Continuously variable transmission

Abstract

A cone pulley continuously variable transmission comprising one primary pulley pair, one secondary pulley pair and one encircling mechanism spanning the pulley pairs. The distances between the pulleys of each pulley pair are adjustable in opposite directions for changing the ratio by way of hydraulic setting device. A spring device acts upon an axially displacable secondary pulley and a spring device prestresses the input-side primary pulley pair in case of gear distance between its pulleys in direction to reduction of the distance. To improve the mode of operation of such a transmission during a towing process, the spring tensions of the input-side spring device and the output-side spring device is coordinated to prevent, during a towing process with deactivated hydraulic pressure supply, a closing of an input-shaft side starting clutch determined by rotational speed and/or drag torque or damage of the primary pulley or of the encircling mechanism.

Description

According to the preamble of claim 1, the invention relates to a cone pulley continuously variable transmission.

In a transmission of this kind, the ratio is determined by the situation of the input-side and output-side tread radii of the encircling means on the cone pulleys, the same as the change thereof produced by an axial displacement of axially displacable cone pulleys. The needed contact and adjusting forces of the cone pulleys are hydraulically applied by adequate setting devices. In the operation of the transmission, the hydraulic pressures are composed of one static and one dynamic portion; the dynamic portion being produced by centrifugal force action upon the hydraulic pressure medium enclosed in the setting device and rotating together with the cone pulleys.

In these transmissions, the pressure medium is usually supplied by way of an oil pump mechanically driven by a prime mover of the vehicle. Failure of the prime mover caused by damage then results in that no sufficiently high static hydraulic pressure exists. A purposeful actuation of a starting clutch or of the hydraulic setting devices is thus no longer possible for the transmission ratio. Particularly in the towing operation of such a vehicle, the problem arises that in the pressure chambers of said setting devices, the same as of the input-side starting clutch, the existing pressure medium is exposed to centrifugal forces which can lead to the adjustment of an undesired transmission ratio and/or to closing of the starting clutch.

Besides, said cone pulley transmission are usually designed so that upon the axially displacable cone pulley of the transmission output or secondary shaft, one coil spring acts by which a minimum contact pressure is ensured on the encircling means. Due to the action of said coil spring, during pressureless shut off of the vehicle and of the transmission, there appears a LOW ratio or underdrive in direction of the lowest transmission ratio.

Mainly in case of cone pulley transmissions having a starting clutch on the side of the primary shaft, i.e., a starting clutch located between the prime mover and the input shaft of the transmission, during a towing operation, there occurs the effect that the cone pulley pairs are, as it were, driven by the vehicle driving wheels via the output shaft of the transmission. In said transmission ratio LOW, this results in very high rotational speeds and drag torques on the input or primary cone pulleys which can produce a skidding of the encircling means, the same as mechanical damages on the encircling means and on the cone pulleys.

To solve this mechanical problem, from DE 100 52 471 A1 is known a cone pulley CVT where a plate spring having a special spring characteristic line is operatively situated upon the axially displacable primary cone pulley. This characteristic line is selected so as to have, in the area of the transmission ratio LOW, a minimum force and in direction to lower reduction ratios to rise up to a maximum spring tension. Shortly before the reduction ratio 1:1, the spring tension drops to a zero value and is in the so-called overdrive range absolutely inactive. It should be advantageous in this design that when the vehicle is shut off with a transmission reduction ratio 1:1, the spring characteristic line prevents its moving in direction to LOW in the absence of static hydraulic pressure.

It is deemed disadvantageous in this CVT that the reduction ratio, departing from the reduction ratio LOW at the start of a towing operation, is adjusted comparatively slow out of the damaging rotational speed range so that an abnormal closing of the primary-side starting clutch, the same as damages on the encircling means and on the cone pulleys, cannot be ruled out with certainty.

With this background, the problem on which the invention is based is to introduce a cone pulley CVT which exclusively, as a result of its mechanical design, ensures that during the towing operation no disadvantageously high rotational speeds and drag torques are generated on the primary side of the transmission.

The solution of this problem results from the features of the main claim while advantageous developments and improvements of the invention can be deduced from the sub-claims.

The invention is accordingly based on a cone pulley CVT having one primary cone pulley pair on the input side, one secondary cone pulley pair on the output side and one encircling means spanning said cone pulley pairs, in which the distances between the cone pulleys of each cone pulley pair are adjustable in opposite directions for ratio change by way of hydraulic setting devices, in which a spring device acts upon an axially displacable secondary cone pulley and in which a spring device is provided which prestresses the input-side primary cone pulley pair in case of great distance of its cone pulleys in direction to reduction of the distance.

