JP4097056B2 - Fuel injection valve - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a fuel injection valve that injects fuel into an intake pipe or a combustion chamber of an internal combustion engine, and in particular, an electromagnetic equipped with an injection hole plate that promotes atomization of sprayed fuel that is injected near an intake valve of the internal combustion engine. Related to fuel injection valves.
[0002]
[Prior art]
Conventionally, an electromagnetic fuel injection valve (for example, Japanese Utility Model Laid-Open No. 2-1463) provided with a mechanism (orifice plate 106) that promotes atomization of sprayed fuel that is injected in the vicinity of an intake valve of an internal combustion engine such as a gasoline engine in a timely manner. Etc.) has been proposed.
[0003]
For example, as shown in FIGS. 10 and 11, such an electromagnetic fuel injection valve has a cylindrical shape having an opening 101 at the center of the tip and a valve seat 102 upstream of the opening 101. A valve body 103, a needle valve 104 that is slidably accommodated in the valve body 103, and interrupts fuel injection by contacting or separating from the valve seat 102, and a valve that closes the opening 101. An orifice plate 106 is provided on the front end surface of the body 103 and has a fuel passage 105 formed between the front end surface of the needle valve 104.
[0004]
The orifice plate 106 has a round hole shape so as to be inclined by a predetermined inclination angle A (°) in a direction returning upstream from the fuel flow direction of the fuel passage 105 from the fuel inlet to the fuel outlet. A nozzle hole (orifice) 107 is formed through. In such an electromagnetic fuel injection valve, the ratio between the plate thickness t (mm) of the orifice plate 106 and the nozzle hole diameter (φd) of the orifice 107 is within a specific range in order to maintain a certain atomization performance. It is desirable to set to.
[0005]
[Problems to be solved by the invention]
However, in the conventional electromagnetic fuel injection valve, the nozzle hole diameter of the orifice 107 is set according to the injection amount size, and the plate thickness of the orifice plate 106 is inevitably determined by the nozzle hole diameter. For this reason, depending on the injection amount size, the plate thickness of the orifice plate 106 becomes thinner than necessary. If the plate thickness of the orifice plate 106 becomes thinner than necessary, the orifice plate 106 is deformed by the fuel pressure applied to the tip of the electromagnetic fuel injection valve.
[0006]
That is, when the orifice plate 106 is deformed so as to swell downward in the figure due to the fuel pressure, the volume (internal volume) in the fuel passage (dead volume) 105 becomes very large, and when the electromagnetic fuel injection valve is closed, that is, the needle Even when the valve 104 is seated on the valve seat 102, if negative pressure is generated in the intake pipe, the fuel in the dead volume 105 whose volume has become very large is sucked out. Thereby, since fuel injection is performed more than the target value of fuel injection quantity, the problem that the injection quantity characteristic of an electromagnetic fuel injection valve will change arises.
[0007]
In addition, in the electromagnetic fuel injection valve having the round hole-shaped orifice 107, the diameter of the injection hole from the fuel inlet to the fuel outlet of the orifice plate 106 is the same, so the electromagnetic fuel injection valve is mounted on the intake manifold of the internal combustion engine. At this time, if foreign matter adheres to the vicinity of the fuel outlet of the orifice 107, the diameter of the nozzle hole of the fuel outlet of the orifice 107 is narrowed, causing a problem that the injection amount characteristic of the electromagnetic fuel injection valve changes.
[0008]
OBJECT OF THE INVENTION
In view of the above problems, the present invention can suppress the change in the injection amount characteristics by maintaining the strength of the plate with the injection holes even in any injection amount size without impairing the effect of promoting atomization of the atomized fuel. Another object of the present invention is to provide a fuel injection valve capable of suppressing a change in injection quantity characteristics even when foreign matter adheres to the vicinity of a fuel outlet of an injection hole.
[0009]
[Means for Solving the Problems]
According to the first aspect of the present invention, the nozzle hole with the nozzle hole that promotes atomization of the sprayed fuel is provided with the nozzle hole that is formed to be inclined and penetrated between the fuel inlet and the fuel outlet of the nozzle hole. A first nozzle hole provided on the fuel inlet side having a different shape and a second nozzle hole provided on the fuel outlet side are provided.
