The present invention relates to a fluid injecting portion and more particularly to surface roughness and a machining method for a fuel injecting portion in a fuel injection valve effective for a direct injection internal combustion engine.
A fuel injection valve in a direct injection internal combustion engine is exposed to combustion gas of a high temperature because it is installed in the interior of the engine. Therefore, for example carbon resulting from fuel combustion is apt to be deposited at a tip portion of the fuel injection valve. Foreign matters such as oil, additives and water are mixed in fuel and are deposited in the fuel injecting portion during operation of the engine. Such deposited foreign matters are called deposits. Once deposits are formed in the fuel injecting portion, there arises the problem that highly accurate fuel injection can no longer be effected no matter high accurately the fuel injection valve may be constructed.
Particularly, in the case of a fuel injection valve having plural orifices, the deposits become more influential because the orifices are small.
In view of this point, for example in Japanese Patent Laid Open No. Hei 10 (1998)-159688 (Patent Document 1), a volatile film is formed on an orifice surface with a surface roughness of Rz 1 micron or less to improve the deposits suppressing effect.
On the other hand, as a method for machining a plurality of deflected orifices in a nozzle there is known an electric discharge machining method which is disclosed in Japanese Patent Laid Open No. 2006-272484 (Patent Document 2). According to the machining method for deflected fine holes (orifices) which method is disclosed in Patent Document 2, prepared holes are formed in a workpiece beforehand by laser beam machining and are established their positions by image processing, thereafter, fine holes are formed by electric discharge machining.
Patent Document 1: Japanese Patent Laid Open No. Hei 10-159688
In Japanese Patent Laid Open No. Hei 10-159688, since orifices are formed by drilling, surface roughness is bad and is adjusted to Rz 1 μm or less by polishing. However, there still occur deposits and a percentage flow rate lowering becomes 10% or more, so a liquid repelling treatment is performed. However, in the prior art in question, no consideration is given to forming a recess (also called an aperture) in a nozzle tip face and making an orifice outlet open in the recess, nor is given any consideration to surface roughness of this recess.
Surface roughness is improved by polishing, but the shape and diameter of each orifice change as a result of polishing and thus the control of such orifice shape and diameter is difficult.
The present invention has been accomplished for solving the above-mentioned problems and it is an object of the invention to reduce the surface roughness of not only orifices but also apertures formed on orifice injection side and thereby prevent the adhesion of deposits without performing a liquid repelling treatment.
It is another object of the present invention to provide a method able to form, by press working, orifices and apertures with reduced surface roughness and thereby form a large number of deflected orifices easily, less expensively, in high productivity, with few variations in shape, accuracy and surface roughness even in a fuel injecting portion of a complicated shape, and without the need of polishing.
In the present invention, for achieving the above-mentioned object, in fuel injecting portions comprising orifices and apertures connected to outlet sides of the orifices, inner surfaces of the fuel injecting portions are all adjusted to Rz 2 μm in surface roughness. More specifically, all of orifices' inner surfaces and apertures' inner surfaces are adjusted to Rz 2 μm or less in surface roughness.
Moreover, apertures are formed by press working so as to have plastic-worked inner surfaces of Rz 0.2 μm or less in surface roughness and then bottom surfaces of the apertures are machined by press working into plastic-worked faces so as to have an orifice surface roughness of Rz 0.2 μm or less. Further, when the nozzle is required to have abrasion resistance, the nozzle is subjected to quenching to finish the inner surface of each fuel injecting portion to a surface roughness of Rz 2 μm or less.
According to the present invention, even in the case of a fuel injection valve having plural orifices in a direct injection internal combustion engine, the adhesion of deposits can be diminished and the fuel injection valve can be improved in durability by adjusting the orifices and apertures to Rz 2 μm or less in surface roughness.
Besides, since orifices and apertures can be formed with reduced surface roughness by press working, the machining can be done easily, less expensively, in high productivity and with few variations in shape, accuracy and surface roughness, using inexpensive equipment.
An embodiment of the present invention will be described below in detail.
An injection valve body 1 is composed of a magnetic circuit, the magnetic circuit comprising a core 2, a yoke 3, a housing 4 and a movable member 5, a coil 6 for energizing the magnetic circuit, and a terminal portion 7 for energizing the coil 6. A seal ring 8 is coupled between the core 2 and the housing 4 to prevent fluid such as fuel or the like from flowing into the coil 6.
