DE102005058646A1 - Nozzle needle for fuel injection valve of internal combustion (IC) engine, has flexible micro fins, individually formed with flanks, formed around tapered seating surface near needle tip region - Google Patents

Abstract

Micro fins (44), individually formed with flanks, are formed around the tapered seating surface (40) near the axial tip region (38) of a nozzle needle (24). Each flank allows each micro fin to flexibly bend in limited fashion and perpendicular to the longitudinal axis (X) of the needle. Furthermore, each flank is inclined at 60 to 120 degrees or at right angle with respect to the longitudinal axis and has a depth greater than the width or fin spacing. Independent claims are included for the following: (1) a nozzle assembly for a fuel injection valve; and (2) a fuel injection valve.

Description

The The invention relates to a nozzle needle for an injection valve, which has a seating area that slopes towards an axial end of the nozzle needle rejuvenated. Furthermore, the invention relates to a nozzle assembly for the injection valve, the nozzle needle and a nozzle body. The nozzle body has a recess with a wall in the area of a nozzle tip one to the nozzle tip of the nozzle body rejuvenating Nozzle needle seat forms. The nozzle needle seat stops in conjunction with the seating area of the nozzle needle in a closed position the nozzle needle a fluid flow towards an injection opening in the nozzle tip and otherwise releases the fluid flow. Furthermore, the invention relates to the Injector containing the nozzle assembly with the nozzle needle includes.

From the DE 100 24 854 A1 Controls for high pressure hydraulic systems are known. The controls for high-pressure hydraulic systems are in particular valve needles and valve control pistons of injectors for common-rail injection systems. The controls have stationary and movable guide surfaces, between which a sealing gap is provided. Leakage between the guide surfaces is minimized by the fact that preferably the movable guide surfaces have a structure influencing the flow in the light gap.

From the DE 103 51 881 A1 For example, an injector with structures for limiting wear-related changes of an opening course is known. The injector has a nozzle needle that has a conical seating area. Further, the injector has a nozzle body in which the nozzle needle is guided axially movable and having a conical contact surface for the seating area. A partial area of the seat area forms with the injector closed a resting on the conical contact surface sealing surface. The sealing surface separates a pressure chamber arranged on a first side of the seat region from at least one injection opening arranged on a second side of the seat region. The injector is characterized in that a plurality of circumferential grooves is arranged on at least one side of the seating area.

The The object of the invention is an injection valve, a nozzle assembly for the Injection valve and / or a nozzle needle for the nozzle assembly to create that or over a long life the injection valve is a precise Metering of fluid through the injector allows.

The Task is solved by the characteristics of the independent Claims. Advantageous embodiments of the invention are characterized in the subclaims.

The Invention is characterized by an injection valve, a nozzle assembly for the Injection valve and through a nozzle needle for the Nozzle assembly. The nozzle needle has a seating area that goes toward one axial end of the nozzle needle rejuvenated. In the seating area, a plurality of fins are formed, which extend around the entire circumference of the nozzle needle. The slats point facing flanks and are designed so that the lamellae bend elastically perpendicular to their flanks, though on the lamellae a force in the direction of a longitudinal axis of the nozzle needle acts.

If the nozzle needle is arranged in the injection valve and at a closing of the nozzle needle and / or in the closed state of the nozzle needle with pressure fluctuations in the injection valve, a force in the direction of the longitudinal axis of the nozzle needle from a jet needle seat of the injection valve on the seating area of the nozzle needle and in particular on transferred the slats is, so the elastic bending of the slats affects a wear of the seat area and the nozzle needle seat opposite. The elastic bending of the blades reduces an elastic Deforming the slats and contributes to it in order to reduce a plastic deformation of the slats. The slats increase thus the elasticity of the seating area opposite the elasticity the seating area without slats. This increases the life of the injector and carries to a precise Metering fluid through the injector over its lifetime the injection valve at.

In According to an advantageous embodiment, the nozzle needle comprises a cylindrical portion and a cone-shaped Section. The cone-shaped section includes the seating area. The cylindrical portion of the nozzle needle allows a precise guidance of the Nozzle needle. The cone-shaped Section can work in conjunction with a cone-shaped nozzle needle seat in the injection valve for effectively suppressing a Fluid flow towards an injection port of the injector contribute.

In a further advantageous embodiment of the nozzle needle close the Flanks of the slats with the longitudinal axis the nozzle needle an angle of 60 to 120 degrees. This contributes to a particularly simple elastic bending of the slats at.