[0010]
Accordingly, even if the ratio between the thickness of the first nozzle hole and the nozzle diameter of the first nozzle hole is set within a specific range for the purpose of maintaining a certain atomization promoting performance, Since the plate thickness of the injection hole plate can be secured by an amount corresponding to the hole, the strength of the injection hole plate can be increased in the fuel injection valve of any injection amount size without impairing the effect of promoting atomization of the atomized fuel. Can keep. As a result, the plate thickness of the nozzle hole plate does not become unnecessarily thin, and conversely, the plate thickness of the nozzle hole plate can be increased. Therefore, the plate with the nozzle hole is formed by the fuel pressure applied to the tip of the fuel injection valve. Therefore, the change in the injection amount characteristic of the fuel injection valve can be suppressed.
[0011]
Further, the nozzle hole area of the second nozzle hole existing on the fuel outlet side of the nozzle hole is made larger than the nozzle hole area of the first nozzle hole existing on the fuel inlet side of the nozzle hole of the nozzle hole plate. The plate thickness of the nozzle hole plate can be increased without impairing the effect of promoting atomization of fuel. When the fuel injection valve is mounted on the internal combustion engine, even if foreign matter adheres to the vicinity of the fuel outlet of the injection hole of the plate with the injection hole and the injection hole diameter of the fuel outlet of the second injection hole is narrowed, the injection amount characteristic is obtained. The change in the injection hole diameter of the first injection hole concerned is not affected at all, so that the change in the injection amount characteristic of the fuel injection valve can be suppressed.
[0012]
Also, Claim 1 According to the invention, the first nozzle hole is a round nozzle hole, the second nozzle hole is a divergent nozzle hole, and the fuel injection valve is arranged with respect to the central axis of the first nozzle hole. The divergent angle of the second nozzle hole on the central axis side is B1 (°), and the divergent angle of the second nozzle hole on the side opposite to the central axis of the fuel injection valve is B2 (°) with respect to the central axis of the first nozzle hole. ), The divergent shape of the second nozzle hole is B1 ≧ B2> 0 with respect to the central axis of the first nozzle hole.
[0013]
Claim 2 According to the invention, the first nozzle hole is a divergent nozzle hole, the second nozzle hole is a divergent nozzle hole, and the center of the fuel injection valve with respect to the central axis of the first nozzle hole. The divergent angle of the second nozzle hole on the shaft side is B1 (°), and the divergent angle of the second nozzle hole on the side opposite to the central axis of the fuel injection valve with respect to the central axis of the first nozzle hole is B2 (°). When the angle of the first nozzle hole is C (°), the shape of the second nozzle hole is B1 ≧ B2> C / 2.
[0014]
Claim 3 According to the invention described in (1), the fuel passage through which the main flow of the fuel flows during fuel injection is formed between the upstream end face of the plate with nozzle holes and the tip face of the valve element. The injection hole of the injection hole plate includes an inner injection hole disposed on the central axis side of the fuel injection valve from a portion where the main flow of the fuel flow flowing in the fuel passage collides with the injection hole plate, The outer injection hole is disposed on the opposite side of the center axis of the fuel injection valve from the portion where the main flow of the fuel flow flowing through the nozzle collides with the plate with the injection holes.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described based on examples with reference to the drawings.
[Configuration of the first embodiment]
1 to 4 show a first embodiment of the present invention. FIG. 1 is a diagram showing the overall configuration of an electromagnetic fuel injection valve, and FIG. 2 shows the main configuration of the electromagnetic fuel injection valve. FIG.
[0016]
The electronically controlled fuel injection device of the present embodiment is composed of a fuel supply system, an intake system, a sensor that detects the operating state of the internal combustion engine, an electronic control unit (ECU) that integrally controls them, and the like. Among these, the fuel supply system pressurizes the fuel to a certain pressure by an electric fuel pump (not shown) and sends the fuel to the electromagnetic fuel injection valve 1 through a delivery pipe (not shown), and the optimum timing. This is a system that can inject fuel.
[0017]
The electromagnetic fuel injection valve 1 is a function (orifice plate) that promotes atomization of spray fuel that is injected in a timely manner near an intake valve (intake port) of an internal combustion engine (hereinafter referred to as an engine) such as a gasoline engine. ). The number of the electromagnetic fuel injection valves 1 according to the number of cylinders of the engine is assembled to an intake manifold (intake pipe) that supplies combustion air.
