EP1111227B1 - Exhaust gas recirculation valve - Google Patents

Abstract

The exhaust gas feedback valve has a linearly displaced valve element, e.g. a valve plate (18), which is rotated about its axis, at least at the beginning of its movement, via the valve element operating mechanism, e.g. a spindle-and-nut operating mechanism (22,24).

Description

Technical area

The invention relates to an exhaust gas recirculation valve.

In the field of automotive engineering, and in particular in connection with the improvement of the emission values of an internal combustion engine, as well as the reduction of its fuel consumption, it is known to provide an exhaust gas recirculation to the air supply of the internal combustion engine.

State of the art

The associated electrical exhaust gas recirculation valves are usually controlled as solenoid valves so that they move in translation, so that a valve element, such as a valve disc, is removed from its associated valve seat, and a passage of exhaust gas is made possible.

DE 197 33 964 A1 discloses in this context an exhaust gas recirculation valve, which selectively directs the exhaust gas flow through a radiator or a bypass. In this case, the movement of one or the other valve disc also takes place in the translational direction.

Due to the flow of the exhaust gas recirculation valve with exhaust gas, the case occurs that the contact area between the valve disk and the valve seat is contaminated, and thereby glued or laked. This contamination can become so extensive that the usual operating mechanisms are no longer able to lift the valve disk from its seat. Accordingly, strong actuating mechanisms must be provided to ensure lifting of the valve disk even with contaminated valve seat.

US 4,646,705 discloses an exhaust gas recirculation valve having a translationally movable valve member which is rotationally actuated. The actuating mechanism has an eccentric, so that a movement takes place transversely to the opening movement.

Presentation of the invention

The invention has for its object to provide an exhaust gas recirculation valve, in which a reliable opening of the valve can be ensured even with contaminated state of the contact surface between the valve seat and valve disc with a compact operating mechanism.

The solution to this problem is achieved by the exhaust gas recirculation valve described in claim 1.

Accordingly, the exhaust gas recirculation valve according to the invention has an actuating mechanism which gives the valve element, which cooperates with the valve seat, that is usually the valve disk, at least at the beginning of the opening process a rotational movement about its axis. In other words, the valve disk is at least slightly rotated about the axis of the associated valve stem at the beginning of the opening process. This movement is therefore extremely effective for a reliable opening with little force, because the adhering contaminants between the valve element and the valve seat resist forces applied as shearing forces less than normal forces. Consequently, it requires a higher force, the valve element in the usual way from the valve seat with which it Due to contamination is deducted due to linear displacement than the force required to rotate the valve member on the valve seat to release the adhesive through the adhesive bond around the axis of the valve lifter.

According to the invention, this advantageous, the adhesive dissolving rotational movement can be carried out at the beginning of the opening process alone, and the translational movement for the actual opening of the valve can be applied subsequently. Alternatively, it is conceivable to combine the rotary and lifting movement with one another, ie to carry out simultaneously, so that the valve element is not lifted "straight" from the valve seat at the beginning of the opening process, but this lifting takes place, as it were, turning. By the measure according to the invention thus the force required for opening can be reduced, and it is ensured that even with a compact operating mechanism over a long life of the valve, a slight opening is possible. In addition, the rotational movement according to the invention, which takes place at least at the beginning of the opening process, leads to a self-cleaning effect of the contact surface between the valve element and the valve seat, so that the described problems with regard to adhesion are thereby also defused. At the same time the sealing effect is improved in the closed state.

Preferred developments of the inventions are described in the further claims.

For the actuating mechanism, an embodiment has been found to be particularly advantageous, having a nut-spindle system. As a result, the rotational movement of a drive motor can be converted into a combined rotary and lifting movement of the valve element in a particularly simple and effective manner.

It offers advantages when the spindle is designed as a ball-bearing spindle. The ball track can be designed in an advantageous manner so that the valve element initially only a rotational movement is granted, and from a certain point in time a combined rotational and lifting movement. For this purpose, the ball track is initially planar and formed spirally from a certain point.

Alternatively, an embodiment of the invention is preferred in which the actuating mechanism comprises a rotary member having a contour or cam surface which runs on an attached to the valve housing member. In this way, a movement of the rotary member can be achieved by the interaction between the provided with the contour of the rotary element and the elements mounted on the valve housing elements such that this is rotated and additionally raised by forming the corresponding contour from a certain time. By a fixed connection between this rotary element and the valve element, so for example the valve stem with the valve disc formed thereon, the combined or successively rotating and lifting movement can be transmitted to the valve element.

For the transmission of the rotational movement of a drive motor to elements which are firmly connected to the translationally displaceable valve element and therefore in turn must be displaceable, it has proved to be favorable to provide translationally mutually displaceable gears.

