EP0271661A2 - Device for transmitting a drive force between two construction parts - Google Patents

Abstract

In a known device for transmitting a drive force between two components a cover engaging with both components which seals off the housing accommodating the one component is moved in the direction of this component's displacement axis. As a result the device takes up a considerable amount of space in the direction of the displacement axis. <??>The invention employs a cover (5) which can rotate in the housing (1) in such a way that, owing to the engagement between the cover (5) and the one component (22), a displacement of the component (22) corresponds to a rotation of the cover (5). <??>The device can be used, for example, to drive a disc-type valve element (second component 2) by means of a servo drive (8) in the valve support (housing 1) of a compressor. <IMAGE>

Description

The invention relates to a device for transmitting a driving force between two components according to the preamble of claim 1.

Such a device is known from DE 33 29 790 A1. There, a driving force is transmitted in a valve carrier between a first component (driver 15) and a second component (lamella 13) via a cover (flat slide valve 34) which is in engagement with the first component on the one hand and with the second component on the other hand, the first component is slidably guided in a housing and the cover seals the housing. The cover is displaced with the first component by engagement with a part of the first component which projects out of the housing. So that the cover can fulfill its sealing function at any time during this displacement, it must be dimensioned sufficiently in the direction of the displacement axis to cover the housing, in particular its opening required for the protruding part mentioned above, in every position of the first component. This means that the cover in the direction of the sliding axis must be twice as long as the housing opening. It follows that the cover takes up considerable space in the direction of the displacement axis, since the overall length of the cover in this direction in any position of the first component, for example, also in its starting position, must be accommodated. This space can often not be made available or cannot be made available without problems.

The invention is therefore based on the object to improve a device of the type mentioned with simple means such that its space requirement in the direction of the axis of displacement of the first component can be significantly reduced.

This object is achieved by the invention specified in claim 1. Further developments, advantageous refinements and an advantageous field of application of the invention are specified in the subclaims.

The invention is suitable for all types of displaceability of the first component; the displaceability can, for example, be straight and / or take place along a curved path.

Characterized in that the cover is rotated instead of moved according to the invention during the displacement or the movement of the components involved, the invention enables a reduction in the relative movements between the cover and the housing and thus a reduction in the corresponding friction work with an increase in the efficiency of the device as a result.

The driving force can come from any of the components involved.

The invention is suitable for all types of movement of the second component. An example is one translatory movement (displacement) or a pivoting movement to think about an axis of rotation, which can run essentially parallel to the axis of rotation of the lid. The axis of rotation of the cover can in turn be arranged to run essentially transversely to the axis of displacement of the first component.

The invention can advantageously be used in a case in which one component is displaceable or movable between two end positions and thereby drives the other component to move or move between two end positions assigned to the end positions mentioned.

In one embodiment, the first component is designed as a driver of an actuator arranged in the housing for moving the second component. In this case, the drive of the second component is important. Such a case exists, for example, when the second component is designed as a lamellar valve member of a valve formed by this valve member and at least one housing opening. In this case, the valve member can be pivoted between two end positions, in one of which it opens (opens) the housing opening and in the other it covers the housing opening (ie closes unless the valve member is lifted from the housing opening, for example by negative pressure transversely to the pivoting direction) ).

The interventions between the cover and the first component on the one hand and the cover and the second component on the other can be carried out in any suitable manner. Cost-effective solutions for this are given in claims 10, 11 and 12. The arrangement of the guide slots specified in these claims ensures the arrangement of the cover which is advantageous in terms of its axis of rotation and which is advantageous according to claims 3 and / or 4.

An embodiment in which the cover does not influence or impair the housing contours results if the cover is sunk in the housing to a flush surface of the housing facing away from the housing with a surface surrounding the cover. This housing surface can be a specially arranged housing surface, for example a countersunk, but also the outer housing surface per se or an inner housing surface.

The above-mentioned recessed arrangement of the cover advantageously enables the second component to be guided on the housing surface mentioned and on the side of the cover facing away from the housing.

