1. Field of the Invention
The present invention relates to an electromagnetic fuel injection valve utilized mainly in the fuel supply system of an internal combustion engine.
2. Description of the Related Art
In recent years, while restrictions on exhaust gas from a vehicle and the like have been tightened, there has been required improvement in atomization of a fuel injected through a fuel injection valve, and hence various kinds of studies about atomization have been made. In the prior arts disclosed in Japanese Patent Application Laid-Open No. 2003-336562 and Japanese Patent Application Laid-Open No. 2003-336563, a fuel injection valve is configured in such a way that respective guide paths are provided for the injection holes, and a fuel rectified and accelerated by means of the guide path flows into a swirl chamber. The fuel forms a swirling flow in the swirl chamber and swirls within the injection hole; then, a fuel spray injected through the outlet of an injection hole plate becomes hollow and cylindrical fuel spray, so that atomization is allegedly facilitated.
Additionally, in prior arts disclosed in Japanese Patent Application Laid-Open No. 2006-2620, Japanese Patent Application Laid-Open No. 2006-336577, and Japanese Patent Application Laid-Open No. 2007-182767, the fuel flow is controlled based on the relationship between the shape of the fuel chamber and the position of the injection hole and a swirling flow is induced at the injection hole inlet, so that atomization is allegedly facilitated.
Meanwhile, in the prior arts disclosed in Japanese Patent Application Laid-Open No. 2003-336562 and Japanese Patent Application Laid-Open No. 2003-336563, a fuel injection valve is configured in such a way that respective guide paths are provided for the injection holes, and a fuel rectified and accelerated by means of the guide path flows into a swirl chamber; therefore, there have been such problems as described below.
[Effect on Flow Rate Characteristics]
In the foregoing prior arts, because the fluid resistance is large at the downstream side of a valve seat, the pressure reducing speed is low at the downstream side of the valve seat during the valve body closing process; therefore, because the valve closing delay time in which a valve closing signal is input and then the valve body is completely closed is long, the flow rate dynamic range is deteriorated.
[Effect on Fuel Spray Characteristics]
Because the fluid resistance is large at the downstream side of the valve seat, the fuel spray injected through the injection hole is liable to adhere; therefore, there may be caused a splashing phenomenon in which the fuel that has not been able to separate from the injection hole and has adhered to the endface, of the injection hole plate, in the vicinity of the injection hole outlet is splashed when the next injection is performed, whereby inferior fuel spray is injected outside the target injection zone; as a result, fuel adhesion to various parts of the engine increases, whereby exhaust gas and the controllability in the engine output may be deteriorated.
[Effect of Atmospheric Change]
Under a high-temperature and negative-pressure condition, due to vaporization of part of fuel in a so-called dead volume, a gas-liquid two-layer flow is caused, and the pressure loss is large when the gas-liquid two-layer flow passes through a narrow flow path; in the example of prior art, because the flow path is configured in such a way that the guide path, i.e., a diaphragm is provide from the downstream side of the valve seat to the injection hole, there has been a problem that, due to change in the temperature or the atmospheric pressure, the flow rate characteristics (static flow rate/dynamic flow rate) and the fuel spray characteristics (fuel spray shape/fuel-spray particle diameter) change considerably.
[Production Cost]
Because the speed of the fuel that flows into each swirl chamber depends on the shape of the guide path, the variation in the shape of the guide path largely affects the deviation of the injection amount of the fuel injected through the injection hole; therefore, a guide path having a high-accuracy shape is required, whereby the production cost is raised. When the deviation of the injection amount is large, the shape of the fuel spray varies, whereby, when the fuel is injected in the engine, the adhesion amount in various part of the engine and the distribution of the fuel-air mixture vary; therefore, the variation in combustion may cause an increase in the amount of exhaust gas or a fluctuation of the engine rotation.
In order to reduce the thickness of fuel liquid film so as to atomize the fuel spray, it is required to exert large swirling force on the fuel in the injection hole. In order to reinforce the swirling force in the swirl chamber, it is required to enlarge the offset between the injection hole inlet and the fuel path; thus, the ratio of depth to width of the fuel path becomes large. Accordingly, the machining of the fuel path becomes difficult, and in the case where the fuel path is formed with a press machine, there has been a problem that the lifetime of the die is shortened and hence the production cost increases.
In the case where a multi-hole injector is adopted for the purpose of further atomizing the fuel spray, the diameter of each injection hole becomes small and hence the fuel path becomes narrow, whereby the machining of the fuel path becomes difficult; therefore, in the case where the fuel path is formed with a press machine, there has been a problem that the lifetime of the die is shortened and hence the production cost increases.
