The invention relates to a fuel injector for internal combustion engines of the kind used, in particular, as a component of a “common rail” injection system for self-ignition internal combustion engines for applications with relatively high maximum flow or injection rates.
A fuel injector for internal combustion engines is known from DE 10 2016 116 690 A1. The known fuel injector is distinguished by a nozzle needle with a needle tip which, below a section of conical design in the direction of a blind hole bottom of a nozzle body, has a cylindrical section with two edges extending radially around a longitudinal axis of the nozzle needle, wherein, in a closed position of the nozzle needle, the second edge, that adjacent to the blind hole bottom, is arranged below a lower inlet edge of an injection opening, wherein, in a partially open position of the nozzle needle, the first edge, that further away from the blind hole bottom, is arranged below an upper inlet edge of the injection opening, and wherein, in a fully open position of the nozzle needle, the second edge is arranged above the lower inlet edge of the injection opening. Such a design of the needle tip of the nozzle needle is intended, in particular, to permit a stable flow between the nozzle needle, the blind hole and the injection opening or to avoid unstable flow states. Such unstable flow states can manifest themselves in a tendency for cavitation in the partial stroke range of the nozzle needle and thus, in particular, may also adversely affect quantitative accuracy over the service life of the fuel injector.
Apart from the desired properties such as the achievement of a stable flow while at the same time having a low dead volume, the fuel injector according to the invention has the advantage above all that its tendency for cavitation is significantly reduced in a partial stroke range of the nozzle needle, in which the cross-sectional area in the region of the seat between the nozzle needle and the nozzle body is smaller than the cross section of the injection openings below the nozzle seat. In addition, high flow efficiency is achieved in the full-stroke range of the nozzle needle.
According to the invention, the abovementioned advantages in the fuel injector according to the invention are achieved in that the diameter of the nozzle needle in the region of the first edge is greater than the diameter of the nozzle needle in the region of the second edge, and in that a distance between the two edges, when viewed in the direction of the longitudinal axis, corresponds to 0.4 times to 1.6 times a diameter of the injection opening in an inlet region to the blind hole in the non-rounded state of the inlet region.
The general concept of the invention described above can be implemented in different ways in terms of construction in order in each case to achieve specifically beneficial advantages. Thus, in a first design implementation, it is envisaged that the nozzle needle has at least one section of conical design between the two edges of the needle tip.
As an alternative to this, however, it is also possible for the nozzle needle to be of cylindrical design between the two edges.
In yet another design alternative to the last two proposals, provision is made for the nozzle needle to be of convex or concave design between the two edges.
Irrespective of the shape of the nozzle needle in the axial end region or in the region of the needle tip, a further embodiment that is preferred in terms of design provides for the nozzle needle to have a section of cylindrical design between the first edge and the sealing surface on the nozzle seat.
In a further development of the last-mentioned proposal, provision is made for the section of cylindrical design to be adjoined in the direction of the sealing surface on the nozzle body by a section of conical design whose angle with respect to the longitudinal axis of the nozzle needle is greater than the angle between the sealing surface and the longitudinal axis.
In a further development of the last proposal made, it is particularly advantageous if the difference between the two angles on the nozzle needle is less than 8.5°. In particular, this avoids a strong deflection of the fuel flow with correspondingly negative effects.
As an alternative to a section of cylindrical design between the first edge and the sealing surface in the region of the nozzle body, provision can also be made for the nozzle needle to have a section of concave design there.
There are also different possibilities with regard to the design of the nozzle needle below the second edge or in the direction of the bottom of the blind hole. Thus, for example, provision can be made for the second edge to delimit a flat end face of the needle tip. As an alternative to this, provision can be made for the needle tip to be of conical design on that side of the second edge which faces away from the first edge.
Irrespective of the specific shape of the nozzle needle described so far, it is also important with regard to flow guidance to configure the design of the nozzle body in an advantageous manner. For this purpose, provision is made, in particular, for the blind hole in the nozzle body to have a cylindrical section which merges into a rounded blind hole bottom, and for the transition between the cylindrical section and the rounded blind hole bottom to be arranged between the upper and lower inlet edges of the injection opening, wherein the longitudinal axis of the injection opening preferably intersects the transition.
A further optimization of the fuel flow in the direction of the injection opening envisages that the injection opening is designed to be rounded in the inlet region to the blind hole.
Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments of the fuel injector and with reference to the drawings.
In the figures, identical elements or elements having the same function are provided with the same reference numerals.
The fuel injector 10 has a nozzle body 12, in which a blind hole 14 is formed. In longitudinal section, the blind hole 14 has a section 16 which is of conical design about a longitudinal axis 15 of the nozzle body 12 and forms a seat surface 17. Section 16 merges into a cylindrical section 18, which is adjoined by a rounded blind hole bottom 20. Opening into the transitional region between the cylindrical section 18 and the blind hole bottom 20 there is at least one injection opening 22, which is designed as a through hole in the nozzle body 12 and via which fuel can be injected from the nozzle body 12 into the combustion chamber of the internal combustion engine.
The injection opening 22 is arranged at an oblique angle α with respect to the longitudinal axis 15, wherein a longitudinal axis 23 of the injection opening 22 preferably intersects the transition between the cylindrical section 18 and the blind hole bottom 20 (
According to the illustration of
The diameter of the injection opening 22 in the region outside the rounded portion 25 is denoted by d.
For the injection of fuel into the combustion chamber of the internal combustion engine, the nozzle body 12 described thus far interacts via the at least one injection opening 22 with a nozzle needle 26 arranged so that it can perform a stroke motion along the longitudinal axis 15. The nozzle needle 26 is moved by means of a magnetic actuator (not illustrated), for example, in a manner known per se, such that, in a lowered position, illustrated in
On the side facing the blind hole bottom 20, the sealing surface 28 of the nozzle needle 26 merges into a cylindrical section 35 as part of a needle tip 34, which is in turn adjoined by a conical section 36. The end face 38 of the nozzle needle 26, which faces the blind hole bottom 20, is designed as a flat end face 38, i.e. extends perpendicularly to the longitudinal axis 15.
The transition between the cylindrical section 35 and the conical section 36 of the nozzle needle 26 forms a first edge 41 with a first diameter D1 extending radially around the longitudinal axis 15. At the transition to the conical section 36, the end face 38 forms a second edge 42, with a second diameter D2 extending radially around the longitudinal axis 15. In this case, the second diameter D2 is smaller than the first diameter D1. Furthermore, an axial distance a is formed between the two edges 41, 42, when viewed in the direction of the longitudinal axis 15. The distance a is 0.4 times to 1.6 times the diameter d of the injection opening 22 outside the inlet region 24, i.e. in the cylindrical region of the injection opening 22.
The nozzle needle 26b illustrated in
The nozzle needle 26c illustrated in
Finally,
Number | Date | Country | Kind |
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10 2019 210 631.5 | Jul 2019 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/064627 | 5/27/2020 | WO |