The present application claims priority from Japanese patent application serial no. 2008-89155 filed on Mar. 31, 2008, the contents of which are hereby incorporated by reference into this application.
The present invention relates to a fuel injection valve used in an internal combustion engine of an automobile, and a method for forming orifices serving as a nozzle for the fuel injection valve.
A fuel injection valve, wherein a convex portion is prominently formed in an orifice plate having orifices, plural recesses are formed at the convex portion, and an opening (outlet) of each of the orifices is formed at the bottom face of the relevant recess, has heretofore been known (for example refer to JP-A No. 77843/2007). In the fuel injection valve, the bottom face of a recess is formed perpendicularly to the axis line of the relevant orifice, consideration is made so that a fuel can be injected at the same time in a circumferential direction from outlets of the orifices. Further consideration, in forming process of the orifices, is made so that bending force may not be exerted on a punch when press forming is applied to a blank for the orifice plate. Further, a length of an orifice is adjusted by changing a depth of the relevant recess.
In the conventional technology, the functions of reducing the bending force exerted to a punch and adjusting the lengths of orifices are given by recesses each of which has only one step. As a result, press forming of orifices and recesses is restricted. For example, the angle between a punch and a press forming face cannot be largely deviated from 90 degrees or a thickness of the punch has to be used if it is attempted to largely deviate the angle. When deep recesses each of which has a large step are formed with a thickness of the punch, the work may weaken the strength of members used for the forming of the orifices.
When the strength of members forming orifices weakens in process of forming plural orifices and recesses, the next press forming is hardly applied to the succeeding orifices and recesses in some cases. Then, as the number of orifices increases, the degree of difficulty in press forming may increase and the degree of freedom in the design of orifices (a number, an inclination angle, an interval, etc.) may be restricted further.
Further, in the case where a large number of orifices are formed, when deep recesses of large diameters are intended to form, it is concerned that recesses of adjacent orifices and moreover a recess and an orifice may interfere with each other. In particular, when it is attempted to change an inclination angle of each orifice with respect to a center axis line of a fuel injection valve for each orifice and orient the orifices in desired directions, interference between recesses or between a recess and an orifice tends to occur among specific orifices. As a result, it is concerned that the degree of freedom in the design of orifices may reduce.
An object of the present invention is to increase the degree of freedom in design and the workability of orifices formed by press forming and used in a fuel injection valve.
In order to attain the above object, a fuel injection valve according to the present invention is configured as follows.
A fuel injection valve of the present invention comprises a convex portion prominently formed on an outer end surface of a nozzle body, stepped recesses each of which has plural steps formed by press forming on the convex portion, and multi orifices as fuel nozzle holes formed by press forming so that an outlet of each of the orifices is located at a bottom face of each of the stepped recesses. Furthermore, the fuel injection valve has plural sets each of which comprises one of the stepped recesses and the relevant orifice, the orifices incline to each other, and a step on a downstream side in each of the stepped recesses has a larger diameter than a step on an upstream side thereof.
Further, the following method for forming orifices as multi-nozzle holes of an injection valve is provided. The method is comprises of: a first press process of forming a first step-recess part in each of stepped recesses by applying extrusion processing or half-blank processing to a convex portion prominently formed on a blank from the convex portion-side; a second press process of forming a second step-recess part in each of the stepped recesses so that the second step-recess part has a smaller diameter than that of the first step-recess part by further applying extrusion processing or half-blank processing inside the first step-recess part; and a third press process of forming each of the orifices at a bottom face of the second step-recess part by extrusion processing, half-blank processing, or stamp processing. Furthermore, plural sets each of which comprises the first step-recess part, the second step-recess part, and the orifice aligned in the order are formed so that plural sets of the orifices incline to each other.
The present invention makes it possible to increase the degree of freedom in design and the workability of orifices formed by press forming, in a fuel injection valve.
Embodiments according to the present invention are hereunder explained in detail in reference to drawings.
