EP2504561B1 - Fuel injection nozzle for internal combustion engines - Google Patents

Description

The invention relates to a fuel injector for internal combustion engines, in particular auto-igniting internal combustion engines, according to the preamble of claim 1, such as in the DE 3,938,551 shown.

In the basic structure similar injection nozzles, especially as parts of injectors, are known in different configurations.

That's how it shows DE 32 27 742 A1 an injection nozzle, in which the guided with a shaft portion in a longitudinal bore of a guide body nozzle needle has a diameter reduced, cylindrical and the pressure chamber passing through the shaft portion of this shaft portion and the fuel supply to the pressure chamber axially on the front side. Also frontally to the pressure chamber of the guide body with a neck of the reduced diameter shaft portion to the guided shaft portion enclosing "ring collar" as a guide part for a supported on the guide body, the nozzle needle in the direction of its closed position axially acting coil spring is formed.

Next shows the EP 1 026 393 A2 as part of an injector, an injection nozzle with a control body adjoining a nozzle body. Nozzle body and control body are central provided with axially merging holes for the nozzle needle and a pressure piston which is located in the control body and is connected to the nozzle needle via a push rod. The push rod passes through a pressure chamber, on the circumferential side, ie radially from the outside, a fuel supply channel opens, in the axial transition region between the control body and nozzle body such that these mutually open areas of the fuel supply channel and the pressure chamber limit, on whose the control body associated part of the pressure piston receiving axial bore opens, in the closed position of the nozzle needle to the mouth adjacent tiered stepped position of the pressure piston. Due to the radial orientation of the fuel supply channel to the pressure chamber notch stresses at the point of discharge should be avoided, also a high pressure and swelling resistance can be achieved.

In a fuel injection valve according to the DE 196 11 884 A1 the nozzle body is also formed with an expiring on the pressure chamber guide bore for the nozzle needle, which has a running in the guide bore shaft portion, which merges incoming into the pressure chamber in a reduced diameter shaft portion. As a result, a gap-like annular space opens out to the guide bore between the latter and the shaft of the nozzle needle and opens up against the pressure chamber. This serves to relieve at the pressure chamber at an acute angle to the nozzle needle and adjacent to this incoming fuel supply channel remaining between the guide bore and the fuel supply channel gusset region of the nozzle body that superimposed on the swelling pressure forces in the fuel supply channel starting from the pressure chamber in the gap-like annulus Counterforces can be built.

Also at the EP 0 961 024 A1 , which shows a fuel injector for a two-stroke large diesel engine, and in which the fuel supply is controlled by two nozzles located one behind the other. To be able to design the second nozzle with the smallest possible blind hole volume with its nozzle needle controlling the spray openings and thereby prevent dripping, the nozzle needle of the second nozzle is stepped in diameter. The larger diameter shaft portion of the nozzle needle is located in a guide bore and passes in the mouth region of the guide bore on the pressure chamber on the smaller diameter shaft portion. Again, the fuel supply to the pressure chamber via acute angle to the nozzle needle extending and adjacent to the mouth region on the pressure chamber incoming fuel supply channels, so that there are vulnerable and to be relieved by two-sided pressurization gusset areas.

Comparable conditions are also at one of the JP 58-13154 A apparent injection nozzle given.

In the basic structure of the preamble of claim 1 corresponding fuel injectors are for example from the DE 39 38 551 A1 known. At the high injection pressures, which are increasingly being used, such injection nozzles are cavitation-prone, in particular when local pressure differences are formed. A nichtzu critical zone is the transition region of guided in the longitudinal bore of the nozzle body shaft portion of the nozzle needle on the reduced diameter, the pressure chamber passing through shaft portion. In conjunction with the substantially radial flow of the projecting into the pressure chamber portion of the guide portion corresponding to the shaft portion and the subsequent thereto curved arched pressure shoulder of the constricted shaft portion resulting pressure differences, like Practice has shown a zone of low pressure result, which can lead to cavitation damage in merging on the pressure shoulder portion of the guide portion corresponding shaft portion.

