DE102014223661A1 - fuel injector - Google Patents

Abstract

The invention relates to a fuel injector (10), in particular a common rail injector, with an injector housing (11) in which a high-pressure chamber (15) is formed which has a supply bore (19) arranged under pressure in the supply housing (11) Fuel is supplied with at least one at least indirectly with the high-pressure chamber (15) connected in the injector (11) formed injection port (12) for injecting fuel into the combustion chamber of an internal combustion engine, with an at least one injection port (12) releasing or occluding injection member (16), and with a measuring device (30) for at least indirect detection of the pressure in the high pressure chamber (15) or the supply bore (19), wherein the measuring device (30) is adapted to an elastic deformation of at least indirectly with the supply bore (19 ) or the high-pressure chamber (15) in operative connection arranged deformation region (27) to detect, and wherein the measuring device (30) has a sensor element (32) which is connected to the surface of the deformation region (27) via an adhesive connection (34). According to the invention, at least the region of the adhesive bond (34) between the deformation region (27) and the sensor element (32) is enclosed by a housing element (40) which seals at least the area of the adhesive bond (34) against the external environment in a media-tight manner ,

Description

State of the art

The invention relates to a fuel injector, in particular a common rail injector, according to the preamble of claim 1.

A fuel injector according to the preamble of claim 1 is from the post-published DE 10 2014 209330 A1 the applicant known. In the case of the known fuel injector, a measuring device with a sensor element which is arranged in the region of a supply bore on the injector housing is used in particular for detecting the point in time of the closing of the nozzle needle when it hits its seat in the injector housing and thereby at least indirectly closes the injection opening formed in the injector housing , The supply bore supplies a high-pressure space, in which the nozzle needle is arranged, with fuel under high pressure. In particular, the injector housing in the region of the measuring device on a deformation region which is formed elastically deformable in dependence on the fuel pressure in the supply bore. With an increase in pressure in the supply bore, the deformation area bulges outwards, which can be detected by means of the sensor element. The sensor element is connected to the deformation region by means of an adhesive bond and designed to detect strains or tensile stresses occurring in the contact region to the injector housing, wherein the size or height of the strains is dependent on the pressure in the supply bore. Characteristic of the above-mentioned closing the injection openings through the nozzle needle is that thereby takes place (relatively strong or faster) pressure increase in the supply line, since no more fuel is discharged through the injection openings, wherein the pressure increase is detected by the sensor element.

During operation of the internal combustion engine, the adhesive bond is exposed not only to different temperatures, but also other environmental influences such as, in particular, soiling or gases which, depending on the composition, can adversely affect the fatigue strength of the adhesive bond.

Disclosure of the invention

Based on the illustrated prior art, the invention has the object to protect the region of the adhesive bond between the deformation region and the sensor element from external influences or media that over the prior art, an improved durability, in particular over the life of the fuel injector is achieved.

This object is achieved in a fuel injector with the characterizing features of claim 1, characterized in that at least the region of the adhesive bond between the deformation region and the sensor element is enclosed by a housing member which seals at least the area of the adhesive bond against the outside environment media-tight. By means of the housing element provided according to the invention, in particular the region of the adhesive bond of the sensor element is protected against environmental influences such as dirt, moisture, oil or similar media.

Advantageous developments of the fuel injector according to the invention are given in the dependent claims.

It is very particularly preferred if the housing element is filled with an inert gas in the area between the housing element and the adhesive connection. Suitable inert gases include, for example, noble gases (Ne, Ar) or chemically particularly inert gas compounds (CO ₂ , SF ₆ , or the like). It is particularly preferred to introduce the inert gas into the housing element during the production process. In particular, it may be provided that the housing element is connected by means of a welded connection to the injector housing, wherein the welding takes place in the desired inert atmosphere.

In an alternative embodiment, it can be provided that the housing element is evacuated in the region between the housing element and the adhesive bond. Again, it is advantageous in turn to design the evacuation during the manufacturing process of the fuel injector, in particular during the connection of the housing element with the injector element in that the bonding (welding or bonding) of the housing element takes place with the injector under vacuum.

