The present invention relates to a fuel injector having an improved high-pressure connection between an injector and a rail.
Fuel injectors are known from the related art in various embodiments. In high-pressure injection systems, a metal-metal connection instead of an o-ring sealing is increasingly used between a rail (fuel storage device) and an injector in order to reduce HC emission. These metal-metal connections, however, require relatively strong forces, using which the surfaces must be pressed onto one another, to ensure a sufficient tightness. Oftentimes, the force necessary thereto is applied to the metal sealing surfaces with the aid of a cap nut which is fastened by screws. In the known approach, a plurality of individual components is, however, necessary, in particular multiple ring segments being used for force transmission. On the one hand, this results in high manufacturing costs due to the plurality of components and, on the other hand, in an increased mounting complexity. It would therefore be desirable to have a reliable connection which may be easily mounted between an injector and a rail even for high-pressure applications.
The fuel injection device according to the present invention has the advantage over the related art that a metal-metal sealing is possible which does not allow leakages in a rail even at high pressures. According to the present invention, an angular misalignment potentially present between the rail and an injector may furthermore be compensated for by a connecting piece according to the present invention. According to the present invention, a flange element is furthermore provided to fasten the injector on the rail, the flange element engaging with an undercut on the one-piece connecting piece and pressing the connecting piece against the rail to enable a reliable metal-metal sealing. In this case, it is possible to reduce the number of parts and furthermore to simplify a mounting.
The metal-metal sealing is preferably a metallic ball-cone sealing, the spherical area preferably being provided on the connecting piece and the cone on the rail.
Furthermore preferably, the flange element has a two-part design having a first and a second part. In this way, a particularly simple mounting of the flange area on the connecting piece may be made possible.
Particularly preferably, the first part of the flange element is constructed identically to the second part of the flange element. This results in a particularly cost-effective manufacturability. Furthermore, the risk of mixing up the parts during mounting is eliminated.
The two-part flange element is preferably divided at a central opening through which the connecting piece is guided. This makes a lateral mounting of the flange element on the connecting piece possible.
According to one alternative preferred embodiment of the present invention, the flange element is designed in one piece. This allows for an even easier mounting of the flange element.
Particularly preferably, the one-piece flange element includes a mounting opening which is connected to the central opening via a continuous connecting slot. This makes it possible for the connecting piece to be guided at least partially through the mounting opening of the flange element and subsequently to be situated in the central opening via the continuous connecting slot. This may take place by tilting the flange element, for example. Particularly preferably, the mounting opening is situated at an angle of approximately 45° to the central opening.
According to another alternative embodiment of the present invention, the flange element is designed in one piece, and a connection in the form of a bayonet joint is provided between the flange element and the connecting piece. In this way, a simple mounting, e.g., by inserting and subsequently rotating the flange element, may take place.
Particularly preferably, the undercut has a partially spherical shape on the connecting piece, and one or multiple partially spherical areas having the same or a very similar radius to the radius on the undercut are formed on the flange element. In this way, a very good angle compensation between rail and injector may be made possible in a particularly simple manner.
Furthermore preferably, a chamfer is provided on a central opening of the flange element which is directed toward the connecting piece. In this way, a contact area between the flange element and the connecting piece is enlarged.
The present invention is preferably used in high-pressure injection systems.
A fuel injection device 1 according to one first preferred exemplary embodiment of the present invention is described in detail below with reference to
Furthermore, fuel injection device 1 according to the present invention includes a flange element 5 which is shown in detail in
As is apparent from
In this way, a reliable metal-metal sealing 9 may be made possible between rail 2 and injector 3 with the aid of a two-part flange element 5. With the aid of the two-part embodiment of flange element 5, flange element 5 may be easily attached to connecting piece 4 from the side below undercut 42, so that connecting piece 4 runs through central opening 50 in flange element 5. By screwing in the two fastening elements 6, 7, flange element 5 is then tightened in the direction of rail 2 and thus applies the preload force necessary for the sealing to connecting piece 4.
Thus, according to the present invention, the injector, including a final extrusion coating using a plug (not shown), may be finished, and it is not until the final assembly that two-part flange element 5 is assembled on the injector, more specifically on connecting piece 4 which is fixedly fastened to injector 3. In addition to reducing the number of parts, flange element 5 may also be attached very quickly and easily. Another advantage is that a risk of damaging spherical area 41 and conic area 42 is considerably reduced due to the mounting below undercut 42. This is a significant advantage over the related art, since the mounting may take place laterally and even the least amount of damage in the spherical area or in the conic area may result in leakages due to the extremely high pressures of above 20 MPa.
It should be noted that on the side of central opening 50 directed toward rail 2 a chamfer (not shown) for a larger contact surface may be provided between connecting piece 4 and flange element 5.
It should be pointed out that tilting back of flange element 5 or unintentional twisting of flange element 5 may be prevented by a plastic clip, for example.
Thus, the second exemplary embodiment has a one-piece flange element 5 having a central opening 50 and a separate mounting opening 60 which is situated at an angle to central opening 50. Flange element 5 may be put into a mounting position for being mounted on rail 2 with the aid of a simple pivoting process.
In
Thus, the three described exemplary embodiments demonstrate a very cost-effective and reliable connection between a rail 2 and an injector 3. Flange element 5 may have a two-part design as described in the first exemplary embodiment or a one-piece design as described in the second and the third exemplary embodiments. In particular, the number of parts needed for mounting injector 3 on rail 2 may be significantly reduced.
Number | Date | Country | Kind |
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10 2011 002 996.6 | Jan 2011 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2012/050591 | 1/17/2012 | WO | 00 | 9/5/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/098087 | 7/26/2012 | WO | A |
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