Due to the possibility of varying the position of the engagement points on the cover and the spacing of the engagement points from its axis of rotation, different force or force can be achieved without any significant additional effort, if not without additional effort at all. Path translations between the components involved can be carried out.

The lid can be rotated in any suitable manner. In a For this purpose, the cover has at least one lateral surface that is rotationally symmetrical with respect to its axis of rotation and with which it is mounted radially in a lateral surface of the housing that is compatible with it. This outer surface can be the outer outer surface, which determines the transverse dimension of the cover, or an inner outer surface. In the former case, the housing should also be sealed between the outer surface of the cover and the outer surface of the housing that is compatible with it.

Depending on their design, the aforementioned lateral surfaces describe at least one circle in the plan. In order to achieve the smallest possible dimensions transversely to the axis of rotation of the cover, the diameter of the lateral surfaces can be dimensioned such that an opening in the form of a housing slot, in which the first component is guided in the direction of its displacement axis, is arranged within the outline of the lateral surface of the housing, at least approximately Kind of a tendon lies in this floor plan.

Relieving the rotatable mounting of the cover from the sealing function is made possible by an embodiment in which the housing has a sealing seat enclosing the lateral surface in a plane lying transverse to the axis of rotation of the cover, on which the cover is arranged with a compatible one and arranged transversely to its axis of rotation Sealing seat rests. The seal created in this way precedes the rotatable bearing, not only relieving it of the sealing function, but also protecting it also against influences that originate on the side of the cover facing away from the housing or on the inner or outer surface of the housing assigned to this side of the cover.

In the floor plan, the outer surface of the cover can show any course. With a constant space requirement in all rotational positions transverse to its axis of rotation, the cover can be designed if its outer lateral surface is rotationally symmetrical to its axis of rotation, that is, depending on the design, has at least one circle as a plan. The embodiment mentioned above with the rotatable bearing upstream seal can be designed to save space by arranging the sealing seats of the cover and housing on a transition surface between the outer lateral surfaces and the lateral surfaces serving to rotatably support the cover.

The mentioned lateral surfaces of the cover on the one hand and of the housing on the other hand can be designed in all suitable and compatible ways while maintaining their function. For example, both lateral surfaces can be cylindrical, conical or crowned. However, the cover-side lateral surface can also be cylindrical, for example, and the housing-side lateral surface can be conical or spherical.

The above-mentioned sealing seats of the housing and of the cover can also be designed in all suitable mutually compatible ways. In consideration all pairings come with surface or line contact. A separate seal can also be arranged between the sealing seats mentioned.

The invention is explained below with reference to an exemplary embodiment shown in the drawing.

• Fig. 1 eine Draufsicht auf einen Ventilträger mit Einrichtung zur Übertragung einer Antriebs­kraft zwischen zwei Bauteilen,
• Fig. 2 einen Schnitt durch den Ventilträger nach Fig. 1 entlang des Linienzugs A-A.

Show it:

• 1 is a plan view of a valve carrier with means for transmitting a driving force between two components,
• Fig. 2 shows a section through the valve carrier of FIG. 1 along the line AA.

In the explanations below, reference is made to the figure in question only to the extent that this is unavoidable for clarification.

The valve carrier shown has a housing (1) in the form of a plate, in and on which a device for transmitting a driving force between two components (22, 2) is arranged. The first component (22) is the driver of an actuator arranged in the housing (1) and generally designated (8). The first component (22) is slidably guided in the housing (1). The guidance takes place in a (straight) housing slot (7). Opposite the housing slot (7), the housing (1) has an opening (27) through which the first component (22) can be knocked out. The The housing slot (7) is covered by a cover (5) in such a way that it protects the housing (1) against influences on the side of the cover (5) facing away from the housing (1) or that side of the cover (5) Side of the housing (1) have their origin seals.

The first component (22) has a part (21) protruding from the housing (1), especially from the housing slot (7), which engages with the cover (5). The cover (5) is rotatably mounted in the housing (1), namely about an axis of rotation (6) extending essentially transversely to the displacement axis (double arrow V) of the first component (22), such that, as a result of the engagement between the cover (5) and the first component (22) of a rotation of the cover (5) corresponds to a displacement (V) of the first component (22).

