DE3418281C2 - Power transmission element for continuously variable transmission - Google Patents

Description

2. Power transmission element for continuously variable transmission according to claim 1, characterized in that U-shaped, resilient jaw clamps (4) are provided for fixing the wedge jaws in the axial direction (XX).

3. Power transmission element according to claim 1 and

2, characterized in that the wedge jaws (3) are made of a metallic material, which in its composition and in its mechanical properties are technically common Corresponds to sliding materials.

4. Power transmission element according to claim 1, characterized in that the largest possible Joint angle arc *, = t / r is approximately limited to a value of 0.1 and that the radial height of the height the joint pressure surfaces (14) is limited to about 0.1 ι.

The invention relates to a power transmission element for continuously variable transmissions of the type of belt transmission, which usually consist of two pairs of axially adjustable conical disks and one endless power transmission element exist, the latter having a keUenähnliche structure.

Power transmission elements with a chain-like structure of the type mentioned above are diverse ^ orm has been suggested. The from the state of Technology emerging features of the invention are in the rule! geared towards the one goal of progress: Improvement of transferable performance.

The following influencing variables, which are decisive for the transmission performance, can also be identified from this:

a) The tensile strength of the chain strand in the direction of rotation.

b) Flexural strength and compressive elasticity of the chain links perpendicular to the direction of rotation.

c) Compressive strength, hardness and wear resistance of the friction contact surfaces on the front sides of the chain links, via which the frictional force is transmitted.

d) The number of chain links in frictional engagement with the conical pulleys, d. H. the whole instantly effective friction contact surface on a pair of conical disks.

In contrast to the flexible belt (V-belt) there is only a chain-like power transmission element a point or line-shaped contact center for each chain link on a conical pulley. When the wedge flank is formed on the chain link as a flat plate, then With the conical surface as the mating body, a radially directed conical surface line results as the center of contact. As a result of the elastic deformation of the two contact bodies, a pressing surface is created in the form of a very narrow rectangle or an ellipse. A widening of the wedge flank surface in the direction of pull does not bring any improvement, because it reduces the friction losses at the inlet and outlet tangcntpoints be enlarged.

Assuming that, according to the state of the art, the material load capacity has been fully exhausted, then obviously the only way to effectively increase the frictional force is to reduce the Chain division, d. H. to try on a given loop length to increase the number of frictional contact points.

The absolute dimension of the chain pitch "t" is not meaningful with regard to the frictional contact density. One a better assessment is obtained from the ratio:

Chain pitch »t« / looping radius »r«.

This ratio indicates the polygon angle or joint flexion angle arcÄ; you can do this angle also referred to as the pitch angle.

The value t / r is therefore at the same time a measure of the radial force component F- / acting on each joint and consequently also a measure of the bending stress acting on each chain transverse element.

The value t / r is also decisive for the kinematic Error that occurs at the entry and exit tangent points (polygon effect) and that is itself again responsible for the extremely disadvantageous phenomena such as running noise, vibration excitation and drilling friction losses.

The smaller the value t / r becomes, the smaller it becomes with it all of these harmful effects which stand in the way of optimizing performance.

Constructive measures to reduce the chain pitch in link chains are z. Tie Documents DE-OS 30 27 834 and DE-OS 30 32 148 proposed. In both examples, the reduction is the chain division is achieved by using the three-link bond, but this has the disadvantage that the unusable empty space within the chain structure is enlarged, the chain builds wider or with the same chain width, the number of plates is reduced, which means that the reduction in the division The advantage gained is bought at the expense of a higher load on the plate.

Both of these examples have the common feature that they use the joint elements as Qaerdruckteile Use (= transverse elements) and their front ropes as friction contact surfaces against the conical pulleys. Since the thickness of these transverse elements can inevitably only be smaller than half the chain pitch, the Flexural strength of these transverse elements is an additional criterion for the load capacity.

These known designs of link chains also have the disadvantage that they are in the tangential plane have no diagonal shear stiffness, which leads to skewing in the case of asymmetrical frictional force distribution and can lead to significant dysfunction.

A fundamentally different advanced system of a chain-like power transmission element is shown in the publication DE-PS 21 16 930 shown. There are massive metal cross members in the circumferential direction lined up and tensioned by means of an endless steel belt. The exciting part (the tensioned Steel band) and the compression-tensioned cross-link chain together form a closed tensioning system. Since with this design no space is required for additional joint parts in the direction of rotation , the pitch from the center of the cross member to the center of the cross member can be made relatively small.

