The invention relates to a fuel injector for internal combustion engines, of the kind which can be used for injecting fuel under high pressure into the combustion chamber of an internal combustion engine.
A fuel injection nozzle or fuel injector for internal combustion engines is known from German Laid-Open Application DE 29 20 100 A1. In the known fuel injector, a nozzle needle is arranged in a longitudinally movable manner in an injector body and interacts by means of a sealing edge formed on the nozzle needle with a nozzle needle seat formed on the injector body and opens and closes a plurality of first injection openings by means of its longitudinal movement. Adjoining this at the combustion-chamber end, the nozzle needle has a pin region, which projects into a blind hole formed in the injector body and thereby closes a plurality of second injection openings. Up to a partial stroke of the nozzle needle, fuel flows into the combustion chamber of the internal combustion engine only through the first injection openings, while the pin region seals off the second injection openings. After the partial stroke, the pin region emerges from the blind hole and thus exposes the second injection openings. A step-shaped injection characteristic which includes good suitability for very small quantities can thereby be achieved. However, the sealing function of the pin region when projecting into the blind hole requires high accuracy of manufacture and high wear resistance.
In contrast, the fuel injector according to the invention exhibits less wear with a similar injection characteristic and, at the same time, requires less accuracy of manufacture.
To achieve this, the fuel injector has a pressure chamber, which is formed in an injector body and in which a nozzle needle is arranged in a longitudinally movable manner, which nozzle needle has, at the combustion-chamber end thereof, a cone region, which is tapered in a combustion chamber direction, and a pin region of constant diameter d23. The injector body furthermore has a substantially conical nozzle needle seat, from which a first injection opening extends, and a blind hole, which adjoins the nozzle needle seat at the combustion-chamber end and has a cylindrical segment having the diameter d31 and a hole base, from which a second injection opening extends. The cone region of the nozzle needle interacts with the nozzle needle seat and thereby opens and closes the first injection opening and the second injection opening with respect to the pressure chamber. At least during a partial stroke of the nozzle needle, the first injection opening and the second injection opening are connected to one another via a throttle gap, which is formed in the blind hole between the pin region and the wall of the blind hole, and the throttle gap remains constant at least over the partial stroke. Owing to the throttle gap, there is no contact or only slight contact between the pin region and the nozzle needle and hence also little or no wear in these regions. Moreover, there can be larger tolerances in manufacture than if the pin region had to perform a sealing function.
In an advantageous embodiment of the fuel injector according to the invention, the difference between the diameter d31 of the blind hole and the diameter d23 of the pin region is greater than 6 μm and less than 30 μm. Thus, the throttle gap is larger by 3 μm on average, and the selected tolerance chain between the pin region and the wall of the blind hole can be relatively large, at up to 3 μm, as long as the nozzle needle is not subject to transverse forces. At the same time, the gap width must be less than 15 μm to achieve sufficient throttling by the throttle gap.
In another advantageous embodiment, one or more second injection openings are present, and the flow cross section through the throttle gap is smaller than the total flow cross section through the second injection opening or through all the second injection openings. The flow cross section through the throttle gap preferably amounts to 15% . . . 70% of the total flow cross section through the second injection opening or through all the second injection openings over the partial stroke. The fuel supply to the second injection openings is thereby throttled for as long as the throttle gap is present, and this means that the fuel injector is well suited to very small quantities.
It is advantageous if the pin region emerges from the blind hole and the flow cross section into the blind hole is enlarged relative to the throttle gap in the case of strokes which are greater than the partial stroke. As a result, more fuel is supplied to the second injection openings, this being necessary to achieve higher engine power outputs.
In another advantageous embodiment, the nozzle needle has an end region which adjoins the pin region at the combustion-chamber end. This enables the transition from partial engine load to full engine load to be made smoother and hence more economical since the curve of the injection rate against time or stroke is shallower in this transition.
In an advantageous embodiment, the end region is embodied as a cone. As a result, the fuel quantity supplied to the second injection openings increases linearly after the partial stroke, leading to an advantageous injection characteristic, depending on the application.
In another advantageous embodiment, the end region is embodied so as to be substantially cylindrical and has at least one lateral recess. As a result, the nozzle needle projects into the blind hole with a portion widened relative to the pin region, even after the partial stroke, and therefore the axial misalignments between the injector body and the nozzle needle are smaller and hence there is also a lower risk of wear during the closing of the nozzle needle. The shape of the lateral recesses can be configured according to the application, ensuring that the fuel supplied to the second injection openings increases quickly or less quickly after the partial stroke.
It is advantageous if the at least one recess is embodied as a ground flat. The desired reduction in the throttling function after the partial stroke can thereby be achieved in a simple manner through a manufacturing technique.
In another advantageous embodiment, the at least one recess is embodied so as to be substantially semicircular in cross section. The potential area of contact between the end region and the wall of the blind hole is thereby enlarged, leading to better guidance of the nozzle needle in the blind hole and hence also to a lower risk of wear.
It is advantageous if the flow cross section into the blind hole is larger than the total flow cross section through all the second injection openings in the case of a maximum stroke of the nozzle needle which is greater than the partial stroke. As a result, the injection characteristic in the case of the maximum stroke is determined substantially by the geometry of the first and second injection openings; there is virtually no longer any throttling function between the injector body and the nozzle needle. The accuracy of manufacture of the two injection openings is therefore decisive for the maximum stroke, while the tolerances of the throttle gap are of subordinate importance in this respect.
