FR2780128A1 - Intermediate pulley for a belt drive with variable speed - Google Patents

Abstract

The intermediate pulley (3) consists of a rotating hub (6) carrying between two fixed end flanges (7), an inverted v-shaped disc (8) that moves axially in order to define in conjunction with the end flanges (7) two parallel throats (9,10) of variable dimensions. These variable throats are designed to receive the v-belts of a first and second belt drive. This hub can be displaced parallel to itself to obtain, in conjunction with the sliding disc, variation in the operating speed. The periphery of the hub (6) and the inner surface of the disc (8) are ribbed so that they engage with each other so that they are solid in rotation.

Description

1 <) Relay pulley for endless transmission of power at speed

  The present invention relates to a relay pulley for infinitely variable power transmission between a driving pulley of a first endless belt transmission and a driven pulley of a second transmission.

endless belt.

  It relates more particularly to a relay pulley consisting of a rotary hub carrying, between two fixed outer flanges, a flange movable axially to delimit

  with the fixed flanges two parallel grooves of variable size adapted respectively to receive a belt of the first or the second transmission without end belt.

  Relay pulleys of the aforementioned type, well known to those skilled in this art, have a major disadvantage due to their size. This large size is related to the fact that the mobile flange of the pulley is mounted on a smooth shaft constituting the hub. This flange is subjected, by endless transmission belts, to two axial forces exerted at diametrically opposite points 2 on the flange. Therefore, the flange tends to occupy relative to its support hub a position that causes a matting of the constituent material of the hub and the flange and clamping problems of the flange. To avoid these problems, it is necessary to increase the thickness of the flange so that its surface in

  contact with the hub has a height H equal to at least 2.5 times the diameter of the hub. This results in a total height of the hub of the very large relay pulley.

  Moreover, most relay pulleys are now made with flanges and a metal hub. The permanent contact metal / metal in the open air 15 causes in time, due to the absence of lubrication, problems of corrosion and wear. A

  However, lubrication can not be considered because the lubricants deposited on the hub of the pulley tend, under the effect of centrifugal force, to settle on the belts and to cause problems of slippage of the belts.

  The object of the present invention is therefore to provide a relay pulley whose design allows a reduction of the radial forces exerted on the hub and therefore a reduction in the overall size of said relay pulley. Another object of the present invention is to provide a relay pulley whose design eliminates any risk of wear and corrosion due to a contact of

  pressure between said constituent materials of the relay pulley.

  For this purpose, the subject of the invention is a relay pulley for the endless transmission of power at variable speed between a driving pulley of a first endless belt transmission and a driven pulley of a second endless belt transmission, said relay pulley being constituted by a rotary hub carrying, between two fixed outer flanges, an axially movable flange for delimiting with the fixed flanges two parallel grooves 5 of variable size able respectively to receive a belt of the first or second transmission without end belt, said hub being movable parallel to itself to obtain, in cooperation with the mobile flange, 10) the speed variation function, characterized in that the rotary hub of the relay pulley and the movable flange

  axially on the hub are made integral in rotation by means of splines formed respectively at the outer periphery of the hub and at the inner periphery of the movable flange centrally recessed.

  Due to the design of the rotating hub in the form of a splined shaft, the bearing surface between flange and hub is increased and the radial force exerted by the flange on the hub is reduced. Therefore, any risk of jamming of the flange is prevented despite a clutter

reduced flange.

  According to a preferred embodiment of the invention, the flanges and the support hub of said flanges are made exclusively of synthetic material. The choice of

  Synthetic materials can eliminate any risk of corrosion or wear over time.

  The invention further relates to a variable speed drive comprising at least one relay pulley of the aforementioned type.

  The invention will be well understood on reading the

  following description of an exemplary embodiment, with reference to the accompanying drawings in which:

  Figure 1 shows a schematic top view of a relay pulley incorporated in a variable speed endless power transmission device; Figure 2 shows a side view of the device shown in Figure 1; 3 shows a perspective view in exploded position of the elements of a relay pulley according to the invention; Fig. 4 shows a perspective view of the relay pulley of Fig. 3 in the assembled state according to the invention, Fig. 5 shows a top view of the movable flange of the relay pulley of Fig. 3 and FIG. 6 represents a view from above of the hub

  support of the flanges of the pulley of FIG.