The axis of rotation (6) of the cover (5) is shown in FIG. 2 as the center line of the cover (5), while FIG. 1 only shows its point projection.

A lamellar valve member is provided as the second component (2) and is pivotally mounted in the housing (1) about a pivot axis (12) parallel to the axis of rotation (6). The pivot axis (12) is shown in FIG. 1 as the center of an unspecified pivot pin which radially supports the second component (2). The pivoting movement of the second component (2) is indicated by a double arrow (S). The cover (5) engages with the second component (2) on its side facing away from the housing (1).

The first component (22) can be displaced between two end positions, which are denoted by (I) or (II) in FIG. 2. When it moves between these end positions, the first component (22) drives the second component (2) between two (swivel) end positions assigned to these end positions in the manner described below. The end position of the second component (2) assigned to the position (I) of the first component (22) is shown in the figures. The second component (2) forms an inlet valve (2, 9) with a housing opening (9), which is the mouth of a housing channel. In its end position assigned to position (I), the second component covers the housing opening (9) and thereby closes the inlet valve (2, 9), unless it is exerted by a force transversely to the pivoting movement, for example as a result of a vacuum, from the housing opening (9) is lifted off. In its end position corresponding to position (II), the second component (2) releases the housing opening (9) and thereby opens the inlet valve (2, 9). The illustration also shows a second housing opening (10) with which the second component (2) forms a further inlet valve (2, 10), for which the determinations just made apply accordingly.

The points of engagement between the cover (5) and the first component (22) on the one hand and between the cover (5) and the second component (2) on the other hand are designed so that the components (22 or 2) when transmitting a driving force between the components on the Cover (5) transverse to its axis of rotation (6) essentially no forces, in other words: in can exert essentially no radial forces on the cover (5). This ensures that the drive force is transmitted without jamming between the components.

To produce such interventions, the engagement points in the exemplary embodiment are designed as follows.

On its side facing the housing (1), the cover (5) has a guide slot (20) which is essentially directed towards its axis of rotation (6) and in which the part (21) of the first component (21) protruding from the housing (1) 22) is performed. On the other hand, the cover (5) has on its side facing away from the housing (1) a driver (4) which is guided in an elongated guide slot (3) formed in the second component (2) in the longitudinal direction thereof, which longitudinal direction essentially runs transverse to the swivel direction (S).

In a manner not shown, the assignment of driver and guide slot to cover and second component could also be interchanged to produce the engagement between cover and second component.

The cover (5) is sunk in the housing (1) such that its surface facing away from the housing (1) is essentially flush with a housing surface (24) surrounding the cover (5). As a result, the surrounding housing surface (24) and the side of the cover (5) facing away from the housing (1) form a coherent surface on which the second component (2) is guided as it moves. The mentioned housing surface (24) is in turn lowered by at least the thickness of the second component (2) compared to the rest of the housing surface on the relevant side. Since the driver (4) of the cover (5) is not thicker than the second component (2), the lowering of the surface (24) means that the device is accommodated in the housing without exceeding the housing dimensions.

For the rotatable mounting of the cover (5), the housing (1) has an outer surface, which is rotationally symmetrical to the axis of rotation (6), for example produced by countersinking. The cover has a jacket surface (26) that is compatible with this jacket surface. With this he is mounted radially in the lateral surface of the housing (1). Depending on their design in the direction of the axis of rotation (6), the lateral surfaces mentioned have, as rotationally symmetrical surfaces, at least one circle as a plan. The housing slot (7) lies within this floor plan. The diameter of the lateral surfaces is dimensioned such that the guide slot in the plan is at least approximately in the manner of a (circular) chord, ie touches or almost touches the plan in the area of its end faces. For a given position of the axis of rotation (6), this results in the smallest possible transverse dimension of the cover (5). If the position of the axis of rotation (6) can be varied within the framework of the desired force or path translations between the components, then it can also be used to determine the smallest possible transverse dimension of the cover (5). If, in a manner not shown, the described rotatable mounting, more precisely: the bed joint, the sealing function described above is also transferred, so the minimum possible transverse dimension of the cover (5) is ensured.