In the prior arts disclosed in Japanese Patent Application Laid-Open No. 2006-2620 and Japanese Patent Application Laid-Open No. 2006-336577, a fuel injection valve is configured in such a way that the fuel flow is controlled based on the relationship between the shape of the fuel chamber and the position of the injection hole and a swirling flow is induced at the injection hole inlet; thus, there have been such problems as described below.
[Effect on Fuel Spray Characteristics]
Because the fuel injection valve according to the foregoing prior arts has no swirl chamber and has a flow opposite to the swirling flow, there has been a problem that the swirling flow does not develop sufficiently and hence the atomization is not facilitated.
In the mechanism in which swirling force is exerted on a fuel so as to atomize the fuel, it is important that the fuel is pressed against the inner wall of the injection hole while swirling within the injection hole so that the fuel is not filled in the injection hole but becomes thin liquid films and is injected in a hollow form through the injection hole outlet, and then the hollow liquid films spread due to centrifugal force, so that the liquid films become thinner, and due to shearing force exerted by air, the liquid films are split. With regard to the shape of a fuel chamber according to the prior arts, at the upstream side of the injection hole, there is provided a shape with which the fuel flow separates from the rest, and the separation of the fuel causes a disturbance in the flow. When the injected hollow liquid films spread due to centrifugal force, there exists a disturbance in the fuel flow in the case of the foregoing prior arts; therefore, the liquid film is split, with the thickness thereof kept thick, in process of spreading. There has been a problem that, because the split liquid thread or liquid drop is not likely to further split, the fuel cannot readily be atomized.
[Effect on Variation in Characteristics]
The flow path is made in such a way that, in the fuel chamber at the upstream side of the injection hole, the fuel flow separates from the rest; therefore, there has been a problem that, due to the disturbance in the separated fuel, the flow rate characteristics and the fuel spray characteristics are likely to vary.
[Effect of Atmospheric Change]
Under a high-temperature and negative-pressure condition, the fuel separation makes the fuel tend to boil under reduced pressure; therefore, there has been a problem that, due to atmospheric change, the flow rate characteristics (static flow rate/dynamic flow rate) and the fuel spray characteristics (fuel spray shape/fuel-spray particle diameter) change considerably.
Also in the prior art disclosed in Japanese Patent Application Laid-Open No. 2007-182767, the fuel flow is controlled based on the relationship between the shape of the fuel chamber and the position of the injection hole and a swirling flow is induced at the injection hole inlet; thus, there has been such a problem described below.
[Effect on Fuel Spray Characteristics]
Because the fuel injection valve according to the foregoing prior art has no swirl chamber and has a flow opposite to the swirling flow, there has been a problem that the swirling flow does not develop sufficiently and hence the atomization is not facilitated.
The present invention has been implemented in order to solve the foregoing problems.
The present invention provides a fuel injection valve in which a valve body for opening and closing a valve seat is provided, and by receiving an operation signal from a control device so as to operate the valve body, a fuel passes a gap between the valve body and a valve seat portion and then is injected through a plurality of injection holes provided in an injection hole plate mounted in a valve seat opening portion at the downstream side of the valve seat. In the fuel injection valve, the injection hole plate is disposed in such a way that an extended line along the plane of the valve seat portion of the valve seat whose diameter is gradually reduced in the downstream direction and an upstream plane of the injection hole plate intersect each other so that a virtual circle is formed; by recessing part of the upstream side of the injection hole plate at a plurality of positions along the valve seat opening portion, a plurality of fuel chambers is formed; the fuel chamber has a shape, the halves of which are symmetric with each other with respect to a line that radially extends from the center of the injection hole plate, and is disposed in a place that ranges from the inside of the virtual circle to the outside of the inner circumference of the valve seat opening portion; and in each of the fuel chambers, two injection holes are arranged outside the inner circumference of the valve seat opening portion in such a way as to flank the radial center line of the fuel chamber.
