WO2022100777A1 - Plate-link chain and pulley-based continuously variable transmission - Google Patents

Abstract

The invention relates to a plate-link chain (1) for a pulley-based continuously variable transmission. According to the invention, each chain link group (30) of the plate-link chain has a width (B) of exactly 33 link plates (2) having a specified link plate width (b1), wherein the central chain link (3-2) has link plates (2) in link plate positions 1 (KLP1), 5 (KLP5), 8 (KLP8), 11 (KLP11), 14 (KLP14), 17 (KLP17), 20 (KLP20), 23 (KLP23), 26 (KLP26), 29 (KLP29) and 33 (KLP33), while a first chain link (3-1) adjoining the central chain link (3-2) has link plates (2) in link plate positions 3 (KLP3), 4 (KLP4), 9 (KLP9), 12 (KLP12), 15 (KLP15), 18 (KLP18), 21 (KLP21), 24 (KLP24), 27 (KLP27), 28 (KLP28) and 32 (KLP32), and a second chain link (3-3) adjoining the central chain link (3-2) has link plates (2) in link plate positions (KLP) 2 (KLP2), 6 (KLP6), 7 (KLP7), 10 (KLP10), 13 (KLP13), 16 (KLP16), 19 (KLP19), 22 (KLP22), 25 (KLP25), 30 (KLP30) and 31 (KLP31).

Description

Link chain and pulley pulley transmission

The present invention relates to a plate-link chain for a conical pulley belt transmission with infinitely variable transmission ratio, whose rocker joints connecting the individual chain links formed by plate assemblies with several link plates are designed as pairs of rocker pressure pieces with rolling surfaces supported on one another and pushed into recesses in the chain plates. In this case, in each case three chain links arranged adjacently in the direction of rotation of the link chain form a chain link group. The link chain is formed by a large number of chain link groups placed directly next to one another in the direction of rotation, the link plates within a chain link group being arranged point-symmetrically to the center point of the chain link group over the entire width of the link chain. Furthermore, the invention relates to a conical pulley belt transmission for a motor vehicle that can be steplessly adjusted in terms of transmission ratio.

A link chain is used as a looping means in a mechanically adjustable continuously variable transmission of a motor vehicle. A mechanically adjustable continuously variable transmission, known as a Continuously Variable Transmission, or CVT for short, allows the ratio to be continuously adjusted without any interruption in traction. The link chain has chain links lined up next to each other, which are connected by pressure pieces. In the case of the chains currently on the market, the pressure pieces are axially secured using securing elements, for example short pieces of wire.

The link chain (or CVT link chain or CVT chain) has the following properties:

It achieves low consumption and excellent driving dynamics.

This is possible thanks to the rocker link construction of the CVT chain, with the small Running circles on the cone pulleys and thus a high gear spread can be realized.

High torques can be transmitted with the CVT chain. Thicker shackles, which can be used optionally, on the outside of the strand even out the stress distribution.

The element is characterized by low internal friction losses due to the rolling of the rocker pressure pieces and thus guarantees good transmission efficiency.

The CVT chain is insensitive to track misalignment thanks to the optionally crowned end faces of the rocker pressure pads. In combination with optionally curved conical pulleys, the additional component of the toe offset that inevitably occurs during adjustment is reduced. Furthermore, the CVT chain is insensitive to pulley set deformation under load, angular errors and relative torsion between the fixed and movable conical pulley. It therefore does not require any ball guides for the axially movable conical pulleys.

When using the CVT chain, there are low axial forces on the primary pulley set. This means that low hydraulic pressure can be used for the given cylinder areas, another advantage in terms of transmission efficiency.

The strand can be designed as a three-tab joint, thus enabling a short basic division. With a short chain link, only the shackle of a plate is located between the adjacent joints.

A second lug length makes it possible to achieve favorable acoustic behavior by mathematically optimizing the pitch sequence of long and short lugs. EP 2 587 091 B1 discloses a link chain for a continuously variable transmission of a motor vehicle, wherein an element assembly of the link chain is formed by three consecutive chain elements, the arrangement pattern in the respective element assemblies being the same and the number of links in three link units contained in each element assembly is 9, 8 and 8, respectively.

The object of the invention is to provide a link chain or a continuously variable transmission with a link chain, with this(these) being further optimized with regard to wear properties. Advantageously, a reduced load on the link plates and the rocker pressure pieces should be achieved by the invention.