Valve parts, including the movable member 5, a nozzle holder 9 and a ring 10 for adjusting the stroke quantity of the movable member 5, are housed in the interior of the housing 4. The movable member 5 comprises a valve element 11 and a movable core 12 coupled together using a joint 13. Between the movable core 12 and the joint 13 is disposed a plate 14 which conjointly with a pipe 18 suppresses bounding when the movable member 5 moves to close the valve.
The housing 4 and the nozzle holder 9, which constitute a shell member, cover the circumference of the movable member 5. In the nozzle holder 9 are provided an orifice plate 15, the orifice plate 15 having at the tip thereof a seat surface 15a (valve seat) and orifices 54 to 59, and a guide plate B17 which together with a guide plate A16 guides the movable member 5 slidably. The orifice plate 15 and the guide plate B17 may be constructed separately or integrally with respect to the nozzle holder 9. The orifices 54 to 59 are each formed with an inlet-side aperture downstream of a seat portion of the seat surface 15a (valve seat) which seat portion is in contact with the valve element 11.
In the interior of the core 2 are disposed a spring 19 for urging the valve element 11 to the seat surface 15a via the pipe 18 and the plate 14, an adjuster 20 for adjusting an urging load on the spring 19, and a filter 21 for preventing the entry of contamination from the exterior.
Now, a detailed description will be given below about the operation of the injection valve body 1 described above.
When the coil 6 is energized, the movable member 5 is attracted toward the core 2 against the urging force of the spring 19 and a gap is formed (valve open condition) between a valve seat portion 11a and the seat surface 15a which are located at the tip of the movable member 5. Pressurized fuel first flows from the core 2, adjuster 20 and pipe 18 into the nozzle holder 9 through a fuel passage 13a formed within the movable member 5. Next, the fuel flows from a fuel passage 16a formed in the guide plate A16 and a passage 9a formed in the nozzle holder into a passage 17a formed in the guide plate B17, then flows through the gap between the valve seat portion 11a and the seat surface 15a, further through the orifices 54 to 59 and is injected. The orifices 54 to 59 are formed at different angles in deflected directions relative to the axis of the injection valve.
On the other hand, upon de-energization of the coil 6, the valve seat portion 11a of the movable member 5 comes into abutment against the seat surface 15a by virtue of the spring 19 and the valve assumes a closed condition.
Next, a detailed description will be given below about the constructions of the orifice plate 15 and orifices 54 to 59 in the injection valve body 1.
The orifice plate 15 is a generally disc-like metallic plate. A spherical portion 30 as a curved convex portion is integrally formed at an approximately central part of one end face of the orifice plate 15 and a generally conical seat surface 15a having a stepped portion which constitutes a valve seat is formed at an end face of the orifice plate 15 on the side opposite to the spherical portion 30. In the spherical portion 30, orifices 54, 55, 56, 57, 58 and 59 for fuel injection are formed in angled directions relative to the nozzle axis, namely, at different angles in deflected directions, the orifices being arranged in predetermined directions relative to positioning holes 31a, 31b and 31c. On the side opening to the spherical portion 30, which side is a downstream side of the orifices 54 to 59, there are formed generally circular apertures A (54a, 55a, 56a, 57a, 58a and 59a) each defining a stepped portion, while on the side connected to the orifices, which side is an upstream side of the orifices, there are formed generally circular apertures B (54b, 55b, 56b, 57b, 58b and 59b) smaller in diameter than the apertures A, the apertures B being formed in bottoms of the apertures A. Thus, the apertures are each in the form of a recess having two stepped portions as a whole. Bottom faces of the apertures A and B are formed so as to be approximately orthogonal respectively to the axes of the orifices. The axes of each pair of apertures A, B and the axis of the associated orifice are substantially aligned with each other. The depth of each aperture A is smaller than the length of each orifice and smaller than the depth of each aperture B.
The orifice length is highly sensitive to the length of penetration, so by changing the depth of the aperture B 54b appropriately it is possible to optimize the length of the orifice 54 in consideration of spray shape and machinability. This is also true of the other orifices. By changing the depth of each aperture B it is possible to change the orifice length and it becomes possible to optimize the spray shape and improve the machinability. Therefore, at least two of the apertures B are different in depth orifice by orifice.
Among the above components, the apertures A and B serve as fuel injecting portions and the respective inner surfaces are quenched plastic-worked surfaces with a surface roughness of Rz 2 μm or less.
Next, a method for machining the orifice plate 15 and the surface roughness of each fuel injecting portion will be described below with reference to
A machining process for the orifice plate 15 will be described below with reference to
First, a description will be given about a punch for press working.
