This application claims priority to EP Patent Application No. 12180213 filed Aug. 13, 2012. The contents of which is incorporated herein by reference in its entirety.
This disclosure relates to a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail of a combustion engine.
Coupling devices for hydraulically and mechanically coupling a fuel injector to a fuel rail are in widespread use, in particular for internal combustion engines. Fuel can be supplied to an internal combustion engine by the fuel rail assembly through the fuel injector. The fuel injectors can be coupled to the fuel injector cups in different manners.
In order to keep pressure fluctuations during the operation of the internal combustion engine at a very low level, internal combustion engines are supplied with a fuel accumulator to which the fuel injectors are connected and which has a relatively large volume. Such a fuel accumulator is often referred to as a common rail.
Known fuel rails comprise a hollow body with recesses in form of fuel injector cups, in which the fuel injectors are received. The connection of the fuel injectors to the fuel injector cups that supply the fuel from a fuel tank via a low or high-pressure fuel pump needs to be very precise to get a correct injection angle and a sealing of the fuel.
One embodiment provides a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail of a combustion engine, the coupling device comprising a fuel injector cup being designed to be coupled to the fuel rail and to engage a fuel inlet portion of the fuel injector, the fuel injector cup comprising a first part comprising a recess, a second part being configured to be received in the recess of the first part and being designed to engage the fuel inlet portion of the fuel injector, wherein the second part has a porosity which is lower than the porosity of the first part.
In a further embodiment, the first and the second part comprise stainless steel.
In a further embodiment, the second part is configured to sealingly interact with a sealing of a fuel injector.
In a further embodiment, the second part is designed such that it provides a surface being configured to interact with the fuel injector.
In a further embodiment, the first part is manufactured by casting.
In a further embodiment, the second part is manufactured by machining, stamping or deep drawing.
In a further embodiment, the first part and the second part are connected by one or both of interference fitting or brazing.
Another embodiment provides a system comprising a coupling device as disclosed above, and a fuel injector comprising a fuel inlet portion and a sealing, wherein the sealing is in engagement with the fuel injector and with the second part of the coupling device such that the fuel inlet portion of the fuel injector is hydraulically coupled to the coupling device.
Another embodiment provides a method for manufacturing a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail of a combustion engine, the method comprising the steps of providing a first part having a recess, providing a second part being configured to be received in the recess of the first part and comprising the step of inserting the second part in the recess of the first part wherein the second part has a porosity which is lower than the porosity of the first part.
In a further embodiment, the first and second parts comprise a metal and the first part is casted and/or the second part is machined, stamped or deep drawn.
In a further embodiment, the method further comprises casting the first part and machining, stamping or deep drawing the second part.
In a further embodiment, the method comprises the step of applying brazing material in at least one circumferential groove being provided in the first part at a contact interface between the first part and the second part before the second part is received in the first part.
In a further embodiment, the method comprises the step of applying brazing material on a contact interface between the first part and the second part via through-holes being provided in the first part.
In a further embodiment, the method comprises the step of heating the first part and the second part, thereby joining the first part and the second part.
In a further embodiment, the method comprises the step of heating the first part and the second part, thereby joining the first part and the second part.
Another embodiment provides a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail of a combustion engine, the coupling device comprising a fuel injector cup being operable to couple to the fuel rail and to engage a fuel inlet portion of the fuel injector, the fuel injector cup comprising a first part comprising a recess, a second part being configured to be received in the recess of the first part and being operable to engage the fuel inlet portion of the fuel injector, wherein the first part has a multitude of voids and the fraction of the volume of said voids over the total volume of the first part is larger than a fraction of the volume of voids of the second part over a volume of the second part.
Example embodiments of the invention are explained in the following with the aid of schematic drawings, in which:
Some embodiments provide a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail which is simple to be manufactured, cost-effective, and facilitates a reliable and precise connection between the fuel injector and the fuel injector cup.
For example, one embodiment provides a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail of a combustion engine. The coupling device comprises a fuel injector cup. The fuel injector cup is expediently designed to be coupled to the fuel rail and to engage a fuel inlet portion of the fuel injector.