The present invention provides another fuel injection valve in which a valve body for opening and closing a valve seat is provided, and by receiving an operation signal from a control device so as to operate the valve body, a fuel passes a gap between the valve body and a valve seat portion and then is injected through a plurality of injection holes provided in an injection hole plate mounted in a valve seat opening portion at the downstream side of the valve seat. In the fuel injection valve, the injection hole plate is disposed in such a way that an extended line along the plane of the valve seat portion of the valve seat whose diameter is gradually reduced in the downstream direction and an upstream plane of the injection hole plate intersect each other so that a virtual circle is formed; by recessing part of the upstream side of the injection hole plate at a plurality of positions along the valve seat opening portion, a plurality of ellipsoidal fuel chambers is formed; the fuel chamber whose major axis is slanted with respect to a line that radially extends from the center of the injection hole plate is disposed in a place that ranges from the inside of the virtual circle to the outside of the inner circumference of the valve seat opening portion; and the injection hole solely provided in the fuel chamber is disposed outside the inner circumference of the valve seat opening portion.
The present invention provides another fuel injection valve in which a valve body for opening and closing a valve seat is provided, and by receiving an operation signal from a control device so as to operate the valve body, a fuel passes a gap between the valve body and a valve seat portion and then is injected through a plurality of injection holes provided in an injection hole plate mounted at the downstream side of the valve seat. In the fuel injection valve, on the circumference of the valve body situated in the vicinity of a valve seat guide portion, for guiding the valve body, that is provided at the upstream side of the valve seat portion, there is formed a plurality of grooves that serve as fuel paths, in such a way as to be slanted by a predetermined angle with respect to the center axis of the valve body and so as to become swirling grooves; the injection hole plate is disposed in such a way that an extended line along the plane of the valve seat portion of the valve seat whose diameter is gradually reduced in the downstream direction and an upstream plane of the injection hole plate intersect each other so that a virtual circle is formed; by recessing part of the upstream side of the injection hole plate at a plurality of positions along the valve seat opening portion, a plurality of fuel chambers is formed; the fuel chamber is provided in a place that ranges from the inside of the virtual circle to the outside of the inner circumference of the valve seat opening portion; the injection hole solely provided in the fuel chamber is disposed outside the inner circumference of the valve seat opening portion; the wall face, of the fuel chamber, that is situated inside the virtual circle is in a shape of an arc, the halves of which are symmetric with each other with respect to a line that radially extends from the center of the injection hole plate; and the wall face, of the fuel chamber, that is situated outside the inner circumference of the valve seat opening portion is in a shape of an arc that is concentric with the injection hole.
A fuel injection valve, according to the present invention, configured in such a way as described above demonstrates the following effects.
[Effect on Flow Rate Characteristics]
A fuel injection valve according to the present invention is configured in such a way that, because the fluid resistance is small at the downstream side of the valve seat, the pressure reducing speed is high at the downstream side of the valve seat during the valve body closing process, and hence, because the valve closing delay time in which a valve closing signal is input and then the valve body is completely closed is short, improvement of the flow rate dynamic range is advantageously performed.
[Effect on Fuel Spray Characteristics]
The present invention demonstrates an effect in which, because the fluid resistance is small at the downstream side of the valve seat, the fuel spray injected through the injection hole is not liable to adhere, and hence, because the fuel spray is detached from the injection hole, the splashing phenomenon can be suppressed.
A fuel injection valve according to the present invention is configured in such a way that, after being pressed against the wall face, of the fuel chamber, which is inside of the virtual circle, the fuel along the valve seat portion flows along the inner wall of the fuel chamber, and then flows into the injection hole while swirling around the injection hole inlet. Accordingly, by being pressed against the injection hole inner wall while swirling within the injection hole, the fuel is not filled into the injection hole, but becomes a thin liquid film and is injected in a hollow form through the injection hole outlet.
In the present invention, the fuel flow is rectified and the swirling flow is reinforced in the fuel chamber; therefore, the centrifugal force in the injection hole is strong, whereby there is demonstrated an effect in which the injected hollow liquid film can be made further thinner. Moreover, the rectification in the fuel chamber suppresses disturbance; thus, when spreading due to the centrifugal force, the injected hollow liquid film does not burst in process of spreading with its thickness kept large; therefore, the thickness of the liquid film can further be reduced. Thus, there is demonstrated an effect in which, by bursting the liquid film, which has been made thin, by means of shearing force of air, atomization is facilitated.
[Effect of Atmospheric Change]
The present invention provides a flow path in which the fuel is not likely to break away; therefore, the fuel is not likely to undergo low-pressure boiling. Even if part of the fuel undergoes low-pressure boiling and an air-liquid double-layer flow occurs in the dead volume, the pressure loss due to the air-liquid double-layer flow is small, because the flow path in the present invention is configured in such a way that there exists no diaphragm between the downstream side of the valve seat and the injection hole; therefore, changes, due to atmospheric change, in the flow rate characteristics (static flow rate/dynamic flow rate) and the fuel spray characteristics (fuel spray shape/fuel-spray particle diameter) are small.
