EP3521598A1 - Method for determining the position of an actuator and actuator module - Google Patents

Abstract

A method for determining the position of an actuator (24) of an internal combustion engine (10), in particular a butterfly valve, a swirl flap or a valve, which is actuated by a DC motor (26), comprises the following steps: a) measuring the current profile (38) b) detecting commutation artifacts (42) in the measured current profile (38), c) determining the number of detected commutation artifacts (42) by a control unit (30), d) determining the position of the actuator ( 24) based on the number of commutation artifacts (42) by the control unit (30). An actuator assembly is also shown.

Description

The invention relates to a method for determining the position of an actuator of an internal combustion engine, in particular a control valve, a swirl flap or a valve. The invention also relates to an actuator assembly for an internal combustion engine having an actuator, a DC motor and a control unit.

In modern internal combustion engines, a large number of controlled or controlled actuators are used which, for optimum operation of the internal combustion engine, have to be brought into specific positions between two end positions. Such actuators are, for example, flaps or valves.

It is therefore necessary to detect the position of the actuator, wherein for detecting the position usually special position sensors, such as Hall sensors, are provided on the actuator. These position sensors result in increased costs of the actuator, both through material and assembly costs. In addition, the position sensors restrict the temperature range and the vibration resistance of the actuator.

It is therefore an object of the invention to provide a method for determining the position of an actuator and an actuator assembly, which allow a determination of the position of the actuator in a cost effective and at the same time robust manner.

1. a) Messen des Stromverlaufs des dem Gleichstrommotor zugeführten Stromes,
2. b) Erkennen von Kommutierungsartefakten im gemessenen Stromverlauf,
3. c) Bestimmen der Anzahl an erkannten Kommutierungsartefakten durch eine Steuereinheit,
4. d) Bestimmen der Position des Stellglieds anhand der Anzahl an Kommutierungsartefakten durch die Steuereinheit.

The object is achieved by a method for determining the position of an actuator of an internal combustion engine, in particular a control flap, a swirl flap or a valve which is actuated by a DC motor, with the following steps:

1. a) measuring the current profile of the current supplied to the DC motor,
2. b) detecting commutation artifacts in the measured current profile,
3. c) determining the number of detected commutation artefacts by a control unit,
4. d) determining the position of the actuator based on the number of Kommutierungsartefakten by the control unit.

A current measurement is usually carried out for DC motors or their drivers for other purposes or can be realized without consuming and sensitive sensors, such as a shunt.

The invention is based on the idea that a determination of the position with sufficient accuracy from the number of commutations is possible. Although the accuracy of position determination using the commutation artifact is less than that of special position sensors, it has been recognized that the accuracy achievable with commutation artifacts is sufficient for many applications in the internal combustion engine.

In the context of this invention, commutation artifacts are understood to mean excursions in the current profile that are generated by the mechanical commutation of the DC motor. These commutation artefacts are also called "ripples".

Preferably, the control unit determines the direction of rotation of the DC motor, in particular based on the polarity of the current, and uses the direction of rotation to determine the position of the actuator zoom.

For example, the number of commutation artefacts is increased by one with rotation of the DC motor in the positive direction of rotation with each additional detected commutation artifact, and decreased by one with each further detected commutation artifact when rotated in the negative direction.

To reduce the influence of measurement errors, the controller may determine the position of the actuator using the number of commutation artifacts relative to an end position of the actuator.

For example, the control unit detects when the actuator has reached the end position, and then determines regardless of the number of Commutation artifacts the position of the actuator as the end position. When an end position is reached, the control unit interprets the current position as the end position. Thus, every time the actuator has reached one of its end positions, a calibration of the measuring method takes place. In addition, the number of commutation artifacts of the completed revolutions and / or the angle of rotation can be set to zero when an end position is reached.

In one embodiment, the control unit determines the number of revolutions completed by the DC motor and / or the completed rotation angle of the DC motor based on the number of Kommutierungsartefakte and uses the number of completed by the DC motor revolutions and / or the completed rotation angle for determining the position of the actuator. In this way, a simple and reliable determination of the position is possible.