The fuel injector cup comprises a first part comprising a recess and a second part being configured to be received in the recess of the first part. The second part is expediently designed to engage the fuel inlet portion of the fuel injector. In particular, the second part has a hollow shape, for example a tubular shape.
According to one aspect of the present disclosure, the second part may have a porosity which is lower than the porosity of the first part. The porosity may sometimes also be called void fraction and is in particular the fraction of the volume of voids over the total volume of the respective part.
In one embodiment, first part and the second part each are metal parts, i.e. they comprise at least one metal or consist of at least one metal or alloy. In one development, the first and the second part are made from the same metal or alloy. The first part and/or the second part is/are made from stainless steel, for example.
In one embodiment, the first part may be designed as an external part, and the second part may be designed as an insert being configured to be inserted into the external part. The first part may line a surface of the recess of the second part.
In particular, the second part of the injector cup is configured to sealingly interact with a sealing of a fuel injector. For example, the sealing may be achieved by a sealing ring such as an o-ring which is positioned between the second part and the fuel injector.
Due to the low porosity of the second part, the second part may provide a smooth sealing surface. In particular, the porosity of the second part may be such that a satisfactory sealing function may be achieved. Thereby, a secure sealing of the fuel injector to the fuel injector cup is possible. As a result, the possibility of leak between the injector cup and the fuel injector may be reduced.
Porosity is a measure of void spaces in a material. For example, the void spaces in the first part may have a size of about 80 μm to 120 μm. The void spaces in the second part may be much smaller, for example 5 μm to 10 μm.
In one embodiment, the second part is designed such that it provides a surface being configured to interact with the fuel injector. For example, the second part may have a surface which represents apart of the bottom surface of the injector cup. In this case, a bottom surface of the first part may comprise a step, which is adapted to the form of the second part, such that after inserting the second part into the first part, a plane surface is achieved. This solution has the advantage that the second part is easy to manufacture.
In one development, the second part may extend—in particular completely—over the bottom surface of the injector cup. In other words, a surface of the second part represents the whole bottom surface. The bottom surface is in particular an end surface of the injector cup at its fuel outlet end. Preferably, it is perpendicular to a longitudinal axis of the injector cup.
This may have the advantage that no step, for example due to manufacturing tolerances, may occur on the bottom surface of the injector cup. Furthermore, the bottom surface may serve as a stop surface for the insertion of the second part. For example, the second part has a tubular shape with a flange, wherein a surface of the flange represents the bottom surface of the injector cup.
For example, the fuel injector may be mounted to the injector cup by a connection plate being mounted to the injector cup, in particular to the bottom surface of the injector cup. The bottom surface of the injector cup may be a reference plane to orient the connection plate of the fuel injector, and, as a consequence, the injector. With the second part extending over the whole bottom surface of the injector cup, a high planarity precision and an accurate injector orientation may be achieved. The connection plate may be fastened to the injector cup by two or more connection means, for example by screws. Alternatively, the fuel injector may be mounted to the injector cup by clamping means, for example by means of a spring clip. In this clamped application, the bottom surface of the injector cup may be the contact plane for the clamping means. Therefore, due to a high planarity precision of the bottom surface, a secure fastening of the fuel injector may be achieved.
According to one embodiment, the first part is manufactured by casting. The second part may be manufactured by machining, stamping or deep drawing. This has the advantage that the injector cup is easy to manufacture and has a high mechanical resistance, and also provides a sufficient sealing function.
Due to the different manufacturing process, the first and the second part may comprise different material properties. In particular, the first and the second part may have a different porosity.
According to one embodiment, the first part and the second part are connected by one or both of interference fitting or brazing. In particular, the first and second parts are configured to maintain a fixed position to each other by means of the connection. For example, the first part and the second part may be connected by press fitting or shrink fitting. Additionally or alternatively, the first part and the second part may be connected by brazing. The brazing material may be, for example, copper.
A brazed connection ensures that the first and the second part may not be displaced with respect to each other or disengage. Furthermore, a brazing joint may also seal the first part and the second part.
