DE102004022619A1 - Liner spring used as reset spring for valve needle of fuel injection valve, has hollow cylindrical shape made of intermediate bars, recesses and grooves - Google Patents

Abstract

The liner spring (15) has a hollow cylindrical shape made of intermediate bars (17), recesses (16,20) and grooves (22). The grooves can be formed in U or taper shape turning away from the recesses. The recesses are formed extending in longitudinal direction while the grooves are formed at the center of the longitudinal extension of the recesses.

Description

The Invention is based on a tube spring according to the preamble of the main claim.

It is already a Bourdon known from WO2000008353 with several Recesses and intermediate webs, for axial preloading a piezoelectric actuator is used. The disadvantage is that the elasticity of the Bourdon tube and their spring travel is low, especially when the Bourdon tube as Return spring for one Serve valve needle of a fuel injection valve.

Advantages of invention

The inventive bourdon tube with the characterizing features of the main claim has the Advantage that in a simple way an improvement to that effect is achieved that the elasticity the bourdon tube increases is, in that the recesses have notches. In this way Spring areas are formed, which makes a greater contribution to the suspension travel can afford.

By in the subclaims listed activities are advantageous developments and improvements in the main claim specified Bourdon tube possible.

According to one Advantageous embodiment, the indentations are triangular or U-shaped, because these are particularly easy to manufacture embodiments.

Especially is advantageous if the notches in one of the recess rejuvenate the opposite direction, because the webs of the Bourdon tube in this way more elastic than when State of the art.

Farther is advantageous if the recesses have a longitudinal extent, wherein the notches each in the middle of the longitudinal extension of the recesses are provided.

Very It is advantageous if the recesses with their longitudinal extent Run in the circumferential direction of the Bourdon tube, since in this way an elasticity in the axial Direction regarding the Bourdon tube is reached.

Also is advantageous if the recesses bone-shaped, oblong-shaped or elliptically are formed, as in this way a sufficiently high strength the Bourdon tube is achieved.

Of is further advantageous if the recesses in rows one above the other are arranged, wherein the recesses of adjacent rows mutually offset laterally, since in this way the arrangement of a sufficiently high number of recesses is possible, the one for one predetermined elasticity is required.

Furthermore is advantageous if the tube spring has frontal edges, at which directly to the edge open edge recesses provided are, in this way, the edge area contributes to the elasticity guaranteed.

According to one advantageous embodiment the recesses are mirror-symmetrical with respect to at least one axis of symmetry educated.

drawing

Two embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. Show it 1 in section a view of a fuel injection valve, 2 a view of an inventively designed Bourdon tube, 3 a first embodiment and 4 A second embodiment of a single recess of the Bourdon tube after 2 ,

description the embodiments

1 shows a fuel injection valve, in which, for example, an inventively designed tube spring is used. However, the tube spring according to the invention can also be used expressly in any other devices.

The Fuel injector serves to fuel into a combustion chamber inject an internal combustion engine and is for example at used the so-called direct injection.

The fuel injection valve has a valve housing 1 with an input channel 2 for the fuel. In the valve housing 1 is a schematically illustrated actuator 3 for the axial adjustment of a valve needle 4 arranged.

The valve needle 4 is in the valve body 1 provided axially movable and in a valve housing 1 provided needle bearing 6 mounted axially movable. The valve needle 4 For example, assigns one to the actuator 3 facing needle shaft 7 and one the actor 3 remote valve closing body 8th on. The actor 3 transmits its movement, for example via a so-called hydraulic coupler 9 on the needle shaft 7 the valve del 4 , whereby the with a valve seat 10 cooperating valve closing bodies 8th the fuel injector opens or closes. The fuel injection valve has, for example, a so-called ball-cone seat, wherein the valve seat 10 is formed, for example, conical and the valve closing body 8th one with the valve seat 10 interacting sphere or radius section 11 having. When the fuel injection valve is closed, the valve closing body is located 8th over its entire circumference at the valve seat 10 with line or surface contact tightly, which in the following as a sealing seat 12 referred to as.

The actor 3 For example, a piezoelectric or magnetostrictive actuator and executed encapsulated with respect to the fuel. Likewise, the coupler 9 sealed for example against the fuel.

The piezoelectric actuator 3 consists of a plurality of piezoceramic layers, which perform an expansion in the axial direction by applying an electrical voltage. In this case, the so-called inverse piezoelectric effect is utilized in which electrical energy is converted into mechanical energy. The elongation of the piezoceramic layers produced by the application of the electrical voltage is transmitted via the hydraulic coupler 9 on the valve needle 4 transferred, with the valve needle 4 For example, executes a stroke of 40 to 50 microns. After the opening of the fuel injection valve, the actuator shortens 3 by switching off the electrical voltage and the valve needle 4 is by means of a bourdon tube 15 again in the direction of the valve seat 10 moved back and closes the fuel injector.

