolic cellulose nitrate solution is almost the same as for diesel fuel. The 5% cellulose nitrate solution has a considerably lower ignition delay than the base fuel, although pure ethanol only has a cetane number of 8.

Der Brennverlauf von Ethanol ist durch einen 8 %igen Zusatz von Cellulosenitrat mit dem von DK nahezu identisch und ein 4 %iger Zusatz von Cellulosenitrat ergibt bereits eine erhebliche Verbesserung gegenüber dem Grundkraftstoff.The burning process of ethanol is almost identical to that of DK due to an 8% addition of cellulose nitrate and a 4% addition of cellulose nitrate already results in a significant improvement over the base fuel.

Beispiel 2Example 2 a) Herstellung des Zündverbesserersa) Manufacture of the ignition improver

Es wird ein Cellulosenitrat wie in Beispiel 1a) hergestellt.A cellulose nitrate is produced as in Example 1a).

b) Formulierung des Treibstoffgemischesb) formulation of the fuel mixture

Mit dem in a) beschriebenen Cellulosenitrat wird eine 4 Gew. %ige und eine 8 Gew. %ige Lösung in technischem Methanol hergestellt und die Lösung mit einer Druckfilternutsche filtriert.The cellulose nitrate described in a) is used to prepare a 4% by weight and an 8% by weight solution in technical grade methanol and the solution is filtered using a suction filter.

c) Motorischer Testc) Motor test

Mit den methanolischen Lösungen des Cellulosenitrats wird wie bei Beispiel 1) der Testmotor betrieben und die charakteristischen Größen mit Dieselkraftstoff DK und Grundkraftstoff GK verglichen. Figur 3 beschreibt den Druckverlauf und Figur 4 den Kraftstoffumsatz bei Verwendung von DK (Kurve 1), GK (Kurve 4), 4 %ige (Kurve 3) und 8 %ige (Kurve 2) methanolische Cellulosenitratlösung.The test engine is operated with the methanolic solutions of cellulose nitrate as in Example 1) and the characteristic quantities are compared with diesel fuel DK and basic fuel GK. FIG. 3 describes the pressure curve and FIG. 4 the fuel conversion when using DK (curve 1), GK (curve 4), 4% (curve 3) and 8% (curve 2) methanolic cellulose nitrate solution.

Obwohl die Zündwilligkeit von Methanol (Cetanzahl = 3) noch schlechter ist als die von Ethanol (Cetanzahl = 8) erreicht man mit der 8 %igen Lösung den gleichen Zündverzug wie mit Dieselkraftstoff. 4 Gew.% Cellulosenitrat in Methanol ergeben bereits eine beachtliche Verbesserung der Zündwilligkeit, wie man aus dem geringen Zündverzug von nur 11 °KW ersieht.Although the ignitability of methanol (cetane number = 3) is even worse than that of ethanol (cetane number = 8), the 8% solution achieves the same ignition delay as with diesel fuel. 4% by weight of cellulose nitrate in methanol already results in a considerable improvement in ignitability, as can be seen from the low ignition delay of only 11 ° KW.

Beispiel 3Example 3 a) Herstellung des Zündverbesserersa) Manufacture of the ignition improver

  • 200 g einer handelsüblichen Nitrocellulose mit einem K-Wert nach Fikent'scher (Cellulosechemie 13. [1932] 58) von K = 730 und einem Stickstoffgehalt von 11,2% werden in200 g of a commercially available nitrocellulose with a K value according to Fikent'scher (Cellulosechemie 13. [1932] 58) of K = 730 and a nitrogen content of 11.2% are in
  • 2 I Wasser verteilt und nach Zugabe von 5 ml Pyridin unter Rühren auf 90 °C erwärmt. Nach 15 Stunden bei 90 °C saugt man die nun gelbliche Collodiumwolle ab und kocht 1 Stunde inDistributed 2 l of water and, after adding 5 ml of pyridine, heated to 90 ° C. with stirring. After 15 hours at 90 ° C, the yellowish collodion wool is sucked off and boiled for 1 hour
  • 2 I 2 %iger wässriger Formaldehydlösung.2 I 2% aqueous formaldehyde solution.

