PULL OR PUSH ROD OR LOCKING NUT FOR A MOLDING MACHINE

Abstract

A pull or push rod for a molding machine having a groove. The groove is suitable for forming a positive-locking connection with a locking nut, by which positive-locking connection forces are transmittable between the locking nut and the pull or push rod. The groove has a groove cross-section, has at least two groove flanks, and has a groove base. The at least two groove flanks, viewed in the groove cross-section, each transition with at least one transition curvature into the groove base. The groove base in the groove cross-section is at least partially formed as a curvature, and the curvature of the groove base differs from the transition curvatures of the groove flanks.

Claims

1. A pull or push rod for a molding machine having at least one groove, wherein the at least one groove is suitable for forming a positive-locking connection with a locking nut, by means of which positive-locking connection, forces are transmittable between the locking nut and the pull or push rod, wherein the at least one groove: has a groove cross-section, has at least two groove flanks and has a groove base, wherein the at least two groove flanks, viewed in the groove cross-section, each transition with at least one transition curvature into the groove base, wherein the groove base in the groove cross-section is at least partially formed as a curvature, wherein the curvature of the groove base differs from the transition curvatures of the groove flanks.

2. The pull or push rod according to claim 1, wherein the pull or push rod has a rotationally symmetrical base body.

3. A locking nut for a molding machine with at least one groove, wherein the at least one groove is suitable for forming a positive-locking connection with a pull or push rod, by means of which positive-locking connection, forces are transmittable between the locking nut and the pull or push rod, wherein the at least one groove: has a groove cross-section, has at least two groove flanks and has a groove base, wherein the at least two groove flanks, viewed in the groove cross-section, each transition with at least one transition curvature into the groove base, wherein the groove base in the groove cross-section is formed at least partially as a curvature, wherein the curvature of the groove base differs from the transition curvatures of the groove flanks.

4. The pull or push rod or locking nut according to claim 1, wherein a radius of an imaginary curvature circle at at least one point of curvature of the groove base has a finite value larger than zero, which differs from a radius of an imaginary curvature circle at at least one point of at least one transition curvature of the transitions.

5. The pull or push rod or locking nut according to claim 1, wherein the at least one groove is formed completely or partially circumferentially on the pull or push rod or locking nut.

6. The pull or push rod or locking nut according to claim 1, wherein at least a first one of the at least two groove flanks has an angle () of 70 to 110 degrees, preferably 80 to 100 degrees, particularly preferably 90 degrees, with respect to a surface of the pull or push rod or a surface of an imaginary core drilling of the locking nut.

7. The pull or push rod or locking nut according to claim 1, wherein a second of the at least two groove flanks has an angle () of 70 to 150 degrees, preferably 88 to 120 degrees, particularly preferably 90 degrees, with respect to a surface of the pull or push rod or a surface of an imaginary core drilling of the locking nut.

8. The pull or push rod or locking nut according to claim 1, wherein the at least one groove in a thread-like manner wraps around a surface of the pull or push rod or a surface of an imaginary core drilling of the locking nut.

9. The pull or push rod or locking nut according to claim 1, wherein the groove has an incline which runs parallel to a central axis of the pull or push rod or the locking nut, and is at least greater than a groove width of the at least one groove per rotation, preferably corresponding to two to four times the groove width per rotation.

10. The pull or push rod or locking nut according to claim 1, wherein at least one transition curvature of the at least two groove side walls transitions tangentially into the groove base, preferably transitions tangentially into the curvature of the groove base.

11. The pull or push rod or locking nut according to claim 1, wherein the transition curvatures are designed as transition radii.

12. The pull or push rod or locking nut according to claim 11, wherein the at least one transition radius of a first groove side wall to the at least one transition radius (R3) of a second groove side wall (3) of the at least two groove side walls (2, 3), is in a ratio of 1 to 2, preferably in a ratio of 1.3 to 1.5, particularly preferably in a ratio of 1.4.

