JP4682452B2 - Fuel injection system for diesel engine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a fuel injection device for a diesel engine.
[0002]
[Prior art]
  In a direct injection type diesel engine, a reentrant type cavity formed at the top of a piston is generally known. For example, in Japanese Patent Laid-Open No. 9-41975, the cavity shape is defined so that the fuel injected toward the lip portion of the piston is peeled off from the cavity side wall when going to the bottom of the cavity from the lip portion. Describes that the mixing of fuel spray and air is improved to suppress the generation of smoke.
[0003]
  Also, Vol.31, No.3, July 2000, pp. 51-56, Automobile Engineering Society Proceedings, if the center of the bottom of the reentrant cavity of the piston is raised, (1) the side wall under the lip during the compression stroke (2) When the fuel is injected, the fuel spray is drawn into the vertical vortex to form a flow that rotates downward along the side wall under the lip, and (3) When the lip diameter is increased, the reverse squish flow is weakened and the outflow of the air-fuel mixture to the squish area is suppressed. (4) The vertical vortex becomes a spiral vortex due to the effect of swirl. (5) It is described that mixture formation and combustion are promoted in the cavity, and (6) after that, the mixture is discharged into the squish area and oxidizes unburned soot.
[0004]
  Further, in a direct injection diesel engine, pilot ignition that injects a small amount of fuel prior to main injection that injects fuel into the combustion chamber near the top dead center of the compression stroke shortens the ignition delay period of main injection. It is known to suppress premixed combustion (rapid combustion) of main injection fuel and reduce engine combustion noise and NOx.
[0005]
[Problems to be solved by the invention]
  An object of the present invention is to suppress generation of NOx in a direct injection diesel engine. That is, the amount of NOx generated increases as the temperature of the mixture increases and as the combustion time of the mixture increases. That is, if a heat spot (local high temperature region) exists in the combustion chamber for a long time, NOx increases. Therefore, the present invention intends to reduce the amount of NOx produced by such early diffusion of heat spots.
[0006]
  In order to solve such a problem, the present inventor forms a fuel vapor region relatively close to the lip portion of the piston by the main injection of fuel, and the fuel vapor is expanded around the cavity of the piston by the expansion flow of the combustion gas. It was found that if it is placed against the wall and guided toward the bottom of the cavity, a strong vertical vortex is generated in the cavity and heat spots can be diffused early.
[0007]
  However, if the pilot injection is executed prior to the main injection, the engine combustion noise and NOx can be reduced as described above, but the longitudinal vortex becomes weak.
[0008]
  In view of the above, the present invention makes it possible to generate and strengthen the vertical vortex by the expansion flow of the combustion gas described above while taking into consideration the reduction of combustion noise and NOx caused by pilot injection.
[0009]
[Means for Solving the Problems]
  The present inventor has studied the generation mechanism of the vertical vortex by the expansion flow of the combustion gas, and the generation of the vertical vortex is caused by the relatively concentrated fuel vapor near the lip portion of the piston during the ignition delay period of the main injection fuel. It has been found that a region needs to be formed. That is, by generating such a region of the fuel vapor, the expansion flow of the combustion gas generated by the ignition in front of the fuel injection direction acts on the fuel vapor to generate a vertical vortex. Therefore, if the ignition delay period of the main injection fuel is shortened by pilot injection, the region of the fuel vapor that can be formed near the lip portion is reduced, and the ignition position is too far from the lip portion, and the expansion flow of the combustion gas becomes fuel vapor. It will not work efficiently, and the desired vertical vortex cannot be generated or strengthened.
[0010]
  On the other hand, engine combustion noise is particularly problematic on the low engine speed or low load side. On the high rotation side and high load side, there is engine vibration and noise other than combustion noise, and the higher the engine speed and load, the longer the ignition delay period. Since combustion becomes shorter, combustion noise is not a big problem.
[0011]
  Therefore, the present invention is designed to suppress the combustion of the pilot injection fuel when the engine load is high and to generate and strengthen the vertical vortex by the expansion flow of the combustion gas.
[0012]
  That is, the invention according to claim 1 is a piston in which a reentrant cavity having a diameter that decreases as it approaches the opening end is formed at the top;
  A fuel injection valve;
  A main injection execution means for main-injecting fuel near the top dead center of the compression stroke so as to go to the lip portion forming the opening edge of the cavity of the piston by the fuel injection valve;
  Due to the main injection, a region of fuel vapor is formed in the vicinity of the lip portion during the ignition delay period of the main injection fuel, and the ignition is caused by the expansion flow of the combustion gas generated by the ignition in front of the fuel injection direction of the fuel injection valve. In the fuel injection device for a diesel engine, the fuel vapor in front of the position is applied to the peripheral wall surface of the cavity and guided toward the bottom of the cavity.
  Pilot injection execution means for performing pilot injection of fuel prior to the main injection by the fuel injection valve;
  In order to obtain an ignition delay period in which a region of fuel vapor is formed in the vicinity of the lip portion in the main injection fuel, when the engine load is equal to or greater than a predetermined value, combustion due to the pilot injection is less than when the engine load is less than the predetermined value. And a pilot combustion suppression means for suppressing the pilot combustion.
[0013]
  More specifically, in the present invention, the fuel vapor is guided from the vicinity of the lip portion toward the bottom of the cavity by using the expansion flow of the combustion gas, so that the heat spot is dispersed or moved. .
[0014]
  In this regard, the conventional vertical vortex combustion concept is that a vertical vortex is formed in the compression stroke, and the fuel spray injected below the lip is placed on the vertical vortex. It is slowly dispersed toward the bottom of the cavity by the vertical vortex inside. For this reason, the fuel vapor suitable for ignition cannot stagnate near the lip portion, and ignition tends to occur at the stagnation site on the downstream side of the vertical vortex of the fuel spray. In that case, the expansion flow of the combustion gas generated by ignition does not work so much when the fuel vapor is strongly applied to the peripheral wall surface of the cavity and guided to the bottom of the cavity, and does not contribute so much to strengthening the vertical vortex. On the other hand, a strong vertical vortex does not occur even if a vertical vortex is generated in the compression stroke.