A fuel injection valve assembly 1 comprises a magnetic circuit including a stationary core 2, a yoke 3, a housing 4 and a movable element 5, an electro magnetic coil 6 to energize the magnetic circuit, and a terminal bobbin 7 to supply electricity to the coil 6. A seal ring 8 is connected between the core 2 and the housing 4 and prevents a fluid such as a fuel from flowing into the coil 6.
Valve parts such as the movable element 5, a nozzle body 9, and a ring 10 to adjust a stroke of the movable element 5 are incorporated in the housing 4. The movable element 5 is formed by connecting a valve needle (valve element) 11 to a movable core 12 with a joint 13. A plate 14 is provided between the movable core 12 and the joint 13 to prevent the movable element 5 from bouncing jointly with a pipe 18 when the valve is closed.
An outer surface of the movable element 5 is surrounded by the housing 4 and nozzle body 9. The nozzle body 9 is provided with an orifice plate 15, a guide plate 16 and a guide plate 17. The orifice plate 15 has a nearly cone-shaped surface including a valve seat 15a and orifices 54-59. The guide plates 16 and 17 are to slidably guide the movable element 5 jointly with each other. The orifice plate 15 and guide plate B17 may be configured either as components separated from the nozzle body 9 respectively or as a single-piece construction integrated with the nozzle body 9.
Inside of the stationary hollow-core 2 is provided with a return spring 19, the pipe 18, a screw-adjuster 20 and a filter 21. The return spring 19 is to press the valve needle 11 against the valve seat 15a through the pipe 18 and the plate 14. The adjuster 20 is to adjust pressing load of the spring 19. The filter 21 is to prevent contaminants from intruding from outside.
Next, operations of the fuel injection valve 1 are explained in detail.
When electricity is supplied to the coil 6, the movable element 5 is pulled up toward the core 2 against the force of the spring 19 and a gap is formed between the movable side-valve seat 11a as a tip of the movable element 5 and the valve seat 15a (namely the valve is in the open state). A pressurized fuel goes through firstly the stationary core 2, the adjuster 20, and the pipe 18 and enters the nozzle body 9 via a fuel channel 13a in the movable element 5. Successively, the fuel passes through a channel 17a of the guide plate 17 through a fuel channel 16a of a guide plate 16 and a channel 9a of the nozzle, and then passes through the gap between the movable element 11 and the valve seat 15a, and injected to outside via orifices 54 to 59. The orifices 54 to 59 are formed respectively at different angles in the directions inclined with respect to a center axis line (hereunder referred to simply as an axis line) of the fuel injection valve.
When the electricity to the coil 6 is turned off, the tip 11a of the movable element 5 is pressed against to the valve seat 15a by the force of the spring 19 and the valve comes to a closed state.
Next, a configuration of the orifice plate 15 and the orifices 54 to 59 of the fuel injection valve 1 are explained in detail.
The orifice plate 15 comprises a disc-shaped metal plate. A spherical surface portion 30 as a convex portion is integrally formed with the orifice plate and prominently formed in the center of one end surface of the orifice plate 15. A nearly cone-shaped surface 15a including the valve seat is formed on the other surface of the orifice plate 15 opposite to the convex portion.
At the spherical surface portion 30 as the convex portion, orifices 54, 55, 56, 57, 58, and 59 used for fuel injection nozzle holes are formed in the directions of angles θ (refer to
The valve needle 11 is provided on the upstream side from the orifices so as to make opening and closing movement jointly with the valve seat.