Since, in this example, the hinge edge "A" has a radial distance from the center of the tensioning strap, the deformation mechanism results in a relative displacement with every change in the curvature of the strap, which then causes friction losses and wear. A significant deficiency in this system is that, in order to guarantee the transfer function, the internal tension forces must be several times greater than the maximum permissible operating circumferential force. However, these internal tension forces cause frictional losses, which are then relatively high at low power loads. In addition, there is the disadvantage that the internal preload is reduced due to operational wear, which must be taken into account when designing the performance.

A chain structure with tensile, massive links and a small pitch is shown in the publications DE-AS 11 37 609 and DE-OS 29 49 061 proposed.

Here the prismatic cross members have approximated one U-shaped profit (double hook) and the tensile and articulated connection of the Chain links are made in such a way that the chain links are alternately hooked into one another (overlapped). No additional joint element is required, which results in a relatively small chain pitch due to the structure results. The centering of the chain links in the radial direction takes place here within the entire overlap width.

This type of radial centering and the proposed joint kinematics make it necessary that the

Inner sides of the overlapping legs must be heavily undercut. As a function of the function, this results in a bending lever arm of the overlap leg that is large in relation to the thickness and an acute-angled groove with only a small groove radius. This function-related profile shape has the disadvantage that it results in a very unfavorable and critical stress distribution, in particular due to the notch effect of the fillet. The material utilization in the area of the leg width is poor and requires a large thickness -2 in relation to the external tensile load on the overlap legs. However, this siei ^: e is the criterion for the smallest possible division dimension. Another disadvantage can be seen in the fact that the end faces of the chain links are provided directly for frictional contact with the Kr-Jjel disc. The given shape of the contact body (conical disk and chain link) inevitably results in only two point-like contact points per chain link - one on each end face - so that the entire friction contact surface is relatively small

The object of the invention is therefore to keep the state of the art in terms of transmission performance and transmission efficiency to improve, whereby by optimizing the shape stability of the chain links Tensile and flexural strength increased, the chain pitch largely reduced and thus the overall frictional contact density be enlarged.

The solution to the problem emerges from the characterizing parts of the main claim.

The description of the invention relates to the following drawings:

F i g. 1 chain section in the direction of rotation with partial view of the face of the chain links or of the wedge surfaces.

Fig. 2 cross section II from Fig. 1 through a pair of chain links with the associated wedge jaw.

Fig. 3 Tangential section III from Fig. 2 through a row of wedge jaws.
Fig. 4 profile detail (shown greatly enlarged) of the

Chain links from the overlap area with joint pressure surfaces.

F i g. 5 Alternative development to F i g. 4. F i ^. ό to F i g. 8 Illustration of the pincer effect of the Chain links and the pretensioning effect.

To Fig. 1 and Fig. 2: The chain links have a pincer-like profile. The chain-like, tension-locking link connection is established in a known manner by reciprocal interlocking of the chain links la, 1 / (la = outside, M = within the dividing line YY). The overlapping parts of the chain links are designated as pincer jaws 13, and the recess open towards the dividing line is designated as pincer throat 12.

The outer chain links 1a and the inner chain links 1 / each form a closed row of links along the dividing line Y-Y , both rows of links are offset from one another by the pitch "/" in the direction of rotation in a known manner.

The purpose and effect of the tong profile are explained in greater detail.

The transmission of the tensile load from one chain link to the other takes place via the joint pressure strips 14, which are set off on the throat side of the gripper jaws. The loaded surfaces of these pressure bars are aligned perpendicular to the direction of rotation (in the XZ plane): they are very narrow in the Z direction (about 0.1 χ pitch t) and thus enable a tilting movement between two connected chain links. The joint pressure strips 14 simultaneously have the function of chain joints, but do not have a positive centering. The chain links can be moved in the Z direction on the pressure strips.

The articulated centering of two connected Chain links are at their end faces by centering pins 31 and Zenirieransätze 32j. 32; the wedge jaw 3 causes. To support the centering pin 31 are on both end faces of each Chain link circular centering troughs 11 sunk. Whose center is in the middle of the joint. Included limit the centering pin 31 the position of the chain links perpendicular to the dividing line and the centering lugs 32a. 32 / delimit the position perpendicularly away from the dividing line.

