JPWO2020084678A1 - Electromagnetic fuel injection valve - Google Patents

Abstract

A core 7 that comes into contact with the mover 3 in the valve open state is provided on the upstream side in the fuel injection direction, and the end face of the mover 3 on the upstream side in the fuel injection direction is contracted from the outer peripheral side end portion toward the downstream side in the fuel injection direction. A tapered surface having a diameter is formed, and the outer peripheral end portion of the core 7 is made to collide with the tapered surface so that the eccentric direction of the valve body 5 including the mover 3 inside the holder 6 after valve opening does not change. .. This prevents the valve body 5 from wobbling in the radial direction after the valve opening bounce, and improves the convergence of the valve opening bounce.

Description

The present application relates to an electromagnetic fuel injection valve.

As a fuel injection device for an internal combustion engine or the like, for example, an electromagnetic fuel injection valve disclosed in Patent Document 1 is known. In the electromagnetic fuel injection valve disclosed in Patent Document 1, an electromagnetic attraction force acts on the mover in the direction of the core by energizing the coil, and the valve body coupled to the mover slides in the holder. After that, the mover comes into contact with the core, which is the fixed iron core, and the valve is opened. Further, as shown in FIG. 5 of the same document, the mover has a tapered surface whose diameter is reduced from the end portion toward the downstream in the fuel injection direction. Further, as shown in FIG. 3 of the same document, the core has a plane facing the mover, and the end portion of the mover collides with the plane of the core when the valve is opened.

Japanese Patent Publication No. 8-506877 (Fig. 1, Fig. 5, Fig. 3)

In the electromagnetic fuel injection valve disclosed in Patent Document 1, when the coil is energized, a mover that receives an electromagnetic attraction force slides in the holder in the direction of the core and collides with the core at a predetermined speed. At the time of this collision, the mover receives a repulsive force in the direction perpendicular to the plane of the core, and the bounce of the valve body including the mover begins. The plane of the core is usually designed to be perpendicular to the axis of the fuel injection valve. However, due to manufacturing variations, there are products in which the plane of the core has an inclination of about several degrees with respect to the vertical. For this reason, the repulsion of the mover also becomes the inclination direction of the plane of the core, and the bounce bounces in the holder in the radial direction, and a product in which the bounce converges slowly has been manufactured. Then, there is a problem that the linearity of the low injection region in the injection amount characteristic deteriorates due to the slow convergence of the bounce.

The present application discloses a technique for solving the above-mentioned problems, and provides an electromagnetic fuel injection valve that improves the convergence of bounce after a valve opening collision and stabilizes the behavior of the valve body. The purpose is to do.

The electromagnetic fuel injection valve disclosed in the present application includes a valve body having a valve portion and a mover, a holder containing the valve body inside and having an inner peripheral surface having a gap with the mover. A core provided on the upstream side in the fuel injection direction of the valve body and in contact with the mover in the valve open state, a coil surrounding the outside of the core, and a valve seat in contact with the valve portion in the valve closed state. A spring that presses the valve body toward the valve closing side is provided.
A tapered surface is formed on the upstream end surface of the mover in the fuel injection direction to reduce the diameter from the outer peripheral end portion toward the downstream in the fuel injection direction, and the outer peripheral side is formed on the downstream end surface of the core in the fuel injection direction. A tapered surface that shrinks in diameter from the end toward the upstream side in the fuel injection direction is formed.
The diameter of the outer peripheral end of the mover is D1, the diameter of the outer peripheral end of the core is D2, the outer diameter of the mover is D3, and the inner diameter of the holder facing the outer diameter of the mover. When D4 is set, it is characterized by having a relationship of | D1-D2 | <D4-D3.

According to the electromagnetic fuel injection valve disclosed in the present application, it is possible to improve the convergence of the bounce after the valve opening collision of the valve body and stabilize the behavior of the valve body.