13. The pull or push rod or locking nut according to claim 11, wherein an outer diameter of the pull or push rod, or a diameter of an imaginary core hole of a locking nut to the at least one transition radius of a first groove side wall of the at least two groove side walls is in a ratio of 30 to 50, preferably in a ratio of 35 to 45.

14. The pull or push rod or locking nut according to claim 11, wherein an outer diameter of the pull or push rod, or a diameter of an imaginary core hole of a locking nut stands in a ratio of 40 to 60, preferably in a ratio of 48 to 58, to the at least one transition radius of a second groove side wall, of the at least two groove side walls.

15. The pull or push rod or locking nut according to claim 1, wherein the curvature of the groove base is designed as a radius.

16. The pull or push rod or locking nut according to claim 11, wherein a ratio between the greater of the amount of at least one transition radius of a first groove side wall, and at least one transition radius of a second groove side wall on the one hand, and a value of the radius of the groove base on the other hand, is 0.3 to 0.8, preferably 0.5 to 0.6.

17. The pull or push rod or locking nut according to claim 15, wherein an outer diameter of the pull or push rod, or a diameter of an imaginary core hole of a locking nut to the radius of the groove base is in a ratio of 10 to 30, preferably in a ratio of 15 to 25.

18. The pull or push rod or locking nut according to claim 11, wherein the radius of the groove base has a finite value greater than zero, differing from the transition radii of the transitions.

19. The pull or push rod or locking nut according to claim 1, wherein a smallest diameter of the pull or push rod at the groove base to an outer diameter of the pull or push rod and/or a diameter of an imaginary core hole of a locking nut to a maximum inner diameter at the groove base is in a ratio of 0.89 to 0.95, preferably in a ratio of 0.89.

20. The pull or push rod or locking nut according to claim 1, wherein at least two grooves are provided, wherein an outer diameter of the pull or push rod, or a diameter of an imaginary core hole of a locking nut, is in a ratio of 5 to 13, preferably in a ratio of 7 to 11, to a pitch of the at least two grooves.

21. The pull or push rod or locking nut according to claim 1, wherein an outer diameter of the pull or push rod, or a diameter of an imaginary core hole of a locking nut, is in a ratio of 15 to 27, preferably in a ratio of 18 to 24, to a groove width.

22. The pull or push rod or locking nut according to claim 1, wherein at least one undercut is provided, wherein the at least one undercut has an undercut cross section, an undercut side wall, and an undercut ramp, wherein the undercut side wall transitions via at least a first undercut transition curvature into an undercut base, and the undercut base transitions via at least a second undercut transition curvature into the undercut ramp, wherein the undercut base, viewed in the undercut cross-section, is formed at least partially as an undercut curvature, wherein the curvature of the undercut base differs from the at least one first, and/or the at least one second undercut transition curvature.

23. The pull or push rod or locking nut according to claim 22, wherein the at least one undercut is formed completely or partially circumferentially on the pull or push rod or locking nut.

24. The pull or push rod or locking nut according to claim 1, wherein the undercut side wall has an angle of 70 to 110 degrees, preferably 80 to 100 degrees, particularly preferably 90 degrees, with respect to a surface of the pull or push rod, or a surface of an imaginary core hole of the locking nut.

25. The pull or push rod or locking nut according to claim 23, wherein the at least one first, or the at least one second undercut transition curvature transitions tangentially into the undercut base, preferably transitions tangentially into the undercut curvature of the undercut base.

26. The pull or push rod or locking nut according to claim 1, wherein a straight section is provided between the at least one first, and/or the at least one second undercut transition curvature and the undercut base, viewed in the undercut cross-section.

27. The pull or push rod or locking nut according to claim 23, wherein the undercut ramp, viewed in the undercut cross section, is designed straight-lined, and has an angle (2) with respect to a surface of the pull or push rod, or a surface of an imaginary core hole of the locking nut, of 175 to 150 degrees, preferably 170 to 160 degrees, particularly preferably 165 degrees.

28. The pull or push rod or locking nut according to claim 23, wherein a radius of an imaginary curvature circle at at least one point of the undercut curvature of the undercut base has a finite value greater than zero, which differs from a radius of an imaginary curvature circle at at least one point of the at least one first undercut transition curvature, and/or from an imaginary curvature circle at at least one point of the at least one second undercut transition curvature.

