SHIFT GATE, SLIDING CAM SYSTEM AND CAMSHAFT

Abstract

The present disclosure provides a shift gate for a sliding cam system with at least two shifting grooves for engaging at least one actuator pin. The shifting grooves extend in a circumferential direction of the shift gate. The two shifting grooves are at least partially separated from one another in an entry region of the actuator pin. In a transition region adjacent to the entry region, they converge on each other in such a manner that they merge into each other and form a common groove. The shifting grooves each comprise at least one groove flank, in particular a lead flank and/or a runoff flank, which narrows the shifting grooves at least in the transition region, in such a manner that a groove width of the shifting grooves in the transition region is smaller than a groove width of the shifting grooves in the entry region of the actuator pin.

Claims

1.-11. (canceled)

12. A shift gate for a sliding cam system, the shift gate comprising: at least two shifting grooves defined on the shift gate and that engage at least one actuator pin, said shifting grooves extending in a circumferential direction of the shift gate, wherein the two shifting grooves are at least partially separated from one another in an entry region of the actuator pin, and in a transition region adjacent to the entry region, they converge on each other in such a manner that they merge into each other and form a common groove; and wherein the shifting grooves each comprise groove flanks, including a lead flank and a runoff flank, which narrows the shifting grooves at least in the transition region, in such a manner that a groove width of the shifting grooves in the transition region is smaller than a groove width of the shifting grooves in the entry region of the actuator pin.

13. The shift gate as claimed in claim 12, wherein the runoff flank converges towards the lead flank, of the shifting grooves at least partially in the transition region, in such a manner that during a displacement action, the actuator pin comes into contact with the lead flank.

14. The shift gate as claimed in claim 12, wherein the groove flank has a narrowing portion that extends laterally into the shifting groove and reduces the groove width of the shifting groove at least in the transition region.

15. The shift gate as claimed in claim 14 wherein the narrowing portion of the groove flank has at least one curvature that extends at least partially into the shifting grooves and forms a smooth transition between the different groove widths of the shifting grooves in the entry region and in the transition region.

16. The shift gate as claimed in claim 14 wherein the narrowing portion is formed at least partially along the shifting grooves in the transition region.

17. The shift gate of claim 12 wherein the runoff flank and the lead flank have at least one parallel flank area relative to one another, which runs along the shifting grooves in the transition region, in such a manner that the groove width is at least partially constant.

18. The shift gate of claim 12, further comprising: at least one web that is arranged in a longitudinal direction of the shift gate between the two shifting grooves, wherein the runoff flank is part of the web.

19. The shift gate as claimed in claim 18 wherein the groove flank forms a sidewall of the web facing the respective shifting groove.

20. The shift gate of claim 19 wherein one of the lead flank and runoff flank is part of at least one outer wall that outwardly delimits the shifting grooves in a longitudinal direction of the shift gate.

21. A sliding cam system with at least one sliding cam element, at least one multiple-pin actuator, in particular a double-pin actuator, wherein the sliding cam element has at least one shifting groove according to claim 12, wherein one of the shifting grooves of the shift gate interacts with at least one actuator pin of the multiple actuator during a displacement action of the sliding cam element.

22. A camshaft with at least one shift gate according to claim 12.

23. The camshaft of claim 22, further comprising the sliding cam system of claim 21.

Description

IN THESE DRAWINGS

[0029] FIG. 1 shows a diagram of a shift gate according to a preferred exemplary embodiment according to the invention, wherein the diagram represents a partial detail of the profile of the shifting grooves as a function of the rotational angle;

[0030] FIG. 2 shows a top view of a transition region of the shift gate according to FIG. 1, in which the shifting grooves approach one another;

[0031] FIG. 3 shows a top view of an entry or exit area of the shift gate according to FIG. 1.

[0032] In the following description, the same reference signs are used for identical and similarly functioning parts.

[0033] FIGS. 1 to 3 show a shift gate 10 according to a preferred exemplary embodiment according to the invention. In concrete terms, FIG. 1 shows a diagram of a shift gate 10 according to an exemplary embodiment according to the invention. The diagram depicts a partial detail of the course of the shift gate 10, wherein a part of an entry region 12, a transition region 13, and a part of an exit region 27 of the shift gate 10 are shown. FIGS. 2 and 3 each show the shift gate 10 in a different rotational position around its longitudinal axis L.