[Production Cost]
In a fuel injection valve according to the present invention, unlike the prior arts disclosed in Japanese Patent Application Laid-Open No. 2003-336562 and Japanese Patent Application Laid-Open No. 2003-336563, there exists no complex guide path; therefore, because the fuel chamber is in a simple shape, high-accuracy machining can be performed, whereby variations in the injection amount can be suppressed at low production costs.
The foregoing and other object, features, aspects, and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
Embodiments 1 to 14 will be explained below; with regard to Embodiment 2 to 14, explanations for the constituent elements that are common to Embodiments 1 to 14 will be omitted, and what differ from Embodiment 1 will mainly be explained.
A fuel injection valve 1 is provided with a solenoid device 2, a housing 3 that is a yoke portion of a magnetic circuit, a core 4 that is a fixed iron core portion of the magnetic circuit, a coil 5 wound around a bobbin provided on the circumference of the core 4, an armature 6 that is a moving iron core portion of the magnetic circuit, and a valve device 7. The valve device 7 is configured with a valve body 8, a valve main body 9, and a valve seat 10. At the front end of the valve body 8, a valve-body front end portion 13, which forms part of a sphere, is mounted, for example, through welding.
The valve main body 9 is pressure-fitted with the outer circumference of the core 4, and then welded to the core 4. The armature 6 is pressure-fitted with the valve body 8, and then welded to the valve body 8 so as to be integrally coupled with the valve body 8. A valve seat opening portion 10b is provided at a place where the diameter of the valve seat 10 is gradually reduced toward the downstream side. An injection hole plate 11 is inserted into the valve main body 9 in such a way as to be bonded with the bottom side of the valve seat 10 at a welding portion 11a; furthermore, the injection hole plate 11 is bonded with the valve main body 9 at a welding portion 11b.
In the injection hole plate 11, there are formed two or more fuel chambers 15 by recessing portions, at the upstream side, of the injection hole plate 11. A plurality of (six, in the case of
The valve-body front end portion 13 is formed in an approximately sphere shape, and the sphere portion is inserted into the valve seat 10 and faces the valve seat portion 10a. In peripheral portion, of the valve-body front end portion 13, which faces guide portion 10c, of the valve seat 10, that guides a sliding surface 13b of the valve-body front end portion 13 that moves in the valve seat 10, there are provided two or more grooves 13a in such a way as to be spaced evenly apart from one another.
When an engine control device transmits an operation signal to a drive circuit for the fuel injection valve 1, a current flows in the coil 5 of the fuel injection valve 1; magnetic flux is produced in a magnetic circuit including the armature 6, the core 4, the housing 3, and the valve main body 9; then, the armature 6 is attracted toward the core 4. The valve body 8 integrated with the armature 6 moves upward inside the valve main body 9. In this situation, the sliding surface 6a of the armature 6 and the valve main body 9 slide on each other; the sliding surface 13b of the valve-body front end portion 13 slides on the guide portion 10c, whereby the valve-body front end portion 13 is guided by the guide portion 10c.
When the valve is opened, an armature upper endface 6b makes contact with the bottom endface of the core 4. When the armature 6 moves to a valve-opening position, the valve-body front end portion 13 of the valve body 8 integrated with the armature 6 leaves the valve seat portion 10a, whereby a gap is formed. The fuel forms a fuel flow 16a; the fuel starts from each of the plurality of grooves 13a provided in the valve-body front end portion 13 and reaches the fuel chamber 15 through the gap between the valve seat portion 10a and the valve-body front end portion 13, and is injected through the plurality of the injection holes 12 into the air-intake pipe of the engine.
When the engine control device transmits an operation stop signal to the drive circuit of the fuel injection valve, power supply to the coil 5 is interrupted; magnetic flux in the magnetic circuit is reduced; a compression spring 14 that always presses the valve body 8 in a valve-closing direction closes the gap between the valve-body front end portion 13 and the valve seat portion 10a; then, the fuel injection ends. The sliding surface 6a of the valve body 8 slides on the valve main body 9, and the sliding surface 13b thereof slides on the guide portion 10c, whereby the valve body 8 is guided.