In a further advantageous embodiment of the nozzle needle, the flanks of the lamellae close with the longitudinal axis of the nozzle needle a right Angle. This allows a uniformly simple elastic bending of the slats in both directions perpendicular to the flanks. This contributes to a reduction in wear, especially in the pressure fluctuations in the closed position of the nozzle needle.

In a further advantageous embodiment of the nozzle needle is a depth of Slats larger than one Width and / or a distance of the slats to each other. This is especially important effective for a simple elastic bending of the slats at.

In a further advantageous embodiment of the nozzle needle, the slats a depth in the range of 50 to 100 microns. In connection with a width and a spacing of the fins that are smaller as the depth of the fins, carries this leads to a particularly effective increase in the elasticity of the seating area at.

In a further advantageous embodiment of the nozzle needle, the slats a width of twenty to 40 microns. In connection with the depth of the fins from 50 to 100 microns, this contributes to a particularly effective increase in the elasticity of the seating area at.

In a further advantageous embodiment of the nozzle needle have the slats a distance of twenty to 40 microns to each other. In connection with the depth of the fins from 50 to 100 microns wearing this to a particularly effective increase in the elasticity of the seating area.

In a further advantageous embodiment of the nozzle needle comprises the plurality of fins more than ten fins. Wear more than ten slats to a high elasticity of the seating area, without one of the slats being stressed too much. Too much stress means in this context, in particular, that the lamella is plastic deformed.

In In a further advantageous embodiment of the nozzle needle, the lamellae are equidistant arranged to each other. This causes a uniform force distribution on the Slats and wears so to a particularly low wear of the seat area and the Nozzle needle seat at.

In a further advantageous embodiment of the nozzle needle have recesses between the slats a rectangular profile. This contributes to one particularly simple elastic bending of the slats and thus to a particularly low wear of the seat area and the Nozzle needle seat at.

In a further advantageous embodiment of the nozzle needle are to the seating area the nozzle needle subsequently formed further fins. If due to wear the original Moving seating area, carry the other slats to a high elasticity of the suspended seating area.

The nozzle assembly includes the nozzle needle and a nozzle body that has a recess with a wall. The wall forms in the area a nozzle tip one to the nozzle tip of the nozzle body rejuvenating Nozzle needle seat. In conjunction with the seating area of the nozzle needle, the seating area is disabled in a closed position the nozzle needle a fluid flow towards an injection opening in the nozzle tip and otherwise releases the fluid flow.

In an advantageous embodiment of the nozzle assembly is the seating area conical trained and graduated with the flanks of the lamellae of the nozzle needle an angle of zero to less than 80 degrees. This carries to a simple elastic bending and a small plastic Deforming of the slats.

In A further advantageous embodiment of the nozzle assembly, the fins between their flanks end faces on that from the nozzle needle are facing away and the an angle of zero to 30 degrees with a Include portion of the wall of the recess of the nozzle body. With the section of the wall are the corresponding slats in the closed position the nozzle needle coupled. This carries at a favorable price Power transmission of the nozzle needle seat on the seating area of the nozzle needle and thus to a lower wear of the seat area and the Nozzle needle seat at.

advantageous Embodiments of the invention are described below with reference to the schematic Drawings closer explained.

It demonstrate:

1 an injection valve,

2 a detailed view of a nozzle assembly of the injection valve according to 1 .

3 a detailed view of a nozzle needle of the nozzle assembly according to 2 ,

elements same construction or function are cross-figurative with the same Reference number marked.

An injection valve ( 1 ) has a body with a recess. The body includes before gives a valve plate 12 , a needle guide body 14 with a recess, a nozzle body 16 with a recess 17 and an injector housing 1 with a recess into which an actuator is inserted, preferably a solid state actuator 4 , For example, a piezo actuator. The injection valve is preferably suitable for metering fuel into a combustion chamber of an internal combustion engine.