[0034] The shift gate 10 according to FIGS. 1 to 3 may be part of a sliding cam element that has at least one cam for actuating or shutting off a valve. The shift gate 10 can be integrally designed with the cam. It is possible for the shift gate 10 to be designed as a separate part. The shift gate 10 can be used as a separate part in this case and/or be part of a constructed sliding cam element. Other applications are possible.

[0035] As shown in FIGS. 1 to 3, the shift gate 10 has two shifting grooves 11 that extend in a circumferential direction of the shift gate 10. The shift gate 10 comprises, as already mentioned above, an entry region 12, an exit region 27, and a transition region 13 arranged therebetween in the circumferential direction. The transition region 13 abuts the entry region 12 and the exit region 27 in the circumferential direction. The entry region 12 and the exit region 27 partially overlap in the circumferential direction. This can be clearly seen in FIG. 3.

[0036] The two shifting grooves 11 extend completely through the entry region 12. The two shifting grooves 11 run parallel in the entry region 12. In addition, the two shifting grooves 11 are spaced apart from one another in the longitudinal direction, i.e. transversely to the circumferential direction of the shift gate 10. In concrete terms, a web 24 that inwardly delimits the two shifting grooves 11 in the longitudinal direction is arranged between the two shifting grooves 11. The web 24 will be discussed in greater detail later.

[0037] The shifting grooves 11 are used to engage an actuator pin that is not shown, in order to move the shift gate 10 in a displacement direction. The displacement direction runs transversely to the circumferential direction. In other words, the displacement direction runs parallel to the longitudinal axis L of the shift gate 10. The entry region 12 is the region in the circumferential direction in which an actuator pin enters one of the two shifting grooves 11 during a displacement action. In a state inserted into the shifting groove 11, the actuator pin radially protrudes into the shifting groove 11.

[0038] It is shown in FIGS. 1 and 2 that the two shifting grooves 11 converge with one another in the transition region 13, in such a manner that they merge into one another to form a common groove 14. In other words, the two shifting grooves 11 converge in the transition region 13 in a V-shaped manner. The grooves 11, 14, form a Y-shaped shifting groove with the profile thereof. The common groove 14 is designed running parallel to the two shifting grooves 11. The common groove 14 passes through the exit region 27. The common groove 14 and the web 24 are located at the same axial position along the longitudinal axis L of the shift gate 10. The common groove 14 and the web 24 are arranged substantially halfway along the shift gate 10.

[0039] According to FIG. 3, starting from the transition region 13, the common groove 14 runs in an ascending manner in the circumferential direction towards the web 24. The common groove 14 is designed in a continuously, particularly radially, ascending manner in the circumferential direction, and opens onto a circumferential surface of the web 24.

[0040] The exit region 27 is the region in which the actuator pin exits the common groove 14 following the displacement of the shift gate 10. The common groove 14 forms an ejection ramp for the actuator pin in this case. In the state in which it has exited the common groove 14, the actuator pin is received by an actuator, in particular a multiple actuator. In the exited state, the actuator pin is spaced apart from the shift gate 10, so that it does not come into contact with the shift gate 10.

[0041] The shifting grooves 11 have a groove width B in the transition region 13 that is smaller than a groove width B of the shifting grooves 11 in the entry region 12. This is particularly evident in FIGS. 1 and 2. Furthermore, FIG. 1 shows that a groove width B of the common groove 14 is greater than the groove width B of the shifting grooves 11. The groove width B, B, B of the grooves 11, 14 is the width of the cross section of the grooves 11, 14 at the respective cross-sectional position. In the entry region 12, the groove width B of the shifting grooves 11 is constant. In the transition region 13, the shifting grooves 11 have a reduced groove width B in relation to the groove width B in the entry region 12. In other words, the shifting grooves 11 are narrowed in the transition region 13. To achieve this, the web 24 has two groove flanks 15, wherein one of the groove flanks 15 in each case abuts one of the shifting grooves 11 on the inside transversely to the circumferential direction. The groove flanks 15 each form a sidewall 25 of the web 24. The groove flanks 15 converge towards a pointed end 28 of the web 24. The groove flanks 15 are referred to as runoff flanks. The groove flanks 15 will be dealt with in greater detail later.