[0015]
  On the other hand, in the present invention, the fuel spray reaches the lip portion during the ignition delay period and forms a region of fuel vapor near the lip portion. Since the ignition position (ignition point) of the fuel spray is a position upstream of the fuel vapor reservoir, the combustion spreads toward the downstream side. Therefore, a strong expansion flow is generated. The reason why the ignition point is located on the upstream side is that a strong vertical vortex is not formed in the compression stroke, so the fuel is over-rich in the vicinity of the lip, and the concentration slightly away from the lip has a concentration suitable for ignition. This is probably because of this. In the present invention, the cavity peripheral wall surface (particularly near the boundary between the lip portion and the portion recessed from the lip portion to the outside in the radial direction of the piston) by the expansion flow of the combustion gas after ignition of the fuel vapor in the vicinity of the lip portion In addition to generating a strong unidirectional expansion flow, the flame propagates following the fuel guided to the bottom of the cavity, and further causes vertical vortices. Will grow. In other words, this is different from the conventional idea in that the expansion flow of the combustion gas is positively used for guiding the fuel vapor to the cavity bottom.
[0016]
  As the fuel vapor is guided toward the bottom of the cavity by the expansion flow of the combustion gas, the flame propagates toward the bottom of the cavity. Go around the bottom. As a result, the heat spot once spreads from the vicinity of the lip portion toward the bottom of the cavity, but since the fuel vapor is reduced in the vicinity of the lip portion, the heat spot is generated toward the bottom of the cavity, so The heat spot disappears quickly. That is, by the end of fuel injection, the highest temperature portion in the cavity moves to the bottom side of the cavity from the lip portion. For this reason, the heat spot does not become large at one part in the cavity, or the disappearance of the heat spot is accelerated, which is advantageous in reducing NOx.
[0017]
  Further, the combustion and combustion of the fuel injected by the pilot increases the temperature and pressure in the combustion chamber, and the formation of flame nuclei (fire types) that induce the ignition of the main injected fuel increases the ignitability of the subsequent main injected fuel. The ignition delay period is shortened. For this reason, the premixed combustion of the main injection fuel is suppressed, the combustion noise is reduced, and the generation of NOx at the initial stage of combustion is suppressed.
[0018]
  Furthermore, in the case of the present invention, when the engine load is a high load equal to or higher than a predetermined value, the pilot combustion suppression means works, and the combustion by the pilot injection is suppressed more than when the engine load is a low load less than the predetermined value. Accordingly, it is possible to avoid the ignition delay period of the main injection fuel from becoming excessively short at the time of high engine load, and it is possible to form a desired fuel vapor region near the lip portion before ignition. As a result, the expansion of the heat spot using the above-described expansion flow of the combustion gas can be prevented and the disappearance can be achieved quickly, which is advantageous in reducing NOx. And, since the combustion noise of the engine is not so much a problem at high load, there is no particular problem even if the pilot combustion is suppressed.
[0019]
  The invention according to claim 2The fuel injection device for a diesel engine according to claim 1,
  The fuel spray reach Sp at the time when 0.42 ms has elapsed from the start of the main injection of the fuel injector, the cone angle Θ of the fuel spray of the fuel injector, and the minimum aperture Dlip at the lip of the cavity Next formula
      Dlip = k × Sp × sin (Θ / 2)
      (However, k = 1.4 to 1.8)
Set to satisfy the relationshipPleaseIt is characterized by being.
[0020]
  That is, the present invention attempts to inject fuel from the fuel injection valve toward the lip portion and cause fuel spray to reach the lip portion during the fuel ignition delay period so that fuel vapor is formed in the vicinity of the lip portion. To do. For this purpose, the fuel spray arrival distance Sp (penetration) at the time when 0.42 ms, which is a typical ignition delay period during medium load operation, from the start of fuel injection is used to set the minimum aperture Dlip of the cavity. The reason why Sp (sin) is multiplied by sin (Θ / 2) is to determine the reach of the fuel spray in the horizontal direction because the fuel is injected with a cone angle Θ.
[0021]
  Then, since the k value is set to 1.4 to 1.8, the fuel spray reaches the lip portion during the ignition delay period. Since the cavity is at a high temperature, vaporization of the fuel spray proceeds simultaneously with mixing of the fuel spray and air, and fuel vapor is formed in the vicinity of the lip portion. Ignition occurs in a combustible mixture of fuel vapor and air, where ignition conditions are reached, but does not occur near the spray tip (near the lip) or near the fuel injection valve. Usually, it occurs at a place away from the fuel injection valve to the front in the injection direction to some extent (and also away from the lip portion).
[0022]
  Therefore, the expansion flow of the combustion gas generated by the ignition strongly presses the fuel vapor existing in the vicinity of the lip portion in front of the combustion gas (front in the injection direction) against the peripheral wall surface of the cavity. As a result, the fuel vapor near the lip is guided toward the bottom of the cavity by the expansion flow. As a result, as described above in the description of the invention of claim 1, the heat spot does not become large at a specific portion in the cavity, or the heat spot disappears quickly, which is advantageous for NOx reduction. .
[0023]
  Here, if the k value is less than 1.4, that is, if the minimum diameter Dlip of the cavity becomes relatively small, the liquid jet of fuel injected from the fuel injection valve will reach the lip portion. It does not divide sufficiently, resulting in incomplete spraying. Therefore, the formation of fuel vapor is insufficient, and the expansion flow of the combustion gas does not work effectively. Furthermore, the core of the fuel spray (the liquid column part present in the fuel spray injected from the fuel injection valve or the part where the fuel concentration is very high) collides with the lip part to worsen the combustion (power reduction), Even if the NO generation amount decreases, the soot generation amount increases.
[0024]
  On the other hand, if the k value exceeds 1.8, that is, if the Dlip is relatively large, the distance from the ignition point to the lip portion becomes long, so that the expansion flow of the combustion gas due to ignition causes the fuel in front of the lip. Even if it acts on the steam, the amount of the fuel steam that is dispersed to the periphery before being applied to the lip increases. That is, the expansion flow does not work effectively for guiding the fuel vapor toward the bottom of the cavity, and the amount of NOx generated increases. From such a viewpoint, the k value is more preferably 1.5 to 1.7.The
[0025]
ContractThe invention according to claim 3 is the fuel injection device for a diesel engine according to claim 1 or 2,
  The pilot combustion suppression means is characterized in that when the engine load is equal to or greater than a predetermined value, the ratio of the pilot injection amount to the main injection amount of the fuel is less than when the engine load is less than the predetermined value.