Alternatively, an embodiment is conceivable in which the entire actuating mechanism including the drive is slidably mounted on the valve housing. Consequently, the actuation and drive mechanism causes not only in addition to the rotational movement according to the invention, at least at the beginning of the opening process for opening the valve required translational movement, but participates in this.

In an advantageous manner, the exhaust gas recirculation valve according to the invention can finally be combined with a reset or fail-save mechanism, which is subjected to torsion and preferably additionally to pressure when the valve is opened. Such a fail-safe function takes into account the fact that the valve element according to the invention is given a rotational movement, so that the return can be done safely by a twisted return device that gives the valve element the required rotation to ensure a closing movement. In experiments, it has been found that this can be achieved particularly safe closing the valve.

Brief description of the drawings

Fig. 1

eine Schnittansicht einer ersten Ausführungsform des erfindungsgemäßen Abgasrückführventils;

Fig. 2

eine Schnittansicht einer zweiten Ausführungsform des erfindungsgemäßen Abgasrückführventils; und

Fig. 3

eine Schnittansicht einer dritten Ausführungsform des erfindungsgemäßen Abgasrückführventils.

The invention will be explained in more detail with reference to embodiments shown by way of example in the drawings.
Show it:

Fig. 1

a sectional view of a first embodiment of the exhaust gas recirculation valve according to the invention;

Fig. 2

a sectional view of a second embodiment of the exhaust gas recirculation valve according to the invention; and

Fig. 3

a sectional view of a third embodiment of the exhaust gas recirculation valve according to the invention.

Detailed description of preferred embodiments of the invention

As shown in FIG. 1, the exhaust gas recirculation valve 10 according to the invention has a valve housing 12, which in its lower region through an opening 14 which with a Valve seat 16 is provided, is flowed through with exhaust gas. The opening 14 is closed by a valve element, in the case shown a valve plate 18. The valve disk 18 is attached to a valve stem 20, which in the case shown is designed as a spindle 22 in its upper area. The spindle 22 is, as shown, ball-mounted in a nut 24 firmly anchored in the valve housing 12. In its upper area, a so-called harmonic drive gear 26 or other compact gearbox is provided to transmit the rotational movement of an electric motor 28 to the valve lifter 20. Finally, on the other hand, a return spring 30 is firmly anchored to the valve housing 12 on the one hand and the upper portion of the valve stem 20, which, as described below, ensures a safe return of the valve in the closed state even in case of failure of the electric motor 28. Below the nut 24 is in this embodiment shown, a seal 32 for sealing the area flowed through by the exhaust gas from the actuating mechanism.

The operation of the exhaust gas recirculation valve shown with the novel actuating mechanism is as follows. In Fig. 1, an open state of the valve is shown. This is achieved by rotating the electric motor 28 and transmitting this rotation to the valve lifter 20 via the harmonic drive gearbox 26 or other compact gearbox. Characterized in that the valve stem 20 is formed in its upper region as a spindle 22, the rotational movement of the valve stem 20 in cooperation with the nut 24 to a translational movement of the valve stem 20 together with the valve plate 18. As a result, the valve plate 18 in the valve seat 16th not only, especially at the beginning of the opening process, twisted, but also raised by this, so that the valve is opened.

According to the illustrated preferred embodiment of the invention, the spindle 22 is ball-mounted in the nut 24. This offers the advantage that the ball raceways can be designed such that the spindle performs a rotational movement to a certain extent only, in order, as described above, to dislodge the valve disk 18 from the valve seat 16 with relatively little effort, despite bonding. The ball raceways are further designed so that they provide at a certain point in addition by a spiral design of the ball raceways for a translational movement of the valve disk 18, and a corresponding, relatively fast opening of the valve disk 18. Since not only the valve plate 18, but also the valve stem 20 and the adjoining thereto up the area, which is already part of the harmonic drive gear 26 or other compact gear, moves translationally, the interaction between the individual gears of the harmonic drive gear 26 or other compactly constructed gear designed so that the gears involved are mutually displaceable.

When opening the valve, the return spring 30 is both twisted, so twisted, and because of the axial displacement, loaded on pressure. The interaction of the energy stored in the return spring 30 in this manner can reliably ensure closure of the valve even in the event that the electric motor 28 fails for some reason.

In the embodiment of the exhaust gas recirculation valve 10 according to the invention shown in Fig. 2, this fail-safe device in the form of the return spring 30 is the same. The actuation of the valve, in particular the lifting of the valve plate 18 of the valve seat 16 is carried out in this embodiment, however, different than in the embodiment of Fig. 1. In this case, a (in Fig. 2 not recognizing) motor, the rotational movement of which is transmitted via a spur gear 34 or other compact gear on a rotating element, in particular a gear 36 which is fixedly connected to the valve stem 20. The coil spring 30 takes over in this case, the additional function of the gear 36 to press against so-called run-up rollers 38 which are rotatably mounted in the valve housing 12. For this purpose, 12 respective axes are firmly connected to the valve housing.