[0042] Furthermore, the shifting grooves 11 comprise two other groove flanks 18 that abut the shifting grooves 11 on the outside in the longitudinal direction of the shift gate 10. The other groove flanks 18 are part of outer walls 26 of the shift gate 10. The other groove flanks 18 are referred to as lead flanks. A groove flank 15 in each case is arranged opposite another groove flank 18. The groove width B of the shifting grooves 11 corresponds to the distance between the groove flank 15 and the other groove flank 18 which is opposite. The distance corresponds to the cross-sectional width of the shifting grooves 11. In other words, the groove flank 15 and the other groove flank 18 lying opposite define the groove width B of the shifting grooves 11.

[0043] In the transition region 13, the groove flank 15 in each case, in particular the runoff flank 17, partially converges towards the other groove flank 18 arranged opposite, in particular the lead flank 16, of the respective shifting groove 11, in such a manner that during a displacement action, the actuator pin comes into contact with the other groove flank 18. The groove flank 15 converges towards the other groove flank 18 in the transition region 13 in a funnel-shaped manner.

[0044] The respective groove flank 15 comprises at least one narrowing portion 19 that extends laterally into the shifting groove 11 and reduces the groove width B of the shifting groove 11 of the entry region 12 to the groove width B of the shifting groove 11 in the transition region 13. The narrowing portion 19 of the groove flank 15 comprises at least one curvature 21 that projects into the shifting groove 11 in sections. The curvature 21 has a convex design and extends laterally into the shifting groove 11. In other words, the narrowing portion 19 comprises a protuberance that extends into the shifting groove 11.

[0045] Furthermore, the narrowing portion 10 of the groove flank 15 has a smooth transition 22 between the different groove widths B, B of the shifting groove 11 in the entry region 12 and in the transition region 13. In other words, the shifting groove 11 with the groove width B transitions smoothly in the entry region 12 to the shifting groove 11 with the groove width B in the transition region 13.

[0046] The narrowing portion 19 of the respective groove flank 15 is formed in sections in the transition region 13 along the respective shifting groove 11. The narrowing portion 19 is arranged on the entry region side in the transition region 13. Adjacent to the narrowing portion 19 is a parallel flank region 23 of the groove flank 15 and the other groove flank 18. The parallel flank region 23 runs along the shifting groove 11 towards the pointed end 28 of the web 24, in such a manner that the groove width B is constant in this portion. This is clearly visible in FIGS. 1 and 2.

[0047] The following describes a displacement action of the shift gate 10 in the displacement direction, i.e. along the longitudinal axis L.

[0048] During a displacement action of the shift gate 10, an actuator pin of an actuator, in particular a double actuator, enters one of the shifting grooves 11 in the entry region 12. The shift gate 10 rotates about its longitudinal axis L in this case. In the entry region 12, the shifting groove 11 has a groove width B that is of a corresponding size in relation to a diameter of the actuator pin, so that a collision with one of the groove flanks 15, 18 is prevented. The actuator pin is located in the entry region 12 in the shifting groove 11 at an off-center track position. Due to the narrowing portion 19 of the groove flank 15 of the web 24, the shift gate 10 is shifted in the transition region 13 on the entry region side, in such a manner that the actuator pin comes into contact with the other groove flank 18.

[0049] The actuator pin cooperates with the other groove flank 18 in such a manner that the shift gate 10 is displaced in the displacement direction. The displacement movement of the gate 10 ends when the two shifting grooves 11 merge into the common groove 14. The actuator pin enters the common groove 14 in the exit region 27 and abuts a braking flank 29, in particular a sidewall, of the common groove 14. The actuator pin is then ejected by the ascending common groove 14, i.e. radially extended from the common groove 14. The displacement action of the shift gate 10 is complete. Another displacement action can be carried out in the opposite displacement direction.

LIST OF REFERENCE SIGNS

[0050] 10 shift gate [0051] 11 shifting grooves [0052] 12 entry region [0053] 13 transition region [0054] 14 common groove [0055] 15 groove flank [0056] 16 entry flank [0057] 17 runoff flank [0058] 18 other groove flank [0059] 19 narrowing portion [0060] 21 curvature [0061] 22 transition [0062] 23 parallel flank region [0063] 24 web [0064] 25 sidewall [0065] 26 outer wall [0066] 27 exit region [0067] 28 pointed end [0068] 29 braking flank [0069] B groove width of the shifting grooves in the transition region [0070] B groove width of the shifting grooves in the entry region [0071] B groove width of the shifting grooves in the exit region [0072] L longitudinal axis of the shift gate