[0026]
  Accordingly, since the amount of fuel that is pilot-injected and combusted is relatively small when the engine is high in load, a large increase in the temperature and pressure of the combustion chamber can be suppressed, and there are few flame nuclei for ignition of the main injection fuel. Become. For this reason, it is avoided that the ignition of the main injection fuel is hardly induced and the ignition delay period becomes excessively short. Therefore, the expansion of the heat spot using the above-described expansion flow of the combustion gas can be prevented and early disappearance can be achieved, which is advantageous in reducing NOx.
[0027]
  The invention according to claim 4 is the fuel injection device for a diesel engine according to claim 1 or 2,
  In order to obtain an ignition delay period in which a region of fuel vapor is formed in the vicinity of the lip portion in the main injected fuel, when the engine load is equal to or greater than a predetermined value, the pilot injection starts from when the engine injection is less than the predetermined value. The time until the start of the main injection is made longer.
[0028]
  Accordingly, since the pilot injection timing is advanced when the engine is under a high load, the fuel injected by the pilot easily diffuses in the combustion chamber to form a lean premixed gas, that is, the amount of fuel burned by self ignition. Less. Alternatively, even if the combustion is ignited, the combustion ends early and the number of fire types effective for igniting the main injection fuel decreases. For this reason, it is avoided that the ignition of the main injection fuel is hardly induced and the ignition delay period becomes excessively short. Therefore, the expansion of the heat spot using the above-described expansion flow of the combustion gas can be prevented and early disappearance can be achieved, which is advantageous in reducing NOx.
[0029]
  The invention according to claim 5 is the fuel injection device for a diesel engine according to claim 4,
  The ratio of increasing the time as the engine load increases is made longer when the engine load is equal to or higher than a predetermined value and longer than when the engine load is lower than the predetermined value.
[0030]
  As a result, when the engine load shifts from a low load to a high load, the effect of the pilot injection suddenly decreases, that is, the ignition delay period of the main injection fuel at a high engine load while avoiding a sudden increase in combustion noise. Therefore, it is possible to prevent the heat spot from expanding and to quickly extinguish using the above-described expansion flow of the combustion gas, so that NOx is reduced.
[0031]
【The invention's effect】
  As described above, according to the present invention, a region of fuel vapor is formed in the vicinity of the lip portion during the ignition delay period of the main injection fuel, and the fuel vapor is spread on the peripheral wall surface of the cavity by the expansion flow of the combustion gas generated by the ignition. In the fuel injection device for a diesel engine, which is directed to the bottom of the cavity, pilot injection of fuel is performed prior to the main injection, and the main injected fuel is disposed near the lip portion. In order to obtain an ignition delay period that forms a region of fuel vapor, combustion by pilot injection is suppressed when the engine load is greater than or equal to a predetermined value than when it is less than the predetermined value. Preventing expansion and early extinction of heat spots using expanded flow of combustion gas while reducing noise and suppressing NOx generation It can be, which is advantageous in reduction of NOx.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0033]
  -Combustion chamber structure of diesel engine-
  In the combustion chamber structure of the direct injection diesel engine shown in FIG. 1, 1 is a piston, 2 is a cylinder block, 3 is a cylinder head, 4 is an intake port (helical port), 5 is an exhaust port, 6 is an intake valve, and 7 is an exhaust. It is a valve. At the top of the piston 1 is formed a reentrant cavity 8 whose diameter decreases as it approaches the open end. The cylinder head 3 is provided with a fuel injection valve 9, and its injection nozzle 10 protrudes slightly to inject fuel directly into the cavity 8. The cylinder head 3 is a flat type, and the valves 6 and 7 are upright.
[0034]
In the piston 1 shown enlarged in FIG. 2, 11 is an annular lip portion projecting inwardly at the piston top surface so as to form an opening edge of the cavity 8, and 12 is a piston radial outward direction following the lip portion 11. It is the annular recessed part recessed in. Further, the piston 1 is formed with a convex portion 13 that protrudes toward the opening of the cavity 8 at the center of the bottom of the cavity 8.
[0035]
  −Diesel engine design−
  The diesel engine is designed as follows.
[0036]
  The fuel spray reach Sp at the time when 0.42 ms has elapsed from the start of fuel injection of the fuel injection valve 9, the cone angle Θ of the fuel spray of the fuel injection valve 9, and the minimum aperture of the lip portion 11 of the cavity 8 (Hereinafter referred to as lip diameter.) Dlip has a relationship satisfying the following expression.
[0037]
      Dlip = k × Sp × sin (Θ / 2) (1)
  However, k = 1.4 to 1.8, and k = 1.5 to 1.7 is preferable. 0.42 ms from the start of fuel injection is a typical ignition delay period in the emission operation mode.
[0038]
  The cone angle Θ is preferably 153 to 157 degrees. That is, in a diesel engine, fuel injection is usually performed in the vicinity of the top dead center of the compression stroke, particularly in the vicinity of several degrees CA (for example, near ATDC 2 °) after the top dead center. In this case, if the cone angle Θ is less than 153 degrees, the fuel spray does not hit the lip portion and moves toward the bottom of the cavity, so that the heat spot cannot be sufficiently dispersed or early extinguished using the above-described expansion flow. . On the other hand, when the cone angle Θ exceeds 157 degrees, the fuel spray injected from the fuel injection valve is directed to the squish area around the opening of the cavity, and this squish area is a place where heat is easily radiated to the cylinder head and the cylinder block. Therefore, incomplete combustion of the fuel spray tends to occur and the amount of soot generated increases. Therefore, from this point of view, the more preferable cone angle Θ is 154 to 156 degrees.
[0039]
  The reach distance Sp is determined by a constant container experiment (fuel injection pressure 80 MPa, atmospheric pressure 2.5 MPa, temperature 20 ° C.). If there is no constant container experiment data, it can be estimated from Guang'an's formula. Guang'an's formula is an empirical formula that relates the reach distance Sp (spray penetration) and the nozzle diameter of the fuel injection valve 9 and is as follows.
[0040]
    Sp = Spb + 2.95 × (ΔP × 10⁶/ ρf)^0.25× (Dn × (t-tb))^0.5
        Spb = 0.39 × (2 × ΔP × 10⁶/ ρf)^0.5× tb
         tb = 28.65 × (ρf × Dn × 10^-3) / (ρA × ΔP × 10⁶)^0.5/Ten^-3
  Where ΔP: differential pressure (MPa) between container pressure and injection pressure, ρf: light oil density (kg / m³), Dn: nozzle diameter (mm), t: time after the start of injection (0.42 ms), and ρA: container air density.