This object is achieved by a link chain for a continuously adjustable conical pulley transmission with the features of patent claim 1 and by a conical pulley continuously variable transmission with the features of patent claim 4. In a plate-link chain designed according to the invention, the individual chain links formed by plate assemblies with several link plates are connecting rocker joints as pairs of in Recesses of the link plates inserted rocker pressure pieces with rolling surfaces supported on each other, with three chain links arranged adjacent in the circumferential direction of the plate link chain forming a chain link group. The link chain is formed by a large number of chain link groups placed directly next to one another in the direction of rotation, the link plates within a chain link group being arranged point-symmetrically to the center point of the chain link group over the entire width of the link chain.

According to the invention, each chain link group of the link chain has a width of exactly thirty-three link plates of a predetermined link plate width. The middle chain link with link plates occupies the first link plate position, the fifth link plate position, the eighth link plate position, the eleventh link plate position, the fourteenth link plate position, the seventeenth link plate position, the twentieth link plate position, the twenty-third link plate position, the twenty-sixth link plate position, the twenty-ninth link plate position, and the thirty-third link plate position. Furthermore, a first chain link with link plates arranged immediately adjacent to the middle chain link occupies the link plate positions of the third link plate position, the fourth link plate position, the ninth link plate position, the twelfth link plate position, the fifteenth link plate position, the eighteenth link plate position, the twenty-first link plate position, the twenty-fourth link plate position, the twenty-seventh link plate position , the twenty-eighth link plate position, and the thirty-second link plate position. Finally, a second chain link with link plates arranged immediately adjacent to the middle chain link (in the other direction) occupies the link plate positions of the second link plate position, the sixth link plate position, the seventh link plate position, the tenth link plate position, the thirteenth link plate position, the sixteenth link plate position, the nineteenth link plate position, the the twenty-second link plate position, the twenty-fifth link plate position, the thirtieth link plate position, and the thirty-first link plate position. This has the advantage that the individual link plates as well as the rocker pressure pieces of link chains of different widths are exposed to a significantly reduced load. The plate forces can be distributed very evenly by the construction described above and the load on individual elements can thus be reduced, whereby a longer service life of the plate chain is achieved with the same load (torque transmission). Alternatively, such a modified link chain can also transmit increased torque with an unchanged service life.

First, the individual elements of the claimed subject matter of the invention are explained in the order in which they are mentioned in the set of claims or their meaning, and particularly preferred embodiments of the subject matter of the invention are described below. A link plate is an essential part of a link chain. The link plate is an elongate plate-like plate that has one or more through openings transverse to its longitudinal extension and the plate surface for the passage and acceptance of so-called rocker pressure pieces (also referred to as pressure pieces or rocker pieces).

In addition to the link plate, a cradle pressure piece is an essential part of the link chain. The cradle pressure piece forms a so-called cradle joint together with the passage opening of the link plate through which it is guided. Due to the rocker joint design of the link chain, it is possible to realize small running circles on the cone pulleys and thus a high gear spread.

A part or a structural configuration is referred to as a securing element, which serves to ensure that the link plates cannot move laterally axially from the pressure pieces. In the simplest case, the pressure pieces are secured at least at one of their axial ends with a welded piece of wire or the like.

Further advantageous refinements of the invention are specified in the dependently formulated claims. The features listed individually in the dependent claims can be combined with one another in a technologically meaningful manner and can define further refinements of the invention. In addition, the features specified in the claims are specified and explained in more detail in the description, with further preferred configurations of the invention being presented.

According to an advantageous embodiment of the invention it can be provided that at least a plurality directly, transverse to

Chain longitudinal direction of immediately adjacent chain link positions within a chain link of the link chain, the link plates of a Chain link for the plurality of chain link positions are formed by a single link plate, so that there are link plates with a first link plate width and with a different from the first link plate width second link plate width within a chain link group. The advantage of this configuration is that the loads on the components of the link chain, in particular the total friction losses between the link plates, of the link chain are further reduced.

According to a further preferred development of the invention, it can also be provided that each chain link group is formed by eighteen link plates with the smallest link plate width, whereby the effort in terms of assembly and storage of parts can be further optimized.

In addition, the object on which the invention is based is achieved by a continuously adjustable conical pulley belt transmission comprising a first pair of conical pulleys arranged on a first shaft and a second pair of conical pulleys arranged on a second shaft and a link chain arranged for torque transmission between the first pair of conical pulleys and the second pair of conical pulleys, wherein the Plate chain according to the invention, as described above, is formed.

Advantageously, the conical disks of the first pair of conical disks and the conical disks of the second pair of conical disks each have a conical disk angle that is greater than seven angular degrees and smaller than thirteen angular degrees, which is measured in particular between nine angular degrees and eleven point five angular degrees. This achieves an optimized interaction with the link chain constructed according to the invention.