In a structurally preferred embodiment of the housing element, this is cup-shaped and surrounds the measuring device completely, with the exception of the deformation region. As a result, not only the immediate area of the adhesive bond between the deformation region and the sensor element is protected against undesired environmental influences, but overall the measuring device is protected.

To a durable, solid and media-tight connection between the housing element and the injector in a particularly simple manner can form, it can be provided that the housing element has a flange-like area with a connection surface, wherein the connection surface is connected by means of a welding or adhesive connection, preferably by means of a laser weld, with the injector. As already explained above, the welding of the housing element to the injector housing preferably takes place either under an inert atmosphere or under a vacuum.

For electrical contacting of the sensor element, it is necessary to connect this with corresponding connection elements or connecting cables. For this purpose, it is provided in a further constructive embodiment of the invention that in a wall of the housing element at least one opening for carrying out an electrical contacting of the sensor element is formed, wherein the at least one opening is formed sealed. In particular, in connection with a welded joint between the housing element and the injector, which is formed under vacuum, the particular advantage is achieved in that a directed in the direction of the sensor element force is generated, which can be used in addition to contacting.

In a further development of the last-mentioned concept of the invention it can be provided that at least one of the electrical contact of the sensor element serving, elastically arranged contact element is provided within the housing, which is in electrical operative connection with the sensor element, in particular with the adhesive side of the opposite side of the sensor element connected , By the at least one elastically arranged contact element while a steady contact of the contact element is made possible on the sensor element, even if this is relatively strongly deflected in the deformation region at a pressure increase, whereby the distance between the sensor element and the breakthrough is reduced, for example.

In particular, it is provided that the sensor element is designed as a piezoelectric element. A design of the sensor element as a piezoelectric element has the advantage that such piezoelectric elements can be produced with relatively low costs and are very well suited for the detection of the deformations of the deformation region in question with respect to the resolution or measurement accuracy and sampling rate.

Particularly preferred is the arrangement of the deformation region in the region of the supply bore or a branch arranged in operative connection with the supply bore. This has the advantage that the connection point between the deformation region and the sensor element can be arranged in a region relatively distant from the combustion chamber in which lower temperatures prevail, in particular during operation of the internal combustion engine than in a region of the injector housing which is close to the combustion chamber. As a result, in particular, the connection between the addressed components thermally relatively little claimed. When using a branch beyond the particular advantage is achieved that despite the combustion chamber distant arrangement of the sensor element can be arranged at almost any location in the circumferential direction of the injector.

In addition, a structural design of the deformation region in the region of a blind-hole-shaped depression or a flattening of the injector housing is preferred. Both variants can manufacture particularly simple and accurate manufacture and also allow the formation of a flat surface for mounting the sensor element by means of the adhesive connection in a relatively simple manner.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawing.

This shows in:

1 a greatly simplified, partially sectioned side view of a fuel injector according to the invention with a measuring device for at least indirectly detecting the fuel pressure in the fuel injector and

2 a longitudinal section in the connecting region between the measuring device and the injector in an enlarged view.

The same elements or elements with the same function are provided in the figures with the same reference numerals.

The Indian 1 highly simplified illustrated fuel injector 10 is designed as a so-called common rail injector, and serves to inject fuel into the combustion chamber, not shown, of an internal combustion engine, in particular a self-igniting internal combustion engine.

The fuel injector 10 has a substantially consisting of metal, possibly multi-part designed injector 11 in, in which on the combustion chamber of the internal combustion engine side facing at least one, preferably a plurality of injection openings 12 are arranged for injecting the fuel. Inside the injector housing 11 This makes a high pressure room 15 out, in which a nozzle needle serving as an injection member 16 in the direction of the double arrow 17 is arranged to be movable. In the illustrated, lowered position of the nozzle needle 16 This forms together with the inner wall of the high-pressure chamber 15 or of the injector housing 11 made a sealing seat so that the injection openings 12 at least indirectly closed, such that the injection of fuel from the high-pressure chamber 15 is avoided in the combustion chamber of the internal combustion engine. In the other, not shown, lifted from the sealing seat position of the nozzle needle 16 this gives the injection openings 12 for injecting the fuel into the combustion chamber of the internal combustion engine free. The movement of the nozzle needle 16 , in particular for releasing the injection openings 12 , takes place in a manner known per se by means of an actuator, not shown, via a voltage supply line 18 can be controlled by a control device of the internal combustion engine. The actuator may in particular be a magnetic actuator or else a piezoactuator.