[0041]
  The cylinder bore diameter B has a relationship satisfying the following formula.
[0042]
      B = K × Dlip (2)
  However, it is preferable that K = 1.8 to 2.5.
[0043]
  That is, if the minimum diameter Dlip of the cavity is too small with respect to the bore diameter B, the maximum output is reduced. On the contrary, if the cavity is too large, the normal squish flow obtained in the compression stroke becomes weak. As a result, the amount of sputum generated increases. From this viewpoint, the K value is set to 1.8 to 2.5, and a more preferable K value is 2.0 to 2.3.
[0044]
  For example, when the reach distance Sp = 27 mm and the cone angle Θ = 154 degrees, the lip diameter Dlip = 38.94 to 44.20 mm and the bore diameter B = 77.87 to 100.33 mm. The height of the convex portion 13 may be about 0.2 to 0.25 times the lip diameter Dlip.
[0045]
  The fuel spray angle θ is preferably θ = 15 to 24 degrees. That is, as the spray angle θ increases, the dispersibility of the fuel spray increases, but the fuel vapor also spreads from the vicinity of the lip portion to the periphery thereof, so the amount of fuel vapor applied to the lip portion by the expansion flow of the combustion gas decreases accordingly. This is disadvantageous for the dispersion movement or early disappearance of the heat spot using the expansion flow. On the other hand, if the spray angle θ becomes too small, the fuel spray core becomes longer and this impinges on the lip and worsens combustion (decrease in output). Even if the amount of NOx generated decreases, the amount of soot generated Will increase. For this reason, the spray angle θ is preferably 15 to 24 degrees, and more preferably 18 to 23 degrees.
[0046]
  The fuel injection pressure P of the fuel injection valve 9 is preferably P = 50 MPa or more. That is, in order to cause the fuel spray injected from the fuel injection valve to reach the lip portion during the ignition delay period and form fuel vapor near the lip portion as described above, the fuel injection pressure is set to 50 MPa or more. It is preferable. A more preferable injection pressure is 80 MPa or more. The upper limit of the injection pressure can be set to 150 MPa, for example, and 200 MPa.
[0047]
  The ratio of the momentum of the swirl to the momentum of the fuel spray at the lip when the fuel spray injected from the fuel injection valve 9 first reaches the lip of the piston cavity is 0.9 to 1.5. It is preferable. This momentum ratio can be obtained by the following equation.
[0048]
    Momentum ratio = ((ρa / ρao) × Va) / ((ρs / ρso) × Vs) (3)
  Where ρa: charged air density, ρao: air density in the standard state, Va: swirl speed of the lip portion 11 at the top dead center of the compression stroke, ρs: density of fuel spray in a constant vessel experiment, ρso: standard Fuel spray density in the state, Vs: Spray speed when reaching the lip in a constant container experiment. The standard state is 20 ° C. and 1 atmosphere (0.1013 MPa).
[0049]
  Where ρa / ρao = (Pin / 101.3) / (Tin / 293.3),
                Va = ρa × SRi × (Dlip / B / 2))²× (N × 2π / 60) × Dlip,
It is. ρs / ρso = 1 can be set.
[0050]
  Where Pin: intake manifold internal pressure (kPa), Tin: intake manifold internal temperature, SRi: swirl ratio in rig test, N: engine speed (rpm).
[0051]
  That is, the swirl generated in the bore in the intake stroke promotes the mixing of fuel spray or fuel vapor and air in the combustion stroke (expansion stroke) and contributes to the reduction of the amount of soot generated. However, if the swirl is too strong, the penetration of the fuel spray becomes small, which is disadvantageous for the reburning of soot using the vertical vortex caused by the expansion flow of the combustion gas. Therefore, the momentum ratio is set to 0.9 to 1.5 in order to effectively use the swirl to reduce the generation amount of the soot in a range that does not adversely affect the generation of the vertical vortex. The momentum ratio is more preferably 1.1 to 1.3.
[0052]
  -Combustion concept-
  2A to 2C show the combustion concept of the present invention.
[0053]
  As shown in the state of the ignition delay period in FIG. 3A, a vertical vortex (flow from the lip portion 11 of the cavity 8 to the lip portion 13 through the recessed portion 12, the deepest portion, and the convex portion 13) is formed in the cavity 8. When substantially not generated, fuel is injected from the fuel injection valve 9 toward the lip portion 11 of the piston 1. During this fuel ignition delay period, the fuel spray 15 reaches the lip portion 11 to form a region of the fuel vapor 16 near the lip portion 11, and the fuel vapor 16 is ignited in front of the fuel injection direction. The ignition point is indicated by an asterisk (*) in FIG.
[0054]
  In this case, the region of the fuel vapor 16 can be formed in the vicinity of the lip portion 11 by increasing the spray penetration. This is advantageous in that the fuel vapor 16 is guided in a large amount toward the recessed portion 12 by the expansion flow described below. Further, increasing the cone angle Θ (Θ = 153 to 157 degrees) is advantageous in forming the region of the fuel vapor 16 in the vicinity of the lip portion 11.
[0055]
  As shown in FIG. 2B, the fuel vapor 16 in front of the ignition position is applied to the lip portion 11 by the expansion flow of the combustion gas 17 caused by the ignition. Thereby, the fuel vapor 16 is guided from the lip portion 11 to the recessed portion 12 and further toward the bottom of the cavity 8 to generate a vertical vortex.
[0056]
  In this case, when the spray penetration is increased, the expansion flow forward in the injection direction is increased, which is advantageous for promoting the vertical vortex. A smaller lip diameter Dlip is advantageous in directing the fuel vapor toward the cavity bottom by strongly applying the expansion flow to the cavity peripheral wall surface. However, if the lip diameter Dlip is too small, the maximum output of the engine is lowered. Therefore, the lip diameter Dlip is preferably larger than ½ of the bore diameter B.
[0057]
  As shown in FIG. 5C, the convex portion 13 at the center of the cavity promotes the winding of the combustion gas 17 from the deepest part of the cavity bottom along the rising surface of the convex portion 13 as shown in FIG. .