According to one embodiment, the first part may comprise one or more through-holes for applying brazing material. For example, the first part has a sidewall, the side wall extending in particular in a longitudinal direction of the injector cup, and the through-hole(s) extend obliquely or perpendicular to the longitudinal direction through the side wall. Via the through holes, the braze joint may be inspected after the brazing took place.
Additionally or alternatively, the first part may comprise at least one groove at the recess, in particular at the interface between the first part and the second part. The groove may serve as a seat for brazing material. Thereby, the distribution of the brazing material between the first and second part may be accurate and reproducible. By applying the brazing material via through holes or in one or more defined groove, brazing wetting or an overflow of brazing material into the fuel injector cup, in particular on the interior sealing surface of the fuel injector cup, may be inhibited.
According to a further aspect, a system comprising a coupling device, a fuel injector comprising a fuel inlet portion and a sealing is specified. The system is in particular a fuel rail assembly. It may expediently comprise a fuel rail such as a common rail.
The coupling device comprises a fuel injector cup. The fuel injector cup in particular has a first part comprising a recess and a second part being configured to be received in the recess of the first part and being designed to engage the fuel inlet portion of the fuel injector, wherein the second part has a porosity which is lower than the porosity of the first part. Preferably, the coupling device is designed as described above.
The sealing, for example the sealing ring, is in engagement with the fuel injector and with the second part of the coupling device such that the fuel inlet portion of the fuel injector is hydraulically coupled to the coupling device. In particular, the sealing may be engaged with an internal sealing surface of the second part.
According to yet another aspect, a method for providing a coupling device for hydraulically and mechanically coupling a fuel injector to a fuel rail of a combustion engine is specified. The method comprises the steps of providing a first part comprising a recess and providing a second part being configured to be received in the recess of the first part, wherein the second part has a porosity which is lower than the porosity of the first part, and comprising the step of inserting the second part in the recess of the first part.
According to one embodiment of the method, the first part is casted. According to a further embodiment of the method, the second part is machined, stamped or deep drawn.
According to one embodiment, the method comprises the step of applying brazing material on a contact interface between the first part and the second part via one or more through-holes being provided in the first part. For example, the through-holes may be provided on opposite sides in a wall of the first part. In particular, the brazing material may be applied via the through holes after the second part has been inserted into the first part. According to a further embodiment, the method comprises the step of applying brazing material in at least one circumferential groove being provided in the first part at a contact interface between the first part and the second part. In particular, the brazing material may be applied before the second part is received in the first part. After applying the brazing material in the groove, the second part may be inserted into the recess of the first part.
According to one embodiment, the method comprises the step of heating the first and the second part, thereby brazing and joining the first and the second part. For example, the parts may be heated in an oven.
Preferably, the method may serve to provide a coupling device as described previously.
The first part 6 is a casted part, while the second part 7 may be machined, stamped or deep drawn. Due to the different manufacturing process, the second part 7 may have a lower porosity than the first part 6.
The second part 7 is inserted in a recess 9 of the first part 6. The recess may open towards a fuel outlet end 40 of the injector cup 4. Opposite the opening at the fuel outlet end, the recess may have a bottom section with a fuel inlet opening 90. Advantageously, the second part 7 lines a surface, in particular an annular side surface, of the recess 9 at an interface 13 with the first part 6. In the present embodiment, the second part 7 has a generally tubular, hollow shape having a longitudinal axis.
The first part 6 and the second part 7 may be connected by brazing or by interference fitting—sometimes also denoted as press fitting or friction fitting—or by both. In particular, the first part 6 and the second part 7 are connected such that a relative movement between these two parts is avoided.
Adjacent to the recess 9 of the first part 6, two bores 16 are located. The bores 16 are provided for fastening a connector plate of a fuel injector to the fuel injector cup 4 (shown in
The second part 7 extends over the bottom surface 17 of the first part 6. For example, the second part 7 has a flange 20 at one end. The bottom surface 17 and the flange are expediently located at the fuel outlet end 40. Thereby, the second part 7 provides a planar surface 11 being configured to align a fuel injector (not shown). The bottom surface 17 may serve as a stop surface for the insertion of the second part 7 into the recess 9 of the first part 6.
