DE102005017212A1 - Freewheeling hub mechanism for cycle, includes carrier for spring-loaded pawls acting against blocking teeth to transmit drive - Google Patents

Abstract

The ratchet mechanism (3) includes a carrier (4) for pawls (6), engaging blocking teeth (7) when transmitting drive. Each pawl is spring-loaded into this position. The spring used is known as a garter spring, spring belt or ring spring. In its configuration, it passes between a resting contour (11) and a bearing section (9) on the pawl. This fits over a peg pivot (8); the pawl section (10) contour (12) being spaced away from the pivot. The resting contour (11) introduces force from the spring. The pawl includes a control contour (14), the resting contour lying between it (14) and the bearing section. The spring presses against the resting contour on one side, and is supported on the other side, against the pawl carrier. The pawl engages the inwardly-pointing blocking teeth. A section of the spring (5) runs over the bearing peg and below the resting contour. The latter is convex in shape and the spring rests within it, when the pawl is not in engagement with the teeth. A variant in which the blocking teeth point outwardly, is also described. The pawl geometry is further described in the disclosure.

Description

The The invention relates to a drive hub for bicycles, comprising a hub shell, a hub axle, several rolling bearings, a driver and at least one ratchet to the direct or indirect transmission of the drive torque over at least one torque path from the driver to the hub shell. The Pawls of the ratchet gear are in a pawl carrier z. B. swiveled in the impeller and are biased towards locking teeth. The pawls grab in the transfer phase in the corresponding locking teeth or in the freewheeling phase overtaken by the ratchet teeth.

In the US 4,400,999 is published a drive hub with two ratchets. On a rotatably connected to the driver latch carrier both outwardly and inwardly directed pawls are arranged. The outer pawls engage in the internal toothing on the hub shell and transmit the drive torque from the driver to the hub shell. The inner pawls transmit the drive torque from the driver to the planet carrier in case of intervention. The pawls are pivotally mounted in corresponding pockets on the latch carrier and are each pressed by an annular spring on the one hand in the pockets and biased against the other locking teeth. Here, the inwardly directed pawls are pressed by a spring ring radially outward and the outward pawls of the other spring ring radially inward. The effective lever arm for the attack of the spring force on the pawl is relatively small, whereby a strong spring ring is needed. If the pawls disengaged, the spring ring is pressed in the direction of locking teeth. In order to reliably prevent contact between the spring ring and the locking teeth, a larger annular gap between the pawl carrier and the locking toothing is required.

The DE 10218664 A1 shows a freewheel hub with a ratchet mechanism. Here, the radially outwardly directed pawls engage in a locking toothing on the hub shell. The pawls sit in pockets on the sprocket carrier and are biased by a coil spring ring to the outside. This coil spring ring is flexurally elastic and radially expandable in all directions. It runs along a groove on the pawl and spans tangentially from pawl to pawl. It is suitable for small preload forces and ensures an approximately equal spring force distribution to the individual pawls. This inexpensive type of latch bias is well suited for use in a freewheel hub. In a drive hub, in particular in a planetary gear, but higher biasing forces are required. In addition, there is little free space within the locking teeth available for in the retracted state of the pawls to a larger diameter expanding coil spring ring.

Of the Invention is the object of a drive hub with to equip a ratchet system, which by means of a one-piece, annular Spring element, the pawls in the direction of locking teeth with the necessary force biases. In addition, the maximum should be Diameter of the coil spring ring by the retraction movement of Do not or only slightly increase pawls.

The object is achieved by the features of the main claim. Further advantageous embodiments of the invention are described in the subclaims and the following embodiment. Essentially, the problem is solved as follows:
The pawl has a bearing portion, at one end a latch portion and at the other end a control contour. Between the bearing portion and the pawl portion or between the control contour and the bearing portion, a contact contour for introducing the biasing force is arranged laterally on the pawl.

The elastic spring element, in the form of a helical spring ring or an elastomeric ring, is guided along the side of the pawl. A portion of the helical spring ring extends, depending on the position or orientation of the locking teeth, above or below the bearing portion or under the bearing pin and presses on the position contour and thus the pawl in the direction of locking teeth. This clever arrangement of the helical spring ring on the pawl, on the one hand, causes a spring element, which can in principle only be loaded on a train and provided with an inwardly directed force profile, depending on the guidance of the helical spring ring, pushes the pawl outwards or inwards and, secondly, that the Outer diameter of the spring element in the retracted state of the pawls not enlarged, since the coil spring ring is stretched over the stationary, not changing in the radial direction, bearing portion or bearing pin. The pawl contact force acting at the end of the pawl portion in the direction of the ratchet teeth is defined by the effective lever arm or the distance of the spring contact point to the pivot point of the pawl and the current spring force of the spring element. The tuning of the pawl contact force is via the Verän the following parameters: Position of the contact contour between the pawl section and the pawl pivot; Spring constant of the spring element or spring tension which sets in the assembled state; Length of the unguided spring portion or distance between the end of the spring guide on Klinkenträgerumfang and the support on the bearing portion of the pawl; Immersion depth of the system contour in the unguided spring section between two support points of the free, tangential section of the coil spring ring. The tuning of the latch pressure can be done by varying individual parameters or by a combination of these parameters.