[0058]
  As described above, the maximum temperature portion in the cavity 8 is shifted from the lip portion 11 to the bottom side of the cavity 8 until the end of fuel injection. Therefore, the heat spot does not become large at a specific part in the cavity, and the disappearance of the heat spot is accelerated, so that NOx can be reduced. In addition, mixing of the combustion gas 17 and oxygen remaining above the center of the cavity progresses due to the above-described hoisting in the later stage of combustion, and further, the combustion gas 17 flows into the squish area, so that the air utilization rate increases, and the combustion gas 17 Soot reburning is promoted and soot emissions are reduced.
[0059]
  -Combustion simulation-
  Next, the simulation result of combustion will be described. That is, the cross-sectional fuel distribution, cross-sectional velocity vector, and cross-sectional temperature distribution of the combustion chamber shown by the piston 1, the cylinder block 2 and the cylinder head 3 are substantially injected through the center of the bore 18 as shown in FIG. It was determined by a cross section extending in the direction. In the figure, S is a swirl.
[0060]
  The calculation conditions are: engine speed: 2000 rpm, average effective pressure: 0.57 MPa, fuel injection valve 9: injection valve (1); injection nozzle diameter 0.15 mm × 6 injection valves (2); injection nozzle diameter 0.17 mm × Six, injection pressure: 80 MPa, injection timing: ATDC 2 °, no EGR. The spray valve (1) has a spray angle θ = 22 degrees, the spray valve (2) has a spray angle θ = 30 degrees, and the cone angle Θ is 154 degrees.
[0061]
  4 to 10 show the results of numerical calculation. In each figure, the result of the injection valve (1) is shown on the upper side, and the result of the injection valve (2) is shown on the lower side. In the cross-sectional fuel distribution in each figure, the region of the fuel vapor is surrounded by a two-dot chain line. In the cross-sectional temperature distribution of each figure, the temperature distribution is represented by an isothermal line, and the temperature increases toward the inner side.
[0062]
  In the ATDC 6 ° shown in FIG. 4, the injection angle 22 degrees and the injection angle 30 degrees are different in that the former has a lower fuel spray dispersion corresponding to the difference in the injection angle. On the other hand, there is no difference between the two in terms of velocity distribution, and there are almost no vertical vortices.
[0063]
  At ATDC 8 ° shown in FIG. 5, the fuel spray hits the lip portion 11 at both the spray angles of 22 ° and 30 °, and a fuel vapor region is formed in the vicinity of the lip portion 11. Subsequently, an expanded flow of combustion gas is generated by ignition, and fuel vapor in front of the combustion gas is blown off to the cavity peripheral wall surface, particularly the boundary portion between the lip portion 11 and the recessed portion 12.
[0064]
  Comparing the spray angle between 22 degrees and 30 degrees, the fuel vapor spreads better toward the recessed portion 12 in the former than in the latter. This is because, as is clear from the cross-sectional velocity distribution, the former has a stronger expansion flow toward the boundary portion or the recessed portion 12 than the latter. In both cases, the temperature of the ignition point is high.
[0065]
  At ATDC 10 ° shown in FIG. 6, at the spray angle of 22 degrees, the expansion flow is strong, so that part of the fuel vapor is blown off from the lip portion 11 toward the recessed portion 12 along the cavity peripheral wall surface. When the spray angle is 30 degrees, the fuel vapor blown off into the recessed portion 12 is smaller than when the spray angle is 22 degrees.
[0066]
  For this reason, in the former (spray angle of 22 degrees), the flame grows greatly from the lip portion 11 toward the recessed portion 12 by the fuel vapor blown off to the recessed portion 12, and the combustion gas is generated as shown in the cross-sectional velocity distribution. The expansion flow is further circulated from the recessed portion 12 to the deepest portion of the cavity bottom. And also in cross-sectional temperature distribution, the heat spot H more than predetermined temperature is extended toward the deepest part of a cavity bottom. On the other hand, in the latter (spray angle 30 degrees), the wraparound of the expansion flow of the combustion gas is weaker than that in the former, and therefore, the heat spot H extends less toward the cavity bottom.
[0067]
  At ATDC 12 ° shown in FIG. 7, when the spray angle is 22 degrees, the fuel vapor further spreads to the deepest part of the bottom of the cavity, and the expansion of the expansion flow of the combustion gas is further strengthened, so that the vertical vortex grows. As a result, the heat spot H near the lip portion 11 is reduced, and another heat spot H appears at the bottom of the cavity. On the other hand, when the spray angle is 30 degrees, the fuel vapor is less spread to the bottom of the cavity and the expansion flow of the combustion gas is less circulated than when the spray angle is 22 degrees. Further, the heat spot H in the vicinity of the lip portion 11 is not yet reduced.
[0068]
  At ATDC 14 ° shown in FIG. 8, when the spray angle is 22 degrees, most of the fuel vapor moves to the deepest part of the bottom of the cavity, and then burns along the convex part toward the center of the opening of the cavity 8. The expansion flow of the gas becomes larger and the vertical vortex grows. And the heat spot H near the lip part 11 has almost disappeared. That is, the highest temperature portion in the cavity 8 is completely shifted to the bottom side of the cavity 8 from the lip portion 11. On the other hand, when the spray angle is 30 degrees, the fuel vapor is less spread to the bottom of the cavity and the expansion flow of the combustion gas is less circulated than when the spray angle is 22 degrees. Further, although the heat spot H appears at the bottom of the cavity 8, the heat spot H near the lip portion 11 has not yet disappeared.
[0069]
  At ATDC 16 ° shown in FIG. 9, the fuel injection is completed, and at the spray angle of 22 degrees, the position of the fuel vapor moves toward the convex portion 13 and the amount of the fuel vapor is also reduced. Further, along with the movement of the fuel vapor, the expansion flow of the combustion gas rolls up along the peripheral wall surface of the convex portion 13, and the heat spot H moves closer to the convex portion 13. On the other hand, when the spray angle is 30 degrees, the movement of the fuel vapor toward the convex portion 13 is less and the expansion of the expansion flow of the combustion gas is less than when the spray angle is 22 degrees. Further, the heat spot H near the lip portion 11 has not yet disappeared.