  2) The relay pulley, object of the invention, is intended to serve as a relay between a first endless transmission Tl belt and a second endless transmission T2 belt. The first endless transmission T1 is a belt transmission 1 between a driving pulley 2 and the relay pulley 3. Driving pulley 2 means a pulley mounted on a motor shaft. The second transmission T2 is also a belt transmission 4 disposed between the relay pulley 3 and a pulley 5 called driven pulley carried by a shaft coupled for example to a wheel shaft of a towed vehicle. The belts 1 and 4 used in transmissions T1 and T2 are trapezoidal belts known per se. The driving and driven pulleys 2 and 5 as well as the relay pulley 3 therefore comprise grooves with trapezoidal cross section.351 The relay pulley 3 is also constituted, in a manner known per se, of a rotary hub 6 carrying, between two external fixed flanges 7 , a movable flange 8 axially to delimit with the fixed flanges 7 two parallel grooves 9, 10 of variable size due to the variation of the spacing of the movable flange 8 with each fixed flange 7. These grooves 9, 10 are also section Trapezoidal transverse. It is the same for the mobile flange 8 axially. One of the gorges, in this case the gorge 9 to

  FIG. 2 of the relay pulley 3 serves to receive the belt 1 of the first transmission T1 while the other groove, in this case the groove 10 in FIG. 2.10, serves to receive the belt of the second transmission T2.

  The hub 6 of the relay pulley 3, supporting the set of flanges 7, 8, is itself movable parallel to itself to obtain, in cooperation with the movable flange 8, the speed variation function. To enable this displacement of the rotary hub 6, this rotary hub 6, supporting the flanges 7 and 8, is rotatably mounted on a carrier shaft 11, this carrier shaft 1120) being carried by a support 13 mounted to pivot about a axis 12 parallel to the carrier shaft 11, as shown in Figures 3 and 4. This mounting of the support 13, consisting of a single plate, about an axis parallel to the carrier axis 11 allows to control at will the displacement angular of this support 13 and, consequently, the displacement of the rotary hub 6 supporting the flanges 7, 8

  to obtain a variation of speed.

  The operating principle of such a transmission is 3) simple. When the motor shaft, carrying the driving pulley 2, is rotated, the power of this shaft is transmitted via the transmission T1 to the relay pulley 3 which itself retransmitted via the transmission T2 this power to the shaft integral in rotation with the driven pulley 5. When it is desired to vary the speed transmitted from the driving pulley 2 to the driven pulley 5, the carrier shaft 11 of the relay pulley 3 is displaced according to the 1 or 2. In order to reduce the speed transmitted to the driven pulley 5, the carrier shaft 11 is moved to the left in FIG. 2 or in FIG. Figure 1. The movable intermediate flange 8 of the relay pulley 5 tends to descend so that the winding diameter of the first belt 1 increases. The rotational speed of the hub 6 supporting the flanges of the relay 3 is reduced. At the same time, due to the lowering of the intermediate mobile flange 8, the belt 4 of the second transmission T2 tends to penetrate deeper into the groove 10 of the relay pulley 3 so that a decrease in the winding diameter is observed. of this pulley and consequently a decrease in the speed transmitted to the driven pulley 5. On the contrary, to obtain an increase in the speed, it is easy to understand that it is appropriate in this case to move the bearing axis of the relay pulley 3 to the right in FIGS. 1 and 2. This displacement is shown in dotted lines in FIGS. 1 and 2 2) As mentioned above, to prevent any jamming of the mobile flange 8 subjected to axial forces exerting at diametrically opposite points of said flange 8, the mobile flange 8 is movably mounted on a hub having axial grooves 14. Of course, the mobile flange 8, which has a central recess 15 for its mounting on the hub 6, also comprises, at the periphery of this recess 15, grooves 16 of complementary shape preferably of the grooves of the hub 6. The hub 6 is preferably grooved over part of its length, the grooved portion of the hub 6 extending between two smooth portions 19 of the hub 6, these smooth portions 19 for receiving the flanges

fixed 7.