In one embodiment, a transmission between the DC motor and the actuator is provided, wherein in the control unit information about the gear ratio are stored, wherein the control unit, the position of the actuator in dependence of the ratio of the transmission and the completed revolutions and / or the completed rotation angle of the DC motor. As a result, the position of the actuator can be determined even when using transmissions.

For example, the transmission is self-locking to avoid measurement errors due to unintentional movements of the actuator.

In a further embodiment of the invention, a value table is stored in the control unit, which indicates the position of the actuator as a function of the number of Kommutierungsartefakten, the number of completed rotations, the completed rotation angle and / or the transmission ratio. In this way, the process can be accelerated.

For example, the current profile is measured by the control unit, a driver of the DC motor or a shunt with voltmeter, whereby an accurate determination of the current profile is possible.

Furthermore, the object is achieved by an actuator assembly for an internal combustion engine with an actuator, a DC motor and a Control unit which is adapted to carry out the method according to the invention.

For example, the control unit is part of a driver and / or a H-bridge for the DC motor, whereby the cost can be further reduced. The driver and / or the H-bridge is in particular part of the actuator assembly.

In one embodiment, the actuator is a control flap for a turbocharger unit of the internal combustion engine, a swirl flap for an intake system of the internal combustion engine or a valve, in particular a multi-way valve for an engine cooling circuit of the internal combustion engine. As a result, actuators, in which an exact knowledge of the position would not lead to an improvement of the internal combustion engine can be realized inexpensively.

For example, the butterfly valve is used to switch between two turbochargers of a turbocharger unit and the swirl flap is used to change the twist, with which the fuel or the fuel-air mixture is introduced into the cylinder.

To provide a translation, the actuator assembly may include a gear having a predetermined gear ratio, the gear being, in particular, self-locking.

• Figur 1 einen Verbrennungsmotor mit einer erfindungsgemäßen Stellgliedbaugruppe,
• Figur 2 eine erfindungsgemäße Stellgliedbaugruppe,
• Figur 3 eine Darstellung eines gemessenen Stromverlaufs während der Durchführung des erfindungsgemäßen Verfahrens, und
• Figur 4 eine Vergrößerung eines Ausschnittes aus dem Stromverlauf gemäß Figur 3.

Further features and advantages of the invention will become apparent from the following description and from the accompanying drawings, to which reference is made. In the drawings show:

• FIG. 1 an internal combustion engine with an actuator assembly according to the invention,
• FIG. 2 an actuator assembly according to the invention,
• FIG. 3 a representation of a measured current profile during the implementation of the method according to the invention, and
• FIG. 4 an enlargement of a section of the current flow according to FIG. 3 ,

In FIG. 1 an internal combustion engine 10 with a turbocharger unit 12, for example a bi-turbocharger, an intake system 14, an engine block 16 of an exhaust system 18 and an engine cooling circuit 20 is shown.

In the embodiment shown, the turbocharger unit 12, the intake system 14 and the engine cooling circuit 20 each have at least one actuator assembly 22, each having an actuator 24 (FIG. FIG. 2 ).

The actuator 24 of the actuator assembly 22 of the turbocharger unit 12 is a control valve that can supply the air or exhaust gas flow between two different turbochargers of the turbocharger unit 12.

In the intake system 14, an actuator assembly 22 with four swirl flaps is provided as actuators 24. The swirl flaps can change the inflow direction of a fuel-air mixture into the cylinders of the engine block and thus the swirl that forms in the corresponding cylinder. The four swirl flaps are connected via a rod 21 to the DC motor 26 and operated.

The actuator 24 of the actuator assembly 22 of the engine cooling circuit 20 is a valve, in particular a multi-way valve that controls the flow of coolant into various branches of the engine cooling circuit 20.

Of course, further actuators can be formed as part of an actuator assembly 22 according to the invention. The applications described are merely exemplary.