[0018]
The electromagnetic fuel injection valve 1 includes a housing mold 2 assembled to a delivery pipe, an electromagnetic coil (solenoid coil) 4 wound around the outer periphery of a resin coil bobbin 3 disposed in the housing mold 2, a housing A substantially cylindrical fixed iron core (stator) 5 fixed in the mold 2, a movable iron core (armature) 6 movable in the axial direction, a valve body 7 provided on the front end side of the housing mold 2, and the valve A needle valve 8 accommodated in the body 7 and an orifice plate 10 that forms a fuel passage 9 between one axial end surface (tip surface) of the needle valve 8 are configured.
[0019]
The housing mold 2 is integrally formed of a resin material. Inside the housing mold 2, a coil bobbin 3, a fixed iron core 5, and an external connection terminal (terminal) 11 are integrally formed. A resin mold 35 surrounding the electromagnetic coil 4 is integrally formed on the outer periphery of the coil bobbin 3 and the electromagnetic coil 4.
[0020]
A connector portion 12 is provided above the housing mold 2 so as to protrude from the outer wall of the housing mold 2. The external connection terminal 11 that is electrically connected to the electromagnetic coil 4 is embedded in the connector portion 12 and the resin mold 36. The external connection terminal 11 is connected to an ECU (not shown) via a wire harness.
[0021]
The fixed iron core 5 is made of a ferromagnetic material and is provided in the resin housing mold 2 so as to protrude upward from the upper end surface of the housing mold 2 in the figure. An axial fuel passage 13 is formed in the fixed iron core 5. A substantially cylindrical adjusting pipe 15 having an axial hole 14 therein is provided on the inner peripheral surface of the fixed iron core 5.
[0022]
The adjusting pipe 15 sets the set load (valve opening pressure) of the coil spring 16 by displacing the inside of the fixed core 5 in the axial direction. After the setting, the adjusting pipe 15 is fixed to the inner peripheral surface of the fixed core 5. The Then, one end of the coil spring 16 is in contact with the tip surface of the adjusting pipe 15. The other end of the coil spring 16 is in contact with the upper end surface of the needle valve 8 shown in FIG.
[0023]
The coil spring 16 urges the movable iron core 6 and the needle valve 8 downward in the figure to seat the seat portion 22 of the needle valve 8 on the valve seat 21 of the valve body 7 (see FIG. 2). When an excitation current flows from the external connection terminal 11 to the electromagnetic coil 4 by the ECU, the movable iron core 6 and the needle valve 8 are attracted toward the fixed iron core 5 against the urging force (spring force) of the coil spring 16. .
[0024]
A nonmagnetic pipe 17 and a magnetic pipe 18 are disposed on one side of the fixed iron core 5 in the axial direction. The nonmagnetic pipe 17 is made of a nonmagnetic material and has a substantially cylindrical shape. The nonmagnetic pipe 17 is connected to the lower end of the fixed iron core 5 in the figure. The magnetic pipe 18 is made of a magnetic material and is formed in a stepped pipe shape. The magnetic pipe 18 is connected to the lower end of the nonmagnetic pipe 17 in the figure. In the internal space of these nonmagnetic pipe 17 and magnetic pipe 18, a movable iron core 6 made of a magnetic material and formed in a cylindrical shape is provided.
[0025]
The valve body 7 is inserted into the magnetic pipe 18 via a hollow disk-shaped spacer 19 and laser-welded. The thickness of the spacer 19 is adjusted so as to keep the air gap between the fixed iron core 5 and the movable iron core 6 at a predetermined value. Here, an electromagnetic actuator is constituted by the housing mold 2, the electromagnetic coil 4, the fixed iron core 5, the movable iron core 6, the non-magnetic pipe 17, the magnetic pipe 18, and the like.
[0026]
Next, the structure of the valve body 7 and the needle valve 8 of the present embodiment will be briefly described with reference to FIGS. These valve body 7 and needle valve 8 are formed in a predetermined shape by a metal material such as SUS. A gap through which fuel passes is formed between the cylindrical surface 23 of the valve body 7 and the four chamfered portion formed in the sliding portion 24 of the needle valve 8. A valve portion is configured by the valve seat 21 of the valve body 7 and the seat portion 22 at the tip of the needle valve 8.