The coil spring ring is guided in a recess or groove on the circumference of the pawl carrier. The ratchet mechanism according to the invention is suitable both for a drive hub with inwardly and outwardly directed ratchet teeth. According to the embodiment of the locking toothing as internal or external toothing, the pawl is biased inwardly or outwardly by the helical spring ring. To push the pawl to the outside of the coil spring ring, as in the embodiment according to 1 and 2 shown tangentially from an edge of the pawl recess on the bearing portion or the bearing pin of the pawl, then under the contact contour, which deflects this coil spring portion inwards and finally back to the next edge of the latch recess, where it is again guided in the circumferential groove of the pawl carrier. In an outwardly directed locking teeth, the pawl of the coil spring ring is pressed inwards, while the coil spring ring extends tangentially from an edge of the pawl recess below the bearing portion or the bearing pin and then above the contact contour, which deflects this coil spring portion upwards and finally back to the next edge the pawl recess, where it is again guided axially and radially in the circumferential groove of the pawl carrier.

A Another embodiment of the invention provides an arrangement of the system contour between the control contour and the bearing section or the bearing pin before, wherein the coil spring ring also between the contact contour and the bearing portion or the bearing pin extends.

The Deflection of the coil spring portion between the edges of the Pawl recess in particular on the contact contour causes a Elongation of the coil spring ring and generates a biasing force, which presses the pawl towards the locking teeth.

in the Retracted state of the pawls is the coil spring section even further deflected. While the lifting of the pawl lock will be several pawls simultaneously retracted, the coil spring ring undergoes its greatest elongation and must be dimensioned accordingly.

to Schraubenfederringmontage be the pawls, the z. In to engage an inwardly directed locking teeth, with the pawl section to the outside pointing. In this position, the coil spring ring easily into the recess of the pawl between the contact contour and the bearing section or the bearing pin loaded under pretension become. The helical spring ring then jumps over an axial displacement Pawl carrier scope almost by itself in the circumferential groove of the pawl carrier and in the correct position on the pawl, namely under the plant contour.

In this version needed the drive hub according to the invention just a very light and easy-to-install coil spring ring, which acts on the individual pawls with a uniform spring force and in Direction locking teeth biased. The clever spring guide below the plant contour and about the bearing portion or bearing pin allows for a large spring deflection On the other hand, an increase in diameter of the over the bearing section or over a Bearing bolt guided coil spring ring avoided when pulling the pawls.

One Such ratchet mechanism is suitable both for torque transmission in a drive hub with planetary gear, as well as for torque transmission in a freewheel hub from the sprocket to the hub shell. there When used in a gear hub, the ratchet mechanism in arbitrary arranged torque path between the driver and hub sleeve be. The use of a coil spring ring and a pawl with a contact contour is suitable for ratchet locking with internal or outboard Locking teeth.

The Invention leaves different embodiments to. To further clarify its basic principle is an execution as Drive hub illustrated by 2 figures and described below.

It demonstrate:

1 a sectional view of the drive hub with the coil spring ring

2 a 3-D representation of the pawl

1 shows a drive hub in section along the coil spring ring. for a bicycle with a hub axle 1 , a hub shell 2 and a ratchet 3 , The ratchet mechanism 3 consists of a latch carrier 4 for receiving, by means of a spring element 5 in the form of a helical spring ring, spring-loaded pawls 6 and a corresponding locking teeth 7 , The pawl 6 has a storage section 9 with the bearing pin 8th and a latch section 10 with a latch contour 12 , The pawls 6 are each about bearing pin 8th in a latch recess 13 both sides in the latch carrier 4 stored. Between the storage section 9 and the pawl portion 10 is on the side of the pawl 6 the plant contour 11 arranged. In the assembled state, the prestressed, annular spring element 5 in a groove on the circumference of the pawl carrier 4 guided axially and radially. In the area of the latch recess 13 The coil spring ring runs tangentially from the edge of the latch recess 13 to the bearing pin 8th , There it is deflected and then around the plant contour 11 around again tangential to the next edge of the latch recess 13 curious; excited. The position of the investment contour 11 on the pawl defines the deflection of the coil spring ring and thus is in addition to the spring constant of the coil spring ring and the length of the unguided portion of the coil spring ring an important parameter to achieve the desired biasing force of the pawl 6 in the direction of locking teeth 7 , In 1 the pawls are shown in different engagement positions. At the other end of the pawl 6 , opposite the latch contour 12 , there is a control contour 14 , This control contour is due to the ratchet bias in contact with the switching contour of a not shown here, rotating shift sleeve. Depending on the angular position of the shift sleeve, the control contour 14 and thus the prestressed pawl 6 raised, causing the pawl 6 with her latch contour 12 from an engagement position in the locking teeth 7 successively brought into the disengagement position. For mounting the coil spring ring, the pawls 6 radial, with the latch contour 12 aligned to the outside. When snapping the coil spring ring in the circumferential groove of the pawl carrier of the coil spring ring passes undisturbed in its operative position between bearing pin 8th and plant contour 11 , The latch carrier 4 comes with folded pawls 6 in the hub shell 2 or pushed into the locking teeth.

