The present invention relates to a fuel injection device having a needle position determination for the exact determination of a needle position and in particular a high-precision determination of an injected fuel quantity.
Various embodiments of fuel injection devices are known from the related art. In addition to magnetic injectors, piezoelectric multi-layer actuators are also used. In this connection, one advantage of piezoelectric actuators is that they are able to carry out deflections very quickly and precisely while simultaneously exercising great forces. One disadvantage of such piezoelectric actuators is, however, that the property degradation of the ceramic components of the piezoelectric actuator as a function of the number of electrical cycles makes a direct correlation of the applied voltage with the expansion of the piezoelectric actuator impossible. This prevents an exact determination of an actual needle position of a nozzle needle of the fuel injection device (needle lift characteristics) at any point in time of the injection process. Furthermore, the actual nozzle needle position in the nozzle seat is influenced by wear, carbon build-up, etc., which is impossible to detect in conventional fuel injection devices. For that reason, a measurement and coding is performed on each piezoelectric actuator before its installation. With the aid of this information, the particular stroke capability of an individual piezoelectric actuator is ascertained. This makes it possible to calculate a theoretical metering of the injected fuel quantity for each piezoelectric actuator. However, the fact that each individual piezoelectric actuator must be measured results in considerable manufacturing expense. Furthermore, the individual control units for the fuel injection device must also be adapted individually to the piezoelectric actuator. Moreover, the theoretically ascertained value may deviate significantly from later actual needle lift characteristics in the installed condition of the piezoelectric actuator. This results in inaccuracies in the injected fuel quantity. It would therefore be desirable to have a possibility for an exact needle position at each point in time of the injection process and to calculate from it a particular injected fuel quantity.
The fuel injection device according to the present invention has the advantage over the related art that, with the aid of a sensor, it is able to determine an exact position of a nozzle needle (needle lift characteristics) at any point in time. Based on the exact position of the nozzle needle, it is possible to make a precise determination of an injected fuel quantity. According to the present invention, this creates a basis for a further increase in efficiency in the case of internal combustion engines, since an extremely exact determination of an injected fuel quantity is possible, which contrasts significantly from the possibilities previously known from the related art. Another advantage lies in an expanded diagnostic capability of the injector, since mechanical defects such as, for example, jamming, and/or wear caused, for example, by carbon build-up, are detectable. Furthermore, resources in the control unit of the fuel injection device may be saved, and an improved protection against undesirable tuning of the internal combustion engine is possible, since the interposition of a tuning control unit for increasing the power of the internal combustion engine and accordingly changing a setpoint quantity for the injection is made more difficult. According to the present invention, this is achieved in that the fuel injection device includes a force sensor for detecting a force applied by an actuator as well as a control unit. The control unit is connected to the force sensor and designed for determining a position of the needle based on the signals supplied by the force sensor. A precise determination of an injected fuel quantity is made using the position determination. The force sensor is thus used for detecting the actuator force, which in the case of piezoelectric actuators is correlated with an accompanying change of length of the piezoelectric actuator. In the case of magnetic injectors, the force of the magnetic actuator is correlated with the movement of the magnetic actuator. For that reason, the idea according to the present invention may be used in magnetic injectors and in piezoelectric actuators independent of the type of actuator, a use in the case of piezoelectric actuators being particularly practical due to the great possibilities for simplification.
The force sensor is preferably a piezoelectric sensor. The piezoelectric sensor may be designed to be single-layered or multi-layered. Furthermore, the use of a piezoelectric sensor as a force sensor makes it possible to have a low overall height and accordingly a compact design.
It is preferred in particular that the actuator of the fuel injection device is a piezoelectric actuator. In addition to the known advantages of using piezoelectric actuators, this yields the above-mentioned manufacturing advantages, so that it is possible to install the piezoelectric actuators directly without additional measurement and it is not necessary to adapt control units individually to the piezoelectric actuators.
According to a preferred embodiment of the present invention, the force sensor includes a passage opening, a nozzle needle of the fuel injection device being guided through the passage opening. The force sensor is connected to a restoring spring for the actuator and detects a restoring force provided by the restoring spring, the restoring force being designed according to the actuator force. This design of the force sensor makes it possible in particular to keep an overall axial length of the fuel injection device unchanged, since no need exists for an additional component to be provided between the nozzle needle and the actuator in the axial direction.
According to a preferred alternative of the present invention, the force sensor is situated in the force flow between the actuator and the nozzle needle. This does cause the overall axial length to be greater by the thickness of the force sensor;
however, the force sensor is able to absorb an actuator force directly. It is preferred in particular that the force sensor is designed in disk form in order to have as short an axial length as possible.
For a particularly compact design, the force sensor is furthermore preferably in direct contact with the actuator or integrated into it by preferably using an identical piezoceramic material for the actuator and the sensor.
The present invention may be used with all types of fuel injectors; however, it is particularly advantageous in the case of piezoelectric actuators. In the case of piezoelectric actuators in particular, the present invention makes it possible to further reduce the cost of manufacturing significantly and makes possible a more exact metering of the injected fuel quantity, resulting in a novel basis for a further increase in efficiency and accordingly in fuel savings.
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According to the present invention, it is thus possible to determine an exact needle position at any point in time, making it possible to use the duration of the current feed to the piezoelectric actuator for defining an exact injection quantity. This also makes it possible to omit the so-called “actuator coding,” i.e., the individual measurement of each actuator during actuator manufacturing, which results in a significant cost reduction, including in the particular control units.
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Identical or functionally identical parts are denoted using the same reference numerals as in the preceding exemplary embodiment.
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Number | Date | Country | Kind |
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102009047611.3 | Dec 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/065323 | 10/13/2010 | WO | 00 | 8/17/2012 |