Es wird danach wieder abgesaugt, mit Wasser neutralgewaschen und das feine, faserige Produkt bei Raumtemperatur auf 10% Restfeuchte getrocknet.It is then suctioned off again, washed neutral with water and the fine, fibrous product is dried at room temperature to 10% residual moisture.

b) Formulierung des Treibstoffgemischesb) formulation of the fuel mixture

4,4 Teile der feuchten Nitrocellulose werden in 92,2 Teilen Ethanol und 3,4 Teilen Wasser gelöst. Man erhält eine 4 %ige Lösung des Zündverbesserers im Ethanol-Wasser-Azeotrop.4.4 parts of the wet nitrocellulose are dissolved in 92.2 parts of ethanol and 3.4 parts of water. A 4% solution of the ignition improver is obtained in the ethanol-water azeotrope.

c) Motorischer Testc) Motor test

Mit der ethanolischen Lösung dieses Zündverbesserers wird der Testmotor betrieben und das Brennverhalten im Vergleich zu DK ermittelt. Figur 5 zeigt den Druckverlauf von DK (Kurve 1) und der Testlösung (Kurve 2).The test engine is operated with the ethanolic solution of this ignition improver and the combustion behavior compared to DK is determined. Figure 5 shows the pressure curve of DK (curve 1) and the test solution (curve 2).

Figur 6 gibt den Brennstoffumsatz von DK (Kurve 1) und der Testlösung (Kurve 2) an. Der Zündverzug der Testlösung ist zwar etwa größer als bei DK, der Druckverlauf ist jedoch sehr ähnlich.Figure 6 shows the fuel conversion of DK (curve 1) and the test solution (curve 2). The ignition delay of the test solution is somewhat larger than with DK, but the pressure curve is very similar.

Beispiel 4Example 4 a) Herstellung des Zündverbesserersa) Manufacture of the ignition improver

Arabinosetetranitrat wird hergestellt, indem 10 g Arabinose in 100 cm3 Salpetersäure (98 %ig) bei 0 °C eingetragen wird. In diese Lösung tropft man 300 cm3 Schwefelsäure (98 %ig) unter Kühlung ein, so daß die Temperatur 2°C nicht überschreitet.Arabinosetetranitrate is produced by adding 10 g arabinose in 100 cm 3 nitric acid (98%) at 0 ° C. 300 cm 3 of sulfuric acid (98% strength) are added dropwise to this solution with cooling, so that the temperature does not exceed 2 ° C.

Das Reaktionsgemisch wird nun auf 2 000 g Eis gegossen, wobei sich eine pulvrige Festsubstanz abscheidet. Diese wird abfiltriert, mit Wasser gewaschen und in 50 ml absolutem Ethanol bei 50 °C gelöst. Beim Abkühlen dieser Lösung auf - 10°C scheiden sich farblose Kristalle ab, die man absaugt und bei 20 °C im Vakuum trocknet.The reaction mixture is then poured onto 2,000 g of ice, a powdery solid substance separating out. This is filtered off, washed with water and dissolved in 50 ml of absolute ethanol at 50 ° C. When this solution cools down to -10 ° C, colorless crystals separate, which are filtered off and dried at 20 ° C in a vacuum.

b) Formulierung des Treibstoffgemischesb) formulation of the fuel mixture

Das Arabinosetetranitrat wird zu 4 Gew.% bzw. 8 Gew.% im Azeotrop Ethanol-Wasser (96 : 4) unter leichtem Erwärmen gelöst.The arabinosetetranitrate is dissolved in 4% by weight or 8% by weight in azeotropic ethanol-water (96: 4) with gentle heating.

c) Motorischer Testc) Motor test

Der Testmotor wird zum Vergleich mit DK, GK und den beiden Testlösungen betrieben.The test engine is operated for comparison with DK, GK and the two test solutions.