From the DE 195 15 936 A1 it is based on similar flow conditions for a following on a guided shaft portion, constricted shaft portion of a valve needle Durchströmungsmittel control device known to achieve by tangential flow of the pressure chamber, a spiral or helical flow around the valve stem to avoid local pressure differences and about cavitation damage ,

The invention has for its object to provide a training for a fuel injector of the type mentioned, with the cavitation damage can be avoided in particular in the transition area of guided in the guide portion of the longitudinal bore shaft portion of the nozzle needle on the constricted shaft portion.

This is achieved with the features of claim 1. The dependent claims contain expedient developments.

Taking into account the given design features and dimensions results from the leading portion of the longitudinal bore radially outwardly delimited, axially against the pressure chamber open annular space in which a largely balanced at least with respect to the pressure ratios, lying on opposite the pressure peaks in the pressure chamber lower level liquid ring can form ,

This has a gradual pressure transition from the pressure chamber to the annular gap between the shaft portion of the nozzle needle and the guide portion of the longitudinal bore result. This results in a certain protective function, once against the formation of gas bubbles in the transition from the pressure chamber to the annular gap and in the annular gap, and on the other also with respect to the cavitation damage causing implosion emerging from the annular gap gas bubbles when the nozzle needle is opened. Thus, at least the formation of gas bubbles is at least reduced and, secondly, a larger liquid volume than in the annular gap is available for glass bubbles emerging from the annular gap on the annular space when opening the nozzle needle within the annular space, so that implosions hardly occur close to the wall. It is essential for the at least largely avoid cavitation damage and the resulting in the direction of the annular gap pressure drop, corresponding to the cross-sectional reduction of the annular space to the annular gap.

This reduction in cross-section is determined by the small, one third of the diameter of the longitudinal bore corresponding distance from the transition of the guide portion of the longitudinal bore on the pressure chamber to the adjacent end of the guided shaft portion of the nozzle needle and lying at 70 ° cone angle of the constricted shaft portion. Further, by the fuel supply to the pressure chamber in radial overlap to the waist of the constriction, as well as, in conjunction with the asymmetrical flow of the nozzle needle, a reduction in pressure differences in the pressure chamber can be achieved. Such a configuration can be realized without substantially reducing the length of the guided shaft portion or an extended nozzle structure

Fig. 1

in vereinfachter Darstellung einen Querschnitt durch eine Kraftstoff-Einspritzdüse zeigt, und

Fig. 2

in vergrößerter Darstellung den auf die Sacklochbohrung ausgehend von der Taillierung auf die Nadelspitze auslaufenden Abschnitt des Schaftes der Düsennadel.

Further details and features of the invention will become apparent from the description, the claims and the drawings. Show it:

Fig. 1

in a simplified representation shows a cross section through a fuel injector, and

Fig. 2

in an enlarged view of the blind hole starting from the sidecut on the needle tip expiring portion of the shaft of the nozzle needle.

In Fig. 1 the injecting onto the combustion chamber of the internal combustion engine, not shown part of an injection nozzle 1 for fuels, especially diesel fuels, shown schematically, which may in particular also be part of a fuel injector. The injection nozzle 1 has a nozzle body 2, which has a longitudinal bore 4 extending in the direction of its longitudinal axis 3 with sections of different diameters. The longitudinal bore 4 receives a nozzle needle 5 and runs in the combustion chamber end of the nozzle body 2 provided injection openings 6.

The nozzle needle 5 has an optionally provided with microgrooves shaft portion 7, with which it is guided axially displaceably in a guide portion 8 of the longitudinal bore 4 of the nozzle body 2 in the direction of the longitudinal axis 3. This guide section 8 opens onto an enlarged in diameter and formed as a pressure chamber 9 part of the longitudinal bore 4, to which a further portion 10 of the longitudinal bore 4 connects, which tapers via a bore-side seat 11 to the injection openings 6.