This system of joint centering is based on the following consideration:

With the features according to the invention - as a solution to the problem - the chain pitch "t" can be made so small that even with the smallest possible looping radius the pitch angle.%, = T / r only reaches the order of magnitude 0.1. As a result, the radial force component resulting from the circumferential tensile force at a hinge point can only reach a maximum of 0.1 χ circumferential tensile load, i.e. it will be smaller than the frictional force present at the hinge pressure strips. It can therefore be assumed that the radially effective centering points II; 31; 32a. X 32; are not used by the operating staff, but only for adjustment.

In Fig. 4 is; in high magnification an example of the design of the jaws 13 with the joint pressure strips 14 is shown. Takes place on the pressure bars the articulated load support according to the well-known principle of rocker joints: a rocker edge with more or less large edge rounding and edge angle smaller than 180 'but greater than 90 rolls or tilts on a flat plate.

In the exemplary embodiment, the cradle edge is produced in that at least the pressure strips of the outer chain links receive an inner bevel 141 with a small bevel angle <f . Since the tilt or roll angle λ should be small at each joint within the scope of the solution to the problem, this bevel angle will be of the same order of magnitude as α ·. It is assumed that, due to the high pressure values, the blunt bevel edge is flattened elastically so that an approximately rounded edge is created under load.

With a view to the fact that the outer and inner chain links should be the same, which, however, is not necessarily a prerequisite, the inner mount 141 can apply to all Chain links are provided (as shown). The bevels must be offset so that under alien Under certain circumstances, an edge of the outer member lies on a flat surface of the inner member.

It is a prerequisite that the joint pressure strips 14 are hardened. In order to avoid the formation of structural notches in the fillet, it is expedient hook the entire area of the pliers throat 12.

As an alternative to the basic concept according to FIG. 4 is proposed in Fig. 5, the joint pressure strips as Insert strips 142 made of foreign material, e.g. B. made of hard metal to use. This has the advantage that on the one hand for the pressure bars the hardness property and on the other hand for all other chain link areas the Tensile strength and toughness properties can be optimized.

A variant of FIG. 4 and FIG. 5 (not shown) consists in the fact that the contact planes of the pressure strips are not perpendicular, but at a small undercut angle! are set to the direction of rotation. This results in a force component acting in the Z direction (= radial) from the circumferential tensile load, which tries to pull the chain links against the dividing line. In this way it is possible to ensure that the geological titration takes place exclusively on the U / 31 peg centering.

In contrast to the examples considered from the prior art, the chain links of the invention themselves have no contact with the conical pulleys. The front sides of the chain links are plane-parallel to the plane of rotation (YZF.bent) . The frictional contact with the conical disks takes place via the wedge jaws 3. The joint axis is assigned a pair of wedge jaws, so that the radial force resulting from the circumferential force is supported on the conical disks directly at the hinge point in the wraparound area. Plane-parallel pressure surfaces 36 are provided on the wedge jaws against the chain link end faces 16. Centering pins 31 and centering lugs 32a, 32; on the wedge jaws cause the radial centering of two connected chain links (always an outer and an inner one), so they still form part of the chain link in terms of functions, but at the same time they cause the wedge jaw to be centered with respect to this chain link.

There are proposals known from the prior art, according to which wedge jaws or healing jaws form-fit are rigidly connected either to a transverse element or to a longitudinal chain element. The essential one The difference between the invention and this prior art can be seen in the fact that each wedge jaw at the same time on an outer and an inner chain link, both of which are articulated in the chain row, rests pressure-tight, and can be pivoted in relation to the two adjacent chain links in the plane plane is.

Since the two articulated chain links on their front sides between the wedge jaws - due to the axial disc contact force - are pinched, the joint movement between the both chain links are hindered by a front friction moment, which on closer examination of the However, influencing factors are shown to be very small. To prove an order of magnitude for this The following must be observed:

a) The contact pressure exerted by the conical disk on a wedge jaw is transmitted via the wedge jaw supported approximately evenly on both adjacent chain links;

b) the relative rotation angle! between wedge jaws and each adjacent chain link is only half of the pitch angle, the relative rotational movements between the chain link and the wedge jaws

follow one after the other with increasing contact pressure starting from the value 0;
c) the coefficient of friction on the forehead pressure surfaces can be kept lower than on the wedge surfaces through the choice of material and favorable lubrication.

Since ^c , total front friction torque (two run-in and two A'_sl; iufstellen together) can be kept in an order of magnitude of less than 0.5% of the nominal torque.