Figur 7 beschreibt den Zylinderdruckverlauf bei Verwendung von DK (Kurve 1), GK (Kurve 4), der 4%igen ethanolischen Lösung von Arabinosetetranitrat (Kurve 3) und der 8%igen ethanolischen Lösung von Arabinosetetranitrat (Kurve 2). Bei 4 % Zusatz von Arabinosetetranitrat zum Ethanol erhält man bereits ein zündfähiges Treibstoffgemisch, während die 8 %ige Lösung fast den gleichen Druckverlauf wie Dieselkraftstoff ergibt.Figure 7 describes the cylinder pressure curve when using DK (curve 1), GK (curve 4), the 4% ethanolic solution of arabinosetetranitrate (curve 3) and the 8% ethanolic solution of arabinosetetranitrate (curve 2). With a 4% addition of arabinosetetranitrate to the ethanol, an ignitable fuel mixture is already obtained, while the 8% solution gives almost the same pressure curve as diesel fuel.

Figur 8 zeigt den Kraftstoffumsatz, der bei der 8 %igen alkoholischen Lösung (Kurve 2) ähnlich steil ansteigt wie bei DK (Kurve 1). Bei 4 % Arabinosetetranitrat in Ethanol (Kurve 3) erhält man bereits rascheren Brennstoffumsatz als bei GK (Kurve 4).FIG. 8 shows the fuel turnover, which increases with the 8% alcoholic solution (curve 2) as steeply as with DK (curve 1). With 4% arabinosetetranitrate in ethanol (curve 3) you get faster fuel conversion than with GK (curve 4).

Der Zündverzug ist bei (Kurve 3) fast genauso gering als bei DK (Kurve 1).The ignition delay is almost as small with (curve 3) as with DK (curve 1).

Claims (1)

  1. Use of ignition improvers for alcoholic fuels for diesel engines, based on nitric acid ester of mono- and/or polysaccharides having a degree of nitration in the range of 1 to 3, characterised in that they are contained in the alcoholic fuel in a quantity of 2 % by weight to 10 % by weight.
EP82106470A 1981-07-24 1982-07-19 Ignition improver for combustion engines Expired EP0071134B1 (en)

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DE3412078A1 (en) * 1984-03-31 1985-10-03 Bayer Ag, 5090 Leverkusen IGNITION ENVIRONMENT FOR FUEL MIXTURES
JPH0253872A (en) * 1988-08-18 1990-02-22 Sumitomo Bakelite Co Ltd Epoxy resin powder coating composition
US6280487B1 (en) * 1991-12-24 2001-08-28 Jgs Research Company, Inc. Process for preparing ignition promoter, and fuel containing an ignition promoter
JPH07303428A (en) * 1994-05-12 1995-11-21 Shinei Kinzoku Seisakusho:Kk Method of driving prop poles for fishery
CA2377464A1 (en) * 2001-05-03 2002-11-03 Michio Ikura Low temperature stable diesel oil/alcohol mixtures
BRPI0803522A2 (en) * 2008-09-17 2010-06-15 Petroleo Brasileiro Sa diesel cycle fuel compositions containing dianhydrohexitols and derivatives

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FR719708A (en) * 1930-07-08 1932-02-09 Expl Des Brevets D Inv S Soc P Process for making alcohols, and in particular methyl and ethyl alcohols, usable as fuel, and product obtained by this process
FR719709A (en) * 1931-07-07 1932-02-09 Emsa Werke Aktien Ges Rubber brush
US2046101A (en) * 1932-03-18 1936-06-30 Sternau & Co Inc S Solidified composition
US2001070A (en) * 1932-04-29 1935-05-14 Hercules Powder Co Ltd Nitrocellulose gel and method of producing
US1995911A (en) * 1933-02-07 1935-03-26 Us Ind Alcohol Co Method of making artificial fuel
FR2343893A1 (en) * 1976-03-08 1977-10-07 Oswald Roger FUEL ENGINE OTHER THAN A PETROLEUM PRODUCT

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