COMBUSTION ENGINE WITH DIRECT FUEL INJECTION, ESPECIALLY COMPRESSION IGNITION ENGINE WITH LOW COMPRE

专利摘要:
The present invention relates to a compression-ignition direct injection internal combustion engine comprising at least one cylinder (10), a cylinder head (12) carrying fuel injection means (14), a piston (16) sliding in this cylinder. cylinder, a combustion chamber (34) bounded on one side by the upper face (44) of the piston having a pin (48) erected towards the cylinder head and disposed in the center of a concave bowl (46), said engine comprising, injection means projecting fuel according to at least two different ply angle fuel jet plies (A1, A2), a lower ply jet ply (36) C1 and an upper ply (38). ) of jet axis C2 and at least two mixing zones (Z1, Z2) of the combustion chamber. According to the invention, one of the zones comprises a toric volume (64) of center B with a flat bottom (56), into which the fuel jets (40) of the lower layer are injected in such a way that C1 axis of the jets of the lower layer is located between the center B and the stud (48).
公开号:FR3016926A1
申请号:FR1450704
申请日:2014-01-29
公开日:2015-07-31
发明作者:Stephane Richard；Lionel Martinez；Olivier Laget
申请人:IFP Energies Nouvelles IFPEN；
IPC主号:

专利说明:

