FR2849052A1 - Preparation of fuel formulations for compression ignition engines to conform to the homogeneous charge compression ignition (HCCI) mode for use over wide speed or load conditions - Google Patents

Abstract

Formulations are characterized using a base fuel 'Jet B', as defined in the standard ASTM D-1655, and incorporating at least one constituent or combination of constituents selected from paraffins, nitro compounds, peroxides, carbonates, acetals, ethers, alcohols, glycol ethers and glycol esters, to produce a distillation curve of behavior representative of a fuel adapted to functioning demands operating in HCCI mode. Independent claims are also included for the formulation of the fuel and its use.

Description

The invention relates to fuel formulations whose composition is

  optimized for operation according to the HCCI combustion mode It also relates to a method for developing these formulations.

  It is known that rather homogeneous phase ignition ("HCCI") of the English "Homogeneous Charge Compression Ignition" can be obtained on both diesel and gasoline engine applications. In two cases, the preparation of the rather homogeneous air-fuel mixture required for the HCCI can be done either by premixing in the intake or by direct injection of the fuel (or an air-fuel mixture) into the combustion chamber. from the HCCI combustion to the diesel engine now relies on the standard EN 590 engine / diesel torque. The relevance of the HCCI technology lies in the possibility of operating in the homogeneous phase over the widest possible range of applications. The only fuel available today in the context of a diesel engine application is this diesel EN 590.

  The mode of combustion by auto-ignition under rather homogeneous fuel-air mixing conditions requires certain "fuel" qualities which are not offered by conventional diesel for a better use. For example, the distillation curve of the diesel fuel EN 590, which does not This does not allow optimal operation in homogeneous mode. Similarly, the self-ignition delay of standard gas oils may not be suitable for use at low load, whereas it will be satisfactory during heavy loads. It is obvious that the available EN 590 diesel does not allow an optimal range of use of the HCCI combustion mode.

  The present invention aims to allow use in HCCI combustion mode under the best possible conditions and over a wider range of possible speed / load, by proposing a new fuel suitable for this use.

  To enable the widest possible operation in HCCI mode, it is necessary: to control the vaporization of the fuel; to control well the setting of the initiation of the combustion; and to control the course of the combustion; for the widest and widest variety of operating conditions.

  The fuel that is proposed to meet these requirements is formulated to meet different criteria relevant to the HCCI combustion mode. These are: to have a higher volatility than a standard diesel to ensure the existence a homogeneous mixture as soon as possible; and to have a controllable self-ignition delay through the carefully chosen base product and through a wide incorporation of different compounds. The formulations developed according to the invention may be defined in that they comprise a major proportion of a "jet B" jet fuel and a combination of constituents whose nature and proportions are judiciously chosen, so as to ensure mixes a distillation curve whose appearance is representative of that of a petroleum product, in particular a diesel fuel.

  The "Jet B" base of these formulations is defined in ASTM standard D1655 or 10 in NATO standard F 45. With a broad cut (from about 70 up to 200 or 250 C), it allows facilitated vaporization.

  To achieve the fuel formulations of the invention, a selection of products selected from a wide variety of compounds such as: paraffins, for example 2-methylhexane, nheptane, 2-methyloctane, 2-methylnonane, n-octane, 3,6-dimethyloctane, 3-methylnonane, 2,9-dimethyl-5,6-diisoamyldecane, nonane, decane, undecane, 3-ethyldecane, 5-butylnonane, 7,8-dimethyltetradecane, 2,6,10-trimethyldodecane, 2,3,10-trimethylundecane, 6-propyldodecane, linear paraffins C n H 2 n + 2 with N> 14; nitro compounds, for example nitromethane, nitroethane, nitropropane, nitrobenzene, nitrotoluene; oxygenated compounds such as: peroxides, for example tert-butyl peroxide; carbonates, for example diethylcarbonate; Acetals, for example polyethoxyethylal; ethers, for example dimethoxymethane, diethoxypropane, diethoxybutane, di-npentylether, di-n-pentoxymethane; alcohols, for example octanol, nonanol, dodecanol; glycol ethers, for example dimethylglycol, dimethyldiglycol, ethyldiglycol, ethyltriglycol; and glycol esters, for example butylglycol acetate.

