EP3032088A1 - Injector - Google Patents

Abstract

The invention relates to an injector with an injector body 1, which has at least one pressurized or deformable by mechanical stresses surface, wherein on the injector body 1, a sensor 16 for detecting a change in the surface is arranged. According to the invention, an injector is specified with at least one sensor 16 for detecting a surface deformation on the injector, wherein the sensor is to be mounted on the injector body 1 such that a reliable function of the injector and the sensor is ensured. This is achieved in that a pressure rod 15 is arranged on the injector body 1 and the sensor 16 is glued to the pressure rod 15. In this case, the pressure rod 15 is arranged between an abutment 12 fastened to the injector body 1 and the injector body 1 in the region of a membrane-shaped wall adjoining the surface, in particular adjacent to a high-pressure line 10.

Description

The invention relates to an injector having an injector body and a nozzle body, wherein the injector has a high-pressure line carrying a fluid and a surface which is pressurized by the fluid or deformable by mechanical stresses, the injector having a sensor for detecting a change, in particular a deformation of the surface ,

State of the art

Such an injector is from the EP 1 042 603 B1 known. This injector is a fuel injector for injecting a fuel, wherein in the injector, a bore for guiding a nozzle orifice controlling a nozzle needle is arranged. The nozzle opening can be supplied via a high pressure line of the fuel. Upon an opening movement or closing movement of the nozzle needle for controlling the fuel sprayed through the nozzle opening, pressure changes which are transmitted to the injector or a surface of the injector, which cause a deformation of the surface and which in turn can be absorbed by a sensor, are triggered in the fuel , The sensor is embedded in an annular recess in the injector and glued for example in the recess.

The invention has for its object to provide an injector with at least one sensor for detecting a change in a surface, in particular a deformation of the surface at the injector, wherein the sensor is to be attached to the injector that a reliable function of the injector and the Sensor is ensured.

Disclosure of the invention

This object is achieved in that a pressure rod is arranged or connected to the injector and that the sensor is arranged on the pressure rod. In this case, a deformation of the surface detected by the sensor may have arisen due to dynamic pressure changes or different pressure changes in the injector. The recorded characteristic profiles of, for example, deformation can be analyzed and evaluated by appropriate evaluation algorithms with a corresponding evaluation device. According to the evaluation results, parameters at the device to which the injector belongs can be changed and optimized. According to the invention, the sensor is not located directly in or on the changing surface of the injector, but can basically be arranged at any position of the pressure rod, which in turn is preferably arranged on the injector in a region of a clearly detectable change or deformation of the surface. Due to the constructive and material engineering design of the push rod a consistent signal quality can be ensured. In addition, no significant intervention in the injector is necessary by this configuration.

The surface is preferably an outer surface of the injector, in particular of the injector body and / or optionally of the nozzle body. This has the advantage that the injector as such does not need to be changed or only to a very limited extent in order to position the pressure rod with the sensor on the injector. Rather, the pressure rod can be attached to the outside with the sensor in a suitable manner to the injector. In principle, it is also possible to install the pressure rod with the sensor in the injector in a suitable manner, for example by the pressure rod is inserted into a corresponding recess in the injector.

In a development of the invention, the sensor is arranged at least approximately in the center of the pressure rod. This is due to the symmetrical arrangement, the preferred embodiment, thereby ensuring a consistent signal quality is ensured.

In a further embodiment of the invention, the pressure rod between the injector and a cooperating with the injector abutment is clamped. The abutment is formed, for example, as a pot-shaped housing and takes in the cup-shaped interior of the push rod with the sensor. The cup-shaped abutment can be attached to the injector, for example by means of a peripheral mounting flange, for example screwed or welded. The connection of the pot-shaped abutment with the component can be designed hermetically sealed depending on the requirement, so that in the cup-shaped recess a constant volume of air is included, which ensures constant measurement conditions and prevents contamination of the measurement setup. However, the trapped volume of air does not necessarily have to be hermetically sealed off from the environment, but serves once to protect the measurement setup against, for example, external mechanical damage and at the same time as a rigid abutment of the pressure rod. The abutment is designed so that it can absorb the resulting deformations of the surface, which can be absorbed by the pressure forces from the pressure oscillations and the resulting compressive stress in the pressure rod over the life of the injector. A conceivable attenuation of the signal due to stiffness losses is to be kept as low as possible, as these can weaken the measurement signal and possibly detune it. Accordingly, suitable material pairings in the structure consisting of the pressure rod and the abutment with respect to the rigidity and the thermal expansion coefficients of the components to be selected and possibly taken into account. A temperature sensor built into the cup-shaped recess can serve as an additional calibration aid for evaluation software.

