Plate link chain

Abstract

A plate link chain for a continuously variable transmission in a motor vehicle comprising chain links. The chain links have link plates coupled to one another by pairs of rocker pins and at least two different sprocket pitches. At least one absorption mass is arranged between two pairs of rocker pins in an absorption space within a link plate inner contour.

Claims

1. A plate link chain for a continuously variable transmission in a motor vehicle, comprising: chain links having link plates coupled to one another by pairs of rocker pins and having at least two different sprocket pitches, wherein at least one absorption mass is arranged between two pairs of rocker pins in an absorption space within a link plate inner contour of one of the link plates and no absorption masses are installed in an outer link plate of the plate link chain.

2. The plate link chain as claimed in claim 1, wherein the at least one absorption mass is arranged between the two pairs of rocker pins within the link plate inner contour, and has a defined play in a direction transverse to a chain longitudinal direction, such that the at least one absorption mass can perform absorption movements in the direction transverse to the chain longitudinal direction during an operation of the plate link chain.

3. The plate link chain as claimed in claim 2, wherein the defined play in the direction transverse to the chain longitudinal direction varies over the link plates of the plate link chain.

4. The plate link chain as claimed in claim 1, wherein the at least one absorption mass is arranged in such a way that the at least one absorption mass is prevented from falling out of the absorption space.

5. The plate link chain as claimed in claim 1, wherein the absorption mass is arranged in a double link plate.

6. The plate link chain as claimed in claim 1, wherein the at least one absorption mass is approximately of a same thickness as the link plate or thicker than the link plate.

7. The plate link chain as claimed in claim 1, wherein the at least one absorption mass is of plate-shaped design.

8. The plate link chain as claimed in claim 1, wherein the absorption mass is of round, oval, ball-shaped or spherical design or of polygonal design with rounded corners.

9. The plate link chain as claimed in claim 1, wherein a plurality of absorption masses are arranged in the absorption space.

10. The plate link chain as claimed in claim 1, wherein each sprocket pitch in the at least two different sprocket pitches corresponds to a spacing between two pairs of rocker pins within the inner link plate contour in a chain longitudinal direction.

11. A plate link chain for a continuously variable transmission in a motor vehicle, comprising: a plurality of link plates coupled to one another by pairs of rocker pins and having at least two link plates of different length, wherein: each link plate includes an absorption space arranged between two pairs of rocker pins at least one absorption mass is arranged within the absorption space of one of the link plates in such a manner that the absorption mass can move freely to a limited extent and no absorption masses are installed in an outer link plate of the plate link chain.

12. The plate link chain as claimed in claim 11, wherein the at least one absorption mass is sized and arranged in the absorption space in such a way that the at least one absorption mass substantially fills the absorption space.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further advantages, features and details of the present disclosure will become apparent from the following description, in which various illustrative embodiments are described in detail with reference to the drawing, in which:

(2) FIG. 1 shows a segment of a plate link chain with three shorter link plates;

(3) FIG. 2 shows a segment of a plate link chain with one shorter and two longer link plates;

(4) FIG. 3 shows one of the shorter link plates from FIG. 1 in isolation in plan view;

(5) FIG. 4 shows one of the longer link plates from FIG. 2 in isolation in plan view;

(6) FIG. 5 shows perspective illustrations of various embodiments of absorption masses for use in a shorter link plate of the kind illustrated in FIG. 3;

(7) FIG. 6 shows perspective illustrations of various embodiments of absorption masses for use in a longer link plate of the kind illustrated in FIG. 4;

(8) FIG. 7 shows a segment of a plate link chain in a triplet arrangement with double link plates, and

(9) FIG. 8 shows a similar illustration to that in FIG. 3 to illustrate a sprocket pitch and dimensions of the link plate.

DETAILED DESCRIPTION

(10) FIG. 1 illustrates a segment of a plate link chain 1 having link plates 3, 4, 5 in plan view. Pairs of rocker pins 8, 9 are used to connect the link plates 3, 4, 5 to one another and to other link plates (not visible or not illustrated) of the plate link chain 1. Each pair of rocker pins 8, 9 comprises two rocker pins and is used to form a rocker joint.

(11) In principle, the plate link chain 1 can be embodied in the same way or in a similar way to the plate link chain described in German Laid-Open Application DE 100 47 979 A1. The plate link chain 1 is used in a continuously variable cone pulley transmission of the kind which has likewise been disclosed in said laid-open application.