  The incorporation rate of these products is generally between 0 and 50% by volume They may be incorporated alone or in mixtures.

  In order to be able to formulate a fuel capable of meeting this wide range of requirements, it is proposed to start from a petroleum cut consisting of a "Jet B".

We will call this cup "B".

  In addition, in order to provide the elements of response to the three requirements mentioned above, the fuels are formulated by decomposing the space into a matrix organized around the cetane number of chemical compounds and the distillation interval of these compounds.

  This matrix, which will be called the self-ignition delay matrix (or "MDAI"), is as follows:

MDAI

  Cetane range 40-45 45-50 50-55> 55 Range of () (II) (III) (IV) distillation (C) 50-100 2 3 4 100-150 5 7 8 150-200 9 10 1 12 Compounds I, II, III and IV are products selected from different chemical families defined above.

  Thus, considering their boiling point and their cetane number (indicated in parentheses after each compound), we consider: as component 1, for example 2-methylhexane (87 C, 40); as component 2, for example dimethylglycol (85 C, 53) and n-heptane (98 C, 56); as constituent 3, for example dimethoxymethane (42 C, 52); as constituent 4, for example nitromethane (100 C,> 100); as component 5, for example diethyl carbonate (127 C, 40) or 2-methylheptane (135 C, 41); as constituent 6, for example 2-methyloctane (148 C, 49); as component 7, for example 2-methylnonane (150 C, 54); as constituent 8, for example diethoxypropane (124 C, 136), diethoxybutane (145 C, 143), nitroethane (115 OC,> 100), nitropropane (120 OC, "100) or n-octane (126 OC 63), as component 9, for example octanol (196 OC, 43), butyl glycol acetate (156 OC, 41) or 3,6-dimethyloctane (166 OC, 41); 3-methylnonane (185 OC, 47) as component 11, for example 2,9-dimethyl-5,6-diisoamyldecane (154 OC, 52), as component 12, for example di-n-pentyl ether ( 187 OC, 109), dimethyldiglycol (162 OC,> 70), nonane (151 OC, 68), decane (174 OC, 76) or undecane (196 OC, 77); ethyldiglycol (202 OC, 41) as component 14, for example 3-ethyldecane (202 OC, 48), as component 15, for example, 5-butylnonane (213 OC, 53), for example nonanol (215 OC, 60), di-n-pentoxymethane (218 OC, 97), nitrobenzene e (210 OC,> 100) or nitrotoluene (230 OC, "100); as component 17, for example, 7,8-dimethyltetradecane (269 OC, 40) or 2,6,10 trimethyldodecane (352 OC, 41); as constituent 18, for example 2,3,10-trimethylundecane (250 OC, 47); as constituent 19, for example 6-propyldodecane (250 OC, 52); and as component 20, for example, dodecanol (260 OC, 68), ethyltriglycol (255 OC,> 70), linear paraffins C n H 2 n + 2, N '> 14) or polyethoxyethylal (> 200 OC, 140 ).

  To formulate a fuel according to the invention, a mixture consisting of a "Jet B" and one or more elements taken at different concentrations in the matrix "MDAI" above is carried out.

  Thus, a formulation of the invention may be represented by the formula: B 100 (a + b + c + d) I Ib II Ic I Vd which represents a mixture consisting of a% of the compound of column I, b% of the compound of column II, c% of the compound of column III and d% of the compound of column IV of the MDAI matrix above.

  For example, a formulation is in the form of a mixture of the formula: BO l (a + b + c + d) 6b 11c 16d which represents a mixture consisting of a% of the compound of family 1, b% of the compound of the family 6, of c% of the compound of the family 11 and d% of the compound of the family 16 said being chosen In a more particular way, the constituents of the mixture are chosen, in appropriate proportions, substantially along the diagonal from the top left to the bottom right of said matrix "MDAI" Preferably, the formulations are made with a representative of each line in suitable proportions to ensure a distillation curve representative of a petroleum product (curve monotone).

