This application is based on and incorporates herein by reference Japanese Patent Application No. 2004-340438 filed on Nov. 25, 2004.
The present invention relates to a fuel injection valve, which is used for an internal combustion engine, and a manufacturing method for the fuel injection valve.
A fuel injection valve needs to have a high performance for atomizing fuel to reduce a toxic substance from exhaust gas and to improve fuel efficiency. Conventionally, a nozzle plate is provided to a tip end of a valve body in a fuel injection valve for producing atomizing performance of fuel. The valve body has a valve seat. The nozzle plate has a nozzle hole, through which fuel is injected. In this structure, when the diameter of the nozzle hole is the same, as the thickness of the nozzle plate decreases, the atomizing performance can be enhanced. By contrast, when the thickness of the nozzle plate decreases, strength of the nozzle plate decreases. High-pressure fuel is supplied to an inlet of the nozzle hole of the nozzle plate through the valve body, so that the fuel is injected into the engine. As the thickness of the nozzle plate decreases, the nozzle plate may deform to the side of the engine due to pressure of the fuel. According to JP-A-2004-60519 (US 2004 0069873 A1), the nozzle plate integrally connects to a cylindrical portion that covers the outer circumferential periphery of the valve body. The cylindrical portion is welded to the valve body, so that the nozzle plate is secured to the valve body. The fuel injection valve has a nozzle holder on the opposite side of the valve body with respect to the nozzle plate. The nozzle holder extends to the radially inner side, so that the nozzle holder supports the nozzle plate from the axially opposite side of the valve body. In this structure, the thickness of the nozzle plate increases excluding the bottom portion, in which the nozzle hole is formed. In addition, the nozzle plate is supported by the nozzle holder, so that the nozzle plate has strength resistive to pressure of fuel.
However, in this structure, the pressure of fuel is applied to the entire surface of the bottom portion of the nozzle plate. The nozzle hole is formed in the bottom portion of the nozzle plate. Therefore, the area of the surface, in which pressure of fuel is applied, increases in the nozzle plate. In addition, the thickness of the bottom portion, in which the nozzle hole is formed, becomes small in the nozzle plate, even though the thickness of the nozzle plate becomes large excluding the bottom portion. The bottom portion needs to be accurately formed in a thin recessed shape. As a result, a process and a cost increase for manufacturing the nozzle plate.
Furthermore, the thickness of the nozzle plate, particularly the thickness of the cylindrical portion may change due to modification in design of the fuel injection valve. In this case, a condition of welding between the nozzle plate and the valve body may change. Accordingly, the condition of welding needs to be set to respective nozzle plate for each design. As a result, versatility decreases.
Furthermore, the nozzle holder radially protrudes inwardly to the vicinity of the nozzle hole for supporting the nozzle plate. In this structure, fuel is apt to remain in the vicinity of the nozzle hole. Besides, the nozzle holder supports the nozzle plate from the outer circumferential periphery of the nozzle plate. In this structure, the thermal capacity increases in the vicinity of the nozzle plate. As a result, fuel remaining around the nozzle hole may be solidified by being exposed to high-temperature gas in a combustion chamber of the engine. Thus, the remaining fuel may become deposit stacking around the nozzle hole.
In view of the foregoing and other problems, it is an object of the present invention to produce a fuel injection valve and a manufacturing method of the fuel injection valve, the fuel injection valve having a strong nozzle plate, around which deposit can be restricted from stacking.
According to one aspect of the present invention, a fuel injection valve includes a valve body, a nozzle plate, and a weld portion. The valve body includes an axial end portion in an axial direction of the valve body. The axial end portion has an opening and an inner periphery. The opening connects with the inner periphery. The inner periphery is a substantially conical surface defining a valve seat. The nozzle plate is provided to the axial end portion of the valve body. The valve body and the nozzle plate form a boundary portion therebetween. The nozzle plate has a plurality of nozzle holes, through which an end surface of the nozzle plate on a side of the opening of the valve body communicates with an end surface of the nozzle plate on a side opposite to the valve body. The weld portion that connects the valve body with the nozzle plate. The weld portion extends from an outer circumferential periphery of the boundary portion, which is between the valve body and the nozzle plate, to an inner side in a radial direction of the valve body.
Alternatively, a nozzle plate has a substantially flat surface, which connects to the axial end portion of the valve body. The boundary portion includes the substantially flat surface of the nozzle plate. The nozzle plate has at least one nozzle hole that is a through hole, through which the opening of the valve body communicates with an end surface of the nozzle plate on a side opposite to the valve body. The weld portion extends from an outer circumferential periphery of the boundary portion, which is between the nozzle plate and the valve body. The weld portion extends to an inner side in a radial direction of the valve body.
A manufacturing method for the fuel injection valve includes welding the valve body with the nozzle plate from an outer side in a radial direction of the valve body to a surface, in which the valve body connects with the nozzle plate.
Alternatively, a manufacturing method for a fuel injection valve includes the following processes. An axial end face of the valve body is connected with an axial end face of the nozzle plate such that a plurality of nozzle holes of the nozzle plate communicates with an opening of the valve body. The axial end face of the valve body is welded with an outer circumferential periphery of the axial end face of the nozzle plate from an outer side in a radial direction of the valve body.