In a further development of the invention, the pressure rod is at least partially formed with a well-defined geometry, namely in particular cylindrical. The design of the pressure rod or its dimensions, in particular the length of the pressure rod, the diameter of the pressure rod and a central taper of the pressure rod resulting from the size of the male signal, such as amplitude and frequency, which are introduced from the deformed surface in the pressure rod. A regular adjustment of the "resting pressure level" is useful for checking the functionality of the system, for example, temperature influences capture and correct. From a functional point of view, however, this is not absolutely necessary since the measurement principle is based on a simple pressure change and not the absolute pressure change. In an advantageous embodiment, the pressure rod on a central and cylindrical taper, which is bordered by opposite conically widening end portions. In this case, the at least one sensor is arranged in the region of the taper. This embodiment has proven to be particularly suitable for reliable signal recording.

In a further development of the invention, four sensors are arranged distributed on the circumference of the push rod. This is the optimal design, but in principle only a single sensor can be arranged on the pressure rod. The at least one pressure sensor is preferably glued to the pressure measuring rod in a suitable manner. The corresponding attachment may include a mechanical bias applied to the sensor. In addition, the attachment may include a spring and / or damping element. It is important that the contact surfaces between the pressure rod and the sensor at any time have contact with each other and not stand out even during a dynamic pressure change. The assignment of the components to each other should not change during operation, with a change would be given for example by a rotation of the push rod. For example, a constructive fixation in the required position, a stable signal over the life of the injector can be detected and evaluated.

In a development of the invention, the sensor is a strain gauge sensor. This is the preferred embodiment, with corresponding strain gauge sensors being available in a variety of designs. In an alternative embodiment, the sensor is a MEMS pressure-strain sensor (MEMS = micro-electro-mechanical system).

Furthermore, the pressure rod is separated from a fluid-carrying region, in particular the high-pressure line, of the injector. The fluid-carrying region or the high-pressure line causes or causes the aforementioned pressurization. In this case, then acts the wall between the fluid-conducting portion of the injector and the pressure rod as a membrane, the one of transmits a change in pressure in the fluid caused deformation of the surface on the pressure rod.

Finally, the injector is preferably a fuel injector as part of a fuel injection system or a reducing agent injector of an exhaust aftertreatment system. The injector thus serves to inject a fuel or a reducing agent. Such an injector is installed on an internal combustion engine and by means of, for example, the fuel injector fuel is injected into an associated combustion chamber of the internal combustion engine. Due to the characteristic curves mentioned above and recorded, it is then possible, for example, to modify and optimize an activation of the fuel injector or of a fuel pump.

Further advantageous embodiments of the invention are described in the drawings, in which an illustrated in the figures embodiment of the invention is described in detail.

Figur 1

eine Ansicht eines Injektors, mit einem teilweisen Längsschnitt durch den Injektor mit einer Darstellung der Positionierung eines topfförmigen Widerlagers, das einen Druckstab mit einem Sensor aufnimmt und

Figur 2

einen Querschnitt durch ein topfförmiges Widerlager mit darin angeordnetem Druckstab, an dem mehrere Sensoren befestigt sind.

Show it:

FIG. 1

a view of an injector, with a partial longitudinal section through the injector with a representation of the positioning of a cup-shaped abutment which receives a push rod with a sensor and

FIG. 2

a cross section through a cup-shaped abutment with pressure rod arranged therein, are attached to the plurality of sensors.

The in FIG. 1 injector shown is preferably a fuel injector, is injected with the pressurized fuel, which is taken, for example, a high-pressure accumulator of a common-rail injection system in a combustion chamber of an internal combustion engine on which the injection system is installed. In principle, however, the injector can also be any other injector. Arranged on the injector is a pot-shaped abutment 12, which is explained below, which has a pressure rod 15 with a sensor 16 for detecting a change in a pressurized or mechanical stress deformable surface of the injector absorbs. The fuel is in particular diesel fuel and the internal combustion engine is preferably a self-igniting internal combustion engine. The injector has an injector body 1, which is screwed to a nozzle body 2 by means of a union nut 3. In the injector body 1 and the nozzle body 2, a bore 4, 4a is incorporated, in which a nozzle needle 5 and a cooperating with the nozzle needle 5 actuating rod 6 are arranged axially movable. In a closed position of the nozzle needle 5, a nozzle needle tip 7 of the nozzle needle 5 cooperates with a nozzle body seat 8 and closes at least one nozzle opening 9, which is arranged in the nozzle body 2 below the nozzle body seat 8.

In an open position of the nozzle needle 5, the nozzle needle tip 7 is in a spaced position relative to the nozzle body seat 8 and then releases a flow connection through a high-pressure bore 10, 10a embedded in the injector body 1 and the nozzle body 2 to the at least one nozzle opening 9. In this position, for example, fuel introduced from the high-pressure accumulator into the high-pressure line 10, 10a is injected through the at least one nozzle opening 9 into the associated combustion chamber of the internal combustion engine.