[0001] The present invention relates to a combustion engine with direct fuel injection and more particularly to a compression ignition engine and a method using such a motor. It relates more particularly to such a motor that can be used in the aeronautical or road field or in the field of stationary installations, such as a generator. This type of engine generally comprises at least one cylinder, a piston comprising a pin disposed in a concave bowl and sliding in this cylinder in a reciprocating rectilinear motion, means for admitting an oxidizer, means for exhausting burnt gases , a combustion chamber, and injection means for injecting a fuel into the combustion chamber. As is generally admitted, during the design of an engine, the constraints of performance, pollutant emissions and mechanical strength of the combustion chamber are becoming stronger while the means to satisfy them are opposite. Thus the increase in performance generally leads to an increase in pollutant emissions and higher mechanical stresses. To overcome these constraints and to ensure a limited emission of pollutants and a satisfactory mechanical strength over the entire operating range of the engine and in particular at very high load, the use of all the oxidant present in the combustion chamber, for example, an oxidizer comprising ambient pressure air, supercharged air, or a mixture of air (supercharged or not) and recirculated flue gas is of great importance.30 Indeed, it is necessary that the fuel mixture (oxidizer / fuel) in the combustion chamber is as homogeneous as possible. In practice, the fuel remains confined in the bowl and can not mix with the oxidant located in particular in the flush, that is to say in the volume located in the upper part of the combustion chamber delimited by the wall of the cylinder and the face of the bolt opposite the piston. This has the drawbacks of creating areas of high wealth in the combustion chamber generating a high production of soot, carbon monoxide (CO) and unburned hydrocarbons (HC) during the combustion of this fuel mixture. In addition, the heat load is concentrated on the reentrant of the piston, i.e. the neck or bowl diameter restriction that marks the transition between the piston bowl and the upper zone encompassing the flush, which can be limiting in terms of mechanical strength at very high loads As is better described in the patent application JP 5-71347, one of the solutions to overcome the aforementioned drawbacks is to use fuel injection means with jets according to at least two web angles and a piston having a bowl with two combustion volumes. This makes it possible to use a larger amount of oxidant compared to traditional engines and to distribute the heat load over a larger area of the combustion chamber. However, this configuration does not make it possible to optimize the internal aerodynamics in order to use all the available oxidant in the two combustion volumes and to minimize the overlap between the fuel jets coming from the different plies. Finally, this configuration does not minimize the wetting of the wall with liquid fuel. To overcome these disadvantages, and as is better described in the French patent application No. 13 60426 of the applicant, it is intended to use an internal combustion engine comprising fuel injection means with jets according to at least two ply angles and a piston having a bowl with two combustion volumes but with a piston shape and internal aerodynamics significantly improving the quality of combustion.
[0002] Nevertheless, this shape is mainly adapted to high compression ratios, for example of the order of 18. Indeed, as the fuel jets of the lower layer directly impact the toric part of the bowl by tangentially the surface of the piston the volume of bowl is restricted. This leads to a low bowl volume and therefore to high compression ratios.
[0003] Engines comprising combustion chambers with lower compression ratios, for example between 13.5 and 16.5, are nevertheless advantageous. They reduce the maximum pressure in compression in the combustion chamber and efforts on the crankshaft. This drop is therefore particularly useful for high performance and high power density engines. The present invention therefore aims to provide an improvement to the motors described above by providing a piston shape and an injection method that substantially improves the quality of the mixture and the combustion for combustion chambers with a compression ratio between 13.5 and 16.5 in order to obtain performance gains accompanied by significant gains in consumption and pollutant emissions (CO, nitrogen oxides, unburnt, soot) while decreasing the maximum pressure constraints in the combustion chamber and the forces undergone by the crankshaft.
[0004] For this purpose, the invention relates to a direct injection internal combustion engine with compression ignition comprising at least one cylinder, a cylinder head carrying fuel injection means, a piston sliding in this cylinder, a combustion chamber defined on one side by the upper face of the piston having a pin rising in the direction of the cylinder head and disposed in the center of a concave bowl, said motor having injection means projecting fuel according to at least two layers of fuel jets; different ply angle, a lower ply jet ply C1 and an upper jet ply layer C2, at least two mixing zones of the combustion chamber, characterized in that one of the zones has a central B-ring volume with a flat bottom into which the lower ply fuel jets are injected in such a way that the Cl-axis of the bottom ply jets is located between the center re B and the nipple. The fuel jet plies may be located axially one above the other. The injection means may comprise at least two injectors projecting 10 fuel according to a tablecloth fuel ply different from each other. The nappe angle of one of the plies is at most equal to 105 ° while the ply angle of the other of the plies is at least 150 °. The motor piston bowl may comprise a toric volume of radius R1 and R2, a bottom diameter of bowl FD, an inner