With 12 an axially extending fuel supply passage is designated, which opens radially to the pressure chamber 9, wherein the fuel supply in the embodiment via two mouth openings 13 takes place asymmetrically on the pressure chamber 9, which is followed by a guided to the shaft portion 7 and radially constricted shaft portion 14 of the nozzle needle 5 is interspersed. At the over the course of the longitudinal axis 3 extending constricted shaft portion 14 includes another shaft portion 15 which is reduced in diameter relative to the shaft portion 7 and the periphery of the longitudinal bore 4 defines an annular space 16, via the fuel supply from the pressure chamber 9 in the direction the seat surface 11 of the nozzle body 2 takes place, to which the nozzle needle 5 adjacent to its nozzle needle tip 17 has a corresponding sealing surface 18.

When the nozzle needle 5 is in the closed position, the fuel supply to the injection openings 6 is blocked by the abutting surfaces 11 and 18. If the nozzle needle 5 is lifted out of its seat, then fuel is injected via the injection openings 6 to the respective combustion chamber, when fuel is supplied via the mouth openings 13 to the pressure chamber 9 in the region of the waist 19 of the constricted shaft portion 14. The waist 19 lies in radial Covering the mouth openings 13, which are arranged offset relative to the longitudinal axis 3 and circumferentially offset from each other with respect to the circumference of the pressure chamber 9, so that due to flow, at least over the peripheral region of the pressure chamber 9, resulting at different pressure levels areas. This can lead to the formation of cavitation bubbles in the respective negative pressure regions, which can lead to damage of the respective surface in the area of higher pressures in the case of near-wall implosion with corresponding pressure differences. Such damage is critical in particular in the guided in the longitudinal bore 4 shaft portion 7 of the nozzle needle 5, especially if they occur at the nozzle needle 5.

According to the invention, at least substantial protection of this area against cavitation damage is achieved in that the shaft section 7 guided in the longitudinal bore 4 of the nozzle body 2 ends at a distance from the mouth of the longitudinal bore 4 on the pressure chamber 9 which is radially widened in relation to the longitudinal bore 4, that is to say the transition between the in the longitudinal bore 4 guided shaft portion 7 and the purpose constricted shaft portion 14 before the mouth of the guide portion 8 of the longitudinal bore 4, and thus within the guide portion 8 of the longitudinal bore 4. This results in incoming from the pressure chamber 9 on the guide portion 8 enclosing the connection region of the constricted shaft portion 14 to the guided shaft portion 7, an annular space 20, in particular a flat triangular annular space 20. Functionally, the liquid ring forming in the annular space 20 is due to the gradual, pressure jumps avoiding or at least re Duzierenden cross-sectional transitions from the pressure chamber 9 to the annular gap between the shaft portion 7 and the guide portion 8 as a "guard ring" against the formation of Kavitationsbläschen in the transition to the annular gap and in the annular gap to understand the necessary even when opening the nozzle needle from the annular gap gas bubbles Free space for a possible implosion of the same in the remote area, so that cavitation damage to the nozzle shaft are at least largely avoided.

Notwithstanding the explanation of the effect according to the invention, which is based in part on theoretical considerations, in practice the embodiment according to the invention has proven to be expedient and suitable for at least substantially avoiding cavitation damage in the area mentioned.

In the context of the invention, it proves to be expedient and sufficient if the distance 21 of the guided shaft portion 7 of the nozzle needle 5 from the transition of the longitudinal bore 4 of the nozzle body 2 to the pressure chamber 9 a fraction of the diameter 22 of the guide portion 8 of the nozzle body 2 corresponds. A preferred size ratio is that the size of the distance 21 is one third of the diameter 22 of the longitudinal bore 3. This in conjunction with a cone angle 24 in the range of 70 °, so that there is a relatively flat cross-section of the triangular annular space 20.

In particular, in conjunction with such proportions, a waist diameter 23 proves to be useful for the constricted shaft portion 14, which is greater than half the diameter of the lying in the nozzle body 2 guide portion of the longitudinal bore 4, and in particular at about two-thirds of the diameter 22 of the guide portion 8 of the longitudinal bore , And thus the diameter of the guided shaft portion 7 is located.