  Furthermore, a procedure for characterizing engine operation in homogeneous combustion mode has been developed. The coupling of this procedure to the self-ignition delay table ("MDAI" matrix) presented above makes it possible to propose suitable fuel formulations. Coupling is shown on the diagram below. 10

  Cetane range 40 45 45 50 50 55> 55 Distillation range (C) (I 1) (IL) (III) (IV) 100 1 2 3 4

SILI Sh Ll 150 n 0 q

D

  200 9 10 il 12 SI Lh 200 250 13 14 15 16 Sh Lh> 250 17 18 19 20 r Engine speed The designation "Sx Lx" relates to the operating point of the engine, the letters S and L respectively denoting the engine speed (Speed ) and the load (Load) Each of these 20 letters is followed by a letter (h or 1) indicating the high or low level of this parameter (high or low) Thus, for a fuel dedicated to low / low speed operation load and high speed / high load, a formulation of type B 110 110 1525 2025 will be adapted.

  Other examples of formulations of great interest as engine fuels operating in the HCCI mode include many others: B 60 15 610 1010 1510 205 and B 70 110 1510 2010.

  Moreover, the promoter role of the mixtures considered in the invention for the homogeneous combustion HCCI can be exalted by coupling with the exhaust gas recirculation circuit (EGR).

Claims (12)