FIG. 5 is an overall cross-sectional view of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged explanatory view of a main part of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged view of a main part of a closed state of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged view of a main part at the time of a valve opening collision of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged view of a main part at the time of a valve opening collision of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged view of a main part at the time of a valve opening collision of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged explanatory view of a main part of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged explanatory view of a main part of the electromagnetic fuel injection valve according to the first embodiment. FIG. 5 is an enlarged explanatory view of a main part for explaining the shape of the mover of the electromagnetic fuel injection valve according to the second embodiment. FIG. 5 is an enlarged view of a main part of the electromagnetic fuel injection valve in the middle of opening according to the second embodiment. FIG. 5 is an enlarged explanatory view of a main part of the electromagnetic fuel injection valve according to the second embodiment.

Hereinafter, preferred embodiments of the electromagnetic fuel injection valve according to the present application will be described with reference to the drawings. In each figure, the same reference numerals indicate the same or corresponding parts.

Embodiment 1.
FIG. 1 is an overall cross-sectional view of the electromagnetic fuel injection valve according to the first embodiment. The electromagnetic fuel injection valve 1 is mounted so that the lower portion faces the intake pipe of the internal combustion engine, and the fuel supply pipe is connected to the upper portion to supply fuel under fuel pressure. In FIG. 1, the intake pipe and the fuel supply pipe are not shown.
The electromagnetic fuel injection valve 1 is provided with a valve portion 2 downstream in the fuel injection direction (hereinafter, simply referred to as downstream) and a mover 3 upstream in the fuel injection direction (hereinafter, simply referred to as upstream), and the valve portion 2 is provided. A pipe 4 for connecting the two is provided between the movable element 3 and the mover 3. The valve portion 2, the mover 3, and the pipe 4 form a valve body 5, and are housed inside the holder 6.

The electromagnetic fuel injection valve 1 is further provided with a core 7 which is a fixed iron core facing the mover 3, a coil 8 surrounding the outside of the core 7, and a spring provided inside the core 7 to press the valve body 5 downstream. 9. A rod 10 that serves as a base for the spring 9 and is solidified in the core 7, a terminal 11 for energizing the coil 8 from the outside, a valve seat 12 on which the valve portion 2 is seated and seats fuel, and a downstream side of the valve seat 12. It comprises a plate 13 that is coupled and has an orifice.

FIG. 2 is an enlarged explanatory view of a main part of the electromagnetic fuel injection valve 1. The upstream end surface of the mover 3 is formed with a tapered surface whose diameter is reduced from the outer peripheral end to the downstream side of the core 7. A tapered surface is formed on the end surface so that the diameter is reduced from the outer peripheral side end portion toward the upstream side. In the present embodiment, the inclination angle of the tapered surface is 10 ° with respect to the horizontal plane.

Here, the diameter of the upstream end of the mover 3 is D1, the diameter of the downstream end of the core 7 is D2, the outer diameter of the mover 3 is D3, and the inner diameter of the holder 6 facing the outer diameter of the mover 3. Let be D4. The mover 3 is housed with a gap from the inner circumference of the holder 6, and as shown in FIG. 2, the gap A on one side is (D4-D3) / 2. Further, the one-sided gap B between the upstream end of the mover 3 and the downstream end of the core 7 is | D1-D2 | / 2.

As shown in FIG. 2, when the coil 8 is not energized, the valve body 5 is pressed in the downstream direction by the load due to the fuel pressure and the load due to the spring 9, and the valve portion 2 comes into contact with the seat surface of the valve seat 12. And seal the fuel. The valve portion 2 is also housed with a gap from the inner circumference of the valve seat 12, and the presence of these gaps makes the valve body 5 slidable inside the holder 6.