The fuel injection valve 1 is positioned in the rotation direction in relation to an electric terminal portion 7 and attached to an automobile. For that purpose, the orifice plate 15 has to be incorporated into the fuel injection valve 1 in a state where the orifice plate 15 is positioned in a rotation direction in relation to the terminal portion 7. However, the orifices 54, 55, 56, 57, 58, and 59 are formed at differently inclined angles with respect to the nozzle body-axis line 15b and hence they cannot be used for positioning the orifice plate 15 in the rotation direction. To cope with that, positioning recesses 31a and 31b are formed at places of 180 degrees apart from each other on a periphery of the spherical surface portion (convex portion) of the orifice plate 15. By so doing, a straight line linking two recesses 31 and 31b as two points 31b is formed and hence it is possible to incorporate the orifice plate 15 into the injection valve 1 in the state where the orifice plate 15 is positioned in the rotation direction in relation to the terminal portion 7. Further, a model type identifying recess 31c is formed between the recesses 31a and 31b on the periphery of the spherical surface portion (convex portion) 30. A model type can be easily identified by changing the position of the recess 31c, the diameter of the recess 31c, or the shape of the recess 31c(for example, a conical shape).
As stated above, it is possible to inject a fuel in desired directions by forming the orifices 54, 55, 56, 57, 58, and 59 at angles different from each in the directions inclined with respect to the nozzle body axis line 15b and hence, by changing the directions of the injection, it is possible to form fuel various splay patterns corresponding to combustion concepts conforming to engine specifications of each manufacturer. For example, by injecting a fuel so as to keep away from an intake valve and allow the fuel to localize around an ignition plug, it is possible to uniformly inject the fuel in a combustion chamber and produce a gas mixed with air very ideally without atomization hindered.
A group A of nearly circular recesses 54a, 55a, 56a, 57a, 58a, and 59a each of which is to be a first-step recess part are formed on the spherical surface portion (convex portion) 30-side on the downstream from the orifices 54, 55, 56, 57, 58, and 59 as shown in
Further, each of bottom faces 54as to 59as of the first step-recess parts A (56a to 59a) and each of bottom faces 54bs to 59bs of the second step-recess parts B (56b to 59b) are formed so that the faces may intersect nearly perpendicularly with the center axis line of the relevant orifice. Further, the center axis line of each of the first step-recess parts A (54a to 59a) and the relevant each of the second step-recess parts B and the center axis line of the relevant orifice are aligned so as to form a nearly straight line. Here, as shown in
In the present embodiment, the first step-recess parts A (54a to 59a) are formed on the curved surface (the spherical surface) of the convex portion 30. It is also possible to form planar surfaces each of which has a larger diameter than the relevant each of the first step-recess parts A (54a to 59a) on the spherical surface of the convex portion 30 beforehand and form each of the first step-recess parts A on the relevant each of the planar surfaces.
Further, as shown in
Each of the orifices 54, 55, 56, 57, 58, and 59 has an outlet (outlet side opening) formed at the bottom of the relevant each of the second step-recess parts B (54b to 59b) in the convex portion 30 and an inlet (inlet side opening) formed at the nearly cone-shaped surface including the valve seat 15a.
The length of an orifice as fuel nozzle hole has an influence on the length of a penetration of injected fuel. It is possible to optimize the length of each of the orifices 54 to 59 by changing the desired depth of each of the second step-recess portion parts B (54b to 59b), thereby being able to optimize the shape of injected fuel spray. In addition, it is possible to improve workability for the orifices. Consequently, the second step-recess parts B (54b to 59b) of at least two orifices have the depths different from each other. On this occasion, it is not necessary to change the thickness of the orifice plate tip 15c and hence the rigidity of the orifice plate 15 is not hindered. For that reason, the present embodiment is suitable for an injection valve of a high fuel pressure type wherein the pressure on the orifice plate tip 15c is as high as 10 MPa or more.