In the exemplary embodiment, however, the rotatable mounting (bearing joint) is relieved of the sealing function. For this purpose, the housing has, in a plane lying transversely to the axis of rotation (6) of the cover (5), a sealing seat, not designated, enclosing the lateral surface, on which the cover (5) with a compatible sealing seat (23) rests.

The sealing seats of the housing (1) and cover (5) are enclosed by an outer outer surface, which is rotationally symmetrical to the axis of rotation (6) and compatible with one another, of which that on the cover is designated by (25). Due to the rotationally symmetrical design of this outer lateral surface, the construction with the smallest possible transverse dimension of the cover (5) is achieved in view of the separation of the rotatable bearing and sealing function. The sealing seats are each formed on transition surfaces in the housing (1) and on the cover (5) between the outer circumferential surface (e.g. 25) and the rotatable bearing-serving circumferential surface (e.g. 26).

The lateral surfaces mentioned are shown as cylindrical surfaces and the sealing seats mentioned are shown as step surfaces between the cylindrical surfaces. However, these surfaces can also be designed in any other way that ensures the required functions.

The described separation of the rotatable bearing and the sealing function also enables, in a manner not shown, that the cover instead of the rotating one The lateral surface (26) has bearing points or surfaces only in a few places on the same circumference.

Overall, the cover (5) is designed as a disk-shaped body, which is sunk with its entire thickness in the housing (1). This arrangement also serves to accommodate the device in the housing, as already mentioned, without changing the overall dimensions.

As shown in FIG. 1, there is another lamellar valve member (13) on the non-lowered area of the housing surface, which forms further inlet valves (11, 13) with housing openings (11) in a manner not described in detail and which forms the second component (2 ) partially covered in the top view. In Fig. 2 the valve member (13) is omitted for the sake of clarity.

The device shown in the exemplary embodiment for transmitting a driving force between two components functions as follows.

The first component can be displaced from its end position (I) into its end position (I) by pressurizing the actuator (8) via an unspecified pressure connection and is pushed back into the end position (I) by a return spring (not specified) when the pressure drops. During these displacements, the first component (22) transmits a driving force in the circumferential direction of the cover (5) to the flank of the guide slot (20) in the cover (5), the end (21) of the first component (22) in the guide slot ( 20) slides. As a result of the torque which the driving force exerts on the cover (5), it rotates. He takes the second component (2) in its swivel direction (S). When driving, the driver (4) of the cover (5) exerts a peripheral force on the flank of the guide slot (3) on the second component (2) about its pivot axis (12), the driver (4) simultaneously in the guide slot ( 3) slides.

It is obvious that a force introduced into the second component (2) is correspondingly transmitted to the first component (22) when the function is reversed.

It is obvious that by changing the distance or distances of the component (22) or the driver (4) from the pivot axis (6), the force and displacement ratio between the first component (22) and the second component ( 2) can be varied. In the exemplary embodiment, the first component (22) and the second component (2) move in the same direction; this is because seen from the pivot axis (12), the points of engagement between the two components (22, 2) and cover (5) are arranged on this side of the axis of rotation (6). An opposite movement, i. H. there is a reversal of force and movement if the said engagement points, again seen from the pivot axis (12), are arranged on different sides of the axis of rotation (6).

Those skilled in the art will recognize that the scope of protection of the present invention is not limited to the exemplary embodiment, but rather encompasses all configurations, the features of which are subordinate to the patent claims.