[0027]
The needle valve 8 corresponds to the valve body of the present invention, and has a joint 25 formed in the upper part of the figure. The joint 25 and the movable iron core 6 are laser-welded, so that the movable iron core 6 and the needle valve 8 are integrally connected. A chamfer as a fuel passage is provided on the outer periphery of the joint portion 25. Further, when the movable iron core 6 is attracted to the fixed iron core 5 by generating a magnetomotive force in the electromagnetic coil 4, the needle valve 8 is lifted until the flange portion 26 comes into contact with the spacer 19. Here, the valve body of the electromagnetic fuel injection valve 1 is constituted by the valve body 7 and the orifice plate 10, and the valve body of the electromagnetic fuel injection valve 1 is constituted by the needle valve 8.
[0028]
On the other hand, a filter 37 is mounted above the fuel passage 13 formed in the fixed iron core 5 in the figure. The filter 37 is a foreign matter removing unit that removes foreign matter such as dust in the fuel that is pumped from the fuel tank by a fuel pump or the like and flows into the electromagnetic fuel injection valve 1.
[0029]
Next, the structure of the orifice plate 10 of this embodiment will be briefly described with reference to FIGS. Here, FIG. 3 is a view showing the passage wall surface of the orifice plate 10, and FIG. 4 is an enlarged view of the orifice of the orifice plate 10.
[0030]
The orifice plate 10 corresponds to the injection hole plate of the present invention, and the tip of the valve body 7 is closed so as to close the round hole-shaped opening 29 formed in the lower end surface (tip surface) of the valve body 7 in the figure. The surface is fixed by laser welding. The orifice plate 10 is made of a metal material such as SUS, and has a plate thickness of a sum of a first plate thickness t1 (mm) and a second plate thickness t2 (mm). The orifice plate 10 is formed with a plurality of orifices (small holes) 30 that control the direction of the atomized fuel and promote atomization of the atomized fuel.
[0031]
These orifices 30 correspond to the injection holes of the present invention and are opened by, for example, electric discharge machining or drilling, and upstream from the fuel inlet to the fuel outlet in the fuel flow direction of the fuel passage 9. The orifice plate 10 is formed so as to be inclined by a predetermined inclination angle A (°) in a direction returning to the side.
[0032]
Further, four orifices 30 are arranged on a single circle imaginary line centering on the central axis of the electromagnetic fuel injection valve 1 (center point of the orifice plate 10). The plurality of orifices 30 are first injection holes provided on the fuel passage 9 (fuel inlet) side formed between the distal end surface of the needle valve 8 and the upstream end surface of the orifice plate 10 in the valve body 7. 31 and a second nozzle hole 32 having a divergent shape provided closer to the intake passage (fuel outlet) than the first nozzle hole 31 is formed in the intake pipe.
[0033]
The first injection hole 31 is a circular injection hole having a predetermined injection hole diameter (φd), and is formed through the depth corresponding to the first plate thickness (t1) of the orifice plate 10. The nozzle hole area from the fuel inlet to the fuel outlet is S1 (mm ² ). The first injection hole 31 is inclined by a predetermined inclination angle (for example, 0 ° <A ° <90 °) with respect to the center line (axis) direction of the electromagnetic fuel injection valve 1, that is, the thickness direction of the orifice plate 10. Is formed.
[0034]
The second nozzle hole 32 is a nozzle hole having a divergent shape, and is formed to penetrate through a depth corresponding to the second plate thickness (t2) of the orifice plate 10. The area of the nozzle hole at the fuel outlet is first. S2 (mm) wider than the nozzle hole 31 ² ). The second injection hole 32 has a divergent angle B1 (°) on the central axis side of the electromagnetic fuel injection valve 1 with respect to the central axis of the first injection hole 31, and the central axis of the first injection hole 31. On the other hand, the end spread angle on the opposite side to the central axis of the electromagnetic fuel injection valve 1 is B2 (°).
[0035]
The hole wall surface of the second injection hole 32 on the central axis side of the electromagnetic fuel injection valve 1 with respect to the central axis of the first injection hole 31 has a curvature with the central axis of the electromagnetic fuel injection valve 1 as the center of curvature. A second portion of the second injection on the opposite side of the central axis of the electromagnetic fuel injection valve 1 with respect to the central axis of the first injection hole 31 is a circular portion (for example, an elliptical shape, an elliptical shape or a circular semicircular arc surface). The hole wall surface of the hole 32 faces in a direction opposite to the hole wall surface of the second injection hole 32 on the central axis side of the electromagnetic fuel injection valve 1 and has a curvature circle with the center axis of the electromagnetic fuel injection valve 1 as the center of curvature. (For example, an elliptical shape, an oval shape, or a circular semicircular arc surface).