In FIG. 2 For example, one of the actuator assemblies 22 is shown very schematically.

The actuator assembly 22 has, in addition to the actuator 24, a DC motor 26 and a gear 28 and a control unit 30 and a driver 32. The DC motor 26, more specifically, the output shaft of the DC motor 26 is connected to the actuator 24 for transmitting torque via the gear 28.

The transmission 28 has a known translation and is for example a worm gear.

The gear 28 is in particular self-locking, so that its position can only be changed by the DC motor 26.

The DC motor 26 is connected via two power lines 34 to the driver 32, which can supply power to the DC motor 26. The driver 32 may include an H-bridge 33.

The driver 32 is electrically connected to the control unit 30 so that the control unit 30 can drive the driver 32.

Of course, the control unit 30 may also be integrated in the driver 32.

In FIG. 2 In addition, a shunt 36 is provided together with voltmeter for current measurement through the power lines 34, which are shown together. The voltmeter is electrically connected to the control unit 30.

For actuating the actuator 24, the control unit 30 instructs the driver 32 to energize the DC motor 26, i. H. Supply electricity.

The DC motor 26 converts the electrical energy supplied to it into a torque or a rotation of its output shaft. The torque is translated by the transmission 28 and supplied to the actuator 24, whereby the actuator 24 is actuated.

In the embodiment shown, in this way, for example, the multi-way valve in the engine cooling circuit 20 is opened, the control flap of the turbocharger unit 12 or a swirl flap of the intake system 14 moves.

The actuator 24 can be moved by the DC motor 26 between two end positions. The direction of movement of the actuator 24 depends on the direction of rotation of the DC motor 26. More specifically, the direction of rotation of the actuator 24 depends on the direction of rotation of the output shaft of the DC motor 26. However, for the sake of simplicity, only the DC motor 26 will be discussed below.

Depending on the polarity of the current supplied to the DC motor 26, the DC motor 26 or its output shaft is rotated in a positive or negative rotational direction, whereby the actuator 24 is adjusted in a positive or negative direction.

The path traveled by the actuator 24 is dependent on the number of revolutions of the DC motor 26 and the transmission ratio 28, so that the position of the actuator 24 based on the number of revolutions, which has completed the DC motor 26, and the ratio of the transmission 28 can be determined.

To determine the completed by the DC motor 26 revolutions and thus the position of the actuator 24, the control unit 30 determines the current waveform 38 of the current that was supplied to the DC motor 26 from the driver 32.

The measurement of the current can be carried out by the driver 32 itself, for example, determines the driver 32 anyway the so-called current mirror. The measurement can also take place in the H-bridge 33.

A more accurate measurement of the current can be made by means of the shunt 36, the current measurement then being performed by the control unit 30 itself.

In FIG. 3 a measured current waveform 38 is shown together with the course 40 of the position of the actuator 24.

In the example shown, the actuator 24 is moved from its first end position E ₁ to its second end position E ₂ .

In FIG. 4 an enlargement of a portion of the current waveform 38 is shown. Commutation artifacts 42 in the course of the current 38, which are very short rashes in the course of the current 38, can easily be recognized. These commutation artefacts 42 are also called "ripples".

The commutation artefacts 42 are formed in the commutation of the DC motor 26 in that the direct current supplied to the DC motor 26 is converted by a mechanical inverter into an AC current.

When the alternating current is reversed, short-term fluctuations occur in the supplied direct current, which are characteristic and therefore easy to recognize.

Depending on the design of the DC motor 26, a certain number of commutations per complete revolution of the DC motor 26 takes place, so that a complete number of commutation artefacts 42 is generated per complete revolution of the DC motor 26.

In the simplest case of a DC motor 26, two commutations take place per complete revolution of the DC motor 26, so that each commutation artifact 42 corresponds to half a revolution of the DC motor 26. For explanation, it is assumed below by way of example of such a DC motor with two commutations. Between two Kommutierungsartefakten the DC motor 26 has rotated by 180 °.