As can be seen in the left portion of the gear 36, this is provided in the region in which it rolls on the run-up rollers 38, with a contour which extends in the direction of the axis of the valve stem 20. This contour causes the gear 36, and thus the connected via the valve stem 20 fixed to the gear 36 valve disc 18 due to the rotational movement, which brings the contour into engagement with the run-up rollers 38, is raised in a suitable manner. In this case, the contour can be adjusted, for example, so that it is initially unchanged in terms of their height with respect to the run-up rollers 38, so that the valve disc 18 performs only a rotational movement on the valve seat 16 at the beginning of the opening process. This allows the described easy release of any adhesions and a cleaning of the valve seat 16th

After this rotational movement, which may possibly be supported by a slight lifting movement, which is effected by a correspondingly slight slope of the contour, the contour may be formed by steeper slope such that a faster opening occurs. This means that high opening forces can be transmitted during the phase of a low slope of the contour. It should be noted that such a characteristic can also be realized by a corresponding design of the ball raceways in the spindle-nut system of the embodiment of Fig. 1. When opening the valve, as explained, the Gear 36 is rotated and additionally raised, so that the fixed to the gear 36 and, anchored to the valve housing 12 return spring 30 is loaded on both pressure and torsion. This ensures, if necessary, an implementation of the energy stored in the spring such that the valve is securely closed by reverse rotation of the gear 36.

In Fig. 3, a further embodiment of the exhaust gas recirculation valve according to the invention is shown, which differs from the embodiment of FIG. 2 by the type of transmission, with which the rotational movement of the electric motor is transmitted to the valve. For this purpose, similar to the embodiment of FIG. 1, a harmonic drive gear 26 or other compact gearbox is provided. By the return spring 30 is one of the gears 36 which is fixedly connected to the valve stem 20, pressed in this embodiment against run-up rollers 38 which are rotatably mounted on the valve housing 12. Consequently, the conversion of the rotational movement takes place in a lifting movement of the valve disk 18 similar to the embodiment of Fig. 2 via a formed on the gear 36 contour, which cooperates with the run-up rollers. In the central region of the valve stem 20, a valve stem guide 40 and a seal 32 can be seen.

A comparison of Figures 3 and 1 shows that from the closed position (see Fig. 3) to the open position (see Fig. 1) of the valve coupled to the shaft of the electric motor gear and the gear 36 (see Fig. 3) of the harmonic drive transmission 26 against each other.

It should be additionally noted that the return spring 36 is shown in all three cases as a combined compression and torsion spring. However, it is also possible to ensure the necessary for closing rotary motion, a pure torsion spring, for example, a so-called Urwerksfeder provide. Furthermore, for the transmission of the Rotary movement of the electric motor, for example, a direct current (DC) motor on the valve and other compactly built gear types than those shown, so for example Stirnrad-, planetary, bevel gear, etc. are used. Finally, it should be noted that the use of an electric motor with rotating output shaft offers certain advantages even without the transmission of rotational movement to the valve disk. For this purpose, for example, the spindle-nut system shown for Fig. 1 are reversed such that the nut is rotatably coupled to the electric motor and the spindle non-rotatably, but translationally movable, is guided in the valve housing and at its lower end the valve disk 18th having. Such an embodiment also offers advantages with regard to the actuation of the valve by means of comparatively low forces.

Claims (7)

1. Waste gas return valve having a translationally movable valve element, in particular a valve disk (18), and an actuating mechanism which confers on the valve element (18) at least at the beginning of the opening operation a turning movement ensuing about the axis thereof.
2. Waste gas return valve according to claim 1, characterised in that the actuating mechanism comprises a nut (24)-spindle (22) system.
3. Waste gas return valve according to claim 2, characterised in that the spindle (22) is mounted on ball bearings, wherein the ball race is shaped in such a way that in sections it is of planar construction and in sections it is of helical construction.
4. Waste gas return valve according to at least one of the preceding claims, characterised in that the actuating mechanism has a turning element (36) having a contour which acts in conjunction with at least one element (38) attached to the valve housing (12).
5. Waste gas return valve according to at least one of the preceding claims, characterised in that the actuating mechanism possesses gear wheels which are translationally displaceable with respect to one another.
6. Waste gas return valve according to at least one of the preceding claims, characterised in that the actuating mechanism, preferably together with a drive (28), is fitted displaceably on the valve housing (12).
7. Waste gas return valve according to at least one of the preceding claims, characterised in that a resetting device (30) is present which when the valve opens applies torsional load and preferably is additionally compressed.

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