JPH0566264U - Fuel injection nozzle - Google Patents

Abstract

(57) [Abstract] [Purpose] Fuel injection that can increase the fuel injection angle with respect to the axis of the engine cylinder according to the engine load, thereby increasing fuel efficiency and reducing the generation of hydrocarbons and the like. Provide a nozzle. [Structure] The plurality of injection holes formed in the nozzle body 30 are
First group of plural injection holes 36 and second group of plural injection holes 37
Includes and. The injection holes of the first group and the injection holes of the second group are alternately arranged in the circumferential direction and are separated from each other. The first group of injection holes forms a smaller angle with respect to the axis of the engine cylinder than the second group of injection holes. The inner end of the injection hole of the first group is located at the valve seat 35, and the inner end of the injection hole of the second group is located further away from the inner end of the injection hole of the first group in the axial direction. In the state where the contact portion 55 of the needle valve 50 is seated on the valve seat, the inner end of the injection hole of the first group faces the outer peripheral surface of this contact portion.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a fuel injection nozzle for injecting fuel, which is pumped from a fuel injection pump, into a combustion chamber of an engine.

[0002]

[Prior Art]

 The fuel injection nozzle includes a hollow elongated nozzle body having a closed lower end and a needle valve housed in the nozzle body, as disclosed in, for example, JP-A-1-92569. The nozzle body has a fuel reservoir chamber, a tapered taper valve seat formed on the inner surface of the lower end portion, and a plurality of injection holes formed in the lower end portion. The inner ends of these injection holes are located at the valve seat of the nozzle body. On the other hand, the needle valve has a pressure receiving portion facing the fuel storage chamber and a tapered cone-shaped contact portion formed at the lower end portion. The needle valve is biased by the force of a spring, and its contact portion is seated on the valve seat. In this seated state, the inner end of the injection hole is blocked by the outer peripheral surface of the contact portion. The pressure of the fuel sent from the fuel injection pump to the fuel storage chamber acts on the pressure receiving part, so that the needle valve lifts against the spring and the contact part separates from the valve seat. As a result, the injection hole is opened and fuel is injected into the engine combustion chamber.

In the above-mentioned fuel injection nozzle, the plurality of injection holes are classified into first and second injection holes. The first injection hole forms an acute angle with the axial direction of the nozzle body, and the second injection hole forms an approximately right angle. The fuel injection nozzle is attached to the engine in a state in which it is inclined with respect to the axis of the engine cylinder, so that all the injection holes have substantially the same inclination angle with respect to the axis of the engine cylinder.

Japanese Utility Model Publication No. 62-87171 discloses a fuel injection nozzle equipped with a nozzle body and a needle valve. The nozzle body has a tapered valve seat formed on the inner surface of the lower end and a small chamber formed below the valve seat. A single first injection hole and a plurality of second injection holes having different inclinations are formed at the lower end of the nozzle body. The first injection hole extends substantially horizontally and the second injection hole extends obliquely downward when the fuel injection nozzle is mounted on the engine in a slightly inclined manner. The inner end of the first injection hole is opened to the valve seat, and the inner end of the second injection hole is opened to the inner peripheral surface of the small chamber. The needle valve has a tapered cone-shaped contact portion and a throttle portion formed at the lower end of the contact portion. The throttle part has entered the small chamber with the contact part seated on the valve seat. In this seated state, the inner end of the first injection hole is closed by the outer peripheral surface of the contact portion, and the inner end of the second injection hole is closed by the outer peripheral surface of the throttle portion. When the needle valve lifts, the abutment part separates from the valve seat in the first stage where the lift is small, so the first injection hole opens and fuel is injected from the first injection hole toward the spark plug. At this initial stage, the second injection hole is closed because the throttle part remains in the small chamber. When the needle valve is further lifted, the throttle portion comes out of the small chamber, so that the second injection hole opens and fuel is injected from the second injection hole.