[0070]
  At ATDC 18 ° shown in FIG. 10, at a spray angle of 22 degrees, the amount of fuel vapor is small and the vertical vortex is weak, but from the bottom of the cavity 8 to the opening of the cavity 8 and further to the squish area. There is a flow. The heat spot H at the bottom of the cavity 8 has almost disappeared. On the other hand, when the spray angle is 30 degrees, a relatively large amount of fuel vapor remains at the bottom of the cavity 8, and the heat spots H near the lip 11 and at the bottom of the cavity 8 have not yet disappeared.
[0071]
  As described above, when the spray angle is 22 degrees, the expansion flow of the combustion gas at the initial stage of combustion is larger than that when the spray angle is 30 degrees, and the fuel vapor near the lip portion 11 is strongly pressed against the peripheral wall surface of the cavity and the recessed portion 12. It is carried to. For this reason, the expansion flow of the combustion gas grows from the lip portion 11 to the cavity bottom through the recessed portion 12, and the heat spot H appears near the cavity bottom, and the heat spot H near the lip portion 11 disappears relatively quickly. ing. Further, the heat spot H near the cavity bottom disappears relatively quickly due to the promotion of the vertical vortex by the expansion flow. From this, it can be seen that the amount of NO generated is smaller at a spray angle of 22 degrees than when the spray angle is 30 degrees.
[0072]
  Further, at the spray angle of 22 degrees, the combustion gas is wound up along the convex portion 13 by the strong vertical vortex described above, and the contact with the air in the center of the cavity 8 is promoted, and further, the contact with the air in the squish area is prevented. Has been promoted. From this, it is understood that the soot discharge amount decreases because the soot reburns in the combustion gas proceeds.
[0073]
  -Relationship between nozzle nozzle diameter, injection angle θ and penetration-
  For a fuel injection valve (1) having a nozzle nozzle diameter of 0.15 mm and a fuel injection valve (2) having a nozzle diameter of 0.17 mm, a constant vessel experiment (injection pressure 70 MPa, atmospheric pressure 2.5 MPa, atmospheric temperature 293 K) ), The spray angle θ and the spray reach distance (penetration) Sp were examined. The result about the spray angle θ is shown in FIG. 11, and the result about the spray reach distance Sp is shown in FIG. In FIGS. 11, 12, and 15, “(1)” of the injection valve (1) and “(2)” of the injection valve (2) are indicated by circle numbers.
[0074]
  As shown in FIG. 11, the spray angle θ hardly changes with the passage of time. In the injection valve (1) having a nozzle diameter of 0.15 mm, the spray angle θ is about 22 degrees, and the injection valve having a nozzle diameter of 0.17 mm. In (2), the spray angle θ is about 30 degrees. As shown in FIG. 12, the spray reach distance Sp in the ignition delay period of 0.42 ms is 27 mm for the injection valve (1) having a nozzle diameter of 0.15 mm, and 21 mm for the injection valve (2) having a nozzle diameter of 0.17 mm. became.
[0075]
  -About k value-
  Next, the influence of the k value on the NO generation amount will be described.
[0076]
  That is, as apparent from the equation (1), the magnitude of the k value is reflected as the magnitude of the lip diameter Dlip, and if the reach distance Sp is constant, the strength of the vertical vortex is affected. Therefore, the amount of NO produced when the k value was changed was examined. The result is shown in FIG.
[0077]
  In the figure, the data of k = 1.9 is of a PAN (flat pot) type with a reentrant rate R = 1 and no convex portion 13 at the center of the cavity. The reentrant rate R is a Dlip / Dmax value when the maximum inner diameter of the cavity 8 is Dmax. The data of k = 1.73 is of a reentrant type having a reentrant ratio R = 1.73 / 1.9 and a convex portion 13 at the center of the cavity. Each data of k = 1.65 and k = 1.54 is reentrant in which the recessed amount Re (see FIG. 2B) of the recessed portion 12 from the lip portion 11 is the same as that of k = 1.73. Of the type.
[0078]
  According to the figure, the NO generation amount decreases as the k value decreases. This is because when the lip diameter is reduced, the expansion flow of the combustion gas at the initial stage of the combustion strongly acts on the peripheral wall surface of the cavity, the vertical vortex is promoted, and the distance between the recessed portion 12 and the projected portion 13 is reduced. This is because a vertical vortex is easily generated. However, if the k value becomes too small, the core of the fuel spray collides with the lip portion 11 to worsen the combustion (power reduction), and the amount of soot increases even if the amount of NO generated decreases. Therefore, in order to reduce the production amount of NO while suppressing the decrease in output and the generation of soot, the k value is preferably set to 1.4 to 1.8, more preferably 1.5 to 1.7.
[0079]
  -Effect of swirl / fuel spray momentum ratio on soot emissions-
  The ratio of the swirl momentum to the fuel spray momentum in the lip portion 11 of the cavity 8 was varied to examine the amount of soot discharged. The measurement was carried out using a cone angle of 154 degrees, a lip diameter of 43.4 mm, a bore diameter of 86 mm, a nozzle nozzle diameter of 0.15 mm (injection valve (1): spray angle of 22 degrees), an average effective pressure of 0.3 MPa at an engine speed of 1500 rpm, The test was carried out for each of an engine speed of 2000 rpm and an average effective pressure of 0.57 MPa, and an engine speed of 2500 rpm and an average effective pressure of 0.9 MPa. The results are shown in FIG.
[0080]
  According to the figure, although there is some variation, both the cases where the momentum ratio becomes smaller and larger with the momentum ratio of about 1.2 as the center point, as indicated by the trend line in the figure. The soot discharge is increasing. The reason why the soot discharge amount increases as the momentum ratio decreases is that the fuel and air cannot be sufficiently mixed by the swirl and the amount of soot generation increases. The amount of soot discharge increases as the momentum ratio increases because the swirl makes it difficult to generate the vertical vortex described above, and soot recombustion (oxidation) in the combustion gas does not proceed.
[0081]
  Therefore, it can be seen from the same figure that if the momentum ratio is within a predetermined range centered at 1.2, the recombustion of the soot can be promoted by the vertical vortex while the soot generation is suppressed by the swirl, for example, It can be said that it is preferably about 0.9 to 1.5, and more preferably about 1.1 to 1.3.