In the enlarged view of the expiring on the nozzle needle tip 17 part of the nozzle needle 5 according to Fig. 2 is in addition to the presentation in accordance with Fig. 1 and the references used there, as well as the explanations thereto, the area around the nozzle needle tip 17 shown. It is thus illustrated that the needle-side sealing surface 18 corresponding to the seat surface 11 on the nozzle body 2 lies between a frustoconical annular region 25 and the nozzle needle tip 17, which adjoins the shaft section 15 and tapers against the nozzle needle tip 17, wherein the annular frustum-shaped annular region 25 Sealing surface 18 and the nozzle needle tip 17, the respective cone angle 26 to 28 are indicated. These decrease in their respective angular size, starting from the cone angle 26 of the nozzle needle tip 17, wherein the preferred values for the cone angle 26 of the nozzle needle tip 17 at 120 °, for the cone angle 27 of the sealing surface 18 at 90 ° and for the cone angle 28 - as so-called Vorwinkeldeld the ring area 25 at 75 °. This in conjunction with an embodiment of the injection nozzle according to Fig. 1 in which the portion 10 of the longitudinal bore, which accommodates the shaft portion 15 and delimits the annular space 16, ends at the level of the annular area 25 and constricts against the annular area 25, in particular in one step. The supplied via the annular space 16 fuel is thus introduced in the amount of the annular region 25 via the nozzle body 2 and the seat 11 of the nozzle body 2 towards tapered annular gap, the annular gap between seat 11 and sealing surface 18 and the nozzle needle tip 17 in the blind hole, from the injection openings 6 go out. The stepped transition for taking place via the annular space 16 fuel supply to the blind hole allows a good command of the flow conditions.

LIST OF REFERENCE NUMBERS

1

injection

2

nozzle body

3

longitudinal axis

4

longitudinal bore

5

nozzle needle

6

Injection port

7

shank portion

8th

guide section

9

pressure chamber

10

section

11

seat

12

Fuel supply passage

13

mouth

14

shank portion

15

shank portion

16

annulus

17

Nozzle needle tip

18

sealing surface

19

waist

20

annulus

21

distance

22

diameter

23

Waist diameter

24

cone angle

25

ring area

26

cone angle

27

cone angle

28

cone angle

Claims (3)

1. Fuel injection nozzle for internal combustion engines, in particular auto-ignition internal combustion engines, with a longitudinal bore (4) which accommodates a nozzle needle (5), runs in a nozzle body (2) and tapers off from a guide section (8) for the nozzle needle (5) via a region expanded to form a pressure space (9) onto at least one injection opening (6), wherein the nozzle needle (5) has a guided shank section (7) which corresponds to the guide section (8) and which is adjoined, as a bridge to a shank part (15) tapering off onto the nozzle needle seat, by a shank section (14) which has a constricted diameter and passes through the pressure space (9), to which at least one fuel supply means (12) leads asymmetrically on the circumferential side, characterized in that that shank section of the nozzle needle (5) which is located in the guide section (8) of the nozzle body (2) ends, in relation to the closed position of said nozzle needle, at a distance from the transition of the longitudinal bore (4) into the pressure space (9) within the longitudinal bore (4), which transition is located at a third of the diameter (22) of the longitudinal bore (4), and in that the constricted shank section (14) adjoins the guided shank section (7) at an angle of taper (24) of around 70°, wherein the fuel supply means (12) leads to the pressure space (9) in a radial overlap with the waist (19) of the constricted shank section (14).
2. Fuel injection nozzle according to Claim 1, characterized in that the diameter (23) of the waist (19) of the constricted shank section (14) is larger than half the diameter (22) of the longitudinal bore (4).
3. Fuel injection nozzle according to either of the preceding claims, characterized in that the diameter (23) of the waist (19) of the constricted shank section (14) is located at two thirds of the diameter (22) of the longitudinal bore (4).

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