In the case where each of the orifices is formed at the concave portion so that the inlet thereof is opened on the cone-shaped surface including the valve seat like the present embodiment, the thickness of the member in which the orifices are formed is thicker than the case of forming orifices in a tabular member having uniform thickness. In particular, when inlets of the orifices are located on a circumference around the nozzle body axis line 15b (coinciding with the center axis line of the fuel injection valve) and the inclination angles θ of the orifices with respect to the nozzle body axis line 15b are different from each other, the outlets of the orifices are not aligned on the circumference around the nozzle body axis line 15b. On this occasion, the distances of the paths in the orifices are different from each other and resultantly the lengths of the orifices are varied. Consequently, it comes to be important to adjust the lengths of the orifices with the second step-recess portions B particularly in such a situation. However, when the function of reducing the bending stress exerting on a punch for press and the function of adjusting the lengths of orifices are given to the a recess, it comes to be difficult to freely change the depths of the recesses. In the present embodiment, the function of reducing the bending stress exerting on the punch is given to the first step-recess parts A (54a to 549) and separated from the function the second step-recess parts B (54b to 549) of adjusting the lengths of the orifices. By so doing, it is possible to realize recesses and orifices having good workability (having a high degree of freedom) with a high degree of machining accuracy.
Incidentally, the bending stress exerting on a punch increases as the angle between the punch and the processed surface is more deviated from 90 degrees. On this occasion, even though a thickness of the punch is used in consideration of the bending stress exerting on the punch, it is possible to prevent the strength of the member used for the processing of orifices from deteriorating since the steps of the first step-recess parts A having large diameters are low (the depths are shallow). It is possible to improve workability even during processing since the strength of the member used for the processing of orifices can be kept high during press forming.
Further, when a large number of orifices is formed, since the depths of the recesses having larger diameters are shallow, it is possible to prevent adjacent recesses and moreover a recess and an orifice from interfering with each other. In particular, even when the inclination angles θ of the orifices with respect to the nozzle body axis line 15b are different from each other and the orifices are oriented in desired directions, it is possible to prevent recesses and a recess and an orifice in specific orifices from interfering with each other. Furthermore, it is possible to increase the degree of freedom in the design of orifices and workability.
The present embodiment is effective also in the case of increasing the plate thickness in order to raise the strength of the orifice plate.
By the above measures, the outlets of the second step-recess parts B (54b to 59b) and the outlets of the orifices are perpendicular to the axis lines of the orifices respectively and hence the timing of fluid injection is equalized over the whole circumference. Consequently, it is possible to equalize the length of the penetration of the fuel injection and improve the evenness of fuel spray even with the orifices deflected from the nozzle axis line 15b. On this occasion, the depths of the first step-recess parts A (54a-59a) are sufficiently lower than the depths of the second step-recess portions B and hence the recesses A do not influence the fuel injection spray.
Next, a method for forming an orifice plate 15 is explained in reference to
Firstly, the orifice plate 15 is formed by cutting the nearly disc-shaped blank 15′ having the spherical surface portion (convex portion) 30 in the center of a surface as shown in
Next, as shown in
Next, as shown in
Next, as shown in
The surface of the stepped recesses is hardened by press-forming the first step-recess parts A (54a to 59a) and the second step-recess parts B (54b-59b) and hence it is possible to process the edges of the second step-recess parts B (54b-59b) and the orifices beautifully with a high degree of accuracy.
Further, since both the punch 43 for forming the first step-recess parts A (54a to 59a) and the punch 44 for forming the second step-recess parts B (54b-59b) pressed from the same directions and in particular the bottom face of each of the first step-recess parts A (54a to 59a) is already nearly perpendicular to the center axis line of the relevant first step-recess part, the material flows evenly in the circumferential direction. As a result, it is possible to align the center axis line of each of the first step-recess parts A (54a to 59b) and the center axis line of the relevant each of the second step-recess portion B nearly on the identical straight line. Further it is possible to keep the bottom face of each of the second step-recess parts B (54b to 59b) more accuracy perpendicular to the center axis lines of the relevant each of the first step-recess parts A (54a to 59a) and the second step-recess parts B (54b to 59b) than the bottom face of the first step-recess part A (54a to 59a).