29. The pull or push rod or locking nut according to claim 23, wherein the at least one first undercut transition curvature is formed as a first undercut transition radius, and the at least one second undercut transition curvature is formed as a second undercut transition radius.

30. The pull or push rod or locking nut according to claim 23, wherein the at least one second undercut transition radius is in a ratio of 20 to 2, preferably in a ratio of 7 to 4, particularly preferably in a ratio of 5.5, to the at least one first undercut transition radius.

31. The pull or push rod or locking nut according to claim 23, wherein the undercut curvature of the undercut base is designed as an undercut radius.

32. The pull or push rod or locking nut according to claim 29, wherein the value of the undercut radius of the undercut base is in a ratio to the at least one first undercut transition radius of 10 to 1, preferably in a ratio of 5 to 2, particularly preferably in a ratio of 3.6.

33. A clamping unit of a molding machine or molding machine having a clamping unit with at least one pull or push rod, and/or at least one locking nut according to claim 1.

34. A clamping unit of a molding machine or molding machine with a clamping unit according to claim 33, wherein one of the at least two groove side walls represents a groove side wall of a pull side, and one of the at least two groove side walls represents a groove side wall of a compression side, wherein the at least one transition radius of the groove side wall of the compression side to the at least one transition radius of the groove side wall of the pull side, which connect the groove side walls to a groove base, are in a ratio of 1 to 2, preferably in a ratio of 1.3 to 1.6, particularly preferably in a ratio of 1.4.

35. A method for producing a pull or push rod or a locking nut for a molding machine, comprising at least the following steps: specification of a desired pulling or compressive force which is transmittable non-destructively with the pull or compression rod or locking nut. selection of a suitable material for the pull or push rod or locking nut specification of a suitable groove geometry, wherein the at least one groove has a groove cross-section, at least two groove side walls and a groove base, wherein the at least two groove side walls, viewed in the groove cross-section, each transition into the groove base with at least one transition curvature, wherein the groove base in the groove cross-section is formed at least partially as a curvature, wherein the curvature of the groove base differs from the transition curvatures of the groove side walls, in particular according to claim 1 specification of the minimum diameter of the pull or push rod or locking nut resulting from the desired pulling or compressive force, the material selected and the specified groove geometry production of pull or push rod or locking nut with the specified diameter and the specified groove geometry from a certain material.

36. The method for producing a pull or push rod or locking nut for a molding machine according to claim 35, wherein the pull or push rod or locking nut is subjected to a coating process.

37. The method for producing a pull or push rod or locking nut for a molding machine according to claim 35, wherein the pull or push rod or locking nut is subjected to a method for changing the material properties.

38. The method for producing a pull or push rod or locking nut for a molding machine according to claim 35, wherein the pull or push rod or locking nut is produced by means of a forming process.

39. The method for producing a pull or push rod or locking nut for a molding machine according to claim 35, wherein the pull or push rod or locking nut is produced by means of a machining process.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0062] Various embodiments of the invention result from the figures as well as the corresponding figure description. In the drawings:

[0063] FIG. 1a, 1b shows a first embodiment of a pull or push rod or locking nut according to invention with detailed view on at least one first groove,

[0064] FIG. 2 shows another embodiment of a pull or push rod or locking nut according to the invention with a detailed view on its groove, and

[0065] FIG. 3 shows a purely exemplary embodiment of a pull or push rod or locking nut according to the invention with an undercut.