2 shows a 3-D representation of the pawl 6 without the bearing pin. Laterally on the pawl 6 there is a recess 15 for receiving the coil spring ring. This recess extends even in the region of the bore 16 into it, so that the coil spring ring rests directly on the bearing pin. Between the pawl section 10 with the upward facing latch contour 12 and the storage section 9 is the investment contour 11 positioned. The coil spring ring is tangent to the bearing pin and sets depending on the angular position or engaged position of the pawl 6 more or less to the investment contour 11 at. The control contour 14 is located at the other, the latch contour 12 opposite, end of the pawl 6 and is directed downwards.

1

hub axle

2

hub sleeve

3

Ratcheting

4

pawl carrier

5

spring element

6

pawl

7

locking teeth

8th

bearing bolt

9

bearing section

10

latch portion

11

contact contour

12

catch contour

13

latch recess

14

control contour

15

recess

16

drilling

Claims (10)

Drive hub with a hub axle ( 1 ), a hub shell ( 2 ), a driver ( 3 ) or Kettenradträger and at least one ratchet gear ( 4 ) for the direct or indirect transmission of the drive torque via at least one torque path from the driver ( 3 ) to the hub shell ( 2 ) characterized in that the ratchet ( 3 ) from a latch carrier ( 4 ), a corresponding locking toothing ( 7 ) and at least one pawl ( 6 ), wherein the pawl ( 6 ) of a locking toothing directed towards the spring force of an annular spring element ( 5 ) is biased and the spring element ( 5 ) between a plant contour ( 11 ) and a storage section ( 9 ) on the pawl ( 6 ) is guided along. Drive hub according to claim 1, characterized in that the pawl ( 6 ) a storage section ( 9 ) with a bearing pin ( 8th ) and at a distance to a pawl section ( 10 ) with a latch contour ( 12 ) and between storage section ( 9 ) and latch section ( 10 ) an investment contour ( 11 ) for the introduction of force of the spring element ( 5 ) is arranged. Drive hub according to claim 1, characterized in that the pawl ( 6 ) a storage section ( 9 ) with a bearing pin ( 8th ) and at a distance to a control contour ( 14 ) and zwi bearing section ( 9 ) and the control contour ( 14 ) an investment contour ( 11 ) for the introduction of force of the spring element ( 5 ) is arranged. Drive hub according to claim 1, characterized in that the spring element ( 5 ) is formed as a helical spring ring, wherein the under bias mounted coil spring ring in the assembled state on the investment contour ( 11 ) and presses on one side at the bearing section ( 9 ) or the bearing pin ( 8th ) and on the other side on the pawl carrier ( 5 ) is supported. Drive hub according to claim 4, characterized in that the latch contour ( 12 ) in a locking toothing ( 7 ) engages with inwardly directed locking contour, wherein a portion of the annular spring element ( 5 ) above the bearing pin ( 8th ) and below the contact contour ( 11 ) runs. Drive hub according to claim 4, characterized in that the pawl ( 6 ) in a locking toothing ( 7 ) engages with outwardly directed locking contour, wherein a portion of the annular spring element ( 5 ) below the storage section ( 9 ) or the bearing pin ( 8th ) and above the contact contour ( 11 ) runs. Drive hub according to claim 4, characterized in that the contact contour ( 11 ) has a convex shape, which applies to the coil spring ring, especially in the retracted state, when the latch contour ( 12 ) of the pawl ( 6 ) not in the locking teeth ( 7 ) intervenes. Drive hub according to claim 4, characterized in that the contact contour ( 11 ) as a survey or as an impressed groove which receives a portion of the coil spring ring, laterally on the pawl ( 6 ) is arranged. Drive hub according to claim 4, characterized in that the helical spring ring on the bearing section ( 9 ) or on the bearing pin ( 8th ), wherein the bearing pin ( 8th ) through the pawl ( 6 ) and this on both sides in the latch carrier ( 4 ) is supported. Drive hub according to claim 4, characterized in that the tuning of the latch pressure force by varying the positioning of the contact contour on the pawl ( 6 ), the spring constant, the length of unguided spring section between bearing section ( 9 ) and the edge of the latch recess ( 13 ), the immersion depth of the plant contour ( 11 ) takes place in the unguided spring section or by a combination of several of these parameters.