The solid state actuator 4 is with a transformer 6 coupled. The transformer 6 is in a leakage room 8th arranged. On-off valve 10 , which is preferably designed as a servo valve is arranged so that it absteuert depending on its switching position, a leakage fluid, which is preferably the fuel in this embodiment. The switching valve is over the transformer 6 with the solid state actuator 4 coupled and is driven by him, that is, the switching position of the switching valve 10 is by means of the solid state actuator 4 set. The switching valve 10 is in the valve plate 12 arranged. It comprises a valve member whose position by means of Festkörperaktuators 4 is adjustable and in a switching position in abutment with the valve plate 12 and so the Absteuern of fluid in the leakage chamber 8th prevented. In a further switching position, the valve member is spaced from a wall of the valve plate 12 and thus allows the Absteuern of the fluid in the leakage chamber 8th ,

The solid state actuator 4 preferably comprises a stack of piezo elements. The stack of the piezo element comprises, for example, 200 piezo elements which are stacked on top of one another. The stack of piezoelectric elements is preferably surrounded by a tubular spring, which is the stack of piezoelectric elements between the transformer 6 and a final element clamps.

The valve plate 12 , the needle guide body 14 , a nozzle needle 24 and the nozzle body 16 form a nozzle assembly by means of a nozzle locknut 18 on the injector housing 1 is attached. The nozzle body 16 and the needle guide body 14 can be integrally formed. The valve plate 12 can be integral with the needle guide body 14 be educated. The valve plate 12 , the needle guide body 14 and the nozzle body 16 can be formed in one piece. The valve plate 12 and / or the injector housing 1 can be multi-piece, for example, formed of several plates.

The recess of the needle guide body 14 sits down in the recess 17 of the nozzle body 16 continued. The nozzle needle 24 is in the recess of the needle guide body 14 and the recess 17 of the nozzle body 16 arranged axially movable. The nozzle needle 24 is in the needle guide body 14 guided. A nozzle spring 26 tenses the nozzle needle 24 into a closed position in which it flows fluid through an injection hole 28 in derogation. The injection hole 28 is in the area of a nozzle 27 of the nozzle body 16 trained and penetrates the nozzle tip 27 outward.

At one axial end of the nozzle needle 24 that is turned to the valve plate 12 , is a tax room 30 formed, which is hydraulically coupled via an inlet throttle with a high pressure supply in the body. The high pressure supply includes a high pressure bore 32 and partly the recess 17 in the nozzle body 16 , The high pressure bore 32 extends in the axial direction through the injector 1 , through the valve plate 12 and the needle guide body 14 and opens into the recess 17 of the nozzle body 16 ,

Is the switching valve located 10 in its closed position, so is the control room 30 hydraulically decoupled from the leakage chamber 8th , This has the consequence that, after a closing of the switching valve 10 the pressure in the control room 30 substantially equal to the pressure in the high pressure supply. About the control room 30 becomes due to the fluid pressure in the control room 30 on an end face of the nozzle needle 24 a force in the closing direction of the nozzle needle 24 exercised. The nozzle needle 24 further comprises axially spaced from its end face on a shoulder, which with fluid passing through the recess 17 of the nozzle body 16 flows, is acted upon, that an opening acting force on the nozzle needle 24 acts, so contrary to the closing direction. Lift the nozzle needle 24 from the nozzle body 16 From, so the fluid pressure acts against the closing direction and at one of the end face of the nozzle needle 24 remote axial end region 38 the nozzle needle 24 , In its closed position prevents the nozzle needle 24 a fluid flow through the injection hole 28 , Moves the nozzle needle 24 starting from its closed position into the control room 30 , so it gives the fluid flow through the injection hole 28 free.

Whether the nozzle needle 24 is in its open position or in its closed position depends on whether the force acting in the closing direction is greater than or less than the force acting against the closing direction by the force of the nozzle spring 26 and the on the end face of the nozzle needle 24 acting pressure is caused.

Is the switching valve located 10 in its open position, fluid flows from the control room 30 through the switching valve 10 into the leakage room 8th , With suitable dimensioning of the inlet throttle then the pressure in the control chamber decreases 30 , which eventually leads to a movement of the nozzle needle 24 out of their closed position leads. The pressure of the fluid in the leakage chamber 8th is significantly lower than the pressure of the fluid in the high pressure supply.

The High pressure supply For example, is hydraulically coupled to a high-pressure fuel storage and so gets fuel under a pressure of for example supplied up to 2000 bar.