(12) The plate link chain 1 in FIG. 1 comprises only link plates 3, 4, 5 with the same sprocket pitch. The plate link chain 1 is therefore also referred to as a single-pitch chain or as an equal-pitch chain. The link plates 3, 4, 5 are preferably shorter link plates, which are also referred to as a link plates. An arrow 11 is used to denote a running radius of the plate link chain 1. Bending angles of the plate link chain 1 are denoted by double arrows 14 and 15.

(13) FIG. 2 illustrates a segment of a plate link chain 21 having link plates 23, 24, 25 in plan view. Pairs of rocker pins 28, 29 are used to connect the link plates 23, 24, 25 to one another and to other link plates (not visible or not illustrated) of plate link chain 21. Each pair of rocker pins 28, 29 comprises two rocker pins and is used to form a rocker joint.

(14) In principle, plate link chain 21 can be embodied in the same way or in a similar way to the plate link chain described in German Laid-Open Application DE 100 47 979 A1. Plate link chain 21 is used in a continuously variable cone pulley transmission of the kind which has likewise been disclosed in said laid-open application.

(15) Link plate 23 is a shorter link plate or a link plate of the kind which is also used in the plate link chain 1 in FIG. 1. Link plates 24 and 25 are longer link plates, which are also referred to as b link plates. Plate link chain 21 thus contains link plates with different sprocket pitches. The longer link plates 24, 25 have a larger sprocket pitch than the shorter link plate 23.

(16) An arrow 31 is used to denote a running radius of plate link chain 21. Bending angles of plate link chain 1 are denoted by double arrows 34 and 35.

(17) The shorter link plate 4, which is illustrated in isolation in FIG. 3, comprises a left-hand link plate side bar 42 and a right-hand link plate side bar 43. The link plate side bars 42 and 43 are connected integrally to one another at the top by an upper link plate bar 44. At the bottom, the two link plate side bars 42 and 43 are connected to one another by a lower link plate bar 45.

(18) The shorter link plate 4, which is also referred to as a short link plate, comprises an opening 48 having an inner contour 49. The opening 48 having the inner contour 49 is used to accommodate the two pairs of rocker pins 8 and 9. A free space 50 between the two pairs of rocker pins 8, 9 within the inner contour 49 is used to accommodate at least one absorption mass (not illustrated in FIG. 3). The free space is therefore also referred to as absorption space 50.

(19) The longer link plate 24, which is illustrated in isolation in FIG. 4, comprises a left-hand link plate side bar 52 and a right-hand link plate side bar 53. Link plate side bars 52 and 53 are connected integrally to one another at the top by an upper link plate bar 54. At the bottom, the two link plate side bars 52 and 53 are connected to one another by a lower link plate bar 55.

(20) The longer link plate 24, which is also referred to as a long link plate, comprises an opening 58 having an inner contour 59. The opening 58 having the inner contour 59 is used to accommodate the two pairs of rocker pins 28 and 29. A free space 60 between the two pairs of rocker pins 28, 29 within the inner contour 59 is used to accommodate at least one absorption mass (not illustrated in FIG. 4). The free space is therefore also referred to as absorption space 60.

(21) Various embodiments of the absorption masses 61 to 71 are illustrated in perspective in FIG. 5. The absorption masses 61 to 71 are intended for arrangement in the absorption space 50 of the shorter link plate 4, which is illustrated in FIG. 3. The absorption masses 61 to 71 are of substantially plate-type design and have approximately the same thickness as the link plate 4 in FIG. 3.

(22) Depending on the location of installation, the absorption masses 61 to 71 can also have a greater thickness than the link plate 4 illustrated in FIG. 3. In particular, the greater thickness of the absorption masses 61 to 71 is used to prevent unwanted falling of the absorption mass out of absorption space 50 during the operation of the plate link chain.

(23) Absorption mass 61 has substantially the shape of a diamond with rounded corners. Absorption mass 62 has substantially the shape of a star with rounded corners. Absorption mass 63 has substantially the shape of a rectangle with semi-oval extensions on the short sides of the rectangle.

(24) Absorption mass 64 has substantially the shape of a rectangle with rounded ends. Absorption mass 65 has approximately the same shape as absorption mass 63 but is of shorter design.

(25) Absorption masses 66 and 67 have the shape of circular plates and are arranged together in the absorption space 50 of link plate 4. Absorption mass 68 has the shape of a circular plate and can be arranged alone in the absorption space 50 of link plate 4.

(26) Absorption masses 69 to 71 have the shape of balls. The two absorption masses 69 and 70 can be arranged together in the absorption space 50 of link plate 4. The ball-shaped absorption mass 71 is arranged alone in absorption space 50.