The Bourdon tube 15 lies with one end, for example, on a shoulder 5 the valve needle 4 and with the other end to the valve body 1 at.

As is the actor 3 and the remaining components of the fuel injector, such as the valve housing 1 , due to different thermal expansion coefficients with temperature change vary greatly, the hydraulic coupler 9 compensate for the differences in the different linear expansion to ensure that the fuel injector with the valve needle 4 regardless of the respective temperature of the fuel injection valve during an opening movement in each case performs the same stroke as the actuator 3 , There must be no lifting losses where the stroke of the actuator 3 not completely on the valve needle 4 is transferred, so that the stroke of the valve needle 4 smaller than the stroke of the actuator 3 ,

The fuel is in the valve body 1 starting from the input channel 2 to the valve closing body 8th upstream of the sealing seat 12 directed. When opening the fuel injection valve lifts the valve closing body 8th from the sealing seat 12 from, whereby a connection is opened to the combustion chamber of the internal combustion engine, so that fuel via a between the valve closing body 8th and the valve seat 10 formed output gap flows into the combustion chamber. The output gap expands, for example, in the flow direction and thus acts as a diffuser. The larger the stroke of the valve needle 4 in the opening direction, the larger the output gap and the more fuel is injected per unit time in the combustion chamber.

The fuel injection valve is for example a so-called outward-opening valve, wherein the valve needle 4 a stroke in from the actuator 3 Of course, it can also be a so-called inward-opening valve.

2 shows a view of the tube spring according to the invention.

The Bourdon tube 15 is designed for example as a hollow cylinder with a cylinder axis 14 and has several recesses 16 with between the recesses 16 remaining bridges 17 on.

The recesses 16 are manufactured for example by means of laser cutting or punching. The Bourdon tube 15 is made of any material, such as steel.

The Bourdon tube 15 indicates due to the recesses 16 a comparison with a hollow cylinder without recesses increased elasticity, so that they have a greater spring travel in the direction of the cylinder axis 14 can perform. A Bourdon tube transmits, in contrast to a coil spring, little or no lateral forces, so that the Bourdon tube 15 no or only small lateral forces on the valve needle 4 be exercised. This leads to lower mechanical loads on the valve needle bearing 6 and a more precise opening and closing of the valve needle 4 , In addition, the bourdon tube is needed 15 a smaller space than other return springs in the prior art.

The recesses 16 are, for example, bone-shaped, oblong-shaped, elliptical or similar. In this way, a sufficiently high mechanical strength of the Bourdon tube 15 achieved.

The recesses 16 are for example in several rows arranged one above the other 18 provided, wherein the recesses 16 a row 18 for example, evenly over the Circumference of the bourdon tube 15 are distributed. The recesses 16 from adjacent rows 18 For example, are laterally offset from each other, so that more recesses 16 can be arranged on the Bourdon tube than in a Bourdon without the offset of the rows 18 ,

The recesses 16 have a longitudinal extent in the circumferential direction with respect to the Bourdon tube 15 and have a circumferentially measured length L (FIG. 3 . 4 ). The circumferential direction is transverse to the cylinder axis 14 Are defined. The recesses 16 have two longitudinal sides extending in the direction of the longitudinal extent 16.1 on, for example, about radii 16.2 connected to each other. In this way are the recesses 16 executed in self-contained.

According to the invention, the recesses 16 the elasticity of the Bourdon tube 15 increasing notches 22 on. For example, the notches 22 on both long sides 16.1 the recesses 16 provided and enlarge the of the recess 16 enclosed area. The notches 22 For example, triangular or U-shaped, for example, with rounded transitions to the adjacent sides of the recess 16 , and rejuvenate in one of the recess 16 remote axial direction with respect to the cylinder axis 14 up to a notch reason 27 , The indentation reason 27 is also rounded, for example. By rounding off the notches 22 at the transitions to the sides of the recess 16 and at the notch reason 27 is the strength of the Bourdon tube 15 not or only slightly affected.

The at least one notch 22 the recesses 16 is according to an advantageous embodiment in each case in the middle with respect to the longitudinal extension of the recesses 16 , ie in the region of half the length L of the recess 16 , intended. In this way, the elasticity of the Bourdon tube 15 particularly high.

The circumferentially extending webs 17 each have a web width SB, which is measured in the axial direction, for example, in the circumferential direction is constant or, for example, in the middle between two webs extending in the axial direction 17 has a minimum. The provision of a minimum of the web width SB, for example, in the middle between two axially extending webs 17 increases the elasticity of the Bourdon tube 15 again.