At the inlet and outlet areas of a belt drive arises as a result of unavoidable kinematic errors (polygon effect) between the Chain link friction surfaces and the conical pulleys the so-called drilling friction. With the arrangement according to the invention the wedge jaw is achieved that the harmful drilling friction effect away from the conical pulleys rhi? Relocated forehead pressure surfaces of the chain links where the sliding friction can be better controlled and largely reduced.

The design of the wedge jaws 3 with regard to their function for transmitting frictional force is shown in the drawings Fig. 1, Fig. 2 and Fig. 3 are shown.

In the area of the chain division line and radially outside the same corresponds to the length of a wedge jaw in the direction of rotation to the pitch »t«. The length indentation radially inwards results from the largest permitted pitch angle (from the smallest possible Pulley diameter). The wedge jaws should lie against one another without any play in the circumferential direction.

The wedge friction surfaces 33 are narrow in the radial line elongated rectangles and are sharply offset at an angle of approx. 45 ° to 60 ° Edges 34 (cross section Fig. 3); this is intended to ensure that a lubricating film is cut off and hydrodynamic Slipping is prevented.

With regard to the joint mechanism, it is not possible to have every wedge jaw rigidly attached to a chain link to fix. Although no operating loads act axially outward on the wedge jaws, they must but be secured against falling out. U-shaped, resilient jaw clips are used for this task 4 provided, each of which hold opposite wedge jaws together at the front and under Press the spring tension against the forehead pressure surfaces of the adjacent chain links.

In the drawn example Fig. 2 and Fig.3 are the Jaw clamps are each arranged between the wedge jaws and span the chain links radially on the outside. But they can also be arranged so as to span radially on the inside. Alternatively, the jaw clamps can also be placed on the middle of the wedge jaws, for which purpose the latter has a radial hole up to approximately the joint axis obtain.

Another type of axial locking wedge can be designed so that on the outer legs the chain links are provided with grooves parallel to the direction of rotation, in which spring elements engage, which are positively connected to the wedge jaws.

The shape of the wedge jaws, their small dimensions and the type of stress are favorable prerequisites for a powder metallurgical manufacturing process. In addition to the advantage of manufacturing costs However, the significant technological advantage is that it can be used to obtain metal mixtures which are in the Melting processes are not producible. For the wedge jaw function according to the invention it would be desirable to that a suitable metal powder coating on the front pressure surfaces and centering parts Metal alloy with a very low coefficient of friction and an alloy with a higher coefficient of friction on the wedge friction surface (if possible with a coefficient of static friction equal to or less than a coefficient of sliding friction).

With regard to a generally favorable coefficient of friction characteristic and consideration can also be given to protecting the conical disks from wear

ίο To manufacture wedge jaws from such brass, bronze or aluminum alloys, which are technically used for highly resilient sliding parts - such as bearing or synchronizer rings.
Based on the representations F i g. 6, fig. 7 and FIG. 8th

r, should be the purpose and effect of the pincer profile of the chain links explained.

The pincer function is explained by the fact that the middle profile part, the tensile stress web section SS, is to be regarded as an elastically deformable joint between the pincer legs 17 which are approximately perpendicular thereto. By spreading the tong legs apart by means of the pretensioning wedge 2, the tong throat width (= division dimension »t«) is reduced.

The purpose of the pincer action is to influence the stress curve within the cross-section caused by the external operating load Fe, so that the given material strength can be optimally used.

In Fig. 6 and Fig. 6a it is shown how a

jo press the preload wedge 2 between the pliers legs 17 these are spread apart; as a result, a static bending stress is generated in the web cut SS , namely a tensile stress at the thigh throat rj and a compressive stress in the area of the tong throats η. A plastic deformation can and may occur at the thigh r _3.

Fig./ and F i g. 7a illustrate the load case! with the external operating load F _Bl (= circumferential tensile force) acting counter-symmetrically on the pressure strips 14.

This results in a stress distribution in section SS such that a tensile stress peak is generated at the pliers throat r \ due to the influence of the shape and a relatively low stress (+/-) is generated in the area of the thigh throat η. For a load case similar to the one shown, the tensile stress occurring in the jaws r \ is the criterion for the permissible operating load. especially when this occurs as an alternating load (mean value with alternating amplitude). In Fig. 8 it is shown which stress profile is given in the section S-Ser. if the operating stress profile according to Fig. 7a is superimposed on the preload profile according to Fig. 6a:

At the tong throats r _t , the dynamic operating stress amplitudes are predominantly in the compressive stress field; Although high tensile stresses appear at the thigh π, these are almost static at the level of the prestress with only very small alternating stress superimpositions.

