DE102013210841A1 - Fuel injector and fuel injection system with a fuel injector - Google Patents

Abstract

The invention relates to a fuel injector (10) with a fuel inlet (14), an injection valve member (17) for dispensing fuel into the combustion chamber of an internal combustion engine, the injection valve (17) being connected to the fuel inlet (14) via a flow path, and with a fuel return (15). According to the invention, a flow measuring device (30) for the fuel flowing in the direction of the injection valve member (17) is arranged in the flow path.

Description

State of the art

The invention relates to a fuel injector according to the preamble of claim 1. Furthermore, the invention relates to a fuel injection system with at least one fuel injector according to the invention.

Such a fuel injector is already known from the prior art and is used in self-igniting or spark-ignited internal combustion engines for injecting fuel into the combustion chamber of an internal combustion engine. For this purpose, the fuel injector has an injection valve member, usually in the form of a nozzle needle, which can be actuated electromagnetically, for example. For this purpose, the fuel injector is coupled to a control device which controls the solenoid in the fuel injector accordingly, so that after lifting the injection valve member or the nozzle needle from a sealing seat under pressure fuel can be injected via at least one injection port into the combustion chamber of the internal combustion engine. The control unit calculates the required parameters (opening time and lift) of the injection valve member and thus a desired injection quantity, for example, based on the driver's desired load and environmental conditions, such as temperature and other parameters. On the one hand, to ensure that sufficient fuel is always available for injection into the combustion chamber and, on the other hand, that temperature-sensitive components of the fuel injector can be cooled down, such known fuel injectors are designed such that they are supplied with more fuel than required for injection into the combustion chamber becomes. The differential amount of fuel is fed back into a fuel return of the fuel injection system via a fuel return port.

Considered over the life of a motor vehicle, the hydraulic or mechanical components of a fuel injection system, and thus also the components of the fuel injector are subject to wear. In addition, due to the manufacturing tolerances, even when the components are new, there is a certain degree of variation in the accuracy of the components, which i.a. also leads to a certain amount of drift between the individual fuel injectors of a fuel system, usual. In order to reduce these effects, which lead to a worse fuel efficiency in the fuel injection system over the life of the motor vehicle, it is already known to produce the hydraulic or mechanical components of the fuel injection system or the fuel injector with the highest possible quality and accuracy, which is relatively expensive is. Moreover, it is possible by a robust, i. conservative interpretation of the components to achieve a low sensitivity to the mentioned (wear) phenomena. Such a conservative design may also be advantageous, for example, in the presence of deposits or the like, which leads to a reduction in the injection quantity.

Finally, it is known to have a drift correction by the control unit take place by measuring engine-specific variables and a defined behavior connected thereto. So there is already a volume control, which operates in dependence on the detected by cylinder pressure sensors pressures in the combustion chambers.

To achieve the highest possible efficiency of the fuel injection system, it is desirable on the one hand to keep the above-mentioned amount of reflux in the fuel return as low as possible, so that the feed pump of the fuel injection system can be operated with the least possible expenditure of energy, and recognize the other possible signs of wear on the individual components can, if necessary, by increasing the affected components to increase the efficiency again. From the DE 10 2005 032 636 A1 It is therefore already known to the Applicant, by means of an ultrasonic flow sensor, which is arranged in the return system of the fuel injection system, to be able to assess the functionality of the fuel injection system. Although such a system allows fundamental conclusions about the efficiency of the fuel injection system, a limitation which component possibly leads to deterioration in efficiency of the fuel injection system over time due to wear or the like is not possible with the known system.

Disclosure of the invention

Based on the illustrated prior art, the present invention seeks to further develop a fuel injector according to the preamble of claim 1 such that considered in particular over the life of the fuel injector statements regarding its performance are possible. In particular, it should be possible to detect a set drift (deviation between a desired injection quantity and an actual injection quantity) over the service life, which may be e.g. by wear on individual components of the fuel injector, or e.g. can lead to a reduction as well as an increase in the actual injection quantity compared to the target injection quantity due to pollution effects.

This object is achieved in a fuel injector with the features of claim 1, characterized in that in the flow path to at least one injection port, a flow measuring device is arranged for the flowing fuel. In other words, this means that the actual flow rate of the fuel is detected in the direction of the at least one injection opening and thus the actual injection quantity actually injected into the combustion chamber of the internal combustion engine. This value can then be supplied, for example, as an input variable to the control unit of the fuel injection system, which can calculate a corresponding quantity deviation from a comparison of the actual injection quantity with the desired injection quantity. It is essential that such a fuel injector can basically be used both in self-igniting internal combustion engines (diesel engines) and in spark-ignited internal combustion engines (gasoline engines).