  1 Method of producing a fuel formulation for an internal combustion engine characterized in that a composition is determined, characterized in that a fuel base is selected from Jet B, as defined in the ASTM standard. D5 1655, and optionally incorporated at least one component or a combination of constituents selected from paraffins nitro compounds; peroxides; Carbonates; acetals, ethers, alcohols; glycol ethers; and the glycol esters, so as to provide the mixture with a distillation curve whose appearance is representative of that of a fuel adapted to the requirements of the operation of the engines in HCCI combustion mode or combustion by self-ignition phase rather homogeneous.   2 Method according to claim 1 characterized in that one chooses the constituents to be added to the Jet B in the matrix below: Cetane range 40-45 45-50 50-55> 55 Range of (I) (II) (III) (IV) distillation (C) 50-100 2 3 4 100-150 5: 7 7 8 150-200 9 10 1 12 200-250 13 14 1 1> 250 17 18 19 in which the numbers from 1 to Each represents a family of compounds having a boiling point and a cetane number within the ranges indicated, said components being selected substantially along a diagonal direction from the top left to the bottom right of said matrix.   3 Method according to claim 2 characterized in that one carries out a formulation by incorporating in Jet B a representative of each line of said matrix.   4 Method according to one of claims 1 to 3 characterized in that the combination of compounds comprises at least one compound chosen from: 2-methylhexane, n-heptane, 2-methyloctane, 2-methylnonane, noctane, 3,6-dimethyloctane, 3-methylnonane, 2,9-dimethyl-5,6-diisoamyldecane, nonane, decane, undecane, 3-ethyldecane, 5-butylnonane, 7,8- dimethyltetradecane, 2,6,10-trimethyldodecane, 2,3,6-trimethylundecane, 6-propyldodecane, linear paraffins C n H 2 n + 2, with 10 N> 14; nitromethane, nitroethane, nitropropane, nitrobenzene, nitrotoluene; tert-butyl peroxide; diethylcarbonate; Polyethoxyethylal; dimethoxymethane, diethoxypropane, diethoxybutane, di-n-pentylether, di-n-pentoxymethane; octanol, nonanol, dodecanol; dimethylglycol, dimethyldiglycol, ethyldiglycol, ethyltriglycol; and butylglycol acetate, in proportions selected according to the boiling point and the cetane number of each of the compounds involved.   Fuel formulation promoting the operation of internal combustion engines in HCCI combustion mode, characterized in that it is prepared by a method according to one of claims 1 to 4, from: a fuel base comprising a jet B, as defined in ASTM D-1655; and optionally a constituent or a combination of constituents chosen from: paraffins; nitro compounds; peroxides; carbonates; acetals; the ethers; alcohols; glycol ethers; and the glycol esters, so as to provide the mixture with a distillation curve whose appearance is representative of that of a compression ignition engine fuel.   Fuel formulation according to claim 5, characterized in that said constituent or said combination of constituents comprises at least one compound chosen from: 2-methylhexane, n-heptane, 2-methyloctane, 2-methylnonane and n-octane , 3,6-dimethyloctane, 3-methylnonane, 2,9-dimethyl-5,6-diisoamyldecane, nonane, decane, undecane, 3-ethyldecane, 5-butylnonane, 7,8-dimethyltetradecane, 2,6,10-trimethyldodecane, 2,3,10-trimethylundecane, 6-propyldodecane, linear paraffins C n H 2 n + 2, with n> 14; nitromethane, nitroethane, nitropropane, nitrobenzene, nitrotoluene; tert-butyl peroxide; diethylcarbonate; polyethoxyethylal; dimethoxymethane, diethoxypropane, diethoxybutane, di-n-pentylether, di-npentoxymethane; octanol, nonanol, dodecanol; dimethylglycol, dimethyldiglycol, ethyldiglycol, ethyltriglycol; and butylglycol acetate, in proportions selected according to the boiling point and the cetane number of each of the compounds involved.   7 fuel formulation according to one of claims 5 and 6 characterized in that the combination of components comprises proportions a, b, c and d of at least one compound selected in each of columns I, II, III and IV of the following matrix: Cetane range 40-45 45-50 50-55> 55 Range of (I) (II) (III) (IV) distillation (C) 50-100 1 2 3 4 100-150 5 6 7 8 Wherein each compound of 1 to 20 is selected from compounds having a boiling point in the distillation range indicated and a cetane number. in the specified cetane range.   8 Fuel formulation according to claim 7 characterized in that, in its composition, the proportions a, b, c and d of each of the compounds entering the combination is between 0 and 50% by volume.   9 Fuel formulation according to one of claims 7 and 8 characterized in that its composition is represented by the formula: B 100- (a + b + c + d) Ia I Ib II Ic I Vd wherein I, II, III, IV, a, b, c and d are defined as in claim 3.   Fuel formulation according to one of Claims 7 to 9, characterized in that component 1 in the MDAI matrix is 2-methylhexane; component 2 is dimethylglycol or n-heptane; component 3 is dimethoxymethane; constituent 4 is nitromethane; component 5 is diethyl carbonate or 2-methylheptane; component 6 is 2-methyloctane; Component 7 is 2-methylnonane; component 8 is diethoxypropane, diethoxybutane, nitroethane, nitropropane or n-octane; component 9 is octanol, butyl glycol acetate or 3,6-dimethyloctane; component 10 is 3-methylnonane; component 11 is 2,9-dimethyl-5,6-diisoamyldecane; component 12 is di-npentyl ether, dimethyl diglycol, nonane, decane or undecane; Component 13 is ethyldiglycol; component 14 is 3-methyldecane; Component 15 is 5-butylnonane; component 16 is nonanol, di-n-pentoxymethane, nitrobenzene or nitrotoluene; component 17 is 7,8-dimethyltetradecane or 2,6,10 trimethyldodecane; component 18 is 2,3,10-trimethylundecane; Component 19 is 6-propyldodecane; and component 20 is dodecanol, ethyltriglycol, a mixture of linear paraffins C n H 2 n + 2, N> 14) or polyethoxyethylal.   Fuel formulation according to one of claims 7 to 10, characterized in that the compounds entering the combination are selected in a substantially diagonal direction from the upper left to the lower right of said MDAI matrix.   Fuel formulation according to claim 11, characterized in that said combination is carried out with a representative of each line of said MDAI matrix.   13. Fuel formulation according to one of claims 7 to 12, characterized in that its composition is represented by one of the formulas: ## STR1 ## and B 70 110 1510 2010.   A method of operating an internal combustion engine characterized by comprising supplying said engine with a fuel formulation developed by a method according to one of claims 1 to 4 or defined in one of the Claims 5 to 13.   The method of claim 14 characterized in that said internal combustion engine is developed for the HCCI combustion mode.