[0036]
Therefore, the orifice plate 10 of the present embodiment has a round hole-shaped first injection hole 31 having the same shape as the normal injection hole from the upstream end (fuel inlet) of the orifice 30 to the position of the depth (plate thickness) t1. The ratio of the plate thickness to the nozzle hole diameter (t1 / φd) determines the spray shape and the characteristics that promote atomization of the sprayed fuel. The injection size (fuel flow rate) characteristic is also determined by the ratio (t1 / φd) of the nozzle hole diameter (φd), the plate thickness, and the nozzle hole diameter.
[0037]
The region (second injection hole 32) from the position of the depth (plate thickness) t1 of the orifice plate 10 to the position of the downstream end (fuel outlet) of the orifice 30, that is, the position of the depth (plate thickness) t2. In order to make the nozzle hole area (S2) at the fuel outlet of the second nozzle hole 32 larger than the nozzle hole area (S1) from the fuel inlet to the fuel outlet of the first nozzle hole 31 up to the plate thickness (t1), A tapered shape (a divergent shape) in which the opening area is gradually expanded by smoothly connecting to the first nozzle hole 31 is assumed. At this time, the divergent shape of the second injection hole 32 is a shape that satisfies the relationship of B1>A>B2> 0 with respect to the central axis of the first injection hole 31.
[0038]
[Operation of the first embodiment]
Next, the operation of the electromagnetic fuel injection valve 1 of this embodiment will be briefly described with reference to FIGS.
[0039]
When the electromagnetic coil 4 of the electromagnetic fuel injection valve 1 is energized by the ECU, the movable iron core 6 is attracted to the fixed iron core 5 against the urging force of the coil spring 16, and the joint 25 is laser welded to the movable iron core 6. The needle valve 8 is lifted until the flange portion 26 abuts against the spacer 19. Then, the valve part which consists of the valve seat 21 of the valve body 7 and the seat part 22 of the needle valve 8 is opened.
[0040]
As a result, the fuel that has been pressurized to a certain pressure by the fuel pump and passed through the filter 37 into the fuel passage 13 formed in the fixed core 5 of the electromagnetic fuel injection valve 1 through the delivery pipe is supplied to the adjusting pipe 15. It passes through a gap between the axial hole 14 formed therein and the two chamfered portion formed in the joint portion 25 of the needle valve 8, and further, the cylindrical surface 23 of the valve body 7 and the sliding portion 24 of the needle valve 8. It passes through the gap between the four chamfered portions formed on the inner surface of the valve body 7 and reaches the fuel passage 9 from between the valve seat 21 of the valve body 7 and the seat portion 22 of the needle valve 8.
[0041]
The main flow of the fuel that has passed between the valve seat 21 and the seat portion 22 collides with the passage wall surface of the orifice plate 10 in the fuel passage 9 so as to follow the passage wall surface of the orifice plate 10, and electromagnetically. The flow is directed toward the central axis side of the fuel injection valve 1. The first injection hole 31 constitutes a circular injection hole having a predetermined injection hole diameter (φd) inclined by a predetermined inclination angle (A °) with respect to the plate thickness direction. The flow of the main flow of the fuel flowing into the fuel inlet of the first nozzle hole 31 does not form a vortex around the fuel inlet of the first nozzle hole 31 and moves from the inside of the fuel passage 9 toward the center of the first nozzle hole 31. It flows in while turning.
[0042]
In addition, the strength of the flow that flows into the fuel inlet of the first injection hole 31 by making a U-turn by the opposed flow at the center of the orifice plate 10 and the flow that goes directly from the outer peripheral portion of the orifice plate 10 to the fuel inlet of the first injection hole 31. Difference between the first and second intensities can be reduced (isotropic flow), and the fuel can be evenly collided at the center of the fuel inlet of the first injection hole 31. As a result, the internal energy of the fuel can be efficiently used in the form of turbulence due to collision between flows, and extremely ideal atomization can be realized.