  To optimize the dimension of the bearing surfaces, each groove of the hub 6 supporting the flanges 7, 8 or respectively of the mobile flange 8 has a width L 7 of its lower base to its height H. Preferably, the height ratio H of the flute on basic width L of the flute is in the range [1.5 - 2.5]. Each flute 14, 16 preferably has a substantially rectangular shape, the width of the base being substantially the same as the width of the top of the flute. The fixed flanges 7, serving in cooperation with the movable flange 8 at the delimitation of the grooves 9, 10, are in turn removably mounted on the rotary hub 6. These removable outer flanges 7 are preferably fixed on the rotary hub. by screwing. To do this, the hub 6 comprises, on a smooth hub portion 19 disposed in the extension of the grooved portion of the hub, axial grooves 17 for receiving screws 18. Furthermore, the movable flange 8 is a hollow flange , the flanks of the recess being interconnected by

  This results in a flange of great rigidity, easy to build and of low weight.

  The rotary hub 6 is itself rotatably mounted on the support shaft 11 by means of ball bearings 21 held in position by means of shoulders.

  22 internal peripherals of the hub 6.

  To avoid the risks of wear and corrosion mentioned above, the flanges 7, 8 and the support hub 6 of said flanges 7, 8 are made exclusively of synthetic material. Due to the presence of grooves on the support hub of the flanges and on the mobile flange 8 and

  the use of synthetic materials for the production of the flanges and the support hub, all the wear, jamming and corrosion problems mentioned in the introduction are eliminated.

Claims (10)

  1. Relay pulley (3) for infinitely variable power transmission between a driving pulley (2) of a first belt endless transmission (T1) (1) and a driven pulley (5) of a second belt endless transmission (T2) (4), said relay pulley (3) consisting of a rotary hub (6) carrying, between two fixed outer flanges (7), a movable flange (8) axially to delimit with the fixed flanges (7) have two parallel grooves (9, 10) of variable size capable respectively of receiving a belt (1, 4) of the first or second endless transmission (T1, T2) with a belt, said hub ( 6) being movable parallel to itself to obtain, in cooperation with the mobile flange (8), the speed variation function, characterized in that the rotary hub (6) of the relay pulley (3) and the movable flange (8) axially on the hub (6) are made integral in rotation via groove es (14, 16) formed respectively at the outer periphery of the hub (6) and at the inner periphery   mobile flange (8) hollowed out centrally.   2. relay pulley (3) according to claim 1, characterized in that each groove (14, 16) of the hub (6) supporting flanges or the movable flange respectively   (8) has a width (L) of its lower base to its height (H).   3. Relay pulley (3) according to claim 2, characterized in that the ratio height (H) over width   (L) of each groove (14, 16) is included in the range [1,5 - 2,5].   4. Relay pulley (3) according to one of claims 1 to 3, characterized in that each groove (14, 15) affects   a substantially rectangular shape, the width (L) of the base being substantially identical to the width of the vertex of the groove.   5. Relay pulley (3) according to one of claims 1 to 4,   characterized in that the fixed flanges (7) are removably mounted on the rotary hub (6). 6. Relay pulley (3) according to claim 5, characterized in that the outer flanges (7) removable   are fixed on the rotary hub (6) by screwing.   7. Relay pulley (3) according to one of claims 1 to 6, characterized in that the movable flange (8) is a flange   hollowed out, the flanks of the recess being interconnected by ribs (20).   8. Relay pulley (3) according to one of claims 1 to 7, characterized in that the flanges (7, 8) and the hub   support (6) of said flanges are made exclusively of a synthetic material.   9. Relay pulley (3) according to one of claims 1 to 8, characterized in that the rotary hub (6) supports   flanges (7, 8) is rotatably mounted on a carrier shaft (11), this carrier shaft (11) being itself carried by a support (13) pivotally mounted about an axis (12) parallel to the carrier shaft (11) so as to be able to control at will the angular displacement of the support (13) and consequently the displacement of the rotary hub (6)   3 () supports the flanges (7, 8) to obtain a variation of speed.   10. Variable speed drive, characterized in that it comprises at least one relay pulley   according to one of claims 1 to 9.