A wall of the recess 17 of the nozzle body 16 forms in the area of the nozzle tip 27 a nozzle needle seat 42 ( 2 ). The nozzle needle seat 42 is preferably conical. The nozzle needle 24 forms in the axial end region 38 the nozzle needle 24 a seating area 40 , In the closed position of the nozzle needle 24 Prevent the seating area 40 and the nozzle needle seat 42 in cooperation, the fluid flow towards the injection port 28 , Outside the closed position of the nozzle needle 24 is the seating area 40 not with the nozzle needle seat 42 coupled so that the fluid flow towards the injection port 28 is released. The nozzle needle 24 preferably includes in the seating area 40 a cone-shaped section 36 the nozzle needle 24 ,

In the seating area 40 are in the nozzle needle 24 slats 44 educated. Preferably, the fins are 44 also subsequently on the seating area 40 educated. The slats 44 extend around the entire circumference of the nozzle needle 24 , The slats 44 each have two flanks 46 on ( 3 ). The flanks 46 are preferably formed so that they with a longitudinal axis X of the nozzle needle 24 an angle between 60 and 120 degrees. The flanks are preferred 46 perpendicular to the longitudinal axis X of the nozzle needle 24 educated. Furthermore, the flanks preferably close to the wall of the recess 17 of the nozzle body 16 an angle between zero and less than 80 degrees. Between the flanks 44 each extends an end face 48 the slat 44 that comes from a core of the nozzle needle 24 are averted.

When operating the injector and at the operating pressure of up to 2,000 bar act when closing the nozzle needle 24 and in the closed position of the nozzle needle 24 large axially directed forces on the nozzle needle 24 at her seating area 40 and on the nozzle body 16 at his nozzle needle seat 42 , When closing the nozzle needle 24 the axially directed forces occur when the nozzle needle 24 on the wall of the recess 17 of the nozzle body 16 hits. In the closed position of the nozzle needle 24 occur the axially directed forces when systemic fluctuates in the injection valve, the fluid pressure by a predetermined value. In the closed position, the nozzle needle 24 with great force against the wall of the recess 17 of the nozzle body 16 pressed. At a nozzle needle 24 the no lamellae 44 has, the pressure fluctuations cause a rubbing of the surface of the seating area 40 at the nozzle needle seat 42 , If the nozzle needle 24 however, the slats 44 has, so they bend perpendicular to their flanks 46 as soon as the axially directed forces act on it. The energy that hits the nozzle needle 24 on the wall of the recess 17 is transmis gene and / or the energy, in the pressure fluctuations on the nozzle needle 24 is thus only negligible in an elastic deformation of the structure of the slats 44 in itself and / or in a plastic deformation of the slats 44 but is converted into an elastic bending of the entire lamella 44 transformed. This will wear the seat area 40 and the nozzle needle seat 42 reduced compared to the wear of the injector with the nozzle needle 24 without the slats 44 ,

In connection with the pressure fluctuations is the vertical formation of the flanks 46 the slats 44 to the longitudinal axis X of the nozzle needle 24 particularly advantageous because the pressure fluctuations forces in both axial directions of the nozzle needle 24 cause. Due to the right-angled design of the flanks 46 to the longitudinal axis X of the nozzle needle 24 is achieved that the slats 44 Almost equally easily elastically bendable in both axial directions. This contributes to a uniform wear reduction for forces in both axial directions.

It is particularly advantageous if ten or more fins 44 in the nozzle needle 24 are formed. The more slats 44 are formed, the better the distribution of the axially directed force on the individual slats 44 and the lower the wear of the nozzle needle 24 and the nozzle body 16 in the region of the seating area 40 or the nozzle needle seat 42 , In this context, it is particularly advantageous if the slats 44 are formed equidistantly from each other, that is, that the slats 44 have a constant clearance between them. The equidistant formation of the lamellae 44 contributes to a suitable good distribution of the forces occurring on the slats 44 at.

Furthermore, the slats 44 preferably designed so that a depth T of the slats 44 is greater than a width B and / or the distance A of the slats 44 to each other. This allows a particularly simple bending of the slats 44 to each other.

In today's commonly used materials for the nozzle needle 24 becomes a particularly high elasticity of the nozzle needle 24 through the slats 44 at the same time suitably high robustness of the slats 44 scored when the slats 44 have a depth T in the range of 50 to 100 microns. In this context, the slats 44 preferably formed so that the width B and the distance A in the range of twenty to 40 microns are formed.

Preferably have recesses between the slats 44 a right-angled profile. This simply contributes to a simple elastic bending of the slats 44 with sufficient robustness of the slats 44 at.