Alternatively, a manufacturing method for a fuel injection valve includes the following processes. A substantially flat surface of a nozzle plate is connected to an axial end surface of a valve body having an opening at a predetermined position such that a plurality of nozzle holes of the nozzle plate communicates with the opening of the valve body. An outer circumferential periphery of the substantially flat surface of the nozzle plate is welded with the valve body from an outer side in a radial direction of the valve body.
In the above structures and methods, force applied from high-pressure fuel onto the nozzle plate can be restricted, so that the thickness of the nozzle plate can be restricted, while the strength of the nozzle plate is maintained. Thus, atomization in the fuel injection can be enhanced by restricting the thickness of the nozzle plate. Therefore, a toxic substance may be reduced in exhaust gas, and fuel efficiency may be improved. Furthermore, the nozzle plate need not special manufacturing work such as reducing the thickness of the nozzle plate in a extremely limited position. Therefore, the structure of the nozzle plate may be simplified, and manufacturing work may be reduced.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
A fuel injection valve (injector) 10 shown in
As shown in
The housing 11 has first axial end, to which an inlet member 15 is provided. The inlet member 15 is press-inserted into the inner circumferential periphery of the housing 11. The inlet member 15 has a fuel inlet 16. A fuel pump (not shown) supplies fuel into the fuel inlet 16. The fuel flows from the fuel inlet 16 to the inside of the housing 11 through a fuel filter 17. The fuel filter 17 removes foreign matters contained in fuel.
The housing has the other end, to which a nozzle holder 20 is provided. The nozzle holder 20 is in a cylindrical shape. The nozzle holder 20 accommodates a valve body 21, which is in a cylindrical shape. As shown in
As referred to
As referred to
The movable core 45 is arranged in the inner periphery of the housing 11 such that the movable core 45 can axially move back and forth. The movable core 45 is formed of a magnetic material such as iron to be in a cylindrical shape. The axial end of the movable core 45 on the opposite side of the fixed core 43 integrally connects with the needle 24. The axial end of the movable core 45 on the side of the fixed core 43 makes contact with a spring 18. The spring 18 serves as a biasing member. The spring 18 has one axial end, which makes contact with the movable core 45. The spring 18 has the other axial end that makes contact with an adjusting pipe 19, which is press-inserted into the fixed core 43. The spring has resilience to extend in the axial direction thereof. Therefore, the movable core 45 and the needle 24 are pressed in the direction, in which the needle 24 seats onto the valve seat 23, by the spring 18. The adjusting pipe 19 is press-inserted into the fixed core 43. Biasing force of the spring 18 can be controlled by modifying degree of press-insertion of the adjusting pipe 19 relative to the fixed core 43. When the coil 42 is not supplied with electricity, the movable core 45 and the needle 24 are pressed to the side of the valve seat 23, so that the seal portion 25 seats onto the valve seat 23.
Next, a structure around the nozzle plate 30 is described.
As referred to
The tip end of the valve body 21 on the side of the opening 22 has a protruding portion 211. The protruding portion 211 of the valve body 21 has the diameter that is greater than the portion of the valve body 21 excluding the protruding portion 211. This valve body 21 excluding the protruding portion 211 guides the movement of the needle 24. The protruding portion 211 of the valve body 21 forms a boundary portion with the nozzle plate 30 therebetween. The valve body 21 forms a weld portion 32 with the nozzle plate 30 therebetween, such that the valve body 21 connects with the nozzle plate 30 via the weld portion 32. The weld portion 32 extends from the radially outer side of the valve body 21 and the nozzle plate 30 to the radially inner side thereof in the radial direction thereof. The weld portion 32 continuously extends in the circumferential direction of the valve body 21 and the nozzle plate 30. The valve body 21 connects with the nozzle plate 30 via the weld portion 32 in a predetermined range from the radially outer side to the radially inner side in the radial direction thereof, so that the valve body 21 and the nozzle plate 30 do not form a space substantially therebetween. That is, the weld portion 32 extends to the radially inner side with respect to the outer circumferential periphery 21b of the protruding portion 211 of the valve body 21.
As shown in
The valve body 21 and the nozzle plate 30 form the weld portion 32 therebetween, so that a space (gap) is restricted from being formed between the valve body 21 and the nozzle plate 30 radially in the predetermined range from the outer circumferential periphery to the radially inner side thereof.
High-pressure fuel passing along the valve seat 23 applies pressure to the radially inner side of the nozzle plate 30 with respect to the weld portion 32. That is, as referred to
As referred to
F=(φd/2)2 ×π×Pf
As shown in
By contrast, in this embodiment, as referred to
Next, an operation of the injector 10 is described.
The fixed core 43 and the movable core 45 do not generate magnetic attraction force therebetween, when electricity is terminated from being supplied to the coil 42. In this condition, both the movable core 45 and the needle 24 are biased by pressing force of the spring 18 to move to the opposite side of the fixed core 43. As a result, when the coil 42 is not supplied with electricity, the seal portion 25 of the needle 24 seats onto the valve seat 23, so that fuel is restricted from being injected through the nozzle hole 31.