The control unit 30 recognizes the commutation artifacts 42 in the measured current profile 38 and counts the number of occurring commutation artifacts 42.

At the same time, the control unit 30 has information about the polarity of the current supplied to the DC motor 26, for example about the sign of the current or through an information of the driver 32.

If the current supplied to the DC motor 26 leads to a rotation of the DC motor or its output shaft in the positive direction of rotation, the control unit 30 increments the number of detected commutation artifacts 42 by one for each detected commutation artifact 42. Similarly, the controller 30 reduces the number of commutation artifacts 42 by one if the current supplied to the DC motor 26 results in rotation in the negative direction of rotation and another commutation artifact 42 has been detected.

From the number of commutation artefacts 42 and the information about the structure of the DC motor 26, the control unit 30 can then close on the rotation angle and the number of completed rotations of the DC motor 26.

In the discussed case, the control unit 30 divides the number of commutation artifacts 42 by two, thereby obtaining the number of fully completed revolutions.

If the number of commutation artefacts 42 is odd, this means that the DC motor 26 also has a rotation angle of over 180 °. If the number of commutation artifacts 42 is even, the rotational angle of the DC motor 26 is less than 180 °.

The number of commutation artefacts 42 and thus the number of completed rotations of the DC motor 26 including the angular position is counted starting from one of the end positions E ₁ and E ₂ .

The control unit 30 can thus determine the path traveled by the actuator 24 from the end position based on the number of completed revolutions of the DC motor and the current angular position of the DC motor 26. For this purpose, the control unit 30 uses the information about the ratio of the transmission 28, which are stored in a memory of the control unit 30.

In addition, information about the type of the actuator 24 is stored in the control unit 30, for example information about the range of motion of the actuator 24th

For example, due to the gear ratio of the transmission 28, a complete revolution of the DC motor 26 corresponds to a rotation of the control flap of the turbocharger unit 12 by 0.5 °. Thus, the control unit 30 may determine that the control damper, ie, the actuator 24, has been rotated 9 degrees when 18 rotations have been completed by the DC motor 26.

In addition, the control unit 30 may have information about the range of motion of the actuator, so the control valve. For example, the range of motion of the control flap 45 °, so that 18 completed revolutions of the DC motor 26 correspond to a 20% open control flap.

If the DC motor 26 is rotated in the opposite direction of rotation, the control unit 30 reduces the number of Kommutierungsartefakte 42 and thus the number of completed revolutions accordingly.

In this way, the position of the actuator 24 relative to one of its end positions without further sensors, such as a position sensor for the actuator 24 can be determined.

The control unit 30 can determine based on data of the driver 32 or the current waveform 38 when the actuator 24 reaches one of its end positions E ₁ , E ₂ . As in FIG. 3 to see the current rises sharply as soon as the end position E ₂ of the actuator 24 is reached. This increase is recognized by the driver 32 or the control unit 30 as reaching the end position E ₂ .

As soon as the control unit 30 determines that the actuator 24 has reached one of its end positions E ₁ , E ₂ , it sets the position determined by it of the actuator 24 to the corresponding end position E ₁ , E ₂ , regardless of whether the number of Commutation artifacts 42 determined position of the actuator 24 matches or not.

It also resets the number of commutation artefacts 42 and also the completed rotations of the DC motor 26 to zero, thereby calibrating the positioning procedure.

Before resetting the number of commutation artefacts 42 or when reaching the end position E ₁ , E ₂ , the control unit 30 compares the number of commutation artifacts 42 with a predetermined minimum number and / or a predetermined range, which is stored in a memory of the control unit 30 is.

The predetermined minimum number and / or the predetermined range are calculated or empirically determined values for the number of commutation artefacts 42 which at least occur during operation of the actuator 24 from one of the end positions E ₁ , E ₂ in the other in error-free operation or between which Number is high probability.

The comparison checks whether it is plausible that the end position E ₁ , E _{2 has been} reached.