In Embodiment 1, as illustrated in
The fuel chamber 15 is in a shape of an approximate heart, the halves of which are symmetric with each other with respect to a line that radially extends from the center of the injection hole plate 11, and disposed in a place that ranges from the inside of the virtual circle 11d to the outside of the inner circumference of the valve seat opening portion 10b; in each of the fuel chambers 15, a pair of (two) injection holes 12 are arranged at positions outside the inner circumference of the valve seat opening portion 10b in such a way as to flank the radial center line of the fuel chamber 15.
The shape of the fuel chamber 15 will be explained in more detail. A wall face 15a situated inside the virtual circle 11d of the fuel chamber 15 is formed of an arc, the halves of which are symmetric with each other with respect to a radial line that extends from the center of the injection hole plate 11; furthermore, wall faces 15b situated outside the inner circumference of the valve seat opening portion 10b of the fuel chamber 15 are each in the form of an arc that is concentric with the corresponding injection hole 12. In
Respective injection hole inlets 12a of the two injection holes 12 are arranged in such a way as to be symmetric with each other with respect to the radial center line of the corresponding fuel chamber 15. Each of the injection holes 12 penetrates the injection hole plate 11 in such a way as to has a given gradient with respect to a direction perpendicular to the injection hole plate 11. In
In a fuel injection valve having such a structure as described above, the fuel passes through the groove 13a of the valve-body front end portion 13 and forms the fuel flow 16a; the fuel flow 16a from the valve seat portion 10a collides with the bottom side 15c of the fuel chamber 15; after that, the fuel flow 16a advances along the wall face 15a situated inside the inner circumference of the fuel chamber and ramifies into two flows that are symmetric with each other with respect to the corresponding radial center line of the fuel chamber 15; then, the fuel flows radially. After that, while advancing along the wall face 15b around the injection hole 12 of the fuel chamber, the fuel forms a swirling flow 16b with respect to the injection hole inlet 12a. The fuel that flows into the injection hole inlet 12a is injected through the downstream-side outlet of the injection hole 12 while swirling within the injection hole 12; therefore, because a hollow and conical fuel spray is formed, atomization is facilitated.
As illustrated in
In such a structure as described above, the fuel passes through a groove 13a of a valve-body front end portion 13 and forms a fuel flow 16a; the fuel flow 16a from a valve seat portion 10a flows to the center of the injection hole plate 11; however, because the wall face 15a inside a virtual circle 11d of the fuel chamber 15 is slanted with respect to the fuel flow 16a that heads toward the center of the injection hole plate 11, the fuel forms a unidirectional swirling flow 16b in the fuel chamber 15 and flows into an injection hole inlet 12a. Therefore, the fuel becomes hollow and conical fuel spray, whereby atomization is facilitated. The configurations other than those described above are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
In Embodiment 3, as illustrated in
The inner wall of a valve seat 10 in the vicinity of the portion where a valve seat portion 10a and a guide portion 10c are connected, i.e., in the vicinity of the outlet of the swirling groove formed of the plane 13c has a curved surface of a curvature R.
On the other hand, a fuel chamber 15 is approximately egg-shaped and provided in a place that ranges from the inside of a virtual circle 11d to the outside of the inner circumference of a valve seat opening portion 10b; in each of the fuel chambers 15, a single injection hole 12 is disposed outside the inner circumference of the valve seat opening portion 10b. A wall face 15a, inside the virtual circle 11d, of the fuel chamber 15 is formed in the form of an arc, the halves of which are symmetric with each other with respect to a radial line from the center of an injection hole plate 11; a wall face 15b situated outside the inner circumference of the valve seat opening portion 10b of the fuel chamber 15 is in the form of an arc that is concentric with the corresponding injection hole 12.
In a fuel injection valve having such a structure as described above, due to the plane 13c of the valve-body front end portion 13, a fuel flow 16c flows into the fuel chamber 15 in such a way as to be slanted by γ° with respect to a radical line that extends from the center of the injection hole plate 11; therefore, the fuel forms a unidirectional swirling flow 16b in the fuel chamber 15 and flows into an injection hole inlet 12a. As a result, at the injection hole outlet, the fuel becomes hollow and conical fuel spray, whereby atomization is facilitated. In this situation, an effect is demonstrated in which the curved-surface portion of the valve seat 10 maintains the swirling flow 16c formed by the plane 13c. The configurations other than those described above are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
Because a plurality of fuel paths can be formed by means of the groove 13a formed of the planes 13d and 13c, fuel flows 16a from a valve seat portion 10a can be circumferentially homogenized. As a result, the fuel homogeneously and evenly flows into respective fuel chambers 15, and the fuel flow in the fuel chamber 15 is stabilized; therefore, there can be expected an effect in which variations in the fuel spray are suppressed. The fuel chamber 15 is the same as that in Embodiment 1 or Embodiment 2. The other configurations are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
In such a way as described above, the cross-sectional area of the fuel chamber 15 is gradually decreased toward the injection hole 12; therefore, because, as is the case with Embodiment 5, the swirling force exerted on a swirling flow 16b is reinforced, there is demonstrated an effect in which atomization is facilitated. The configurations other than those described above are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
In Embodiment 7, a fuel chamber 15 is formed through coining on a conveyer line utilized during manufacturing of an injection hole plate. Accordingly, because there can readily be secured the accuracy of the position of an injection hole in the fuel chamber 15, variations in fuel spray can be suppressed at low production costs.