Advantageous developments of the fuel injector according to the invention are listed in the subclaims.

It is very particularly preferred if the flow measuring device is arranged in the region of an inlet throttle in the flow path. Such an installation location has the advantage that in the area of the inlet throttle the influence of the (component) tolerances, compared to other components, is the lowest, and that, moreover, the flow velocity in the flow case is highest, whereby a high signal quality can be achieved.

It is very particularly preferred if the flow measuring device is at least indirectly designed to determine the mass flow rate of the flowing fuel. As a result, temperature and pressure influences, which lead to different volume flows per unit time, can be equalized. As a result, in contrast to flow measuring devices which detect volume flows, it is not necessary to carry out consideration of pressures and temperatures that would otherwise be achieved by means of suitable sensors.

In a particularly preferred embodiment of the flow measuring device, this is designed as a thermal flow measuring device. Such a thermal flow measuring device can be realized in terms of device technology with relatively little effort and, moreover, operates with sufficient accuracy relatively reliably.

In a concrete embodiment of the flow measuring device is proposed that it has at least two viewed in the flow direction of the fuel spaced-apart thermal sensing elements and arranged between the sensing elements heating element as part of a heater which is adapted to increase the fuel temperature of the flowing fuel. The measuring principle thus operates on the basis of the temperature difference of the flowing fuel detected by the two measuring elements, it being possible to infer the energy supplied to the fuel via the heating device to the mass flow rate of the flowing fuel.

To simplify the measurement or to increase the measurement accuracy, it may also be provided that the inlet throttle is designed as a bypass in the flow path. This means that not all of the fuel flowing in the direction of the injection valve member is considered in the measurement or considered in terms of its mass, but only a subset, wherein the subset of the known cross sections in the inlet throttle and the remaining flow cross sections can calculate the entire flow cross section.

In a constructive embodiment of the heating element, this is designed such that it surrounds the flow path in a section at least indirectly peripherally and is preferably designed as a heating plate with a passage for forming or enclosing the flow path. Such a heating element has the particular advantage that it does not affect the flow cross-section of the fuel.

The invention also includes a fuel injection system having at least one fuel injector according to the invention, wherein a control device for controlling the at least one fuel injector is provided, such that the fuel injector emits a desired injection quantity into the combustion chamber of the internal combustion engine via its injection valve member. According to the invention, it is provided that the control device is designed to adapt the actuation of the fuel injector, taking into account the actual injection quantity detected by the flow measuring device. In other words, this means that on the basis of the difference between the detected actual injection quantity and the setpoint injection quantity predetermined by the control unit in the event that, for example due to increased wear, the actual injection quantity is greater than the desired injection quantity, the control device the relevant fuel injector controls such that it has, for example, a shorter injection time to adjust the actual injection quantity to the desired injection quantity. In the case that the actual injection quantity is smaller than the target injection quantity, which occurs, for example, when due to coking or linings of the flow cross-section is reduced in the direction of the injection valve member, an adaptation takes place such that, for example, the injection time is extended.

It is very particularly preferred if all fuel injectors have a flow measuring device in the case of a plurality of fuel injectors. Such a fuel injection system has the advantage that overall it has an optimized efficiency with regard to the amount of fuel injected into the combustion chambers.

Alternatively, however, it can also be provided that in the case of several fuel injectors, only a part of the fuel injectors has a flow measuring device, and that the control device adapts the nominal injection quantity of those fuel injectors which have no flow measuring device, taking into account those fuel injectors which have a flow measuring device. Such a fuel injection system has the advantage that, assuming the same behavior or the same effects on the individual fuel injectors, a relatively high degree of efficiency can also be achieved in spite of the relatively low complexity of the apparatus.

A further preferred embodiment of the fuel injection system provides that the control device is designed to communicate via an interface with a diagnostic system and the stored data regarding the at least one flow measuring device can be supplied to the diagnostic system. Such a fuel injection system has the advantage that fuel injectors affected by a deviation can be identified very easily, for example in the context of workshop visits, on the basis of the data transmitted.

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 portion of a fuel injection system using a fuel injector according to the invention in a simplified representation,

2 a section in the region of a fuel supply to an injection valve member of the fuel injector according to 1 to explain the operation of the measuring principle of a flow measuring device and

3 a section in the region of an inlet throttle of the fuel injector according to 1 with a flow measuring device.