However, in the actual electromagnetic fuel injection valve 1, the valve body 5 receives an eccentric load by the spring 9, and as shown in FIG. 3, the mover 3 comes into contact with the right side of the inner circumference of the holder 6, and A = on the right. (D4-D3) / 2 It is in an eccentric state. At this time, since the one-sided gap B between the upstream end of the mover 3 and the downstream end of the core 7 is formed shorter than A, the right end 3R of the mover 3 is shorter than the right end 7R of the core 7. It is on the right side, and the left end 3L of the mover 3 is on the right side of the left end 7L of the core 7.

In this state, when the coil 8 is energized through the terminal 11 by a command from a control device (not shown), an electromagnetic attraction force acts on the mover 3 in the direction of the core 7, and the electromagnetic force is a load due to the spring 9 and fuel pressure. When the amount exceeds, the valve body 5 is displaced toward the upstream, a gap is formed between the valve portion 2 and the valve seat 12, and fuel injection is started. The radial electromagnetic attraction acting between the outer circumference of the mover 3 and the inner circumference of the holder 6 is maximum on the right side where the gap is small, so that the magnetic attraction force is displaced in the axial direction while maintaining the state of being tilted to the right. In the above, right, right, or left, left means the right, right, or left, left in FIG. 3, and similarly in the following description, right, right, or right in the figure. It shall mean left and left.

After that, as shown in FIG. 4, when the mover 3 comes into contact with the core 7, the electromagnetic fuel injection valve 1 is opened. When the right tapered surface of the mover 3 collides with the right end portion 7R of the core 7, the mover 3 receives a reaction force F toward the right from the core 7 and repels, and bounce is started. Before the valve opening collision, the valve body 5 is in an eccentric state to the right side, and by receiving a reaction force in the right direction at the time of a collision, the valve body 5 is surely maintained in a state of being pressed to the right side, and there is radial rattling during bounce. Since there is no such thing and the behavior of the valve body 5 is stable, the convergence of bounce is improved.

FIG. 5 is a diagram illustrating a case where the left tapered surface of the core 7 and the left end 3L of the mover 3 collide with each other. When the left tapered surface of the core 7 collides with the left end 3L of the mover 3, the mover 3 receives a reaction force F toward the right of the core 7 and repels and starts bounce. Even in this state, the valve body 5 is in a state of being eccentric to the right side before the valve opening collision, and by receiving the reaction force F in the right direction at the time of the collision, the state of being pressed to the right side is surely maintained and bouncing. Since there is no rattling in the radial direction and the behavior of the valve body 5 is stable, the convergence of bounce is improved. In FIG. 5, C1 shows the center line of the end face of the core 7, and C2 shows the center line of the end face of the mover 3.

In FIG. 6, the right tapered surface of the mover 3 collides with the right end portion 7R of the core 7, and the mover 3 receives a reaction force F toward the right from the core 7 and repels to start bounce.

In this way, when the mover 3 is eccentric to the right in the holder 6, the right end 3R and the left end 3L of the mover 3 are on the right side of the right end 7R and the left end 7L of the core 7. Since they are located at each position, the mover 3 receives a reaction force in the right direction even if the inclination direction of the end face of the core 7 is different and the collision position is changed. Therefore, the state of being pressed to the right side is surely maintained, there is no radial rattling during bounce, and the behavior of the valve body 5 is stable, so that the convergence of bounce is improved.

As shown in FIG. 7A, the valve body 5 may be manufactured by inserting the pipe 4 into the mover 3 and then welding the boundary portion between the two over the entire circumference by, for example, irradiating the laser beam L. The boundary between the mover 3 and the pipe 4 irradiated with the laser beam L is once melted to form a joint, and then solidified to complete the joint. Since the melted portion contracts during solidification, the mover 3 swings from the joint as a starting point, and as shown in FIG. 7B, for example, it swings to the left.