[0082]
  -Effects of spray angle θ and EGR rate on NOx emissions and soot emissions-
  At a cone angle of 154 degrees, a lip diameter of 43.4 mm, a bore diameter of 86 mm, an engine speed of 2000 rpm, and an average effective pressure of 0.57 MPa, an injection valve (1) (injection diameter of 0.15 mm, spray angle of 22 degrees) and an injection valve (2 ) (Nozzle diameter 0.17 mm, spray angle 30 degrees), respectively, by changing the EGR rate (the ratio of the exhaust amount recirculated from the engine exhaust system to the intake system (EGR amount) with respect to the total intake amount) The amount and soot discharge were measured. The results are shown in FIG.
[0083]
  According to the figure, when the injection valve (1) having a nozzle diameter of 0.15 mm and a spray angle of 22 degrees is used, NOx emission is smaller than when the injection valve (2) having a nozzle diameter of 0.17 mm and a spray angle of 30 degrees is used. It can be seen that when both the amount and the soot discharge amount are decreased, however, when the EGR rate is increased, the NOx reduction effect by reducing the spray angle θ is not obtained so much.
[0084]
  -Effects of pilot injection on NOx emissions-
  How is NOx emission affected by the presence or absence of pilot injection under the operating conditions of cone angle 154 degrees, lip diameter 43.4 mm, bore diameter 86 mm, engine speed 2500 rpm, average effective pressure 0.9 MPa and EGR? We investigated whether it was a real machine bench test. As a result, it was found that with the pilot injection, the NOx emission reduction effect utilizing the expanded flow of the combustion gas described above is halved compared with the case without pilot injection.
[0085]
  Examining this point, the ignition delay period of the main injection fuel was 7 degrees in crank angle without pilot injection, but the ignition delay period was 4 degrees with pilot injection. Therefore, with pilot injection, the ignition delay period of the main injected fuel is shorter than with no pilot injection, so the area of fuel vapor that can be formed near the lip portion 11 before ignition becomes smaller, and moreover, due to early ignition. It can be said that the ignition position is far from the lip portion 11. For this reason, with pilot injection, the expansion flow of the combustion gas does not act efficiently on the fuel vapor, resulting in insufficient generation and strengthening of the vertical vortex, and the NOx emission reduction effect is halved compared to without pilot injection. It is what.
[0086]
  −Measures to reduce the effect of longitudinal vortex effect during pilot injection−
  The problem that the effect of reducing the NOx emission amount during pilot injection is halved can be countered by controlling pilot injection. That is, the fuel injection valve 9 mainly injects fuel near the top dead center of the compression stroke so as to go to the lip portion 11 forming the cavity opening edge of the piston 1, and the fuel injection valve 9 Pilot injection execution means for performing pilot injection of fuel prior to injection, and pilot combustion suppression means for suppressing combustion by the pilot injection when the engine load is equal to or greater than a predetermined value than when the engine load is less than the predetermined value. It is to provide.
[0087]
  FIG. 16 shows the flow of fuel injection control. In step S1 after the start, data such as the engine speed and the accelerator opening necessary for fuel injection control are input. In the subsequent step S2, the basic fuel injection amount Qb is calculated and set from the fuel injection amount map based on the engine speed, the accelerator opening, etc., and the basic injection timing (main injection start time) Ib is calculated from the basic injection timing map. Is calculated and set. The fuel injection amount map is created so that the basic injection amount Qb increases as the accelerator opening increases and as the engine speed increases. The injection timing map defines the optimal injection timing corresponding to the engine water temperature and the engine speed. For example, if the engine water temperature and the engine speed are different, the ignition delay period is different. A proper injection timing Ib is set.
[0088]
  In the subsequent step S3, the main injection amount Qm and the pilot injection amount Qp are calculated and set from the map relating to the pilot injection ratio based on the engine speed and the accelerator opening, and the pilot injection start timing Ip is set from the map relating to the pilot injection timing. Calculate and set.
[0089]
  The map related to the pilot injection ratio defines an optimal ratio (Qp / Qb) of the pilot injection amount Qp corresponding to the engine speed and the accelerator opening. This ratio is set to be smaller in a high load region where the engine load is a predetermined value or more than in a low load region where the engine load is less than a predetermined value.
[0090]
  That is, as shown in FIG. 17, the basic injection amount Qb and the pilot injection amount Qp in the low engine speed range, the basic injection amount Qb increases as the engine load increases, but the pilot injection amount Qp is low. In the load region, the engine load increases slightly as the engine load increases, but gradually decreases as shown by the solid line when the engine load becomes a high load that exceeds a predetermined value. In this high load region, the pilot injection amount Qp may be reduced as a whole as compared with the low load region as indicated by a chain line. The pilot injection amount Qp can be made smaller in the middle engine speed range or in the high speed range than in the low speed range.
[0091]
  The map related to the pilot injection timing is an optimum time t from the pilot injection timing Ip to the main injection timing Qb corresponding to the engine speed and the accelerator opening. As shown in FIG. 18, when the engine speed is constant, the time t gradually increases as the engine load increases in a low load region where the engine load is less than a predetermined value. As shown, the rate of increase in time t accompanying the increase in engine load is determined to be greater than the rate of increase in the low load region.
[0092]
  In the engine low load region, the time t may be substantially constant regardless of the increase in engine load. Further, as indicated by a chain line in FIG. 18, the time t may be generally increased by a predetermined amount in the engine high load region than in the low load region. Further, as shown in FIG. 19, when the engine load is constant, the time t is increased as the engine speed increases.
[0093]
  Then, in step S4, based on the crank angle signal, pilot injection is executed at the injection amount Qp when the pilot injection timing Ip is reached, and main injection at the injection amount Qm is executed when the main injection timing is reached. Execute.
[0094]
  In the above configuration, the pilot combustion suppression means is configured by setting the ratio (Qp / Qb) of the pilot injection amount Qp to be smaller in the engine high load region than in the low load region.
[0095]
  Therefore, when pilot injection is performed, the temperature and pressure in the combustion chamber rise due to the combustion of the injected fuel, and the formation of a fire type increases the ignitability of the subsequent main injected fuel and shortens the ignition delay period. Become. For this reason, the premixed combustion of the main injection fuel is suppressed, the combustion noise is reduced, and the generation of NOx at the initial stage of combustion is suppressed.
[0096]
  However, the pilot combustion suppression means operates in a high load region where the engine load is a predetermined value or more, and combustion by the pilot injection is suppressed more than in the low load region. That is, in the engine high load region, the ratio of the pilot injection amount (Qp / Qb) is smaller than that in the low load region, so the amount of fuel injected and burned is reduced, and the temperature and pressure of the combustion chamber are greatly increased. And the number of flame nuclei for ignition of the main injection fuel is reduced.