Furthermore, the conical pulley belt transmission can also be further developed in such a way that the conical pulleys of the first pair of conical pulleys and the conical pulleys of the second pair of conical pulleys are made of case-hardened steel called CrMo or CoNiMo, which is also formed a low-wear interaction of the link chain constructed according to the invention with the conical pulleys of the transmission is conducive.

According to a further preferred embodiment of the conical pulley belt drive, it can be provided that the conical pulley belt drive with its pairs of conical pulleys is designed to be driven on the input side at a speed of approximately 4000 rpm to 6500 rpm and on the output side at a speed of approximately 12000 rpm. so that an operation is guaranteed within which a wear-reduced operation of the link chain is made possible.

Finally, the invention can also be implemented in an advantageous manner such that the driving conical disk pair is designed to transmit a torque of at least 150 Nm. Advantageously, the cone pulley pair is optimized for a torque range up to a maximum of 460 Nm.

The invention and the technical environment are explained in more detail below with reference to the figures. It should be pointed out that the invention should not be limited by the exemplary embodiments shown. In particular, unless explicitly stated otherwise, it is also possible to extract partial aspects of the facts explained in the figures and to combine them with other components and findings from the present description and/or figures. In particular, it should be pointed out that the figures and in particular the proportions shown are only schematic. The same reference symbols designate the same objects, so that explanations from other figures can be used as a supplement if necessary.

Show it:

FIG. 1 shows a partial section of a link chain according to the prior art in a perspective view, Figure 2 shows a conventional link chain in a section in a plan view in the upper representation and a sectional view along a rocker pressure piece of a link chain in the lower representation, with the structure and the designations of the individual elements of a link chain being discussed on the basis of these schematic representations,

Figure 3 shows the basic structure of a chain link group in a schematic representation, in a plan view, with the upper representation showing three individual chain links and the lower representation showing a combination of these three chain links in the form of a chain link group consisting of the three chain links,

FIG. 4 shows a link chain constructed according to the invention in a partial section in a top view, and

FIG. 5 shows a schematic representation of a CVT transmission unit with a conical pulley belt transmission, integrated into the drive train of a hybrid vehicle.

FIG. 1 shows a link chain 1 according to the prior art for a mechanically adjustable continuously variable transmission for a motor vehicle. This plate link chain 1 comprises a plurality of link plates 2, a plurality of rocker pressure pieces 5 and a plurality of securing elements 50, the rocker pressure pieces 5 for the articulated connection of the link plates 2 transverse to a longitudinal direction of the plate link chain 1 in recesses 20 of the link plates 2 to form rocker joints 4 are arranged, and the link plates 2 are arranged secured via the securing elements 50 against axial migration from the rocker pressure pieces 5 .

FIG. 2 shows a detail of a conventional link chain 1 in the top view and a sectional view in the bottom view along a rocker pressure piece 5 of a rocker joint 4 of a link chain 1, the structure and designations of the individual elements of a link chain 1 being intended to be clarified on the basis of these schematic representations. In the upper illustration it is easy to see how the individual chain links 3; 3- 1 , 3-2, 3-3 arranged one behind the other within the link chain 1 form individual chain link groups 30 and the chain link groups 30 of identical construction arranged one behind the other form the link chain 1 .

In the illustration below, the arrangement of the individual link plates 2 at corresponding successive link plate positions KLP, from a first link plate position KLP1 to a last link plate position KLPn, over the width B of the link plate assembly can be seen. The width B of the chain link assembly corresponds approximately to the inner distance between two securing elements 50 on the rocker pressure piece 5 shown. The outer chain width b, also shown, corresponds approximately to the axial length of a rocker pressure piece 5 - measured in its center axis.

Figure 3 shows the basic structure of a chain link group 30 in a schematic representation, in a top view. In this case, three isolated chain links 3; 3-1, 3-2, 3-3 and the lower illustration shows a combination of these three chain links 3-1, 3-2, 3-3 in the form of one of the three chain links 3-1, 3-2, 3 -3 existing chain link group 30 shown as part of a link chain 1. The individual chain links 3 are via rocker joints 4 - formed by the two pressure pieces 5 of adjacent chain links 3, which penetrate the openings 20 within the link plates 2 of a chain link 3, linked or connected to one another. A link chain 1 is composed of a large number of chain link groups 30 of the same structure which are arranged one behind the other and are connected to one another. The illustration below shows that the link chain 1 has a plurality of link links 2 over its width (link assembly width) B transversely to the longitudinal extension of the link chain 1 . Each link plate 2 is assigned a link plate position KLP seen over the width B of the link chain 1 - represented here by the link plate positions from the first link plate position "one" KLP1 (below) to the last link plate position "n" KLPn (above). In the area of the axial ends of the rocker pressure pieces 5, these each have a securing element 50, via which a lateral loss of link plates 2 is prevented.