By coordinating the profile dimensions I _u h and section SS it can be achieved that from the operational load case Fig.7 the bending stresses at the thigh o are always at the value zero, so that no alternating stresses act in the resulting stress field Fig.8 at this point.

From the tension picture F i g. 8 can still be as follows Derive assessment: As a result of the pressure bias on the pliers throats / -, the flow of force, which initiated by the operating load on the pressure bars 14

is displaced towards the center of the tension web, section 5-5, creating the notch effect in the entire area the throats of the pliers is weakened.

The tensile strength of a chain link with a chain link according to the invention is increased by the action of the clamp pretension Profile increased significantly.

An increase in tensile strength in the same sense can be achieved through surface hardening in the area of the Also reach pliers throats, z. B. by shot peening, pressing or rolling or by special hardening processes (Diffusion hardening, boriding, nitriding).

A further embodiment of the invention is provided through the use of special materials The wedge jaws transfer the frictional force between the conical pulleys and the force transmission element Allow exclusion of viscous lubricants.

The document DE-OS 33 15 390 already contains explanations that with the application of special Plastic composite material with »dry frictional engagement« advantages over a »lubricated one Frictional engagement «are to be expected.

With reference to the prior art, the invention is developed in such a way that the wedge jaws 3 both the wedge friction surfaces 33 and the face pressure surfaces 36 with the centering elements 31 and 32 a thermoplastic composite material is used, as is known in the specification for dry sliding bearings Applies.

Furthermore, the invention can be varied in such a way that between the chain link end faces 16 and the wedge jaws 3 a pressure plate is inserted, which, although the profile outer contour of the chain link, but without a leg groove, and which in particular have an extremely low coefficient of friction has the wedge jaw.

In an alternative embodiment, the profile shape of the outer and inner pincer members can be different. Since the radial force component acting on the wedge jaws is generally supported on the outer chain links, instead of circular centering recesses 11, a flat centering surface facing the dividing line YY can be provided on the inner chain links.

The technical progress that can be achieved with the agents according to the invention essentially consists in that by reducing the shape-related critical stress concentrations within the chain link a more favorable power flow is generated. The tensile strength of the chain link, but above all that for the Operational load critical fatigue strength are increased significantly.

This results in the decisive advantages for an increase in transmission performance: Compared to the state With technology, the chain pitch can be further reduced and thus the friction force-effective contact surface (related on the same arc of wrap): the flexion angle at the joints becomes smaller and the harmful effects of the polygon effect are reduced.

The proposed arrangement of wedge jaws enables an optimal transmission of frictional force Material selection and results in a sufficiently large one with the radially stretched but very narrow wedge flanks effective frictional contact surface, thus improving the strength The increase in tensile load obtained can also be implemented as a frictional force on the conical pulleys Fully automatic processes can be used for the production of the individual parts as well as for their assembly will.

For this purpose 3 sheets of drawings

Claims (1)

Patent claims: 1. Power transmission element for continuously variable transmission, which consists of axially adjustable conical pulleys and an endless power transmission element, the latter consisting of individual Links is composed like a chain and the chain links in the direction of rotation on both sides the dividing line are lined up one behind the other without a gap and the tension-locking connection is made by overlapping each other with the chain links in the axial direction solid and the joint function is carried out similar to the principle of rocker joints and Wedge jaws are provided for the transmission of the frictional force between conical pulleys and chain links are characterized by the following features, 20th a) the prismatic chain links have a tong-like profile with two radially aligned tong legs (17) and with two tension bars acting in the circumferential direction, the first tension bar being designed as a tension bar which is at a first distance (I ₁ ) from the dividing line (YY) is located away and with a second tension bar, which is pressed in as a pre-tensioning wedge (2) under a compressive biasing force between the pliers legs (17) and at a second distance (I ₂ ) which is greater than the first distance (h) from the tension bar isi; b) the overlap of the joint surfaces (14) has a margin in the radial direction (ZZ) and the means for articulated fixation of the chain links are provided on their plane-parallel end faces as circular centering recesses (11) on the chain links and as centering pins (31) and centering lugs (32a, 32 /; on the wedge jaws (3); c) the wedge jaws (3) are each arranged in the middle of the chain joint and centered on the chain links by means of centering pins (31) and each wedge jaw is supported in the axial direction (XX) against an outer (\ a) and an inner (M) chain link and can be pivoted through a small angle in relation to the two adjacent chain links in the plane plane (XZ) and wedge jaws and chain links have plane-parallel pressure surfaces (16; 36).