As the punch 43 for forming the first step-recess parts A (54a to 59a), a punch having a larger diameter than the punch 44 for forming the second step-recess parts B (54b-59b) can be used. Further, the depth of each of the first step-recess parts A (54a to 59a) is shallower than the depth of the relevant second step-recess parts B (54b to 59b). As a result, as shown in
Next, as shown in
A problem here is that, when an orifice is deflected from the direction of the normal to the spherical surface portion 30, a punch undergoes uneven load during the forming of each of the first step-recess parts A (54a to 59a), bending load is imposed on the cutting blade 43a of the punch 43, and the punch 43 is damaged. By the present invention however, since the length of the cutting blade 43a of the punch 43 is shorter than the length of the cutting blade 45a of the punch 45 and the diameter of the cutting blade 43a is larger than the diameter of the cutting blade 45a, it is possible to enhance bending stiffness and form a planar portion nearly perpendicular to the orifice axis line without the punch 43 damaged even when bending load is imposed during processing. Further, during the succeeding processes of forming the second step-recess parts B (54b-59b) and the orifices, bending loads are not imposed on the cutting blade 44a of the punch 44 and the cutting blade 45a of the punch 45 and hence it is possible to press-form the second step-recess parts B (54b-59b) and the orifices with a high concentricity without the punches 44 and 45 damaged. Furthermore, the axis line of each of the orifices intersects nearly perpendicularly with the bottom face of each of the relevant the first step-recess parts A which is located at the exit of the relevant each of the second-step recess parts B and the bottom face of the relevant each of the second step-recess parts B which is located at the exit of the relevant orifice but it is also possible to form the bottom face of each of the second step-recess parts B so as to intersect more perpendicularly than the bottom face of each of the first step-recess parts A.
In the present embodiment, the diameters of the first step-recess parts A (54a to 59a), the second step-recess parts B (54b-59b), and the orifices decrease in this order. Consequently, the diameters of the punches used for the press forming of the portions also decrease in the order of the punch 43 for the first step-recess parts A (54a to 59a), the punch 44 for the second step-recess parts B (54b-59b), and then the punch 45 for the orifices. On the other hand, the forming depths increase in the order of the orifices (54 to 59), the second step-recess parts B (54b to 59b), and the first step-recess parts A (54a-59a). The punch 43 for the first step-recess parts A (54a to 59a) susceptible to the largest bending stress has a larger diameter and a shallower forming depth and hence the durability the punch improves.
In the case where inlets of the orifices are opened on the cone-shaped surface including the valve seat like the present embodiment, the thickness of the member forming the orifices is thicker than the case of forming orifices on a tabular member having a uniform thickness. Consequently, it comes to be important to reduce a bending stress exerting on a punch and adjust the lengths of the orifices by forming stepped recesses such as the first step-recess parts A (54a to 59a) and the second step-recess parts B (54b-59b) particularly in such a situation. On this occasion, it is possible to realize recesses and orifices having good workability with a high degree of machining accuracy by giving the function of reducing the bending stress exerting on a punch to the first step-recess parts A (54a to 59a), giving the function of adjusting the lengths of the orifices to the second step-recess parts B (54b-59b), and thus separating the functions of the first step-recess parts A (54a to 59a) and the second step-recess parts B (54b-59b).
Finally, by forming each of the orifices into a sac hole, the extruded portion 15b formed at the concave on the opposite surface of the spherical surface portion 30 is cutout by forming the nearly cone-shaped surface 15a (the valve seat) as shown in
In this way, by forming two-stepped recesses each of which has a plane nearly perpendicular to the center axis line of the relevant orifice at the spherical surface portion (convex) on the downstream side of the orifice, it is possible to easily form orifices having different injection directions by press forming with a high degree of accuracy. Consequently, even with a martensitic stainless steel (for example, SUS420J2) having a carbon content of 0.25% or more, it is possible to easily form a deep hole of an aspect ratio of 1.5 or more by pressing. Here, when a martensitic stainless steel having a carbon content of 0.25% or more is used, it is desirable that the hardness after quenching is not lower than 52 in HRC.
Further, since the outlet of each of the second step-recess parts B (54b-59b) and the outlet of the relevant orifice are formed on planes perpendicular to the axis line of the orifice, the injection timing of a fluid can be uniform over the whole circumference and it is possible to equalize the length of penetration and improve the homogeneity of injected fuel spray even with the orifices deflected (inclined) from the axis line of an injection valve.