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

In the 1 is a subsection of a fuel injection system 100 shown, which serves for injecting fuel into at least one combustion chamber of an internal combustion engine, not shown. The internal combustion engine may be a self-igniting internal combustion engine (diesel engine) or else a spark-ignited internal combustion engine (gasoline engine). In addition, such an internal combustion engine has at least one combustion chamber, but in practice has a plurality of combustion chambers, each of which has a fuel injector according to the invention 10 assigned. For the sake of simplicity, in the 1 but only a single fuel injector 10 shown.

Such, from the prior art per se known fuel injector 10 points in a housing 11 a not shown in detail injection valve member 17 , usually in the form of a nozzle needle, which lifts for injecting the fuel under (high) pressure into the combustion chamber of a sealing seat, not shown, and thereby the fuel via at least one injection port 19 for example in the form of in the 1 illustrated fuel jets 12 injected into the combustion chamber.

The fuel injection system 100 has, in a manner also known per se, a fuel supply system comprising, for example, a high-pressure pump and a fuel reservoir in the form of a rail, which via a fuel supply line 13 with the fuel injector 10 connected is. The fuel supply line 13 flows into a fuel feed 14 in the area of the housing 11 , Laterally next to the fuel inlet 14 shows the case 11 in addition, a fuel return 15 on that with a return line 16 coupled via which the difference amount from the via the fuel supply line 13 the fuel injector 10 conveyed and via the fuel injector 10 is fed back into the combustion chamber amount of fuel in the fuel return system.

The actuation of the injection valve member 17 For example, electromagnetically by means of a magnetic coil, in operative connection with the injection valve member 17 is arranged. Of course, other types of actuation of the injection valve member 17 , For example, piezo-controlled injection valve members 17 or the like. For controlling the injection valve member 17 or the fuel injector 10 this is via an electrical connection cable 18 with one as a control unit 20 trained control device of the fuel injection system 100 connected. About the connection line 18 finds the electrical control and thus the activation of the injection valve member 17 of the fuel injector 10 instead, leaving the injection valve member 17 for injecting fuel into the combustion chamber lifts off from a sealing seat and the injection opening (s) 19 releases. The control unit 20 calculated by way of example via an input line 21 the control unit 20 supplied data, in particular data from engine sensors and a load request of the driver a desired injection quantity or injection time to achieve a desired injection quantity of fuel. In addition, it may be provided that the control unit 20 via a diagnostic line 22 and an interface not shown in detail 23 with an external diagnostic device 25 can be connected to data from the control unit 20 to be able to read.

According to the invention, it is provided that at least one of the fuel injectors 10 of the fuel injection system 100 a flow meter 30 for that amount of fuel that is above the fuel feed 14 and the injection valve member 17 is injected into the combustion chamber of the internal combustion engine. The flow measuring device 30 is via a connection line 31 with the control unit 20 connected such that the control unit 20 on the basis of the flow measuring device 30 detected values can calculate the actual injection amount of fuel that can be detected by the fuel injector 10 is discharged into the combustion chamber. For this purpose, it is provided that the flow measuring device 30 is designed as a mass flow meter in the region of the flow path of the fuel between the fuel inlet 14 in the case 11 and the injection valve member 17 is arranged. In particular, it is provided that the flow measuring device 30 in the area of one in the 3 exemplified inlet throttle 33 is arranged. It can be an inlet throttle 33 act on which all the fuel, by means of the injection valve member 17 is injected into the combustion chamber, flows, or to an inlet throttle 33 that bypasses the flow path between the fuel inlet 14 and the injection valve member 17 is arranged, such that due to the known geometry or the flow cross-sections of the inlet throttle 33 and the flow path can be closed to the actual injection quantity of the fuel.

The flow measuring device 30 is designed, at least indirectly, the mass of the through the inlet throttle 33 to detect flowing fuel. For this purpose, the flow measuring device 30 as a thermal flow measuring device 30 with two spaced apart in the flow direction thermal measuring elements 35 . 36 educated. In the flow direction between the two measuring elements 35 . 36 is in the case 11 of the fuel injector 10 one with a voltage source 37 connected intermediate plate 38 arranged, the part of a heating device 40 for the fuel is. The heater 40 or the intermediate plate 38 has a passage opening 41 on, which forms an edge boundary of the flow path of the fuel, so that the intermediate plate 38 in the area of the passage opening 41 directly in contact with the flowing fuel. Of course, it can also be provided that the passage opening 41 the intermediate plate 38 is formed such that it surrounds a flow channel or the flow path of the fuel at a distance. The only important thing is that it is through the heater 40 is allowed to transfer an amount of heat to the fuel, such that it is heated.