[0005]

[Problems to be solved by the device]

 In the fuel injection nozzle disclosed in Japanese Unexamined Patent Publication No. 1-92569, the fuel injection angle with respect to the axis of the engine cylinder is constant irrespective of the load, so that the required fuel injection angle cannot be obtained under low load and high load. .. More specifically, when the load is small and the amount of fuel injection is small, the temperature of the wall surface of the combustion chamber is low, so it is necessary to reduce the fuel injection angle and inject fuel downward. If the fuel injection angle is large, the fuel will adhere to the inner surface of the cylinder head (which forms part of the combustion chamber) due to the air flow accompanying the rise of the piston, and the vaporization of the fuel will be delayed, causing the generation of hydrocarbons, etc. It is from. Further, when the load is high, it is required to increase the fuel injection angle. This is because if the fuel injection angle is small, the fuel cannot be injected in a sufficiently wide range. When the actual fuel injection angle is brought closer to the relatively small fuel injection angle required under low load, the above problem under high load becomes remarkable. On the contrary, when approaching the relatively large fuel injection angle required under high load, the problem under low load becomes remarkable.

Even if the fuel injection nozzle of Japanese Patent Laid-Open No. 1-92569 is mounted parallel to the axis of the engine cylinder, there are the following drawbacks. That is, the inner ends of the first and second injection holes are at the same position in the axial direction of the nozzle body. Therefore, when the needle valve is lifted, the pressures at the inner ends of the first and second injection holes are equal, so that the fuel is always injected in the first injection regardless of the lift amount of the needle valve, that is, regardless of the load. The fuel is injected diagonally downward from the hole, and the fuel is injected laterally from the second injection hole, so the fuel injection direction cannot be changed according to the load. In particular, since the direction of fuel injection from the second injection hole is horizontal, there is a problem that fuel adheres to the inner surface of the cylinder head at low temperature when the load is low.

In the fuel injection nozzle of Japanese Utility Model Laid-Open No. 62-87171, when the needle valve lift is small, the fuel is injected laterally from the first injection hole, so it is similar to the fuel injection nozzle of Japanese Patent Laid-Open No. 1-92569. There is a problem.

An object of the present invention is to increase the injection angle of fuel with respect to the axis of the engine cylinder according to the engine load, that is, the fuel injection amount, thereby increasing combustion efficiency and generating hydrocarbons and the like. It is to provide a fuel injection nozzle that can be reduced.

[0009]

[Means for Solving the Problems]

 The fuel injection nozzle of the present invention has the following basic structure like the conventional fuel injection nozzle. (A) A hollow elongated nozzle body with a closed tip. This nozzle body has a fuel reservoir chamber formed at an intermediate position, a tapered taper valve seat formed on the inner surface of the tip portion, and a plurality of injection holes formed at the tip portion and separated from each other in the circumferential direction. ing. (B) A needle valve housed in the nozzle body. This needle valve has a pressure receiving portion formed to face the fuel storage chamber of the nozzle body, and a tapered cone-shaped contact portion formed ahead of the pressure receiving portion. (C) Spring means for urging the needle valve to seat its abutting portion on the valve seat. Due to the fuel pressure in the fuel storage chamber acting on the pressure receiving portion, the needle valve receives a force against the spring step and the contact portion separates from the valve seat. The fuel injection nozzle is attached to the cylinder head so that its tip end faces the cylinder of the engine. The fuel injection nozzle of the present invention further has the following features. The plurality of ejection holes include a plurality of ejection holes of the first group and a plurality of ejection holes of the second group. The injection holes of the first group and the injection holes of the second group are alternately arranged in the circumferential direction and are separated from each other. The first group of injection holes forms a smaller angle with respect to the axis of the engine cylinder than the second group of injection holes. The inner end of the injection hole of the first group is located at the valve seat, and the inner end of the injection hole of the second group is located further away from the inner end of the injection hole of the first group in the axial direction. In the state where the contact portion of the needle valve is seated on the valve seat, the inner end of the injection hole of the first group faces the outer peripheral surface of the contact portion.

[0010]

[Action]

 Due to the throttling effect in the clearance between the valve seat of the nozzle body and the contact portion of the needle valve, the injection hole can be selected according to the engine load. More specifically, when the engine load, that is, the fuel injection amount is small, the fuel is injected from the injection holes of the first group, so the fuel injection angle with respect to the axis of the engine cylinder is small, and the adhesion of fuel to the cylinder head is reduced. You can When the engine load is large, the fuel is injected from the injection holes of the second group, so this fuel injection angle is large and the fuel can be widely distributed. Moreover, since the plurality of injection holes of the first and second groups are formed in the circumferential direction, the deviation of the fuel distribution in the circumferential direction of the engine cylinder is reduced. As a result, combustion efficiency can be improved and the generation of hydrocarbons and the like can be reduced.