The supply of the high pressure room 15 with fuel under high pressure (system pressure) via one within the injector housing 11 arranged or in components of the fuel injector 10 trained supply hole 19 , in particular eccentric to the longitudinal axis 21 of the injector housing 11 in an edge region of the fuel injector 10 , at least substantially parallel to the longitudinal axis 21 , runs. The supply hole 19 is also via a fuel connection, not shown, with a fuel line 22 connected, which in turn with a fuel storage 25 (Rail) is coupled.

In one of the injection ports 12 or the combustion chamber axially relatively far-spaced portion of the injector 11 is in its outer wall 23 an example of a blind hole-shaped depression 24 designed so that the wall thickness of the injector housing 11 in the area of the depression 24 is reduced. In addition, it is mentioned that instead of a blind hole-shaped depression 24 the injector housing 11 may also have a flattening, in whose area the wall thickness of the injector 11 is reduced.

The level educated reason 26 the depression 24 forms part of a deformation area 27 out. On the well 24 opposite side of the injector 11 is the injector housing 11 exemplary in operative connection with a branch 28 arranged, in turn, in the supply hole 19 empties. As a result, the acts in the supply hole 19 instantaneous prevailing fuel pressure also in the injector housing 11 on the well 24 opposite side. Thereby, that the wall thickness of the injector housing 11 in the area of the depression 24 is reduced, the wall section acts 29 of the injector housing 11 on the well 24 facing side as deformation area 27 in the manner of an elastically deformable membrane, wherein the deformation, which forms as a curvature, the greater, the higher the instantaneous fuel pressure in the supply bore 19 or the branch 28 is.

For detecting the time profile of the fuel pressure in the branch 28 or in the supply bore 19 and thus also in the high pressure room 15 , which indicates the instantaneous position of the nozzle needle 16 for controlling the nozzle needle 16 is used, the fuel injector points 10 a measuring device 30 on. The measuring device 30 includes a piezoelectric element 31 trained sensor element 32 ,

The piezo element 31 is with the deformation area 27 via a cohesive connection in the form of an adhesive bond 34 connected. The adhesive connection 34 is over a subarea of the area of the ground 26 the depression 24 formed such that between the adhesive bond 34 and one the depression 24 limiting peripheral wall 35 a radially encircling, adhesive-free area 36 is trained. The particular a round cross-section having piezoelectric element 31 or the measuring device 30 is by means of a pot-shaped or cup-shaped housing 40 protected with a preferably round cross-section against external environmental influences or arranged media-tight. For this purpose, the housing 40 on the reason 26 the depression 24 facing side by way of example a flange-like peripheral edge region 41 on that with the reason 26 the depression 24 in the adhesive-free area 36 connected is. Particularly preferred for connecting the housing 40 with the injector housing 11 or the reason 26 the depression 24 is the formation of a welded joint, in particular a laser welding joint, such that a completely circumferential laser weld 42 is produced. The formation of the weld or the laser weld 42 takes place according to the invention in an inert atmosphere, or under vacuum, so that in the interior 44 of the housing 40 , ie in particular in the area between the housing 40 and the adhesive bond 34 either an inert gas, or vacuum is formed.

Furthermore, the particular housing made of metal 40 in an approximately parallel to the surface of the sensor element 32 arranged wall 45 two breakthroughs 46 . 47 on, through the either arranged sealed electrical connection cables 48 . 49 are guided, with the sensor element 32 or the piezo element 31 are connected, or two connector elements on the the piezoelectric element 31 facing Side, ie inside the interior 45 of the housing 40 , with elastically formed contact elements 53 . 54 , For example, in the form of compression springs connected. The contact elements 53 . 54 are electrically conductive on the surface of the piezoelectric element 31 on, in particular in the region of arranged there electrodes of the piezoelectric element 31 (Not shown) to that of the piezoelectric element 31 at a deformation generated voltages across the connecting cables 48 . 49 to supply a control or evaluation unit, not shown.