Claims (19)

1. Device for transmitting a driving force between two components with the features: a) A first component is slidably guided in a housing; b) a part of the first component protruding from the housing engages with a cover sealing the housing; c) on its side facing away from the housing, the cover engages with a second movable component,
characterized by the following features: d) The cover (5) is rotatably mounted in the housing (1) such that, as a result of the engagement between the cover (5) and the first component (22), a rotation of the cover (5) corresponds to a displacement of the first component (22). 2. Device according to claim 1, characterized in that the axis of rotation (6) of the cover (5) is arranged substantially transversely to the axis of displacement (double arrow V) of the first component (22). 3. Device according to one of claims 1 or 2, characterized in that the point of engagement is formed between the cover (5) and the first component (22) in such a way that the first component (22) transfers a driving force between the components (22) and (2) to the cover (5) transversely to its axis of rotation ( 6) can exercise essentially no force. 4. Device according to one of the preceding claims, characterized in that the point of engagement between the cover (5) and the second component (2) is designed such that the second component (2) in the transmission of a driving force between the components (22) and (2) substantially no force can be exerted on the cover transversely to its axis of rotation (6). 5. Device according to one of the preceding claims, characterized in that the movement of the second component (2) is a pivoting movement (double arrow S) about a pivot axis (12). 6. Device according to claim 5, characterized in that the pivot axis (12) extends substantially parallel to the axis of rotation (6) of the cover (5). 7. Device according to one of the preceding claims, characterized in that the first component (22) between two end positions (I and II) is displaceable and that the second component (2) is movable between two end positions assigned to them. 8. Device according to one of the preceding claims, characterized in that the first component (22) is designed as a driver of an actuator (8) arranged in the housing (1) for moving the second component (2). 9. Device according to claims 6, 7 and 8, characterized in that the second component (2) is designed as a lamellar valve member of a valve member and at least one housing opening (9) formed valve (2, 9), the housing opening ( 9) can be covered by the latter in an end position of the valve member. 10. Device according to one of the preceding claims, characterized in that the cover (5) on its side facing the housing (1) has a substantially on its axis of rotation (6) to the guide slot (20), in which the out of the housing (1) projecting part (21) of the first component (22) for producing the engagement between the cover (5) and the first component (22) is guided. 11. Device according to one of claims 5 to 10, characterized in that the cover (5) on its side facing away from the housing (1) has a driver (4) which for producing the engagement between the cover (5) and the second component ( 2) in an elongated guide slot (3) of the second component (2) in the longitudinal direction of the guide slot (3) slidably guided is which longitudinal direction is essentially transverse to the pivoting direction (S). 12. Device according to one of claims 1 to 10, characterized in that the second component has a driver which is guided to produce the engagement between the cover and the second component in a guide slot in the cover on the side facing away from the housing, which guide slot essentially is directed towards the axis of rotation of the lid. 13. Device according to one of the preceding claims, characterized in that the cover (5) is arranged sunk in the housing (1), such that its surface facing away from the housing (1) with one or the housing surface surrounding the cover (5) ( 24) is essentially flush. 14. Device according to claim 13, characterized in that the second component (2) on the cover (1) surrounding the housing surface (24) and the housing (1) facing away from the cover (5) is guided. 15. Device according to one of the preceding claims, characterized in that the cover (5) has at least one jacket surface (26) which is rotationally symmetrical with respect to its axis of rotation (6) and with this for producing its rotatable mounting in a jacket surface of the housing which is compatible therewith ) is mounted radially. 16. The device according to claim 15, characterized in that the diameter of the lateral surfaces is dimensioned such that a within the circular plan of the lateral surface of the housing (1) arranged housing slot (7) in which the first component (22) in the direction of its displacement axis (V) is guided, at least approximately in the manner of a tendon in this plan. 17. Device according to one of claims 15 or 16, characterized in that the housing (1) in a transverse to the axis of rotation (6) of the cover (5) lying plane has a sealing surface enclosing the sealing surface on which the cover (5) for Production of the seal of the housing (1) with a compatible sealing seat (23) arranged transversely to its axis of rotation (6). 18. Device according to one of the preceding claims, characterized in that the outer circumferential surface (25) of the cover (5) to its axis of rotation (6) is rotationally symmetrical. 19. The device according to claim 18, characterized in that the sealing seats (z. B. 23) each on a transition surface between the outer circumferential surfaces (z. B. 25) and for the rotatable mounting of the cover (5) serving mantle surfaces (z. B. 26) are arranged.

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