In the 2 is the measuring principle of the flow measuring device 30 by means of one only at one point in the region of a flow path 42 arranged heating element 43 shown. The fuel flows through the flow path 42 in the direction of the arrows 44 ie in the drawing plane from left to right. One recognizes that by the over the heating element 43 heat transfer to the fuel flow fields 45a to 45d are formed, which are to represent different (increased) temperatures of the fuel, wherein in the region of the flow field 45a the fuel has the highest temperature and in the area of the flow money 45d the least. It can be seen that the temperature of the fuel decreases in its flow direction, so that of the measuring element 36 the temperature is detected in the flow field 45d prevails. However, this temperature is higher than a temperature that is in the range of the measuring element 35 is detected, since in this area upstream the heating element 43 can not heat the fuel.

The of the two measuring elements 35 . 36 detected temperatures are used as input values via the connecting line 31 the control unit 20 supplied, such that the control unit 20 by means of one in the control unit 20 stored algorithm can calculate the actual actual injection quantity. From a comparison between the actual injection quantity and the desired injection quantity, an adaptation of the desired injection quantity can be carried out such that the actual injection quantity corresponds to the desired injection quantity. In addition, the control unit 20 adapted to the time course or the data of the flow measuring device 30 to save these over the diagnostic line 22 for the diagnostic device 25 made available to read.

The fuel injection system described so far 100 or the fuel injector 10 can be modified or modified in many ways without departing from the spirit of the invention. Essential to the invention is only that by means of a suitable device, the actual flow rate of the fuel in a fuel injector 10 is detected, which is discharged via an injection valve member in the combustion chamber of an internal combustion engine.

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 102005032636 A1 [0005]

Claims (11)

Fuel injector ( 10 ) with a fuel feed ( 14 ), an injection valve member ( 17 ) for discharging fuel into the combustion chamber of an internal combustion engine, wherein the injection valve member ( 17 ) at least one injection opening ( 19 ) opens or closes, and preferably with a fuel return ( 15 ), characterized in that in the flow path to at least one injection opening ( 19 ) a flow measuring device ( 30 ) is arranged for the flowing fuel. Fuel injector according to claim 1, characterized in that the flow measuring device ( 30 ) in the region of an inlet throttle ( 33 ) is arranged in the flow path. Fuel injector according to claim 1 or 2, characterized in that the flow measuring device ( 30 ) is at least indirectly designed to determine a mass per unit of time of the fuel flowing in the flow path. Fuel injector according to claim 3, characterized in that the flow measuring device ( 30 ) as a thermal flow measuring device ( 30 ) is trained. Fuel injector according to claim 4, characterized in that the flow measuring device ( 30 ) at least two, in the flow direction of the fuel spaced from each other thermal measuring elements ( 35 . 36 ) and one between the measuring elements ( 35 . 36 ) arranged heating element ( 38 ; 43 ) configured to increase the fuel temperature of the flowing fuel. Fuel injector according to one of claims 2 to 5, characterized in that the inlet throttle ( 33 ) is formed as a bypass in the flow path. Fuel injector according to claim 5 or 6, characterized in that the heating element ( 38 ) surrounds the flow path on a portion circumferentially and preferably as a heating plate with a passage ( 41 ) is designed to form or enclose the flow path. Fuel injection system ( 100 ) comprising at least one fuel injector ( 10 ) according to one of claims 1 to 7 and a control device ( 20 ) for controlling the at least one fuel injector ( 10 ) such that this via its injection valve member ( 17 ) emits a desired injection quantity into the combustion chamber of the internal combustion engine, characterized in that the control device ( 20 ) is adapted to control the at least one fuel injector ( 10 ) taking into account the flow meter ( 30 ) adjusted actual injection quantity. Fuel injection system according to claim 8, characterized in that with several fuel injectors ( 10 ) all fuel injectors ( 10 ) a flow measuring device ( 30 ) exhibit. Fuel injection system according to claim 8, characterized in that with several fuel injectors ( 10 ) only a part of the fuel injectors ( 10 ) a flow measuring device ( 30 ), and that the control device ( 20 ) the desired injection quantity of those fuel injectors ( 10 ), which does not have a flow measuring device ( 30 ) taking into account those fuel injectors ( 10 ), which is a flow measuring device ( 30 ) exhibit. Fuel injection system according to one of claims 8 to 10, characterized in that the control device ( 20 ) is adapted, via an interface ( 23 ) with a diagnostic system ( 25 ) and thereby the stored data with regard to the at least one flow measuring device ( 30 ) the diagnostic system ( 25 ) can be supplied.

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