To solve the stated problem, it is provided in combination with the above mentioned features, that the spring tensions of the input-side spring device and of the output-side spring device be coordinated so that during a towing operation with deactivated hydraulic pressure supply, there is prevented a closing of an input-side starting clutch caused by rotational speed or drag torque or damage of the primary cone pulleys and/or of the encircling means.

It is preferably provided here that the input-side spring device be not axially prestressed but fixed on the axially displacable primary cone pulley. The input-side spring device can be designed as a plate spring or as a coil spring.

As long as a coil spring is used as a primary-side device, this development of the invention is based on a cylinder-side section of the primary cone pulley and of the inner side of a pressure cylinder associated with said primary cone pulley.

For the case that a plate spring is used, this is preferably limited in its axial spring stroke. The spring stroke is limited preferably by a guard ring situated on a bearing section or a guide section of the axially displacable primary cone pulley and inserted in an annular groove on the bearing section or on the guide section.

In one other development of the invention, it is provided that the axially displacable primary cone pulley with its bearing section and its guide section be accommodated in the pressure cylinder which has a contact section on which the plate spring can support itself for adjusting a reduction ratio having no hydraulic pressure.

For clarification of the invention, with the description one drawing is enclosed which shows:

FIG. 1 is a cross-section through a cone pulley CVT in the area of a plate spring acting on the axially displacable primary cone pulley at the highest possible ratio;

FIG. 2 is a graph according to FIG. 1, but with a coil spring;

FIG. 3 is a graph as in FIG. 1 at the lowest possible ratio;

FIG. 4 is a graph, according of FIG. 1, at a towing reduction ratio; and

FIG. 5 is a graph as in FIG. 1 with a radially outwardly disposed guard ring for the plate spring.

In the drawing, CVT components have been omitted which are known to the expert and can be deduced from DE 100 52 471 A1. Such a transmission essentially comprises one primary or transmission input shaft 1 which can be connected via a starting clutch (not shown) on the transmission input side with the prime mover of a motor vehicle. Upon the transmission input shaft 1 are non-rotatably fastened two cone pulleys 2, 3 of the so-called primary cone pulley set, the cone pulley 2 being axially displacably supported upon a bearing section 4 of the primary shaft 1. In addition, between the two cone pulleys 2 and 3 an encircling means 4 is inserted with which the input torque produced by the prime mover can be transmitted to the secondary output shaft of the variator.

To that end, upon the secondary shaft of the CVT is non-rotatably situated a so-called secondary cone pulley set of the two cone pulleys of which one cone pulley is axially firm and the other axially displacable. The encircling means 5 is accommodated between these two cone pulleys.

To produce upon the encircling means, a contact pressure that makes it possible to transmit the torque from the primary cone pulley set to the secondary cone pulley set, the same as a ratio-changing pressure, the axially displacable cone pulleys with their side axially remote from the encircling means are designed as pistons 6 which are axially displacable into respective coordinated pressure cylinders 7. In relation to this, to exert a contact or adjusting force, hydraulic oil is introduced under pressure during operation of the transmission into the pressure chamber 8 of said piston-cylinder arrangements.

According to FIGS. 1, 3, 4 and 5, within the pressure chamber 8 is located one recoil spring designed as plate spring 9 which supports itself axially, on one side, on a section 13 close to the encircling means of the axially displacable cone pulley 2 and, on the other side, on a guard ring 10.

In the embodiment shown in FIG. 1, the guard ring 10 is inserted in an annular groove 16 of the bearing section 11 of the cone pulley 2 while in the development of the invention shown in FIG. 5 such a guard ring 12 is fastened in an annular groove 17 on the cylinder-side guide section 18.

According to the alternative shown in FIG. 2, it is possible to use a coil spring 14 instead of the plate spring 9, so as to exert, a ratio-changing active axial force upon the axially displaceable cone pulley 2, in case of failure of the static hydraulic pressure.

In relation to the invention, it is now important to mention that upon the axially displacable secondary cone pulley disposed on the secondary shaft, likewise, acts one recoil spring with which the transmission, in pressureless state of the secondary-side piston-cylinder arrangement, substantially in case of arrest of the vehicle or of a defect of the prime mover, without the action of the primary-side recoil spring 9, would be adjusted to the ratio LOW. In this reduction ratio, the two primary cone pulleys 2, 3 are moved the farthest from each other so that in a concrete cone pulley CVT, a reduction ratio, for example of 1:0.4 appears.