The nozzle needle 5 is adjusted, for example via the actuating rod 6 of a built-in injector body 1 actuator directly or indirectly in the open position and the closed position, to provide an electrical connection between the actuator and a control unit, a control line is provided by an actuator cable bore 11th is guided through the injector body 1. Alternatively, the nozzle needle 5 is adjusted via a hydraulic control system. Below the actuator bore 11, a cup-shaped abutment 12 is attached to the injector body 1. For example, the pot-shaped abutment 12 has a peripheral fastening edge 13, in the region of which a circumferential weld seam 14 connects the cup-shaped abutment 12 tightly with the injector body 1 and absorbs and transmits the required abutment forces. In the cup-shaped abutment 12 is an in FIG. 2 arranged closer to the pressure rod 15, on which distributed circumferentially sensors 16 are mounted to accommodate changes. The changes are, in particular, a surface deformation of the injector body 1 in the region of the high-pressure line 10. This region of the injector body constitutes the surface described above. To accommodate the change, the cup-shaped abutment 12 is arranged on the injector body 1 in such a way that the pressure rod 15 is arranged exactly perpendicular in the region of the high-pressure line 10 or oriented perpendicular to it.

The in FIG. 2 shown cross section through a portion of the injector body 1 and the cup-shaped abutment 10 welded thereto shows in detail the structure of the measuring device. Trained as a housing cup-shaped abutment 12 is connected in the region of circumferential mounting edge 13 by means of the weld 14 with the injector 1. The pot-shaped abutment 12 may have stiffening structures in the region of the pot periphery and is particularly stiff in the region of the pot bottom 17, a stiffening attachment plate 19 being arranged in the interior 18 formed by the cup-shaped abutment 12. Between the Anbindeplatte 19 and the opposite injector body 1 and the Anbindeplatte 19 opposite surface of the injector body 1, the push rod 15 is clamped, for example, facing each other conical relationship conical end portions 27 having a defined geometric taper 26 in its central region, for example in the form of a Border cylinder section. The conical or conical end portions 27 are used in particular to ensure "smooth transitions", while the region of the taper 26 can be adjusted in its configuration to the load cases in shape and cross-section to an optimum. In the region of the cylindrically shaped taper 26, four sensors 16 are arranged on the pressure rod 15, distributed over the circumference thereof, in particular adhesively bonded, the sensors 16 preferably being designed as strain gauge sensors or as MEMS pressure-strain sensors. Each of the sensors 16 is connected to contacts 21a, 21b via cabling 20a, 20b. An electrical connection to an evaluation unit is made via lines connected to the contacts 21a, 21b. Each of the four sensors 16 may have their own contacts 21a, 21b or all four sensors 16 are connected to common contacts 21a, 21b.

As has already been stated above, the pressure rod 15 is aligned perpendicular to the deforming surface, wherein the high pressure line 10 is followed by a high-pressure area 22 of the injector body 1 or the high-pressure area 22 is the high pressure line 10. The injector 1 In particular in the region of the high-pressure region 22, a membrane-forming wall 23 forming the surface can form, which can deform within the dashed region 24 (shown in a covered manner) in the direction of the pressure rod 15. In addition to the high-pressure region 22, the injector body 1 has a wall region 25 with reduced stresses. The pressure changes occurring in the high-pressure line 10, in particular during an opening movement of the closing movement of the nozzle needle 5, cause the movements of the membrane-shaped wall 23, which cause a compression and subsequent elongation of the pressure rod 15 and thus of the sensors 16. The changes thus recorded with the measuring device are evaluated by the evaluation device.

Claims (11)

An injector having an injector body (1) and a nozzle body (2), wherein the injector has a high-pressure line (10.10a) carrying a fluid and a surface which is pressurized by the fluid or deformable by mechanical stresses, and wherein at the injector a sensor (16 ) is arranged for detecting a deformation of the surface,
characterized in that a pressure rod (15) is arranged on the injector in the region of the deformable surface, and that the sensor (16) is arranged on the pressure rod (15). Injector according to claim 1,
characterized in that the sensor (16) is arranged at least approximately in the middle of the pressure rod (15). Injector according to one of the preceding claims,
characterized in that the pressure rod (15) between the injector and a cooperating with the injector abutment (12) is clamped. Injector according to one of the preceding claims,
characterized in that the pressure rod (15) is at least partially cylindrical. Injector according to one of claims 1 to 4,
characterized in that the pressure rod (15) has a centrally disposed taper (26). Injector according to claim 5,
characterized in that the taper (26) is cylindrical. Injector according to one of claims 4 to 6,
characterized in that the pressure rod (15) has opposite conical end portions (27). Injector according to one of the preceding claims,
characterized in that four sensors (16) are arranged distributed on the circumference of the push rod (15). Injector according to one of the preceding claims,
characterized in that the sensor (16) is a Dehnmessstreifensensor. Injector according to one of the preceding claims,
characterized in that the sensor (16) is a MEMS pressure-strain sensor. Injector according to one of the preceding claims,
characterized in that the sensor (16) is glued to the push rod (15).

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