[0097]
  For this reason, it is difficult for the ignition of the main injection fuel to be induced and the ignition delay period of the main injection fuel is prevented from being excessively shortened, and an intended fuel vapor region can be formed near the lip before ignition. it can. As a result, the expansion of the heat spot using the above-described expansion flow of the combustion gas can be prevented and the disappearance can be achieved quickly, which is advantageous in reducing NOx.
[0098]
  Further, when the time t from the start of pilot injection to the start of main injection is made longer in the engine high load region than in the low load region, the pilot injection timing is thereby advanced, so that the fuel injected by the pilot Is easily diffused in the combustion chamber to form a lean premixed gas. That is, the amount of fuel that burns by self-ignition decreases. Alternatively, even if the combustion is ignited, the combustion ends early and the number of fire types effective for igniting the main injection fuel decreases. For this reason, it is difficult to induce the ignition of the main injection fuel, and the ignition delay period of the main injection fuel is prevented from being excessively shortened, which is advantageous for the reduction of NOx using the expansion flow of the combustion gas.
[0099]
  In addition, when the pilot injection amount Qp and the pilot injection timing Ip are not changed suddenly at the boundary between the engine low load region and the high load region (characteristics shown by solid lines in FIGS. 17 and 18), the engine load is in the low load region. Even if the vehicle shifts from the high load region to the high load region, the effect of pilot injection is suddenly reduced, that is, the combustion noise does not suddenly increase, and the passenger does not feel uncomfortable.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a structure of a diesel engine according to an embodiment of the present invention.
FIG. 2 is an explanatory view (sectional view) showing a combustion concept of the present invention.
3 is a plan view of a combustion chamber displaying cross-sectional positions in FIGS. 4 to 10. FIG.
FIG. 4 is a view showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution in a combustion chamber at ATDC 6 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 5 is a diagram showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution in a combustion chamber at ATDC 8 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 6 is a diagram showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution in a combustion chamber at ATDC 10 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 7 is a diagram showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution in a combustion chamber at ATDC 12 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 8 is a diagram showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution in a combustion chamber at ATDC 14 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 9 is a view showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution of the combustion chamber at ATDC 16 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 10 is a diagram showing a cross-sectional fuel distribution, a cross-sectional velocity vector, and a cross-sectional temperature distribution in the combustion chamber at ATDC 18 ° obtained by simulation for spray angles of 22 ° and 30 °.
FIG. 11 is a graph showing the relationship between the nozzle diameter and the spray angle θ.
FIG. 12 is a graph showing the relationship between the nozzle diameter and the spray reach distance (penetration) Sp.
FIG. 13 is a graph showing the relationship between k value and NO generation amount.
FIG. 14 is a graph showing the amount of soot discharged when the ratio of the momentum of the swirl to the momentum of the fuel spray is variously changed.
FIG. 15 is a graph showing the relationship between the spray angle θ and the EGR rate, the NOx emission amount, and the soot emission amount.
FIG. 16 is a flowchart of fuel injection control.
FIG. 17 is a graph showing the relationship between engine load, basic injection amount Qb, and pilot injection amount Qp.
FIG. 18 is a graph showing the relationship between engine load, main injection timing, and pilot injection timing.
FIG. 19 is a graph showing the relationship between engine speed, main injection timing, and pilot injection timing.
[Explanation of symbols]
    1 piston
    2 Cylinder block
    3 Cylinder head
    4 Intake port (helical port)
    5 Exhaust port
    8 cavities
    9 Fuel injection valve
  10 Injection nozzle
  11 Lip part
  12 Recessed part
  13 Convex
  15 Fuel spray
  16 Fuel vapor
  17 Combustion gas

Claims (5)

A piston formed with a reentrant-type cavity whose diameter decreases as it approaches the open end at the top;
A fuel injection valve;
A main injection execution means for main-injecting fuel near the top dead center of the compression stroke so as to go to the lip portion forming the opening edge of the cavity of the piston by the fuel injection valve;
Due to the main injection, a region of fuel vapor is formed in the vicinity of the lip portion during the ignition delay period of the main injection fuel, and the ignition is caused by the expansion flow of the combustion gas generated by the ignition in front of the fuel injection direction of the fuel injection valve. In the fuel injection device for a diesel engine, the fuel vapor in front of the position is applied to the peripheral wall surface of the cavity and guided toward the bottom of the cavity.
Pilot injection execution means for performing pilot injection of fuel prior to the main injection by the fuel injection valve;
In order to obtain an ignition delay period in which a region of fuel vapor is formed in the vicinity of the lip portion in the main injection fuel, when the engine load is equal to or greater than a predetermined value, combustion due to the pilot injection is less than when the engine load is less than the predetermined value. A fuel injection device for a diesel engine, comprising pilot combustion suppression means for suppressing the diesel combustion. The fuel injection device for a diesel engine according to claim 1,
The fuel spray reach Sp at the time when 0.42 ms has elapsed from the start of the main injection of the fuel injector, the cone angle Θ of the fuel spray of the fuel injector, and the minimum aperture Dlip at the lip of the cavity The following equation: Dlip = k × Sp × sin (Θ / 2)
(However, k = 1.4 to 1.8)
A fuel injection device for a diesel engine, which is set so as to satisfy a relationship satisfying The fuel injection device for a diesel engine according to claim 1 or 2,
The diesel engine is characterized in that the pilot combustion suppression means reduces the ratio of the pilot injection amount to the main injection amount of the fuel when the engine load is equal to or greater than a predetermined value than when the engine load is less than the predetermined value. Fuel injectors. The fuel injection device for a diesel engine according to claim 1 or 2,
In order to obtain an ignition delay period in which a region of fuel vapor is formed in the vicinity of the lip portion in the main injected fuel, when the engine load is equal to or greater than a predetermined value, the pilot injection starts from when the engine injection is less than the predetermined value. A fuel injection device for a diesel engine, characterized in that the time until the start of the main injection becomes longer. The fuel injection device for a diesel engine according to claim 4,
A fuel for a diesel engine characterized in that the time is increased by increasing the rate of increasing the time as the engine load increases so that the time is increased when the engine load is greater than or equal to a predetermined value than when the engine load is less than the predetermined value. Injection device.

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