As long as the pressure medium supply for the piston-cylinder arrangement of the two axially displacable cone pulleys is inactive, due to stoppage or to a defect of the vehicle prime mover, the towing reduction ratio shown in FIG. 4 appears as result of the balance of forces then active between the recoil springs on the axially displacable secondary cone pulley and the recoil springs 9, 14 on the axially movable primary cone pulley.

As shown in this connection by a comparison, especially of FIG. 1 with FIG. 4, the plate spring 9 comes to abut with recoiling effect on a section 15 of the pressure cylinder 7 pointing axially in a direction to the encircling means 5 only when the cone pulleys 2, 3 of the primary cone pulley set 2, 3 have a predetermined axial distance from each other.

At the same time, the plate spring 9, while supported on the bearing section 15 of the pressure cylinder 7, presses the cone pulley 2 axially so far in direction to the stationary cone pulley 3 that the encircling means 5 is positioned removed from its smallest and largest tread radius in this cone pulley set. In a concrete cone pulley CVT, the characteristic liens of the recoil springs on the primary and secondary sides are coordinated for the movable cone pulleys preferably so that in such a towing phase the transmission ratio assumes a value of 1:1.5.

It is achieved by the transmission design described that already at the start of a towing operation such a reduction ratio of the transmission is adjusted that inadmissibly high rotational speeds of the primary shaft cannot be generated. It can thus be reliably prevented that the starting clutch becomes abnormally closed due to dynamic pressure medium forces and/or that the primary cone pulleys suffer mechanical damages on account of a skidding of the encircling means 5.

Contrary to that, the primary-side spring device known from DE 100 52 471 A1, only takes care that when the prime mover is stationary and the transmission, if necessary, is still loaded with hydraulic pressure, a force is exerted upon the displacable primary cone pulley that extricates the transmission from the underdrive adjustment LOW and leads it to a reduction ratio 1:1 only during the towing operation.

REFERENCE NUMERALS

1 primary shaft 11 bearing section of primary cone pulley

2 axially movable primary cone pulley 12 guard ring

3 undisplacable primary cone pulley 13 cylinder-side section of primary cone

4 bearing section of the primary shaft pulley

5 encircling means 14 spring device, coil spring

6 piston 15 bearing section of the cylinder

7 pressure cylinder 16 groove

8 pressure chamber 17 groove

9 spring device, plate spring 18 guide section

10 guard ring

Claims

1-8. (canceled)

9. A cone pulley continuously variable transmission comprising: an input-side primary cone pulley pair; an output-side secondary cone pulley pair; and an encircling mechanism spanning said primary and secondary cone pulley pairs, a distance between cone pulleys of each cone pulley pair are adjustable in opposite directions for changing a ratio by way of hydraulic setting devices, a spring device acts upon an axially displacable secondary cone pulley and another spring device is provided which prestresses the input-side primary cone pulley pair when the cone pulleys of the input-side primary cone pulley pair are at great distance in direction to a reduction of the distance, spring tensions of the input-side spring device (9, 14) and of an output-side spring device are coordinated so as to prevent, during a towing operation with deactivated hydraulic pressure supply, a closing of an input-shaft side starting clutch determined by one or more of a rotational speed, drag torque, damage of primary cone pulleys (2, 3), and of the encircling means (5).

10. The cone pulley continuously variable transmission according to claim 9, wherein the input-side spring device (9, 14) is not prestressed but fixed on the axially displacable primary cone pulley (2).

11. The cone pulley continuously variable transmission according to claim 9, wherein the input-side spring device (9, 14) is designed as one of a plate spring (9) or as a coil spring (14).

12. The cone pulley continuously variable transmission according to claim 11, wherein the input-side coil spring (14) is supported on a cylinder-side section (13) of the primary cone pulley (2) and a pressure cylinder (7) coordinated with said primary cone pulley (2).

13. The cone pulley continuously variable transmission according to claim 11, wherein an axial spring stroke of the plate spring (9) is limited.

14. The cone pulley continuously variable transmission according to claim 13, wherein the spring stroke is limited by a guard ring (10, 12) situated on one of a bearing section (11 ) or guide section (18) of the axially displacable primary cone pulley (2).

15. The cone pulley continuously variable transmission according to claim 14, wherein the guard ring (10, 12) is inserted in an annular groove (16, 17) on one of the bearing section (11) or the guide section (18).

16. The cone pulley continuously variable transmission according to claim 9, wherein the axially displacable primary cone pulley (2) having a bearing section (11) and a guide section (17) is accommodated in a pressure cylinder (7) which has a contact section (15) on which a plate spring (9) can is supported for adjusting a reduction ratio without hydraulic pressure.