[0043]
The atomized fuel thus efficiently atomized flows from the fuel outlet of the first injection hole 31 to the fuel inlet of the second injection hole 32, and the second injection hole 32 forms a divergent injection hole. Therefore, without passing through the fuel inlet of the second injection hole 32, the effect of atomization of the atomized fuel is not reduced, and the fuel outlet of the second injection hole 32 is close to the intake valve of the engine (intake port). It is injected with good timing.
[0044]
[Effects of the first embodiment]
As described above, the electromagnetic fuel injection valve 1 of the present embodiment is a plate for the first injection holes 31 of the plurality of orifices 30 provided in the orifice plate 10 for the purpose of maintaining a certain atomization promoting performance. Even when the ratio of the thickness (t1) and the nozzle hole diameter (φd) of the first nozzle hole 31 is set within a certain range, the end-divided second nozzle hole 32 connected to the downstream side of the first nozzle hole 31 Therefore, the total plate thickness of the orifice plate 10 can be increased by an extra amount, that is, by the plate thickness (t2), and the entire plate thickness of the orifice plate 10 can be ensured by the required strength.
[0045]
Therefore, the strength of the orifice plate 10 can be maintained at a required level or more in the electromagnetic fuel injection valve 1 of any injection amount size without impairing the effect of promoting atomization of the atomized fuel. As a result, the total plate thickness of the orifice plate 10 does not become unnecessarily thin, and conversely, the total plate thickness of the orifice plate 10 can be excessively increased by the plate thickness (t2). Therefore, the electromagnetic fuel injection valve 1 Since the orifice plate 10 is not greatly deformed by the fuel pressure applied to the tip of the fuel, the change in the injection amount characteristic of the electromagnetic fuel injection valve 1 can be suppressed.
[0046]
Further, in the orifice 30 of the orifice plate 10, the injection of the second injection hole 32 existing on the intake passage (fuel outlet) side of the injection hole area (S1) of the first injection hole 31 existing on the fuel passage 9 (fuel inlet) side. By increasing the hole area (S2), the entire plate thickness of the orifice plate 10 can be increased by an amount equivalent to the plate thickness (t2) without impairing the performance of promoting atomization of the atomized fuel.
[0047]
When the electromagnetic fuel injection valve 1 is mounted on the engine, foreign matter adheres to the vicinity of the fuel outlet of the second injection hole 32 of the orifice 30 of the orifice plate 10 and the injection hole diameter of the fuel outlet of the second injection hole 32 becomes narrower. Even if it does, it does not have any influence on the change in the injection hole diameter of the first injection hole 31 related to the injection quantity characteristic, so that the change in the injection quantity characteristic of the electromagnetic fuel injection valve 1 can be suppressed.
[0048]
[Second Embodiment]
FIG. 5 shows a second embodiment of the present invention and is an enlarged view of the orifice of the orifice plate.
[0049]
The first injection hole 31 among the plurality of orifices 30 formed in the orifice plate 10 of the electromagnetic fuel injection valve 1 of the present embodiment is a circular injection hole having a predetermined injection hole diameter (φd). The nozzle area of the fuel outlet is S1. The first injection hole 31 is formed at a portion of the first plate thickness (t1) of the orifice plate 10 so as to be inclined by a predetermined inclination angle (A °) with respect to the plate thickness direction of the orifice plate 10. .
[0050]
On the other hand, the second injection hole 32 of the orifice 30 is formed in a shape that expands toward the end of the second plate thickness (t2) of the orifice plate 10. The second injection hole 32 is formed by the second plate thickness (t2), and the injection hole area of the fuel outlet is S2 wider than that of the first injection hole 31.
[0051]
The second injection hole 32 has a divergent angle B1 ° on the central axis side of the electromagnetic fuel injection valve 1 with respect to the central axis of the first injection hole 31 and the central axis of the first injection hole 31. The end spread angle on the opposite side to the central axis of the electromagnetic fuel injection valve 1 is B2 °. That is, the divergent shape of the second injection hole 32 is A> B1 = B2> 0 with respect to the central axis of the first injection hole 31.
[0052]
[Third embodiment]
FIG. 6 shows a third embodiment of the present invention and is an enlarged view of the orifice of the orifice plate.
[0053]
The fuel inlet of the first injection hole 31 among the plurality of orifices 30 formed in the orifice plate 10 of the electromagnetic fuel injection valve 1 of this embodiment has a predetermined injection hole diameter (φd) and the first injection hole 31. Is a divergent nozzle hole, and its nozzle hole area is S1. The first injection hole 31 is formed at a portion of the first plate thickness (t1) of the orifice plate 10 so as to be inclined by a predetermined inclination angle (A °) with respect to the plate thickness direction of the orifice plate 10. . In addition, the end spread angle of the first injection hole 31 is C (°).