When the coil 42 is supplied with electricity, the coil generates magnetic field, so that magnetic flux flows through the plate housing 44, the nozzle holder 20, the first magnetic portion 12, the movable core 45, the fixed core 43, and the second magnetic portion 14, thereby forming a magnetic circuit thereamong. Thus, the fixed core 43 and the movable core 45 generate magnetic attractive force therebetween. When the magnetic attractive force between the fixed core 43 and the movable core 45 becomes greater than the resilience of the spring 18, the movable core 45 and the needle 24 integrally move to the side of the fixed core 43. Thus, the seal portion 25 of the needle 24 lifts from the valve seat 23.
Fuel flows into the injector 10 through the fuel inlet 16, and the fuel flows through the fuel filter 17, the inner spaces of the inlet member 15, the adjusting pipe 19, and the movable core 45. The fuel further flows through a communication hole 451, the space between the housing 11 and the movable core 45, and the space between the needle 24 and the nozzle holder 20, so that the fuel flows into a fuel passage 26. The inside of the movable core 45 communicates with the outside of the movable core 45 through the communication hole 451. The fuel passing through the fuel passage 26 flows into the nozzle hole 31 through the space, which formed is between the valve seat 23 and the seal portion 25, and the opening 22. Thus, the fuel is injected through the nozzle hole 31.
When electricity supplied to the coil 42 is terminated, the attractive force between the fixed core 43 and the movable core 45 disappears. In this condition, the movable core 45 and the needle 24 are integrally moved to the opposite side of the fixed core 43 by resilience of the spring 18. Therefore, the seal portion 25 seats onto the valve seat 23 again, so that fuel is restricted from flowing between the fuel passage 26 and the nozzle hole 31. Thus, fuel injection is terminated.
In this embodiment, the valve body 21 and the nozzle plate 30 are welded from the radially outer position thereof on the extension line of the surface, via which the valve body 21 makes contact with the nozzle plate 30. In this method, the weld portion 32 is formed to extend from the radially inner side to the radially outer side between the valve body 21 and the nozzle plate 30. The weld portion 32 extends from the outer circumferential periphery 21b of the protruding portion 211 of the valve body 21 to the radially inner side in the protruding portion 211 of the valve body 21, so that the inner diameter φd1 of the pressure receiving surface of the nozzle plate 30 decreases. As a result, the force applied from the high-pressure fuel onto the nozzle plate 30 is reduced, so that the thickness of the nozzle plate 30 can be reduced, while the strength of the nozzle plate 30 is maintained. Thus, atomization in the fuel injection can be enhanced by reducing the thickness of the nozzle plate 30. Therefore, a toxic substance can be reduced in exhaust gas, and fuel efficiency can be improved. Furthermore, the nozzle plate 30 does not need special manufacturing work such as reducing the thickness thereof around the nozzle plate 31. Therefore, the structure of the nozzle plate 30 can be simplified, and manufacturing work can be reduced.
In this embodiment, the valve body 21 connects to the nozzle plate 30 by welding from the radially outer position on the extension line of the boundary surface between the valve body 21 and the nozzle plate 30. Therefore, the valve body 21 can be easily welded to the nozzle plate 30, regardless of the thickness of the nozzle plate 30. In this method, output power of the welder 51 need not be adjusted in accordance with the thickness of the nozzle plate 30, for example. Therefore, a welding facility need not be modified for every design of the nozzle plate 30, so that versatility of the welding facility can be enhanced by commonly using the welding facility for manufacturing various kinds of injectors.
In this embodiment, only the thin plate-shaped nozzle plate 30 is provided to the tip end of the valve body 21. Therefore, a protruding portion or another member is not provided in the vicinity of the nozzle hole 31 of the nozzle plate 30. The nozzle plate 30 is in a plate shape having a substantially uniform thickness, so that projections and depressions can be reduced in the vicinity of the nozzle hole 31. Furthermore, the nozzle plate 30 is provided to the protruding portion 211, which has the small diameter in the valve body 21, so that a thermal capacity decreases in the vicinity of the nozzle plate 30, thereby restricting fuel from remaining around the nozzle hole 31. As a result, even when fuel remaining around the nozzle hole 31 is exposed to high-temperature combustion gas in the combustion chamber 2, the fuel around the nozzle hole 31 can be restricted from solidifying. Thus, deposit can be restricted from stacking around the nozzle hole 31.
In this embodiment, as shown in
In this embodiment, the outer diameter of the small-diameter portion 27 is set to be substantially the same as the outer diameter of the nozzle plate 30. Therefore, the valve body 21 can be easily welded to the nozzle plate 30 from the radially outer position thereof.
In the third embodiment, as shown in
In the forth embodiment, as shown in
In the fifth embodiment, as shown in
The above structures of the embodiments can be combined as appropriate.
Various modifications and alternations may be diversely made to the above embodiments without departing from the spirit of the present invention.
Number | Date | Country | Kind |
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2004-340438 | Nov 2004 | JP | national |