diameter of bowl bottom FID, a diameter of the bowl opening BD, a neck diameter GD , a high injection diameter ID1, a developed length of the bowl 2 * Cb diameter cup, a nipple height H, and a bowl height L, and the bowl dimensions can satisfy at least one of following condition: the ratio BD / L may be less than 6, preferentially less than 4, the ratio FD / BD may be less than 1, FD-FID may be strictly positive, the ratio 2 * Cb / BD may be to be less than 2, the ratio GD / BD may be between 0.7 and 1, the ratio H / L may be greater than 50%, preferably greater than 60%, the ratio R 2 / R 1 may be less than 1, preferentially less than 30 0.6, - the ratio ID1 / GD may be greater than 1, - ID1 may be less than (GD-E (2 * Cb -GD) * 2/3). The bowl may comprise an angle of inclination a3 for the inclined flank of the stud, an angle of inclination a4 formed by the main axis of the fuel jets of the lower ply injected into the torus by impacting the torus in a point and by the tangent to the point of impact, an angle of inclination a5 considered at the tangency of the outer rounded surface with the side wall, and an angle of inclination a6 with respect to the horizontal and the tangent to the substantially planar wall and in which the bowl satisfies at least one of the following conditions: - a3 may be substantially equal to the half-angle of the jet ply A1 / 2 of the low ply, 10 - a4 may be greater than 100 ° - a5 can be between 0 ° and 60 °, preferably between 30 ° and 40 °, - a6 can be between 15 ° and 75. The invention also relates to an injection method for an internal combustion engine with direct injection with compression ignition comprising at least one a cylinder, a cylinder head carrying fuel injection means, a piston sliding in this cylinder, a combustion chamber bounded on one side by the upper face of the piston having a pin extending towards the cylinder head and disposed in the center a concave bowl, said method comprising injecting the fuel according to at least two different ply angle fuel jet plies, a C1 lower jet axis ply and a C2 upper jet axis ply, characterized in that it consists, for a position D of the piston considered between the bottom of the bowl and the origin of the fuel jets of the upper sheet, substantially corresponding to D = L4 + ID1 / tan (a2) where L4 is the 25 height between the bottom of the bowl and the point of impact of the fuel sprays of the upper sheet, ID1 is the high injection diameter considered between the points of impact and a2 which is the half angle at the top of the top sheet , to inject the combus the bottom ply in an area which has a central B-ring volume with a flat bottom in such a manner that the Cl-axis of the ply fuel jets is located between the center B and the nipple. The other features and advantages of the invention will now appear on reading the following description, given solely by way of illustration and not limitation, and to which are appended: FIG. 1 which shows a combustion engine FIG. 2 is a fragmentary view of a half section of the profile of the piston bowl of the engine of FIG. 1. Referring to FIG. 1, a combustion engine internal injection direct injection compression ignition comprises at least one cylinder 10, a cylinder head 12 closing the cylinder in the upper part, fuel injection means 14 carried by the cylinder head and a piston 16 of axis XX 'sliding in the cylinder in a reciprocating rectilinear motion. By fuel is meant a liquid fuel, such as diesel, kerosene or any other fuel having the physico-chemical characteristics enabling the operation of a compression ignition type engine including a direct fuel injection system. This engine also comprises an exhaust means 18 for burned gases with at least one exhaust pipe 20, the opening of which can be controlled by any means, such as for example an exhaust valve 22 and an intake means 24. an oxidizer with at least one inlet pipe 26 whose opening can be controlled by any means, such as an intake valve 28. By the term oxidant, it is inclusive of air at ambient pressure or supercharged air or a mixture of air (supercharged or not) with flue gas. The injection means comprise at least one fuel injector 30, preferably disposed in the axis XX 'of the piston whose nose 32 has a multiplicity of orifices through which the fuel is sprayed and projected towards the chamber combustion engine 34.
[0005] It is from these injection means that the projected fuel forms at least two plies of fuel jets, here two plies 36 and 38 of fuel jets 40 and 42, which, in the example shown, have an axis general confused with that of the piston 16 while being located axially one above the other.
[0006] More precisely, the ply 36 which is located closest to the plunger 16 is hereinafter referred to as the lower ply, while the ply 38 placed furthest from this plunger is called the upper ply. As can be seen in FIG. 1, these two plies form plane angles A1 and A2 that are different from one another. By ply angle, it is understood the angle at the summit that forms the cone from the injector and whose imaginary peripheral wall passes through all the axes C1 and C2 of the fuel jets 40 and 42. Advantageously, the angle of Al ply of the low ply is at most equal to 105 °, preferably between 40 ° and 75 °, while the ply angle A2 of the high ply is at most equal to 180 °, preferably between 150 ° and 180 °. For reasons of simplification in the rest of the description, the angle α1 corresponds to A1 / 2 while the angle α2 corresponds to A2 / 2 (see FIG. 2).