DETAILED DESCRIPTION OF THE INVENTION

[0066] FIGS. 1a and 1b show a detailed view of a pull or push rod or locking nut according to the invention with a groove 1 in cross-section. The groove 1 is designed with two groove side walls 2, 3 and a groove base 4. Hereby it can be clearly seen that the groove side wall 2 first runs at a rectangular angle from the surface of the pull or push rod or a surface of the imaginary core hole of the locking nut in the direction of groove base 4, which transitions tangentially into the transition curvature, which in this embodiment is formed as transition radius R1. This transition radius R1 subsequently flows tangentially into the curvature of the groove base 4, which in this exemplary embodiment is designed as radius R2. The groove base 4, designed by the radius R2, subsequently runs tangentially into the second transition curvature, which is designed as transition radius R3, which in turn transitions tangentially into the groove side wall 3. The groove side walls 2, 3 shown in this embodiment are chamfered by a radius R4 at their transition to the surface of the pull or push rod or the surface of the imaginary core hole of the locking nut. Depending on the force to be transmitted by the locking nut or the pull or push rod, the side wall length 5 can be adjusted, or also several grooves 1 can be provided at a distance of 6 from each other.

[0067] It can be seen well from the figures that the design of the groove base 4 as radius R2 makes it possible to reduce the notch effect through the transition radii without this causing a significant deepening of the groove 1.

[0068] FIG. 2 shows a detailed view of a groove 1 of another embodiment of a pull or push rod or locking nut according to the invention. Compared to FIG. 1a or 1b, the groove side wall 3 is here inclined at an angle to the surface of the pull or push rod or the surface of the imaginary core hole of the locking nut. With such an embodiment, as shown in FIG. 2, the incline of the groove side wall 3 can be used to achieve an optimal force transmission. Thus, this groove side wall 3, which is inclined by the angle , can serve as the pull side when in use, and the groove side wall 2 as the compressive side. The groove 1, as shown in FIG. 2, has an incline of 7, so that the at least one groove wraps around a surface of the pull or push rod or a surface of the imaginary core hole of the locking nut in a thread-like manner. In addition, FIG. 1b shows the groove width 8 as well as the outer diameter 9 of the pull or push rod or the diameter 10 of the imaginary core hole of the locking nut.

[0069] FIG. 3 shows a partial view of a pull or push rod or locking nut according to the invention with an undercut 100 in cross-section(in the undercut cross section). Thereby only the undercut 100 is shown, and the at least one groove 1 is blanked out for reasons of clarity. The undercut 100 is designed with an undercut side wall 200, an undercut base 400, and an undercut ramp 300. Thereby the undercut side wall 200 transitions tangentially into a first undercut transition curvature (in this embodiment shown as undercut transition radius R10), which in turn transitions tangentially into the undercut curvature of the undercut base 400 (which in this embodiment is designed as undercut radius R20). The undercut base 400 or undercut radius R20 transitions tangentially into the second transition. This second transition is hereby designed as a two-part transition. First, by a straight-lined section 500, which enters directly into the undercut base 400, which in turn transitions tangentially into the undercut transition curvature (shown here as the undercut transition radius R30), which connects tangentially the straight-lined undercut ramp 300. The undercut ramp 300 is inclined at an angle of 2 to the surface of the pull or push rod or to the surface of an imaginary drilling of the locking nut. The entire undercut has an undercut length 600 and an undercut depth 700. This undercut depth 700 and undercut length 600 can be varied depending on the area of application and loads.

[0070] It can be clearly seen from FIG. 3 that the design of undercut base 400 as undercut radius R20 allows to reduce the notch effect by means of the undercut transition radii without this leading to a significant deepening of undercut 100.

LIST OF REFERENCE SIGNS

[0071] 1 groove

[0072] 2 groove side wall

[0073] 3 groove side wall

[0074] 4 groove base

[0075] 5 side wall length

[0076] 6 distance

[0077] 7 incline

[0078] 8 groove width

[0079] 9 outer diameter of pull or push rod

[0080] 10 diameter of the imaginary core hole of the locking nut

[0081] R1 transition radius

[0082] R2 radius

[0083] R3 transition radius

[0084] R4 radius

[0085] angle

[0086] angle

[0087] 100 undercut

[0088] 200 undercut side wall

[0089] 300 undercut ramp

[0090] 400 undercut base

[0091] 500 straight section

[0092] 600 undercut length

[0093] 700 undercut depth

[0094] R10 undercut transition radius

[0095] R20 undercut radius

[0096] R30 undercut transition radius

[0097] 2 angles