When operating the fuel injector 10 deforms the deformation area 27 depending on the in the supply hole 19 prevailing fuel pressure elastic to the outside. This deformation is transmitted via the adhesive bond 34 on the piezo element 31 and generates there in dependence of the deformation or the tensile stresses electrical voltages that can be used by means of a suitable evaluation circuit, at least indirectly to a position of the nozzle needle 16 in the injector housing 11 close.

The fuel injector described so far 10 can be modified or modified in many ways, without departing from the spirit, so in particular the shape or structure of the piezoelectric element 31 differ from the illustrated embodiments.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102014209330 A1 [0002]

Claims (10)

Fuel injector ( 10 ), in particular common-rail injector, with an injector housing ( 11 ), in which a high pressure room ( 15 ) is formed, which via a in Injektorgehäuse ( 11 ) arranged supply bore ( 19 ) is supplied with pressurized fuel, with at least one at least indirectly with the high-pressure chamber ( 15 ), in the injector housing ( 11 ) formed injection port ( 12 ) for injecting fuel into the combustion chamber of an internal combustion engine, with one of the at least one injection port ( 12 ) releasing or occluding injection member ( 16 ), and with a measuring device ( 30 ) for the at least indirect detection of the pressure in the high-pressure chamber ( 15 ) or the supply bore ( 19 ), the measuring device ( 30 ) is adapted to an elastic deformation of at least indirectly with the supply bore ( 19 ) or the high pressure room ( 15 ) operatively connected deformation region ( 27 ), and the measuring device ( 30 ) a sensor element ( 32 ), which coincides with the surface of the deformation region ( 27 ) via an adhesive bond ( 34 ), characterized in that at least the region of the adhesive bond ( 34 ) between the deformation region ( 27 ) and the sensor element ( 32 ) of a housing element ( 40 ) is enclosed, at least the area of the adhesive bond ( 34 ) against the outside environment media tight seals. Fuel injector according to claim 1, characterized in that the housing element ( 40 ) in the area between the housing element ( 40 ) and the adhesive bond ( 34 ) is filled with an inert gas. Fuel injector according to claim 1, characterized in that the housing element ( 40 ) in the area between the housing element ( 40 ) and the adhesive bond ( 34 ) is evacuated. Fuel injector according to one of claims 1 to 3, characterized in that the housing element ( 40 ) is cup-shaped and the measuring device ( 30 ) completely, with the exception of the area of the deformation area ( 27 ) surrounds. Fuel injector according to one of claims 1 to 4, characterized in that the housing element ( 40 ) a flange-like area ( 41 ), which by means of a welding or adhesive bond, preferably by means of a laser weld ( 42 ), with the injector housing ( 11 ) is tightly connected. Fuel injector according to one of claims 1 to 5, characterized in that in a wall ( 45 ) of the housing element ( 40 ) at least one breakthrough ( 46 . 47 ) for carrying out an electrical contacting of the sensor element ( 32 ), and in that the region of the at least one breakthrough ( 46 . 47 ) is formed sealed. Fuel injector according to claim 6, characterized in that inside the housing ( 40 ) at least one of the electrical contacting of the sensor element ( 32 ) serving, elastically arranged contact element ( 53 . 54 ) is provided which in electrical operative connection with the sensor element ( 32 ), in particular with the adhesive connection ( 34 ) opposite side of the sensor element ( 32 ), connected is. Fuel injector according to one of claims 1 to 7, characterized in that the sensor element ( 32 ) as a piezo element ( 31 ) is trained. Fuel injector according to one of claims 1 to 8, characterized in that the deformation region ( 27 ) in the region of a blind hole-shaped depression ( 24 ) or a flattening of the injector housing ( 11 ) is arranged. Fuel injector according to one of claims 1 to 9, characterized in that the deformation region ( 27 ) in the area of the supply bore ( 19 ) or one with the supply bore ( 19 ) operatively connected branch ( 28 ) is arranged.

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