[0011]

【Example】

 Hereinafter, the present invention will be described with reference to the drawings. As shown in FIG. 3, the fuel injection nozzle N has an elongated nozzle holder 10, a disk-shaped spacer 20, and an elongated nozzle body 30 in order from top to bottom. The nozzle body 30 is supported by the nozzle holder 10 by a tubular retainer 40. More specifically, a male screw 11 is formed on the outer periphery of the lower end of the nozzle holder 10. A female screw 41 is formed on the inner circumference of the upper end of the retainer 40, and a tapered step 42 is formed on the inner circumference of the lower end. A tapered step 38 is formed in the middle of the nozzle body 30. Then, by inserting the female screw 41 of the retainer 40 into the male screw 11 of the nozzle holder 10 with the nozzle body 30 inserted in the retainer 40, the nozzle body 30 is coaxial with the nozzle holder 10 and is attached to the nozzle holder 10. Supported. In this supporting state, the spacer 20 is sandwiched between the lower surface of the nozzle holder 10 and the upper surface of the nozzle body 30, and the step 42 of the retainer 40 strongly contacts the step 38 of the nozzle body 30. In this way, the nozzle holder 10, the spacer 20, the nozzle body 30 and the retainer 40 cooperate to form one body.

The nozzle body 30 has an elongated tubular shape, and the lower end is closed. The nozzle body 30 has a guide hole 31, a fuel reservoir chamber 32, a fuel passage hole 33, and a tapered taper hole 34 in order from the upper end to the lower end side. The fuel passage hole 33 has a smaller diameter than the guide hole 31, and both are coaxial. The fuel reservoir chamber 32 includes a fuel inlet 18 formed in the upper end surface of the nozzle holder 10, a fuel passage 19 formed along the longitudinal direction of the nozzle 10, a fuel passage 29 formed in the spacer 20, and a nozzle. They are connected to each other via a fuel passage 39 extending in the longitudinal direction of the main body 30. The fuel inlet 18 is connected to a fuel injection pump (not shown) via a pipe.

A needle valve 50 is housed in the nozzle body 30. The needle valve 50 has a slide portion 51, a pressure receiving portion 52, an extension portion 53, a first taper portion 54, and a second taper portion 55 which are arranged coaxially in this order from the upper end to the lower end. There is. The extension portion 53 has a smaller diameter than the slide portion 51, and the pressure receiving portion 52 is tapered. The slide portion 51 is accommodated in the guide hole 31 of the nozzle body 30 so as to be slidable in the axial direction. The pressure receiving portion 52 faces the fuel storage chamber 32 of the nozzle body 30 and receives the pressure of the fuel storage chamber 32. The extension portion 53 is disposed in the fuel passage hole 33 of the nozzle body 30, and the gap between the outer peripheral surface of the extension portion 53 and the inner peripheral surface of the fuel passage hole 33 is provided as a fuel passage. The tapered first taper portion 54 and second taper portion 55 are arranged in the taper hole 34 of the nozzle body 30.

As well shown in FIG. 1, the taper angle of the second taper portion 55 of the needle valve 50 is extremely small (for example, about 10 minutes) larger than the taper angle of the taper hole 34, Practically equal. Therefore, the second tapered portion 55 can make surface contact with the inner peripheral surface of the tapered hole 34 in a slightly elastically deformed state by the force of the spring 60 described later. Hereinafter, the second tapered portion 55 will be referred to as a contact portion. Since the taper angle of the first taper portion 54 is smaller than the taper angle of the contact portion 55 and the taper hole 34, it does not contact the inner peripheral surface of the taper hole 34. Of the abutting portion 55, the boundary portion of the second tapered portion 54 comes into strong contact with the inner peripheral surface of the tapered hole 34, so that it is provided as the main abutting portion 55a, and the portion below the abutting portion 55a is the sub-abutting portion. It is provided as part 55b. Further, an annular portion of the inner peripheral surface of the tapered hole 34 with which the contact portion 55 abuts is provided as a valve seat 35. A portion of the valve seat 35 with which the main contact portion 55a abuts is provided as a main seat portion 35a, and a portion with which the sub contact portion 55b makes a surface contact is provided as a sub seat portion 35b.