The Bourdon tube 15 has at the front ends in each case an edge 23 with an example annular bearing surface 24 on, with one of the bearing surfaces 24 for example, on the shoulder 5 the valve needle 4 and the other bearing surface 24 on the valve body 1 is applied.

Immediately at the front edges 23 the bourdon tube 15 For example, each is an outer row 19 of marginal recesses 20 with notches 22 arranged. The marginal recesses 20 run from the edge 23 starting in the material of the Bourdon tube 15 in the axial direction and in the circumferential direction with respect to the cylinder axis 14 and are open and not like the other recesses 16 between the outer rows 19 self-contained and on both sides of webs 17 limited executed. The marginal recesses 20 for example, have two from the edge 23 starting radii 16.2 and a single one with the radii 16.2 connected longitudinal side 16.1 , In this long side 16.1 the edge recess 20 is a notch 22 , For example, in the middle of the long side, provided.

The marginal recesses 20 the outer rows 19 For example, are evenly distributed over the circumference and interrupt each of the annular bearing surface 24 , so that, for example, circular section-shaped support feet 25 arise between which the Bourdon tube 15 can collapse. Through the edge recesses 20 is the elasticity of the Bourdon tube 15 further increased, since this an additional spring travel in the direction of the cylinder axis 14 enable.

The marginal recesses 20 For example, have the shape of a longitudinal direction with respect to the recess 16 cut recess 16 , For example, the edge recesses 20 the shape of a longitudinally bisected bone or long hole.

The tube spring according to the invention 15 can be used both as a tension spring and as a compression spring.

3 shows a first embodiment of the recesses of the bourdon tube according to the invention.

At the recess after 3 are the opposite to the Bourdon tube after 2 and the fuel injector 1 Constant or equivalent parts by the same reference numerals.

The recess 16 is executed in a bony shape according to the first embodiment.

The notches 22 the recesses 16 For example, have a height H in the range of 0.3 to 2 millimeters and a width B in the range of 0.5 to 2 millimeters. The height H is from the transition from the remaining recess 16 to the notch 22 starting in the axial direction up to the notch bottom 27 and the width B of the notches 22 in the direction of the longitudinal extension of the recess 16 measured.

The recesses 16 . 20 For example, they are mirror-symmetric with respect to at least one symmetry axis 21 the recess 16 executed. For example, the recesses 16 with respect to one in the direction of the cylinder axis 14 and with respect to a circumferentially extending axis of symmetry 21 provided mirror-symmetrically and have a length L in the range of 5 to 20 millimeters.

4 shows a second embodiment of the recesses of the bourdon tube according to the invention.

At the recess after 4 are the opposite to the recess after 3 Constant or equivalent parts by the same reference numerals.

The recess after 4 differs from the recess after 3 in that it is elongated and not bone-shaped.

Claims (11)

Bourdon tube consisting of a hollow cylinder with a plurality of recesses and intermediate webs, characterized in that the recesses ( 16 . 20 ) Notches ( 22 ) exhibit. Bourdon tube according to claim 1, characterized in that the notches ( 22 ) are designed triangular or U-shaped. Bourdon tube according to claim 1, characterized in that the notches ( 22 ) in one of the recess ( 16 ) taper away. Bourdon tube according to claim 1, characterized in that the recesses ( 16 ) have a longitudinal extent with a length (L), wherein the notches ( 22 ) in each case in the middle of the longitudinal extension of the recesses ( 16 ) are provided. Bourdon tube according to claim 4, characterized in that the recesses ( 16 ) with its longitudinal extent in the circumferential direction of the Bourdon tube ( 15 ). Bourdon tube according to claim 1, characterized in that the recesses ( 16 ) are bone-shaped, oblong-shaped or elliptical. Bourdon tube according to claim 1, characterized in that the recesses ( 16 ) in rows ( 18 ) are arranged one above the other, wherein the recesses ( 16 ) of adjacent rows ( 16 ) are arranged laterally offset from each other. Bourdon tube according to claim 1, characterized in that the bourdon tube ( 15 ) front edges ( 23 ) at which directly to the edge ( 23 ) open edge recesses ( 20 ) are provided. Bourdon tube according to claim 8, characterized in that at the front edges ( 23 ) Support feet ( 25 ) are formed. Bourdon tube according to claim 1, characterized in that the recesses ( 16 . 20 ) mirror-symmetrical with respect to at least one axis of symmetry ( 21 ) are formed. Bourdon tube according to claim 1, characterized in that between the recesses ( 16 ) Webs ( 17 ) are formed, wherein the circumferentially extending webs ( 17 ) each have a web width (SB), each between two axially extending webs ( 17 ) has a minimum.