[0054]
On the other hand, the second injection hole 32 of the orifice 30 is formed in a shape that expands toward the end of the second plate thickness (t2) of the orifice plate 10. The second injection hole 32 is formed by the second plate thickness (t2), and the injection hole area of the fuel outlet is S2 wider than that of the first injection hole 31.
[0055]
The second injection hole 32 has a divergent angle B1 ° on the central axis side of the electromagnetic fuel injection valve 1 with respect to the central axis of the first injection hole 31 and the central axis of the first injection hole 31. The spread angle on the opposite side of the central axis of the electromagnetic fuel injection valve 1 is B2 °. That is, the divergent shape of the second injection hole 32 is B1>A>B2> C / 2 or A> B1 = B2> C / 2 with respect to the central axis of the first injection hole 31.
[0056]
[Fourth embodiment]
FIGS. 7 and 8 show a fourth embodiment of the present invention. FIG. 7 is a view showing the main structure of an electromagnetic fuel injection valve. FIG. 8 is a view showing a passage wall surface of an orifice plate. .
[0057]
In this embodiment, the number of nozzle holes in the orifice 30 is doubled compared to the first embodiment in which the orifice plate 10 has four orifices 30. That is, an example is shown in which twelve orifices 30 are arranged on an imaginary line of a double circle centered on the central axis of the electromagnetic fuel injection valve 1 (the central point of the orifice plate 10). In addition, arrangement | positioning of the some orifice 30 can be freely arrange | positioned within the range which does not reduce the effect which promotes atomization of spray fuel.
[0058]
[Fifth embodiment]
FIG. 9 shows a fifth embodiment of the present invention and is a diagram showing the main configuration of an electromagnetic fuel injection valve.
[0059]
In the orifice plate 10 of the present embodiment, a plurality of inner injection holes disposed on the central axis side of the electromagnetic fuel injection valve 1 from a portion where the main flow of the fuel flow flowing in the fuel passage 9 collides with the orifice plate 10. (Orifice) 40 and the direction of the main flow flowing in the fuel passage 9 on the opposite side of the central axis of the electromagnetic fuel injection valve 1 from the portion where the main flow of the fuel flow flowing in the fuel passage 9 collides with the orifice plate 10 A plurality of outer nozzle holes (orifices) 50 disposed at positions opposite to each other are formed.
[0060]
The plurality of inner nozzle holes 40 and the plurality of outer nozzle holes 50 have first and second nozzle holes 41, 42, 51, 52 having the same structure as that of the first embodiment. Here, reference numeral 53 denotes an annular plate-like plate sandwiched between the front end surface of the valve body 7 and the passage wall surface of the orifice plate 10, and is attached to the front end surface of the valve body 7 and the passage wall surface of the orifice plate 10 by laser welding. It is joined.
[0061]
[Modification]
In the present embodiment, the fuel injection valve for the internal combustion engine such as the electromagnetic fuel injection valve (fuel injector) 1 is attached to the intake manifold of the gasoline engine. However, the fuel injection valve for the internal combustion engine is attached to the cylinder of the engine. Alternatively, the fuel injection valve may be attached to a combustion apparatus such as a water heater or an oil stove.
[0062]
In the present embodiment, the example in which the valve body such as the needle valve 8 is applied to the electromagnetic fuel injection valve 1 that reciprocally moves in the axial direction by the electromagnetic actuator has been described. However, the valve body is mechanically reciprocated in the axial direction. You may apply to a fuel injection valve. For example, the present invention may be applied to a fuel injection nozzle that opens a valve body when fuel is supplied into the valve body and reaches a predetermined oil pressure.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing the overall configuration of an electromagnetic fuel injection valve (first embodiment).
FIG. 2 is a cross-sectional view showing a main configuration of an electromagnetic fuel injection valve (first embodiment).
FIG. 3 is a plan view showing a passage wall surface of an orifice plate (first embodiment).
FIG. 4 is an enlarged cross-sectional view of an orifice of an orifice plate (first embodiment).
FIG. 5 is an enlarged cross-sectional view of an orifice of an orifice plate (second embodiment).