In this way, when the valve body 5 in which the mover 3 is swung to the left is used, the collision position of the valve body 5 at the time of the valve opening collision is the right end portion 7R of the core 7, and the case shown in FIG. Similarly, since the right end portion 7R of the core 7 collides with the tapered surface of the mover 3, the mover 3 receives a reaction force in the right direction and surely maintains a state of being pressed to the right side in the radial direction during bounce. Since there is no rattling and the behavior of the valve body 5 is stable, the convergence of bounce is improved.

Embodiment 2.
Next, the electromagnetic fuel injection valve according to the second embodiment will be described. FIG. 8 is a diagram illustrating the shape of the mover of the electromagnetic fuel injection valve according to the second embodiment. The second embodiment is the same as the first embodiment except for the mover, and only the mover is shown in FIG.
In the electromagnetic fuel injection valve according to the second embodiment, a tapered surface is formed on the upstream end surface of the mover 3 so as to reduce the diameter from the outer peripheral end to the downstream, as in the first embodiment, and the inner diameter of the tapered surface is formed. The step portion 30 shown in FIG. 8 is formed on the side. The diameter D5 of the step portion 30 is D5 when the diameter of the downstream end of the core 7 is D2, the outer diameter of the mover 3 is D3, and the inner diameter of the holder 6 facing the outer diameter of the mover 3 is D4. It is configured to be <D2- (D4-D3). Therefore, even if the mover 3 has an eccentricity of (D4-D3) / 2 which is a clearance on one side, the step portion 30 is on the left side of the right end portion 7R of the core 7, and the tapered surface of the mover 3 is formed. It will collide with the right end 7R of the core 7. As shown in FIG. 8, a flat surface 31 having the same height as the right end 3R or the left end 3L of the mover 3 is connected to the step 30 to be formed on the inner peripheral side of the mover 3 to be flat. The inner diameter D6 of the surface 31 is connected to a curved portion or a chamfered portion (hereinafter referred to as a curved portion) 32 connected to the inner peripheral surface of the mover 3.

In this way, the step portion 30 is formed on the inner diameter side of the tapered surface of the mover 3, the diameter of the step portion 30 is D5, the diameter of the downstream end portion of the core 7 is D2, and the outer diameter of the mover 3 is D3. When the inner diameter of the holder 6 facing the outer diameter of the mover 3 is D4, the mover 3 is set in the relationship of D5 <D2- (D4-D3) during valve opening shown in FIG. The fuel flow G, which is pushed away by the movement and discharged from the outer peripheral side to the inner peripheral side of the mover 3, causes a fluid loss due to a sudden reduction in the flow path area when passing through the step portion 30, and the valve body 5 It becomes a resistance to the movement of the valve body, and when the gap between the mover 3 and the core 7 immediately before the valve opening is small, a buffering action for decelerating the valve body 5 works. This valve opening buffering action has the effect of reducing the amount of bounce in the axial direction of the valve body 5. That is, in the first embodiment, the wobbling of the valve body 5 in the radial direction is prevented to improve the convergence of the bounce, but in the second embodiment, the axial speed of the valve body 5 is reduced to reduce the bounce amount. It has been reduced and the convergence has been further improved.

In the second embodiment, a flat surface 31 having the same height as the right end 3R or the left end 3L of the mover 3 is connected to the step portion 30, and the inner diameter D6 of the flat surface 31 is the inner circumference of the mover 3. It is connected to the curved portion 32 formed on the surface. A fluid loss occurs in the fuel flow G that is pushed away by the movement of the mover 3 during valve opening and is discharged from the outer peripheral side to the inner peripheral side of the mover 3 due to the rapid contraction of the flow path when passing through the step portion 30. Not only this, but when the fluid flows out from the flat surface 31 to the inside of the mover 3, a fluid loss occurs in the curved portion 32 due to the rapid expansion of the flow path, so that it acts as a resistance to the movement of the valve body 5 and is movable immediately before the valve is opened. When the gap between the child 3 and the core 7 is small, a buffering action that decelerates the valve body 5 works.