As shown in FIG. 3, the needle valve 50 is urged downward by the force of the spring 60, and the contact portion 55 is in contact with the valve seat 35. The spring 60 is housed in the housing hole 15 formed at the lower end of the nozzle holder 10, and acts on the needle valve 50 via the spring receiver 61 and the protrusion 58 formed at the upper end of the needle valve 50.

Next, the features of the present invention will be described with reference to FIGS. 1 and 2. At the lower end of the nozzle body 30, five injection holes 36 of the first group (hereinafter referred to as first injection holes) and five injection holes 37 of the second group (hereinafter referred to as second injection holes) are provided. Are formed. The first injection holes 36 and the second injection holes 37 are alternately arranged in the circumferential direction and are separated from each other. Each of the first injection holes 36 and 37 extends along an imaginary plane including the axis X of the nozzle body 30. Angle Θ formed by the axis X of the nozzle body 30 and the first injection hole 36 ₁ Is the angle Θ formed by the axis X and the second injection hole 37.₂Smaller than The inner end of the first injection hole 36 and the inner end of the second injection hole 37 are both located on the valve seat 35 and are separated from each other in the axial direction of the nozzle body 30. That is, the inner end of the first injection hole 36 is located above the inner end of the second injection hole 37. The inner ends of all the first injection holes 36 are arranged on an imaginary plane orthogonal to the axis of the nozzle body 30, and similarly, the inner ends of all the second injection holes 37 are also orthogonal to the axis of the nozzle body 30. It is placed on another virtual plane. Further, the outer ends of all the first injection holes 36 and the second injection holes 37 are separated from each other in the circumferential direction, and are arranged on another virtual plane orthogonal to the axis of the nozzle body 30.

The fuel injection nozzle N configured as described above is attached to the engine E as shown in FIG. In this embodiment, the axis line X of the fuel injection nozzle N is parallel to the axis lines of the cylinder S and the piston P and is eccentric to the right in the figure. Accordingly, as shown in FIG. 2, the distance between the injection holes 36 and 37 located on the right side of the nozzle body 30 is wider than the distance between the injection holes 36 and 37 located on the left side.

Fuel is intermittently sent from the fuel injection pump to the fuel injection nozzle N configured as described above. Since the needle valve 50 is pushed downward by the force of the spring 60 in the state where no fuel is pumped, the contact portion 55 of the needle valve 50 is seated on the valve seat 35 in a surface contact state. In this state, the inner ends of the injection holes 36 and 37 face the outer peripheral surface of the contact portion 55 and are closed by this outer peripheral surface.

When the fuel is pumped from the fuel injection pump, the pressure in the fuel reservoir chamber 32 rises, and this pressure acts on the pressure receiving portion 52 of the needle valve 50, so that the needle valve 50 lifts and the needle valve 50 The abutting portion 55 of is separated from the valve seat 35. At this time, the fuel that has passed through the fuel passage hole 33 from the fuel reservoir chamber 32 is injected into the combustion chamber C of the engine E from either of the injection holes 36 and 37. The fuel injection direction changes due to the throttling effect in the clearance between the outer peripheral surface of the contact portion 55 and the inner peripheral surface of the valve seat 35. The details will be described below.

When the load of the engine E is small and the amount of fuel pumped from the fuel injection pump is small, the lift amount of the needle valve 50 is small. In this case, since the clearance between the outer peripheral surface of the contact portion 55 and the inner peripheral surface of the valve seat 35 is small, the fuel is delayed by this clearance and injected from the first injection hole 36. In other words, due to the pressure loss due to the throttling effect in this clearance, the inner end of the first injection hole 36 is higher than the pressure of the inner end of the second injection hole 37, so that the first injection hole 36 is for fuel injection. The fuel injection from the second injection hole 37 is not performed. Therefore, as shown by the arrow A in FIG. 4, the fuel is injected obliquely downward from the lower end of the fuel injection nozzle N into the combustion chamber C at a small angle with the axis of the cylinder S. Therefore, the fuel does not adhere to the surface of the cylinder head H due to the air flow accompanying the rise of the piston P, and the vaporization of the fuel can be favorably performed even if the temperature of the surface of the cylinder head H is low. Also, by injecting the fuel diagonally downward, the fuel can be collected near the center of the combustion chamber, and a proper mixture ratio of fuel and air can be locally obtained despite the small amount of fuel injection. You can Further, since the fuel injection is performed through the plurality of first injection holes 36 that are separated in the circumferential direction, it is possible to avoid a significant deviation in the fuel distribution in the combustion chamber C. As a result, the combustion efficiency can be increased and the generation of hydrocarbons can be suppressed.