(27) Various embodiments of absorption masses 81 to 91 are illustrated in perspective in FIG. 6. Absorption masses 81 to 91 are intended for arrangement in the absorption space 60 of the longer link plate 24, which is illustrated in FIG. 4. Absorption masses 81 to 91 are of substantially plate-type design and have approximately the same thickness as the link plate 24 in FIG. 4.

(28) Depending on the location of installation, absorption masses 81 to 91 can also have a greater thickness than the link plate 24 illustrated in FIG. 4. In particular, the greater thickness of absorption masses 81 to 91 is used to prevent unwanted falling of the absorption mass out of absorption space 60 during the operation of the plate link chain.

(29) Absorption mass 81 has substantially the shape of a diamond with rounded corners. Absorption mass 82 has substantially the shape of a star with rounded corners. Absorption mass 83 has substantially the shape of a rectangle with semi-oval extensions on the short sides of the rectangle.

(30) Absorption mass 84 has substantially the shape of a rectangle with rounded ends. Absorption mass 85 has approximately the same shape as absorption mass 83 but is of shorter design and has larger rounding radii in the corners.

(31) Absorption masses 86 and 87 have the shape of circular plates and are arranged together in the absorption space 60 of link plate 24. Absorption mass 88 has the shape of a circular plate and can be arranged alone in the absorption space 60 of link plate 24.

(32) Absorption masses 89 to 91 have the shape of balls. The two absorption masses 89 and 90 can be arranged together in the absorption space 60 of link plate 24. The ball-shaped absorption mass 91 is arranged alone in absorption space 60.

(33) FIG. 7 shows a plate link chain 101 having shorter and longer link plates in a triplet construction. The triplet construction is also referred to as a group of three plates. The longer and shorter link plates or chain links have different pitches in order to allow randomization.

(34) Plate link chain 101 comprises four double link plates 104 to 107 in the segment illustrated. The double link plates 104 to 107 each comprise two identical link plates. The double link plates 104 to 107 have absorption spaces of the kind denoted by 50 and 60 in FIGS. 3 and 4.

(35) Absorption masses that are twice as thick as those installed in individual link plates can be installed in the absorption spaces of the double link plates 104 to 107. This reduces the risk that they would fall or slip out of the respective absorption space.

(36) FIG. 8 illustrates the shorter link plate 4 from FIG. 3 with double arrows 111, 112 and 113 to illustrate size ratios. Double arrow 111 illustrates a sprocket pitch, which is also referred to as pitch.

(37) Double arrow 112 illustrates a width of an absorption mass or of an absorption space between the pairs of rocker pins 8 and 9. Double arrow 113 illustrates a height of the absorption mass or of the absorption space within the inner contour 49 of link plate 4.

(38) A ratio between the width 112 and the height 113 of the absorption mass to the pitch 111 of link plate 4 should vary only between 0.5 and 1.5. The best results were obtained at these values in tests and studies carried out in the context of the present disclosure.

(39) By arranging the absorption masses in the absorption spaces, it is possible, in particular, to achieve acoustic advantages through damping/absorption. Moreover, the chain strength of the plate link chain can be increased by the absorption masses in the absorption spaces. Among the advantages thereby achieved is that part of a guide and/or bending tips on the link plates can be eliminated.

(40) If required, the absorption masses can also be installed together with conventional slide rails. By means of the absorption masses, the mass distribution can be varied in any desired manner. Absorption masses can advantageously be installed at all points in the plate link chain.

LIST OF REFERENCE SIGNS

(41) 1 plate link chain 3 link plate 4 link plate 5 link plate 8 pair of rocker pins 9 pair of rocker pins 11 arrow 14 double arrow 15 double arrow 21 plate link chain 23 link plate 24 link plate 25 link plate 28 pair of rocker pins 29 pair of rocker pins 31 arrow 34 double arrow 35 double arrow 42 left-hand link plate side bar 43 right-hand link plate side bar 44 upper link plate bar 45 lower link plate bar 48 opening 49 inner contour 50 absorption space 52 left-hand link plate side bar 53 right-hand link plate side bar 54 upper link plate bar 55 lower link plate bar 58 opening 59 inner contour 60 absorption space 61 absorption mass 62 absorption mass 63 absorption mass 64 absorption mass 65 absorption mass 66 absorption mass 67 absorption mass 68 absorption mass 69 absorption mass 70 absorption mass 71 absorption mass 81 absorption mass 82 absorption mass 83 absorption mass 84 absorption mass 85 absorption mass 86 absorption mass 87 absorption mass 88 absorption mass 89 absorption mass 90 absorption mass 91 absorption mass 101 plate link chain 104 double link plate 105 double link plate 106 double link plate 107 double link plate 111 double arrow 112 double arrow 113 double arrow