The invention is not limited to the specified embodiments. The slats 44 For example, may be formed so that the flanks 46 an angle of 60 to 120 degrees with the longitudinal axis X of the nozzle needle 24 lock in. Furthermore, the slats 44 be formed so that the flanks 46 an angle of zero to 80 degrees with the nozzle needle seat 42 lock in. Furthermore, in the nozzle needle 24 a much larger number of slats 44 be formed, for example, 100 or 1,000 fins 44 , Furthermore, the seating area 40 and / or the nozzle needle seat 42 deviating from its conical shape, as long as an effective inhibiting the fluid flow to the injection port 28 in the closed position of the nozzle needle 24 is guaranteed. In addition, the recesses can 50 between the slats 44 For example, have a round profile, as long as a bending of the slats 44 perpendicular to their flanks 46 is possible.

Claims (16)

Nozzle needle ( 24 ) for an injector that has a seating area ( 40 ) which extends to an axial end region ( 38 ) of the nozzle needle ( 24 ) and in which a plurality of fins ( 44 ) are formed, which extend around the entire circumference of the nozzle needle ( 24 ), the mutually facing flanks ( 46 ) and which are formed so that the slats ( 44 ) perpendicular to their flanks ( 46 ) bend elastically when on the slats ( 44 ) a force in the direction of a longitudinal axis (X) of the nozzle needle ( 24 ) acts. Nozzle needle ( 24 ) according to claim 1, comprising a cylindrical portion ( 38 ) and a conical section ( 36 ), which covers the seating area ( 40 ). Nozzle needle ( 24 ) according to one of the preceding claims, in which the flanks ( 46 ) of the slats ( 44 ) with the longitudinal axis (X) of the nozzle needle ( 24 ) enclose an angle of sixty to one hundred and twenty degrees. Nozzle needle ( 24 ) according to claim 3, in which the flanks ( 46 ) of the slats ( 44 ) with the longitudinal axis (X) of the nozzle needle ( 24 ) enclose a right angle. Nozzle needle ( 24 ) according to one of the preceding claims, wherein a depth (T) of the slats ( 44 ) is greater than a width (B) and / or a distance (A) of the slats ( 44 ) to each other. Nozzle needle ( 24 ) according to one of the preceding claims, in which the lamellae ( 44 ) have a depth (T) in the range of fifty to one hundred microns. Nozzle needle ( 24 ) according to claims 5 and 6, wherein the lamellae ( 44 ) have a width (B) of twenty to forty microns. Nozzle needle ( 24 ) according to claims 5 and 6 or 7, wherein the lamellae ( 44 ) have a distance (A) of twenty to forty microns to each other. Nozzle needle ( 24 ) according to one of the preceding claims, in which the plurality of lamellae ( 44 ) more than ten slats ( 44 ). Nozzle needle ( 24 ) according to one of the preceding claims, in which the lamellae ( 44 ) are arranged equidistant from each other. Nozzle needle ( 24 ) according to one of the preceding claims, wherein the recesses between the slats ( 44 ) have a rectangular profile. Nozzle needle ( 24 ) according to any one of the preceding claims, wherein the seating area ( 40 ) of the nozzle needle ( 24 ) then further fins ( 44 ) are formed. Nozzle assembly for an injection valve comprising a nozzle needle ( 24 ) according to one of claims 1 to 12 and a nozzle body ( 16 ), which has a recess ( 17 ) has a wall which in the area of a nozzle ( 27 ) to a nozzle tip of the nozzle body ( 16 ) tapered nozzle needle seat ( 42 ) in cooperation with the seating area ( 40 ) of the nozzle needle ( 24 ) in a closed position of the nozzle needle ( 24 ) fluid flow to an injection port ( 28 ) in the nozzle ( 27 ) and otherwise free. Nozzle assembly according to claim 13, wherein the seating area ( 40 ) is cone-shaped and with the flanks ( 46 ) of the slats ( 44 ) of the nozzle needle ( 24 ) includes an angle from zero to less than eighty degrees. Nozzle assembly according to one of claims 13 or 14, in which the lamellae ( 44 ) between their flanks ( 46 ) End faces ( 48 ), which from the nozzle needle ( 24 ) and which are at an angle of zero to thirty degrees with a portion of the wall of the recess ( 17 ) of the nozzle body ( 16 ), with which the corresponding lamellae ( 44 ) in the closed position of the nozzle needle ( 24 ) are coupled. Injector, which the nozzle assembly according to a the claims 13 to 15.