It is advantageous if a plurality of first injection openings and/or a plurality of second injection openings is/are present. Uniform injection of the fuel into the combustion chamber can thereby be achieved.
A nozzle needle 20 is arranged in a longitudinally movable manner in the pressure chamber 30. In the detail shown, the nozzle needle 20 has a central part 21 and a cone region 22 arranged on the combustion-chamber end thereof, a pin region 23 and an end region 24. The cone region 22 and the end region 24 are embodied so as to taper in the direction of the combustion chamber 110, and the pin region 23 is embodied so as to be cylindrical with the diameter d23.
In the detail shown, the injector body 10 has a cylindrical body stem 11 and, adjoining the latter at the combustion-chamber end, a conical nozzle needle seat 17 and a blind hole 31, which represents part of the pressure chamber 30. At least one first injection opening 1 of diameter d1 leads into the combustion chamber 110 from the blind hole 31, and at least one second injection opening 2 of diameter d2 leads into the combustion chamber 110 from the nozzle needle seat 17. The blind hole 31 has a cylindrical section of diameter d31 and, adjoining the latter at the combustion-chamber end, a hole base, which is of rounded design in the illustrative embodiment shown. There can be both one or more first injection openings 1 and one or more second injection openings 2.
In the closed operating state shown, the nozzle needle 20 interacts with the nozzle needle seat 17 at a sealing edge 22a formed at the transition from the central part 21 to the cone region 22 and thus closes the hydraulic connection from the pressure chamber 30 to the first injection opening 1 and the second injection opening 2; the blind hole 31 is thereby separated hydraulically from the remainder of the pressure chamber 30. The cylindrical pin region 23 of diameter d23 projects into the cylindrical section of the blind hole 31 of diameter d31 and thus forms a throttle gap 32 of width t/2 with the wall of the blind hole 31, where t=d31−d23. The first injection opening 1 and the second injection opening 2 are continuously connected hydraulically via the throttle gap 32.
To inject fuel through the two injection openings 1, 2, the nozzle needle 20 is moved in the opening direction 29 by a control operation (not shown), e.g. the lowering of a pressure in a control chamber at the end of the nozzle needle 20 remote from the combustion chamber, with the result that the cone region 22 and the sealing edge 22a rise from the nozzle needle seat 17 and the hydraulic connection from the pressure chamber 30 to the two injection openings 1, 2 and the blind hole 31 is freed.
Up to a partial stroke s of the nozzle needle 20, the pin region 23 projects into the blind hole 31, and therefore the throttle gap 32 exists in the blind hole 31 between the pin region 23 and the wall of the blind hole 31. During this partial stroke s, the throttling effect due to the throttle gap 32 is greater than the throttling effect due to the second injection opening 2 or the total throttling effect due to all the second injection openings 2; the flow cross section through the throttling gap 32 is thus smaller than the total flow cross section through all the second injection openings 2. To achieve this, the width t/2 of the throttle gap 32 and the clearance t for the pin region 23 within the blind hole 31 should be designed as follows:
The flow cross section through throttle gap ADS is:
where d31>>t:
Flow cross section through all x second injection openings A2.EÖ:
Up to the partial stroke (s), the following should apply: ADS<A2.EÖ
Up to the partial stroke (s), the following should preferably apply:
Up to the partial stroke s, the injection characteristic is thus determined substantially by the geometry of the first injection opening 1 and of the throttle gap 32.
After the partial stroke s, the pin region 23 emerges from the blind hole 31, but initially the end region 24 remains in the blind hole 31. Owing to the conical shape of the end region 24, the flow cross section between the blind hole 31 and the nozzle needle 20 widens as the stroke increases. At a maximum stroke v, the pin region 23 and the end region 24 have emerged from the blind hole 31 to such an extent that the flow cross section between the injector body 10 and the nozzle needle 20 is larger than the total flow cross section through all the second injection openings 2. At the maximum stroke v, the injection characteristic is thus determined substantially by the geometry of the first and second injection openings 1, 2.
The illustrative embodiment in
Number | Date | Country | Kind |
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10 2013 217 371 | Aug 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/066770 | 8/5/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/028261 | 3/5/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
1833080 | Kenworthy | Nov 1931 | A |
3559892 | De Luca | Feb 1971 | A |
4200237 | Urlaub | Apr 1980 | A |
4360162 | Eckert | Nov 1982 | A |
4506833 | Yoneda | Mar 1985 | A |
5947389 | Hasegawa et al. | Sep 1999 | A |
Number | Date | Country |
---|---|---|
2803774 | Aug 1979 | DE |
10207189 | Sep 2002 | DE |
1283336 | Feb 2003 | EP |
1190361 | Oct 1959 | FR |
S547020 | Jan 1979 | JP |
S61130487 | Jun 1986 | JP |
H10141179 | May 1998 | JP |
H11280610 | Oct 1999 | JP |
2000145586 | May 2000 | JP |
2002322957 | Nov 2002 | JP |
2005517122 | Jun 2005 | JP |
2006063951 | Mar 2006 | JP |
2011033036 | Mar 2011 | WO |
Entry |
---|
International Search Report for Application No. PCT/EP2014/066770 dated Oct. 17, 2014 (English Translation, 3 pages). |
Number | Date | Country | |
---|---|---|---|
20160215745 A1 | Jul 2016 | US |