[0007] The gap between the two rib angles is therefore at least 50 ° in order to limit overlaps of fuel jets between the two layers and therefore the formation of pollutants, such as soot. Of course, it may be provided that the injection means are not arranged in the axis XX ', but in this case, the general axis of the fuel jet layers coming from the fuel injector is for the less substantially parallel to this axis XX '. Similarly, it may be provided that each web is carried by a separate injector (single web injector) with dedicated targeting in separate areas of the combustion chamber. The combustion chamber 34 is delimited by the internal face of the cylinder head 12 opposite the piston, the circular inner wall of the cylinder 10 and the upper face 44 of the piston 16. This upper face of the piston comprises a concave bowl. 46, here of axis 5 coincides with that of the cylinder, whose concavity is turned towards the cylinder head and which houses a pin 48 located substantially in the center of the bowl, which rises towards the cylinder head 12, being preferably coaxial with the cylinder. However, it may be provided that the axis of the bowl is not coaxial with that of the cylinder but the essential lies in the arrangement according to which the axis of the fuel jet web, the axis of the stud and the axis of the bowl are preferably merged. Referring additionally to FIG. 2, the generally frustoconical stud 48 has an apex 50 which, by moving symmetrically away from the axis XX 'towards the outside of the piston 16, continues with a surface inclined 52 substantially rectilinear continuing with an inclined flank 54 to arrive at a bottom 56 of the bowl. Of course and without departing from the scope of the invention, the inclined surface 52 may be non-existent (zero length) and the inclined side 54 then connects the top of the stud to the bottom of the bowl. In the example of FIG. 2, the bottom of this bowl is materialized by the substantially planar surface 56 and is connected on one side, at the point K, to a concave curved surface 58 in an arc of radius R1, called said surface. internal rounded, connected to the bottom of the inclined sidewall 54 and is connected, on the other side, to the point M, to another concave rounded surface 60 in an arc of radius R2, said outer rounded surface, connected by the other of its ends at a side wall 62, here substantially vertical, at a point N. The two rounded surfaces 58 and 60 and the flat surface 56 thus define the lower part of a toric volume, here a torus of substantially cylindrical section 64. The side wall 62 continues, always deviating from the axis XX ', by a rounded convex surface 66 in the form of a circular arc of radius R3, referred to as a reentrant, ending in an inclined plane 68 connected to a surface concave inflexion 69 connected to a sensitive surface This planar surface is continued by an outer convex surface 72 in an arc of radius R5 which arrives at a flat surface 74 extending to the vicinity of the wall of the cylinder. The combustion chamber thus comprises two distinct zones Z1 and Z2 in which mixing takes place between the oxidant they contain (air 10 - supercharged or non-air or mixture of air and recirculated flue gas) and the fuel coming from the injector and the combustion of the fuel mixture thus formed. Zone 1, delimited by the stud 48, the torus 64 of the bottom of the bowl, the wall 62 and the rounded convex surface 66, forms the lower zone of the combustion chamber which is associated with the lower layer 36 of fuel jets. C1 axis. The zone Z2, demarcated by the inclined plane 68, the concave surface 69, the substantially planar surface 70, the convex surface 72, the flat surface 74, the peripheral inner wall of the cylinder and the yoke 12 constitute the upper zone of this zone. chamber which is associated with the upper layer 38 of C2 axis fuel jets. In this configuration, the bowl comprises, for a position of the piston close to the top dead center: an outer diameter of the bottom of the bowl FD with a radius considered between the axis XX 'and the point M which makes the junction between the surface plane 56 and the surface 60 of radius R2. an inner bowl bottom diameter FID with a radius considered between the axis XX 'and the point K which makes the junction between the flat surface 56 and the surface 58 of radius R1. a diameter of the bowl opening BD with a radius considered near the bottom of the bowl and corresponding to a distance taken between the axis XX 'and the furthest point of the external concave surface 60, - a neck diameter GD with a radius corresponding to the distance between the axis XX 'and the vertical wall 62 which defines the outlet section of this bowl, - a high injection diameter D1 with a radius corresponding to the distance between the axis XX 'and the beginning of the inflection surface 69 at the point P between the inclined plane 68 and the concave surface 70 delimiting a length L6 of the jets 38 between the origin T2 of the axis C2 of the jets on the axis of the nose of the injector and the point P and which corresponds to the formula 'Dl isin (a2), - a developed length of the diametral half-section Cb of the bowl constituted by the length from the intersection of the top of the nipple with the axis XX 'to the wall of the cylinder, - a height H of nipple between the bottom of the bowl at point M to the top of the nipple, - a height L of the bowl between the bottom of the bowl at the point M to the flat surface 74, - a junction height L3, which corresponds to the extent of the side wall 62, considered between the end of the surface outer radius 60 at the point N and the beginning of the outer rounded surface 66, - a height L4 considered between the point P and the point M, - an inclination angle a3 with respect to a vertical for the inclined side 54, - a angle of inclination a4 formed by the main axis C1 of the fuel jets of the lower ply 36 impacting the torus with the tangent at the point of impact F by delimiting a length L5 of the jets 40 between the origin T1 of the axis Cl jets on the axis of the nose of the injector and the point F. This length L5 meets the formula ID2 / sin (al) with ID2 which corresponds to a low injection diameter with a radius that corresponds to the distance between the axis XX 'and the point F. - an angle of inclination a5 considered at the tangency of the rounded surface e 60 with the side wall 62 at the point N, - an angle of inclination a6 with respect to the horizontal and the tangent to the substantially plane wall 70, - an angle of inclination a7 with respect to the horizontal and the plane inclined 