FIG. 4 shows a link chain 1 constructed according to the invention in a partial section in a plan view. The link chain 1 shown is designed for a conical pulley belt transmission 100 (see FIG. 5) of a motor vehicle that can be steplessly adjusted in terms of transmission ratio. The individual chain links 3 formed by plate assemblies with several link plates 2 connecting rocker joints 4 are configured as pairs of rocker pressure pieces 5 pushed into recesses 20 of the link plates 2 with rolling surfaces W (FIG. 1) supported on one another. Every three chain links 3 arranged adjacent to each other in the direction of rotation of the link chain 1 form a chain link group 30, the link chain 1 being formed by a large number of chain link groups 30 placed directly next to one another in the direction of rotation, and the link links 2 within a chain link group 30 over the entire width of the link chain 1 or are arranged point-symmetrically to the center point P of the chain link group 30 seen over the width B of the plate assembly. Each chain link group 3; 3-1, 3-2, 3-3 has a width B of exactly thirty-three link plates 2 of a predetermined link plate width b1, the middle chain link 3-2 of the chain link group 30 link plates 2 of the predetermined link plate width b1 on the link plate positions one KLP1, five KLP5 , eight KLP8, eleven KLP11, fourteen KLP14, seventeen KLP17, twenty KLP20, twenty-three KLP23, twenty-six KLP26, twenty-nine KLP29 and thirty-three KLP33. A first chain link 3-1 arranged immediately adjacent to the middle chain link 3-2 has link plates 2 on the link plate positions three KLP3, four KLP4, nine KLP9, twelve KLP12, fifteen KLP15, eighteen KLP18, twenty-one KLP21, twenty-four KLP24, twenty-seven KLP27, twenty-eight KLP28 and thirty-two KLP32, and a second chain link 3-3 arranged immediately adjacent (in the other direction) to the middle chain link 3-2 occupies link plates 2 on the link plate positions two KLP2, six KLP6, seven KLP7, ten KLP10, thirteen KLP13, sixteen KLP16 , nineteen KLP19, twenty-two KLP22, twenty-five KLP25, thirty KLP30 and thirty-one KLP31. Every Chain link group 3 is formed by thirty-three link plates 2 of the same link plate width b1.

Figure 5 shows Figure shows a CVT transmission unit with a conical pulley belt transmission 100, integrated into the drive train of a hybrid vehicle in a schematic representation. The conical pulley transmission 100 (also referred to as a variator) comprises a first conical pulley pair 300 with a first conical pulley 301 designed as a fixed pulley and with a second conical pulley 302 configured as a moving pulley arranged to be axially displaceable and a second conical pulley set 500 with a first conical pulley 501 designed as a fixed pulley and an axial one slidably arranged second conical disk 502 designed as a displacement disk, as well as the two conical disk sets 300; 500 connecting means designed as a link chain 1. The CVT transmission unit also includes an actuator unit AE, by means of which the displacement disks 302; 502 of first and second pulley sets 300; 500 are axially adjustable in such a way that a desired translation between the first set of conical disks 300 and the second set of conical disks 500 can be set. The first set of conical pulleys 300 can be driven via an electric machine EM and/or an internal combustion engine BKM. Between the internal combustion engine BKM and the driven variator, the electric machine EM is integrated into the drive train via a separating clutch arranged on the internal combustion engine side and a separating clutch arranged on the variator side. The second set of conical pulleys 500 is connected to a drive axle of the motor vehicle via a transmission unit. The actuator unit AE is controlled via a control unit that is not shown.

FIG. 5 also shows that the conical disks 301, 302 of the first conical disk pair 300 and the conical disks 501, 502 of the second conical disk pair 500 each have a conical disk angle θ1, 2. This is advantageously greater than seven angular degrees and smaller than thirteen angular degrees and particularly preferably between nine angular degrees and eleven point five angular degrees. The invention is not limited to the embodiments shown in the figures. The foregoing description is therefore not to be considered as limiting but as illustrative. The following patent claims are to be understood in such a way that a mentioned feature is present in at least one embodiment of the invention. This does not exclude the presence of other features. If the patent claims and the above description define 'first' and 'second' feature, this designation serves to distinguish between two features of the same type, without specifying a ranking.