FIG. 6 is an enlarged sectional view of an orifice of an orifice plate (third embodiment).
FIG. 7 is a cross-sectional view showing the main configuration of an electromagnetic fuel injection valve (fourth embodiment).
FIG. 8 is a plan view showing a passage wall surface of an orifice plate (fourth embodiment).
FIG. 9 is a cross-sectional view showing the main configuration of an electromagnetic fuel injection valve (fifth embodiment).
FIG. 10 is a cross-sectional view showing a main configuration of an electromagnetic fuel injection valve (prior art).
FIG. 11 is an enlarged sectional view of an orifice of an orifice plate (prior art).
[Explanation of symbols]
1 Electromagnetic fuel injection valve
7 Valve body
8 Needle valve
9 Fuel passage
10 Orifice plate (plate with nozzle hole)
21 Valve seat
29 Valve body opening
30 Orifice
31 First nozzle hole
32 Second nozzle hole
40 Inner nozzle hole
41 First nozzle hole
42 Second nozzle hole
50 Outer nozzle
51 First nozzle hole
52 Second nozzle hole

Claims (3)

A tubular valve body having an opening at the tip and a valve seat upstream of the opening;
A valve body that is slidably accommodated in the valve body and interrupts fuel injection by contacting or separating from the valve seat; and
An injection hole plate having an injection hole disposed on the front end surface of the valve body so as to close the opening of the valve body and injecting fuel ;
The injection hole is formed through the injection hole plate so as to be inclined with respect to the plate thickness direction from the fuel inlet toward the fuel outlet.
Between the fuel inlet and the fuel outlet of the nozzle hole, a first nozzle hole provided on the fuel inlet side having a different shape and a second nozzle hole provided on the fuel outlet side are provided,
A fuel injection valve having a nozzle hole area of the second nozzle hole larger than a nozzle hole area of the first nozzle hole ;
The first nozzle hole is a round nozzle hole, the second nozzle hole is a divergent nozzle hole,
With respect to the central axis of the first injection hole, a diverging angle of the second injection hole on the central axis side of the fuel injection valve is B1,
When the end spread angle of the second nozzle hole on the opposite side of the center axis of the fuel injection valve is B2 with respect to the center axis of the first nozzle hole,
The fuel injection valve according to claim 1, wherein a shape of the end of the second nozzle hole is such that B1 ≧ B2> 0 with respect to a central axis of the first nozzle hole . A tubular valve body having an opening at the tip and a valve seat upstream of the opening;
A valve body that is slidably accommodated in the valve body and interrupts fuel injection by contacting or separating from the valve seat; and
An injection hole plate having an injection hole disposed on the front end surface of the valve body so as to close the opening of the valve body and injecting fuel;
The injection hole is formed through the injection hole plate so as to be inclined with respect to the plate thickness direction from the fuel inlet toward the fuel outlet.
Between the fuel inlet and the fuel outlet of the nozzle hole, a first nozzle hole provided on the fuel inlet side having a different shape and a second nozzle hole provided on the fuel outlet side are provided,
A fuel injection valve having a nozzle hole area of the second nozzle hole larger than a nozzle hole area of the first nozzle hole;
The first nozzle hole is a divergent nozzle hole, the second nozzle hole is a divergent nozzle hole,
With respect to the central axis of the first injection hole, a diverging angle of the second injection hole on the central axis side of the fuel injection valve is B1,
B2 is the end spread angle of the second injection hole on the opposite side of the central axis of the fuel injection valve with respect to the central axis of the first injection hole .
When the end spread angle of the first nozzle hole is C ,
The fuel injection valve according to claim 1, wherein the end-spreading shape of the second injection hole satisfies a relationship of B1 ≧ B2> C / 2 . The fuel injection valve according to claim 1 or 2 ,
Between the upstream end face of the injection hole plate and the front end face of the valve body, a fuel passage is formed in which a main flow of fuel flows during fuel injection,
The nozzle hole flows in the fuel passage and an inner nozzle hole arranged on the central axis side of the fuel injection valve from a portion where a main flow of the fuel flow flowing in the fuel passage collides with the plate with the nozzle hole. A fuel injection valve comprising an outer injection hole disposed on a side opposite to a center axis of the fuel injection valve from a portion where a main flow of the fuel flow collides with the plate with the injection hole .

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