68 at the point of intersection P. 3016 926 11 All these parameters are appreciated for a position of the piston 16 in the vicinity of the top dead center which corresponds to a distance D considered between the point M and the origin T2 of the axis C2 jets 42. More precisely, this distance D is equal to the sum of the height L4 and 5 of the height C, height C which corresponds to the axial height between the origin T2 and the point P. This height corresponds to the formula ID1 / tan (a2). Thus, the dimensional and angular parameters of this bowl satisfy at least one of the following conditions: the angle a4 is greater than 100 °. This amounts to impacting the fuel jets of the lower sheet on the descending surface 58 of radius R1 and redirecting this jet of fuel towards the flat surface 56 and the surface 60 of radius R2 and thus to ensure aerodynamic movement in the torus rising upwards and the center of the cylinder, which further minimizes the interaction with the upper layer; the angle a5 must be positive and less than 60 °. Preferably, it must be of the order of 30 ° to 40 ° to direct the fuel jets 40 of the lower sheet 36 to the volume of oxidizer S2 to use the oxidant of this zone while limiting the rise of this fuel to the upper sheet 38; The position of the top of the stud 48 is as close as possible to the nose 32 of the injector 30 in order to limit the volume of oxidizer under the injector which will not be impacted by the fuel jets. Thus the H / L ratio is greater than 40% and preferably greater than 60%; the angle a3 is substantially equal to the angle a1 of the lower sheet. Thus, the general axis of the jets of the lower layer tangents the flank 54 of the nipple. The lower jets can thus impact the rounded surface 58 by vaporizing completely before impacting the piston; the volume of oxidant S2 between the two layers is not zero since the interaction between the layers is harmful to the pollutants. The volume S2 must nevertheless be minimized. To do this, the junction length L3 between the torus and the reentrant 66 (convex rounded surface of center R3) must be such that L3 / (2 * length of R2) <1 or (L3 / length of R2 <2) so to ensure that the volume of oxidizer S2 available between the upper 38 and lower 36 is low relative to the fuel volume generated by the jets of the lower layer; - The second combustion zone Z2 located in the upper part of the piston which starts from the reentrant 66 is for the fuel jets 42 of the upper web 38; the combustion volume of zone Z2 is at least equal to one tenth of the total volume of the bowl; the so-called hunting zone is formed by the inclined plane 68, the concave surface 69, the flat surface 70, the convex surface 72 and the flat surface 74. The angle a6 is between 10 ° and 75 °, which makes it possible to burst the fuel jets 42 to create an aerodynamic movement above the piston and additionally to use the oxidizer in the hunting zone. This aerodynamics allows a better fuel / oxidant mixture above the piston, especially during the expansion phase of the engine and thus promote the oxidation of the flue gases; - To promote the impact of the jets 42 on the flush, a guide surface 68 is provided between the reentrant 66 and the surface 70. This guide surface may be rounded in extension of the reentrant or substantially flat. This guide surface serves to concentrate the fuel jets 42 and to guide them towards the convex surface 72. Thus this guide surface has an angle a7 at the point of intersection P whose difference with the angle a2 is less than 45 °. the surfaces 58 and 60 are obligatorily connected by a flat bottom of length (of dimension equal to FD less FID) non zero - the location of the inflection surface 69 is such that the distances (L5 + (FD-FID)) and L6 are of approximately the same order (0.5 <(L5 + (FDFID)) / L6 <2). Thus, advantageously, the fuel jets of the lower and upper layers will substantially simultaneously impact the surface 60 of the core and the zone of inflection respectively. the diameter ID1 must be such that ID1 / GD> 1 and ID1 <(GD + (Cb-GD) * 2/3). This allows the fuel jets 42 to optimize the aerodynamics above the piston.
[0008] In addition, the ratio BD / L is less than 6, preferably less than 4, the ratio R2 / R1 is less than 1, preferably less than 0.6, the ratio FD / BD is less than 1, the ratio Cb / BD is less than 2 to keep a complete vaporization of the fuel and prevent the wetting of the wall of the cylinder, - the ratio GD / BD is between 0.7 and 1 for the aerodynamics of the torus and the rise of the fuel jets, - the H / L ratio is greater than 40%, preferably greater than 60% to minimize the volume of oxidant between the nozzle nose and the nipple, - the ratio (L5 + (FD-FID)) / L6 is between 0.5 and 2 for the impact of the two plies of fuel jets at the same time on the inflection zone and the ascending portion of the torus, - Al is between 40 ° and 105 ° with al = A1 / 2, - A2 is included between 150 ° and 180 ° with a2 = A2 / 2, - a3 is substantially equal to a1, - a4 is greater than 100 °, - a5 is comprised between e 0 ° and 60 °, preferably between 10 ° and 50 °, the angle a6 is between 15 ° and 75 °, -7-a2 is less than 45 °, the ratio ID1 / GD is greater than 1 , - Dl is less than (GD + (Cb-GD) * 2/3), Thus, thanks to this setting of the bowl, the fuel jets of the lower sheet 36 directly target the torus 64 and do not directly impact the reentrant 66. As a result, the combustion of the fuel / lower oxidant mixture takes place essentially in the low volume of the piston, that is to say in the torus 30, whereas the combustion of the fuel / higher oxidant mixture essentially takes place in the hunting and above the piston.
[0009] This bowl setting adapted to low compression rates, for example between 13.5 and 16.5, makes it possible to ensure that the interaction of the jets of the upper layer with the jets of the lower layer is much more limited, which makes it possible to homogenize the oxidant / fuel mixture while respecting constraints of mechanical strength at high or very high load.