The orifice plate 15 is machined in the following manner. As shown in
Next, the fuel injecting portions are subjected to press working. In this step, positioning holes 31, apertures A (54a to 59a), apertures B (54b to 59b) and orifices 54 to 59 are subjected to press working in a continuous manner while chucking the blank 15′.
As shown in
Likewise, positioning holes 31b and 31c are formed. By thus forming the positioning holes 31a, 31b and 31c in the blank 15′ there is obtained such an orifice plate 15 as shown in
Then, while holding the orifice plate 15 with the collet chuck 42, the spherical portion 30 is urged with the cutting blade 43a of the punch 43 to form the aperture 54a by extrusion. Likewise, the apertures A (55a, 56a, 57a, 58a and 59a) are formed. Machining for the apertures A may be press working plus surface work hardening. By thus press working the orifice plate 15, such apertures A as shown in
Next, as shown in
Next, as shown in
When press-working the apertures A and B, the material is extruded forward like 15b, so that the plate thickness of each orifice-machined portion can be made larger than in the form of a blank and hence it is possible to suppress the occurrence of a fracture surface.
Besides, since the blank can be made thin, a machining stress in orifice machining can be made low and hence it is possible to improve the orifice accuracy and the punch life.
Further, since each orifice-machined portion swells partially (15b) as a result of extrusion of each aperture B, the flow of material to an adjacent orifice in orifice machining is lessened and a previously-machined orifice is difficult to deform, thus permitting a high accuracy machining.
Additionally, since each orifice is formed in the shape of a blind hole, its rigidity is high, and when an adjacent orifice is subjected to press working, an already-machined orifice is difficult to deform and hence a highly accurate machining can be achieved (if each orifice is punched, the orifice becomes less rigid and therefore becomes easier to deform when an adjacent hole is formed by punching).
Next, as shown in
Next, for improving the abrasion resistance of the seat surface 15a which serves as an abutting surface of the movable valve 5, the orifice plate 15 is subjected to quenching to a hardness of HRC 52 to 56 for example in the case of martensitic stainless steel SUS420J2. At this time, the orifice plate 15 undergoes recrystallization by martensitic transformation and the inner surfaces of the apertures A, B and orifices become Rz 2 μm or less in surface roughness.
Next, as shown in
Lastly, burrs developed on the upstream side of the orifices are removed by seat surface finish machining to complete the orifice plate. As the method for removing the burrs there may be adopted any of various methods, but it is preferable that the burrs be removed at a time by water jet for example.
By going through the above steps a plurality of orifices and apertures different in deflection angle can be formed easily, less expensively, in good productivity, with a surface roughness of Rz 2 μm or less, and with few variations in shape, accuracy and surface roughness.
Consequently, the adhesion of deposits such as carbon resulting from combustion of fuel in direct injection to the apertures A, B and orifices can be diminished and it is possible to provide a fuel injection valve which retains the performance in its initial state and which is superior in durability.
For example, in a running test with an actual gasoline-fueled vehicle, a fuel injection valve using an orifice plate having one-step apertures formed with orifices (surface roughness Rz 5.5 μm) by electric discharge machining had deposits, etc. adhered to the apertures and orifices after 30,000 km running, resulting in 15% lowering of the flow rate. This was made clear in the above test.
On the other hand, as to the fuel injection valve according to the present invention, since the apertures A, B and orifices are superior in surface roughness to those of the valve machined by electric discharge machining, so that the adhesion of deposits to the apertures A, B and orifices could be diminished and there was no change in the flow rate after 42,000 km running.
Moreover, by forming the positioning holes, apertures A, B and orifices while chucking the blank, the machining can be done with a high positional accuracy in each step without the need of alignment for plural orifices deflected relative to the axis of the injection valve.
The method of forming the orifices by press working according to the present invention, in comparison with the electric discharge machining method for the orifices, can shorten the machining time per orifice to about one-thirtieth, thus making it possible to suppress equipment investment and provide a less expensive orifice plate.
Although the present invention has been described above by way of an embodiment thereof, the present invention is not limited to the above embodiment, but various changes may be made within the scope of the inventive idea of the present invention.
For example, although in the above embodiment a description was given assuming that the apertures A-forming area was the spherical portion 30, the said area may be any other curved surface area (curved surface portion) than the spherical area. Moreover, the apertures A may be omitted and there may be a one-step shape with only apertures B.
Number | Date | Country | Kind |
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2008-227722 | Sep 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/062169 | 6/26/2009 | WO | 00 | 8/17/2010 |