A fuel chamber 15 is formed in the intermediate plate 17 through press machining; in the injection hole plate 11, there is formed only an injection hole 12. After the positions of an injection hole inlet 12a and the fuel chamber 15 are adjusted, the intermediate plate 17 and the injection hole plate 11 are welded with each other. The diameter of the intermediate plate 17 is made smaller than that of the injection hole plate 11; the intermediate plate 17 is inserted into recesses 10e formed by recessing the downstream side endface of the valve seat by the thickness of the intermediate plate 17.
Because the intermediate plate 17 is provided, the thickness of the injection hole plate 11 can be reduced. Accordingly, because, when the injection hole plate 11 is welded with the valve seat 10, the amount of welding heat can be reduced, the thermal deformation in a valve seat portion 10a is suppressed; therefore, there can be expected an effect in which the gastightness of the valve is raised. The shape of the fuel chamber 15 is the same as that in any one of Embodiments 1 to 6. The other configurations are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
As a result, because the fuel flow from the swirl chamber 18 to an injection hole 12 becomes smooth, there exists no loss in the fuel flow, whereby the swirling effect is raised; therefore, atomization is facilitated. Moreover, because the fuel evenly flows into the slanted injection hole 12, distortion of the fuel flow in the injection hole 12 can be suppressed; therefore, there can be expected an effect in which variations in the fuel spray are suppressed.
The foregoing configuration demonstrates an effect in which there are suppressed a fuel flow 16d that passes a place where the fuel chamber 15 is not formed and a fuel flow 16e that radially heads from the center of the fuel injection valve to the fuel chamber 15. The radial fuel flow 16e faces the fuel flow 16a that flows into a place where the fuel chamber 15 is formed; therefore, by suppressing the radial fuel flow 16e, the swirling force is reinforced, whereby there can be expected an effect in which atomization is facilitated. The other configurations are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
The nozzle hole 19a has a shape, the halves of which are symmetric with each other with respect to a radial line that extends from the center of the injection hole plate 11; the nozzle hole 19a has a shape, the halves of which are symmetric with each other with respect to the radial center line of the fuel chamber 15 and which is elongated in the radial direction; the flow rate coefficient of the nozzle hole is sufficiently larger than that of the injection hole. The fuel flows into the fuel chamber 15 through the nozzle hole 19a.
Accordingly, there cab be suppressed a fuel flow 16d that passes a place where the fuel chamber 15 is not formed and a fuel flow 16e that radially heads from the center of the fuel injection valve to the fuel chamber 15; therefore, the swirling force is reinforced, whereby there can be expected an effect in which atomization is facilitated. The other configurations are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
Embodiment 14 is obtained by providing in
As a result, there is reduced the amount of the fuel vaporized in the dead volume under a high-temperature and negative-pressure condition; therefore, variations, due to atmospheric change, in the flow rate characteristics (static flow rate/dynamic flow rate) and the fuel spray characteristics (fuel spray shape/fuel-spray particle diameter) can be suppressed. The other configurations are the same as those of Embodiment 1; therefore, explanations therefor will be omitted.
Various modifications and alterations of this invention will be apparent to those skilled in the art without departing from the scope and spirit of this invention, and it should be understood that this is not limited to the illustrative embodiments set forth herein.
Number | Date | Country | Kind |
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2009-119977 | May 2009 | JP | national |
This application is a divisional of U.S. application Ser. No. 12/609,855, filed Oct. 30, 2009, which claims priority from Japanese Patent Application No. 2009-119977, filed May 18, 2009, the contents of which are incorporated herein by reference in their entirety.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 12609855 | Oct 2009 | US |
Child | 14035230 | US |