权利要求:
Claims (7)
[0001]
CLAIMS1) Direct injection internal combustion engine with compression ignition comprising at least one cylinder (10), a cylinder head (12) carrying fuel injection means (14), a piston (16) sliding in this cylinder, a combustion chamber (34) delimited on one side by the upper face (44) of the piston having a stud (48) extending towards the cylinder head and disposed in the center of a concave bowl (46), said motor having injection means projecting fuel according to at least two different ply angle fuel jet plies (A1, A2), a lower Cl-axis ply (36) and an upper spine ply (38). C2, at least two zones of mixing (Z1, Z2) of the combustion chamber, characterized in that one of the zones comprises a toric volume (64) of center B with a flat bottom (56) in which are injected the fuel jets (40) from the lower layer in such a way that the axis C1 of the ts of the lower sheet is located between the center B and the stud (48).
[0002]
2) Internal combustion engine according to claim 1, characterized in that the fuel jet plies (24, 26) are located axially one above the other.
[0003]
3) Internal combustion engine according to claim 1 or 2, characterized in that the injection means comprise at least two injectors projecting fuel according to a tablecloth of different angle fuel jets different from each other .
[0004]
4) Internal combustion engine according to one of the preceding claims, characterized in that the lap angle (A1) of one (24) of the plies is at most equal to 105 ° while the lap angle ( A2) on the other side of the plies is at least 150 °.
[0005]
5) Motor according to one of the preceding claim wherein the bowl comprises a toric volume (64) of radius R1 and R2, a bottom diameter of bolFD, an inner diameter of bowl bottom FID, a diameter of the opening of BD bowl, a neck diameter GD, a high ID1 injection diameter, a developed length of the cup 2 * Cb diameter cup, a height H of pin, and a height L of the bowl, characterized in that the dimensions of the at least one of the following conditions: - the ratio BD / L is less than 6, preferentially less than 4, - the ratio FD / BD is less than 1, - FD-FID is strictly positive - the ratio 2 * Cb / BD is less than 2, - the ratio GD / BD is between 0.7 and 1, - the ratio H / L is greater than 50%, preferably greater than 60% - the ratio R2 / R1 is less than 1, preferably less than 0.6, the ratio ID1 / GD is greater than 1, and ID1 is less than (GD + (2 * Cb-GD) * 2/3). 15
[0006]
6) Motor according to one of the preceding claims wherein the bowl comprises an outer rounded surface (60) connected to a side wall (62) continuing with a convex rounded surface (66) resulting in an inclined plane (68) connected to a concave inflexion surface (69) connected to a substantially planar surface (70), an inclination angle (a3) for the inclined sidewall (54) of the stud (48), an inclination angle (a4) formed by the main axis (C1) of the fuel jets (40) of the lower sheet (36) injected into the torus (64) by impacting the torus at a point (F) and by the tangent at the point of impact (F). ), an angle of inclination (a5) considered at the tangency of the outer rounded surface (60) with the side wall (62), and an angle of inclination (a6) with respect to the horizontal and the tangent to the substantially planar wall (70) and wherein the bowl satisfies at least one of the following conditions: - a3 is substantially equal to half-angle of a layer of jets A1 / 2 of the low sheet, 30 - a4 is greater than 100 °, - a5 is between 0 ° and 60 °, preferably between 30 ° and 40 °, - a6 is between 15 ° and 75 ° 3 0 1692 6 17
[0007]
7) Injection method for a compression-ignition direct injection internal combustion engine comprising at least one cylinder (10), a cylinder head (12) carrying fuel injection means (14), a piston (16) sliding in this cylinder, a combustion chamber (34) bounded on one side by the upper face (44) of the piston having a pin (48) erected in the direction of the cylinder head and arranged in the center of a concave bowl ( 46), said method of injecting the fuel into at least two different ply angle fuel jet plies (A1, A2), a lower Cl-axis ply (36) and an upper ply (38). C2 axis of jet, characterized in that it consists, for a position D of the piston (16) considered between the bottom of the bowl (M) and the origin (T2) fuel jets of the upper layer, corresponding substantially to D = L4 + ID1 / tan (a2) where L4 is the height between the bottom of the bowl and the point of impact (P) d The top injection fuel jets, D 1, is the high injection diameter considered between the points of impact (P) and a 2 which is the half-angle at the top of the upper layer, to inject the fuel from the lower layer. in an area which has an O-ring volume (64) of center B with a flat bottom (56) in such a manner that the Cl-axis of the fuel jets of the web is located between the center B and the nipple (48) .20