Further, by changing the depths of the second step-recess parts B (54b-59b), it is possible to change the lengths of the relevant orifices and optimize the shape of injected fuel spray. On this occasion, since it is not necessary to change the thickness of the orifice plate tip 15c, the rigidity of the orifice plate 15 does not lower. For that reason, the present embodiment is suitable for an injection valve of a high fuel pressure type wherein the pressure on the orifice plate tip 15c is as high as 10 MPa or more.
Furthermore, since the depths of the first step-recess parts A (54a to 59a) are shallower than those of the relevant second step-recess parts B (54b-59b), the first step-recess parts A (54a to 59a) do not affect injected fuel spray.
Furthermore, by forming the first step-recess parts A (54a to 59a) on the spherical surface portion, bending load is not imposed on the punches during the forming of the second step-recess parts B (54b-59b) and the orifices and hence it is possible to press-form the second step-recess parts B (54b-59b) and the orifices with a high concentricity. Consequently, orifices of good surface roughness can be formed in comparison with the orifices formed by electric discharging or cutting, for example. As a result, it is possible to: reduce the amount of cinders, such as carbon produced by the combustion of a fuel when the fuel is injected into a cylinder, sticking to the first step-recess parts A (54a to 59a), the second step-recess parts B (54b-59b), and the orifices; and improve the fractionization, the shape, and the positional accuracy of atomization. In a running test of a real gasoline-powered vehicle, it is experimentally clarified that, in the case of a fuel injection valve using an orifice plate wherein the orifices are formed by electric discharging and each of the recesses has one step, cinders stick to the first step-recess parts A (54a to 59a) and the orifices and the flow rate lowers by 15% after the running of 30,000 km. In contrast, in comparison with a product by electric discharging, the concentricity and the surface roughness of the first step-recess parts A (54a to 59a), the second step-recess parts B (54b-59b), and the orifices of the present invention are good and hence it is possible to reduce the amount of cinders sticking to the first step-recess parts A (54a to 59a), the second step-recess parts B (54b-59b), and the orifices and control the variation of the flow rate to 1.7% or less.
Further, by positioning and forming the first step-recess parts A (54a to 59a), the second step-recess parts B (54b-59b), and the orifices while a blank is chucked, they can be positioned and formed at the processes with a high degree of accuracy without the necessity of positioning the plural orifices deflected from the axis line of an injection valve.
Furthermore, the method for press-forming orifices according to the present invention can reduce the processing time per hole up to about one thirtieth the processing time per hole in the method for processing orifices by electric discharging and hence it is possible to reduce the equipment investment and provide an orifice plate less expensive than a product by electric discharging.
Although the embodiments according to the present invention are concretely explained above, the present invention is not limited to the embodiments but may be variously modified within the range of the tenor of the present invention. For example, the explanations have been made on the premise that the region where the planar portion 33 is formed is the spherical surface portion 30 in the above embodiments, but the region may be a curved surface (a convex portion) other than a spherical surface.
Yet further, the spherical surface portion 30 of the blank 15′ is formed by cutting in the above embodiments but may be formed by press forming such as forging.
Still further, although the orifices are formed by extrusion in the above embodiments, each of the orifices may be formed by cutting off the fractured surface of the orifice so as to have a whole sheared surface when the seat surface is formed by cutting or electric discharging from the upstream side after the orifice is formed by punching.
In the present embodiments, since the rigidity (strength) of the orifice plate 15 is never lowered during the press forming of the orifices and the stepped recesses up to the end of the processing, it is possible to facilitate the press forming and realize the method for producing a fuel injection valve and orifices with high mass-productivity.
Further, it is possible to prevent orifices and stepped recesses from interfering with each other between adjacent orifices and increase the degree of freedom in the design of orifices (for example, an inclination angle, an orientation, and others).
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