When the load on the engine E increases, the amount of fuel pumped from the fuel injection pump increases, and the lift amount of the needle valve 50 increases. In this case, first, in the initial stage of lift of the needle valve 50, the clearance between the outer peripheral surface of the contact portion 55 and the inner peripheral surface of the valve seat 35 is small. Is ejected obliquely downward as indicated by arrow A. Further, when the needle valve 50 is lifted by a predetermined amount or more, the clearance is increased. As a result, the fuel passes through this clearance and tends to stay at the lower end of the nozzle body 30. Then, the pressure at the inner end of the first injection hole 36 becomes lower than the pressure at the inner end of the second injection hole 37 due to the Venturi effect accompanying the passage of fuel through this clearance. As a result, the fuel injection is switched from the second injection hole 37, and the injection is performed at a large angle with respect to the axis of the cylinder S from the lower end of the nozzle body 30 as shown in FIG. Therefore, the fuel can be widely distributed. Since the fuel injection is performed through the plurality of second injection holes 37 that are separated in the circumferential direction, the fuel distribution in the combustion chamber C can be homogenized. As described above, when the fuel injection amount is large, the fuel can be widely and evenly distributed to optimize the mixing ratio with air, so that the combustion efficiency can be improved and the occurrence of smoke and the like can be suppressed.

In the embodiments described below, the configurations corresponding to the preceding embodiments are denoted by the same reference numerals in the drawings, and detailed description thereof will be omitted. In the embodiment shown in FIG. 5, the nozzle body 30 includes a tapered hole 34, a valve seat 35 formed by a part of the inner peripheral surface of the tapered hole 34, a first injection hole 36, and a second injection hole 37. And have. On the other hand, the needle valve 50 has a slide portion and a pressure receiving portion (not shown), an extension portion 53, a first taper portion 54, a second taper portion 55 (contact portion), and a third taper portion 56. is doing. The relationship between the first taper portion 54, the contact portion 55, and the taper angle of the valve seat 35 is the same as in the above-described embodiment. The taper angle of the third taper portion 56 is much larger than the taper angle of the valve seat 35. In this embodiment, only the inner end of the first injection hole 36 is located on the valve seat 35, and is closed by the outer peripheral surface of the contact portion 55 when the needle valve 50 is seated. The inner end of the second injection hole 37 opens at the lower end of the inner surface of the tapered hole 34, but is separated downward from the valve seat 35. In the seated state of the needle valve 50, the second injection hole 37 is not blocked by the outer peripheral surface of the contact portion 55.

In the embodiment of FIG. 6, the taper angle of the contact portion 55 of the needle valve 50 is slightly larger than the taper angle of the valve seat 35, and only the main contact portion 55 a of the contact portion 55 has the valve seat 35. Line contact with the main sheet portion 35a. In FIG. 6, the difference in taper angle between the two is exaggerated. In this embodiment, the sub seat portion 35b of the valve seat 35 and the sub contact portion 55b of the contact portion 55 are separated from each other by a very small amount. The inner end of the first injection hole 36 is located in the sub seat portion 55b and is not completely blocked by the outer peripheral surface of the contact portion 55 of the needle valve 50.