As shown in FIG. 10, the flow path area when flowing out to the inside of the mover 3 is such that the flat surface 31 has the same height as the end portion of the mover 3, so that the mover 3 and the core 7 of the curved portion 32 are used. Since the gap height H of the curved portion 32 is extremely small, the flat surface 31 is connected to the inner peripheral side of the curved portion 32, and the diameter of the curved portion 32 is also relatively small, the flow path area of the curved portion 32 is extremely small. Therefore, the shape is such that the fluid loss due to the rapid expansion of the flow path is maximized.
Further, in the first embodiment, since the upstream end surface of the mover 3 is a tapered surface, the gap with the core 7 is large on the inner peripheral side, but in the second embodiment, the flat surface is on the inner peripheral side. By forming 31, the gap with the core 7 on the inner peripheral side becomes relatively small, and the electromagnetic attraction force acting on the mover 3 is further improved.

Although the present application describes various exemplary embodiments and examples, the various features, embodiments, and functions described in one or more embodiments are applications of a particular embodiment. It is not limited to, but can be applied to embodiments alone or in various combinations.
Therefore, innumerable variations not illustrated are envisioned within the scope of the techniques disclosed in the present application. For example, it is assumed that at least one component is modified, added or omitted, and further, at least one component is extracted and combined with the components of other embodiments.

1 Electromagnetic fuel injection valve, 2 valve, 3 mover, 3L left end, 3R right end, 4 pipe, 5 valve body, 6 holder, 7 core, 7R right end, 7L left end, 8 coil , 9 springs, 10 rods, 11 terminals, 12 valve seats, 13 plates, 30 steps, 31 flat surfaces, 32 bends, C1, C2 centerlines, F reaction forces, G fuel flow, L laser light.

Claims (5)

A valve body with a valve and a mover,
A holder that houses the valve body inside and has an inner peripheral surface that has a gap with the mover.
A core provided on the upstream side in the fuel injection direction of the valve body and in contact with the mover in the valve open state,
The coil that surrounds the outside of the core and
A valve seat that comes into contact with the valve when the valve is closed,
A spring that presses the valve body toward the valve closing side is provided.
A tapered surface is formed on the upstream end surface of the mover in the fuel injection direction to reduce the diameter from the outer peripheral end portion toward the downstream in the fuel injection direction, and the outer peripheral side is formed on the downstream end surface of the core in the fuel injection direction. A tapered surface that shrinks in diameter from the end toward the upstream side in the fuel injection direction is formed.
The diameter of the outer peripheral end of the mover is D1, the diameter of the outer peripheral end of the core is D2, the outer diameter of the mover is D3, and the inner diameter of the holder facing the outer diameter of the mover. An electromagnetic fuel injection valve having a relationship of | D1-D2 | <D4-D3 when D4 is set. The electromagnetic fuel injection valve according to claim 1, wherein the valve body is formed by welding a plurality of members. When a step portion is formed inside the tapered surface formed on the mover and the diameter of the step portion is D5, D5 <D2- (D4-) between the D2, the D3, and the D4. The electromagnetic fuel injection valve according to claim 1 or 2, wherein the electromagnetic fuel injection valve has the relationship of D3). A flat surface having the same height as the outer peripheral end portion is formed inside the tapered surface formed on the mover, and the flat surface is connected to a curved portion or a chamfered portion formed on the inner circumference of the mover. The electromagnetic fuel injection valve according to claim 1 or 2, wherein the electromagnetic fuel injection valve is formed as described above. When a step portion is formed inside the tapered surface formed on the mover and the diameter of the step portion is D5, D5 <D2- (D4-) between the D2, the D3, and the D4. With the relationship of D3)
A flat surface having the same height as the outer peripheral end portion is formed inside the tapered surface formed on the mover, and the flat surface is connected to a curved portion or a chamfered portion formed on the inner circumference of the mover. The electromagnetic fuel injection valve according to claim 1 or 2, wherein the electromagnetic fuel injection valve is formed as described above.

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