The second part 7, in particular the flange of the second part 7, comprises bores 19 which are concentrically aligned to the bores 16 of the first part 6. When a fuel injector is mounted to the fuel injector cup 4, for example by screws being received in the bores 16 and 19, the second part 7 may be securely fastened to the first part 6. In this case, an interference fitting may be sufficient to connect the first part 6 and the second part 7. A brazing of the first part 6 and the second part 7 may be unnecessary.
In particular, the second part 7 does not fully extend over the bottom surface 17 of the first part 6. In other words, the second part 7 partially exposes the bottom surface 17. Particularly, the second part 7 does not extend over the bores 16 of the first part 6. It comprises only a small collar 20 which serves as a stop for the insertion into the recess 9 of the first part 6. The first part 6 comprises a step which is adapted to the form of the second part 7, such that a planar surface 11 is provided at the bottom of the fuel injector cup 4. The second part 7 shown in
There are two through-holes 14 located in a wall 21 of the first part 6. The through-holes 14 may be omitted in the coupling device of the second embodiment, for example when the first and second parts 6, 7 are coupled by friction fitting.
The through-holes 14 are provided for applying brazing material between the first part 6 and the second part 7, in particular on an interface 13 between the first part 6 and the second part 7. By means of the through-holes 14, brazing wetting or an overflow of brazing material on an interior surface 22 of the second part 7 may be inhibited. Furthermore, after the brazing has occurred, the brazing joint may be inspected via the through-holes 14.
In the present embodiment, the coupling device 1 has a lug 26. The lug 26 may be formed integrally with the first part 6, for example.
It is in particular provided for establishing a—preferably rigid—mechanical connection between the injector cup 4 and cylinder head (not shown), for example of an internal combustion engine. The lug 26 may have a hole for receiving a screw, for example (see
In the present embodiment, the first part 6 comprises a circumferential groove 15 at the interface 13 between the first part 6 and the second part 7. This groove 15 is provided to serve as a seat for the brazing material. The brazing material may be applied into the groove 15 before the second part 7 is inserted into the first part 6. By applying the brazing material into the circumferential groove 15, it may be ensured that the brazing material is evenly distributed around the interface 13 between the first part 6 and the second part 7. Thereby, the quality of the brazing joint may be precise and reproducible.
The fuel injector 3 is mounted to the fuel injector cup 4 of the coupling device 1 via a connection plate 23. The connection plate 23 is aligned at the surface 11 of the injector cup 4, in particular of the second part 7, and fastened by means of two screws 25 being inserted through the bores 16, 19 of the first part 6 and the second part 7. The connection plate 23 and the fuel injector 3 may mechanically interact—for example by means of a wire ring or a snap ring 27—to block axial movement of the injector 3 with respect to the connection plate 23 at least in one axial direction. In this way, the connection plate 23 is in particular provided for positionally locking the fuel injector 3 in the recess 9.
A sealing 10, in particular an o-ring, is located around the fuel injector 3. The sealing 10 is in engagement with the interior surface 22 of the second part 7. Due to the low porosity of the second part 7, a satisfactory sealing may be achieved between the injector cup 4 and the fuel injector 3. Thereby, a fuel inlet portion 5 of the fuel injector 3 may be hydraulically coupled to the injector cup 4.
In one embodiment of the method, brazing material may be applied in a circumferential groove of the first part in step C. The circumferential groove may be located in the recess of the first part.
In a subsequent step D, the second part may be inserted into the recess of the first part.
In one embodiment, additionally or alternatively to step C, brazing material may be applied on an interface between the first part and the second part in a step C′, after the second part has been inserted into the recess of the first part. For example, brazing material may be applied via through-holes in a wall of the first part.
Afterwards, in a step E, the first part and the second part may be connected by brazing. For example, the parts may be heated in an oven.
In a further embodiment, the first and the second part may be connected only by interference fitting without brazing.
With this method, for example a coupling device according to any of
The invention is not limited to specific embodiments by the description on the basis of said exemplary embodiments but comprises any combination of elements of different embodiments. Moreover, the invention comprises any combination of claims and any combination of features disclosed by the claims.
Number | Date | Country | Kind |
---|---|---|---|
12180213 | Aug 2012 | EP | regional |