The present invention is not limited to the above-described embodiments, and can be modified as appropriate without departing from the scope of the invention. When the fuel injection nozzle is mounted so as to be inclined with respect to the axis of the engine cylinder, the inclination angles of the first injection holes with respect to the axis of the nozzle body are different from each other, and the inclination angles with respect to the axis of the engine cylinder are equal to each other. Similarly, the inclination angles of the second injection holes with respect to the axis of the nozzle body are also different, and the inclination angles with respect to the axis of the engine cylinder are equal to each other. Further, the inclination angle of the first injection hole with respect to the axis of the engine cylinder is smaller than the inclination angle of the second injection hole with respect to the axis of the engine cylinder. In this case, it is preferable that the outer end of each injection hole is arranged on a virtual plane orthogonal to the axis of the engine cylinder. The positions of the inner ends of all the first injection holes are preferably arranged on a plane orthogonal to the axis of the nozzle body. Similarly, the positions of the inner ends of all the second injection holes are also the axes of the nozzle body. It is preferable to dispose it on a plane orthogonal to.

The fuel injection nozzle may be provided with three or more groups of injection holes which are located at the inner end with respect to the axis of the nozzle body and have different inclination angles with respect to the axis of the engine cylinder. In this case, the injection holes of the first, second, and third groups are repeatedly arranged in this order in the circumferential direction of the nozzle body. Even if the injection holes are in the same group, the position of the inner end with respect to the axis of the nozzle body and the angle of inclination with respect to the axis of the engine cylinder may be slightly different from each other, as long as they can be distinguished from the injection holes of other groups. Good.

[0026]

[Effect of the device]

 As described above, according to the present invention, when the engine load, that is, the fuel injection amount is small, the fuel is injected from the injection holes of the first group, so that the fuel injection angle with respect to the axis of the engine cylinder is small and the cylinder head is small. It is possible to reduce the fuel adhesion to the. When the engine load is large, the fuel is injected from the injection holes of the second group, so that the fuel injection angle is large and the fuel can be widely distributed. Moreover, since the injection holes of the first and second groups are also formed in the circumferential direction, the deviation of the fuel distribution in the circumferential direction of the engine cylinder is reduced. As a result, the combustion efficiency can be improved and the generation of hydrocarbons and the like can be reduced.

[Brief description of drawings]

FIG. 1 is an enlarged cross-sectional view of a lower end portion of a fuel injection nozzle according to the present invention.

FIG. 2 is a bottom view of the fuel injection nozzle.

FIG. 3 is a vertical sectional view of a fuel injection nozzle according to the present invention.

FIG. 4 is a schematic cross-sectional view showing a state in which the fuel injection nozzle is attached to an engine.

FIG. 5 is a view corresponding to FIG. 1 showing another embodiment.

FIG. 6 is a view corresponding to FIG. 1 showing still another embodiment.

[Explanation of symbols]

 N ... Fuel injection nozzle E ... Engine P ... Piston S ... Cylinder 30 ... Nozzle body 32 ... Fuel storage chamber 35 ... Valve seat 36 ... First group injection hole 37 ... Second group injection hole 50 ... Needle valve 52 ... Pressure reception Part 55 ... Contact part 60 ... Spring means

Claims (1)

[Scope of utility model registration request] 1. A hollow elongated nozzle body having a closed end. This nozzle body has a fuel reservoir formed at an intermediate position, a tapered taper valve seat formed on the inner surface of the tip portion, and a plurality of injection holes formed at the tip portion and separated from each other in the circumferential direction. ing. (B) A needle valve housed in the nozzle body. This needle valve
The nozzle body has a pressure receiving portion formed to face the fuel storage chamber, and a tapered cone-shaped contact portion formed ahead of the pressure receiving portion. (C) Spring means for urging the needle valve to seat its abutting portion on the valve seat. Due to the fuel pressure in the fuel storage chamber acting on the pressure receiving portion, the needle valve receives a force against the spring means, and the contact portion separates from the valve seat. A fuel injection nozzle having the above-mentioned configurations (a) to (c), which is mounted on a cylinder head such that a tip portion of the fuel injection nozzle faces an engine cylinder. The plurality of injection holes include a plurality of injection holes of the first group and a plurality of injection holes of the second group. The injection holes of the first group and the injection holes of the second group are alternately arranged in the circumferential direction and are separated from each other. The first group of injection holes forms a smaller angle with respect to the axis of the engine cylinder than the second group of injection holes. The inner end of the injection hole of the first group is located at the valve seat, and the inner end of the injection hole of the second group is located further away from the inner end of the injection hole of the first group in the axial direction. In the state where the contact portion of the needle valve is seated on the valve seat, the inner end of the injection hole of the first group faces the outer peripheral surface of the contact portion.