Reference character list

1 tab chain

2 chain strap

20 recess

3 chain link

3-1 first chain link

3-2 second chain link

3-3 third chain link

30 chain link group

4 rocker joint

5 rocker pressure piece

W rolling surface

50 fuse element

100 conical pulley belt transmission

200 first shaft (cone pulley belt transmission)

300 first pair of pulleys

301 first pulley of the first pair of pulleys

302 second pulley of the first pair of pulleys

400 second shaft (cone pulley belt transmission)

500 second cone pulley pair

501 first pulley of the second pair of pulleys

502 second pulley of the second pair of pulleys

KLP chain plate position

B Width of the link plate assembly b (middle) width of the pressure piece

01 , 32 sheave angle BKM internal combustion engine

EM electric machine

AE actuator unit

P Center or point of symmetry (to point symmetry of the chain link group)

Claims

Claims link chain (1) for a conical pulley belt transmission with infinitely variable transmission ratio,

- the rocker joints (4) connecting the individual chain links (3) formed by plate sets with several link plates (2) are designed as pairs of rocker pressure pieces (5) pushed into recesses (20) of the link plates (2) with rolling surfaces (W) supported on one another,

- wherein in each case three chain links (3; 3-1, 3-2, 3-3) arranged adjacent in the direction of rotation of the plate-link chain (1) form a chain link group (30),

- wherein the link chain (1) is formed by a large number of chain link groups (30) placed directly next to one another in the direction of rotation,

- and wherein the link plates (2) within a chain link group (30) are arranged point-symmetrically to the center point (P) of the chain link group (30) over the entire width of the link chain (1), characterized in that

- each chain link group (30) has a width (B) of exactly thirty-three link plates (2) of a predetermined link plate width (b1), -- wherein the middle chain link (3-2) has link plates (2) on the link plate positions (KLP) one (KLP1 ), five (KLP5), eight (KLP8), eleven (KLP11), fourteen (KLP14), seventeen (KLP17), twenty (KLP20), twenty-three (KLP23), twenty-six (KLP26), twenty-nine (KLP29) and thirty-three (KLP33 ) proven,

-- wherein a first chain link (3-1) adjacent to the middle chain link (3-2) has link plates (2) on the link plate positions (KLP) three (KLP3), four (KLP4), nine (KLP9), twelve (KLP12), fifteen (KLP15), eighteen (KLP18), twenty-one (KLP21), twenty-four (KLP24), twenty-seven (KLP27), twenty-eight (KLP28), and thirty-two (KLP32), and

-- wherein a second chain link (3-3) adjacent to the middle chain link (3-2) has link plates (2) on the link plate positions (KLP) two (KLP2), six (KLP6), seven (KLP7), ten (KLP10), thirteen (KLP13), sixteen (KLP16), nineteen (KLP19), twenty-two (KLP22), twenty-five

(KLP25), thirty (KLP30) and thirty-one (KLP31). Link chain (1) according to claim 1, characterized in that in at least a plurality of directly adjacent link link positions (KLP) within a chain link (3, 3-1, 3-2, 3-3) of the link chain (1), the link links (2) are formed by a single link plate (2) with an increased link plate width (b2), in particular with twice the link plate width (b2). Link chain (1) according to claim 1, characterized in that each chain link group (30) is formed by eighteen link plates (2) with the smallest link plate width (b1). Continuously variable ratio conical pulley belt transmission (100), comprising a first pair of conical pulleys (300) arranged on a first shaft (200) and a second pair of conical pulleys (500) arranged on a second shaft (400) and one for torque transmission between the first pair of conical pulleys (300) and the second pair of conical disks (500) arranged link chain (1), characterized in that the link chain (1) formed according to one of the preceding claims. Conical pulley transmission (100) according to Claim 4, characterized in that the conical pulleys (301, 302) of the first conical pulley pair (300) and the conical pulleys (501, 502) of the second conical pulley pair (500) each have a conical pulley angle (01, 2) which is greater than seven degrees and less than thirteen degrees, which is measured in particular between nine degrees and eleven point five degrees. Conical pulley belt transmission (100) according to claim 4 or 5, - 17 - characterized in that the conical disks (301, 302) of the first conical disk pair (300) and the conical disks (501, 502) of the second conical disk pair (500) are made of case-hardened steel with the designation 15CrMo5 or the designation 17CoNiMo6. Cone pulley belt transmission (100) according to one of the preceding claims 4-6, characterized in that the driving cone pulley pair (300) is designed to be driven at a rotational speed of up to a maximum of 12000 rpm, in particular at a rotational speed of up to a maximum of 6500 rpm. Conical pulley belt transmission (100) according to one of the preceding claims 4-7, characterized in that the driving conical pulley pair (300) is designed to transmit a torque of at least 150 Nm.