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引用文献:

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JPH0571347A|1991-09-09|1993-03-23|Yanmar Diesel Engine Co Ltd|Combustion chamber of direct injection type diesel engine|

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法律状态:
2016-01-12| PLFP| Fee payment|Year of fee payment: 3 |

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2017-01-16| PLFP| Fee payment|Year of fee payment: 4 |

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2018-01-26| PLFP| Fee payment|Year of fee payment: 5 |

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2020-01-28| PLFP| Fee payment|Year of fee payment: 7 |

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2021-10-08| ST| Notification of lapse|Effective date: 20210905 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1450704A|FR3016926B1|2014-01-29|2014-01-29|COMBUSTION ENGINE WITH DIRECT FUEL INJECTION, ESPECIALLY COMPRESSION IGNITION ENGINE WITH LOW COMPRESSION RATE|

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FR1450704|2014-01-29|FR1450704A| FR3016926B1|2014-01-29|2014-01-29|COMBUSTION ENGINE WITH DIRECT FUEL INJECTION, ESPECIALLY COMPRESSION IGNITION ENGINE WITH LOW COMPRESSION RATE|

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CN201580006250.9A| CN105940200B|2014-01-29|2015-01-12|The compression ignition engine of fuel direct injection internal combustion engine and more specifically little compressible|

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PCT/EP2015/050410| WO2015113803A1|2014-01-29|2015-01-12|Direct fuel injection combustion engine and more particularly a compression-ignition engine having a low compression ratio|

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EP15700652.9A| EP3099908B1|2014-01-29|2015-01-12|Direct fuel injection combustion engine and more particularly a compression-ignition engine having a low compression ratio|

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US15/115,222| US10215082B2|2014-01-29|2015-01-12|Direct fuel injection combustion engine and more particularly a compression-ignition engine with a low compression ratio|