If the number of commutation artifacts 42 is below the predetermined minimum number and / or outside the predetermined range, the controller 30 concludes that there is a problem with the actuator assembly 22 and generates an error message, for example.

If the actuator 24 is subsequently moved out of the end position E ₂ , then the control unit 30 counts the number of commutation artifacts 42 away from zero, whereby an accurate determination of the position is always achieved.

It is of course also conceivable that in the control unit 30, a value table is stored, the position of the actuator 24 directly with the number the commutation artifacts 42 linked without the control unit 30 has to make calculations for the number of completed revolutions of the DC motor 26 or the ratio of the transmission 28.

Of course, the value table can also specify the position of the actuator 24 as a function of the number of completed rotations of the DC motor 26 or the completed rotation angle.

Claims (13)

Method for determining the position of an actuator (24) of an internal combustion engine (10), in particular a control flap, a swirl flap or a valve, which is actuated by a DC motor (26), comprising the following steps: a) measuring the current profile (38) of the DC motor (26) supplied current, b) detecting commutation artifacts (42) in the measured current profile (38), c) determining the number of detected commutation artifacts (42) by a control unit (30), d) determining the position of the actuator (24) based on the number of Kommutierungsartefakten (42) by the control unit (30). A method according to claim 1, characterized in that the control unit (30) determines the direction of rotation of the DC motor (26), in particular based on the polarity of the current, and for determining the position of the actuator (24). A method according to claim 1 or 2, characterized in that the control unit (30) determines the position of the actuator (24) using the number of Kommutierungsartefakten (42) relative to an end position (E ₁ , E ₂ ) of the actuator (24). A method according to claim 3, characterized in that the control unit (30) detects when the actuator (24) has reached the end position (E ₁ , E ₂ ), and then regardless of the number of Kommutierungsartefakte (42), the position of the actuator ( 24) as the end position (E ₁ , E ₂ ) determined. A method according to claim 4, characterized in that the control unit (30) upon reaching the end position (E ₁ , E ₂ ) checks whether the number of Kommutierungsartefakte (42) is above a predetermined minimum number and / or within a predetermined range. Method according to one of the preceding claims, characterized in that the control unit (30) determines the number of revolutions completed by the DC motor (26) and / or the completed angle of rotation of the DC motor (26) on the basis of the number of commutation artifacts (42) and for determining the Position of the actuator (24) used. A method according to claim 6, characterized in that a transmission (28) between the DC motor (26) and the actuator (24) is provided, wherein in the control unit (30) information about the translation of the transmission (28) are deposited, wherein the Control unit (30) determines the position of the actuator (24) as a function of the ratio of the transmission (28) and the completed revolutions and / or the completed rotation angle of the DC motor (26). Method according to one of the preceding claims, characterized in that a value table is stored in the control unit (30), which determines the position of the actuator (24) as a function of the number of commutation artifacts, the number of completed revolutions, the completed angle of rotation and / or Gear ratio (28) indicates. Method according to one of the preceding claims, characterized in that the current profile (38) by the control unit (30), a driver (32) of the DC motor (26) or a shunt (36) is measured with a voltmeter. An actuator assembly for an internal combustion engine comprising an actuator (24), a DC motor (26) and a control unit (30) arranged to perform a method according to any one of the preceding claims. An actuator assembly according to claim 10, characterized in that the control unit (30) is part of a driver (32) and / or an H-bridge for the DC motor (26). An actuator assembly according to claim 10 or 11, characterized in that the actuator (24) comprises a control flap for a turbocharger unit (12) of the internal combustion engine (10), a swirl flap for an intake system (14) of Internal combustion engine (10) or a valve, in particular a multi-way valve for an engine cooling circuit (20) of the internal combustion engine (10). An actuator assembly according to any one of claims 10 to 12, characterized in that the actuator assembly (22) comprises a transmission (28) with a predetermined ratio, wherein the transmission (28) is in particular self-locking.

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