DE102005014007A1 - Switching mechanism for actuating bicycle`s multi gear box, has catcher supporting in catch contour at cable reel/ switch housing, and acceleration spring fixed to reel/housing, where spring and catcher are designed as spiral spring - Google Patents

Abstract

The mechanism has a catcher (8) arranged between a cable reel and a switch housing and supporting with a retaining contour in a catch contour in the reel/housing. An acceleration spring is arranged parallel to the catcher and fixed to the reel/housing. A lifter stretches the catcher and the spring, until the catcher jumps out from the catch contour, while releasing the lifter. The spring and the catcher are designed as a spiral spring.

Description

The The present invention relates to a switching mechanism for actuating at least a gearbox on a bicycle according to the preamble of the main claim.

Switches are used for winding and releasing the spring-biased shift cable and remain in the current shift position. Such switches are from the patents DE 197 34 682 A1 and DE 100 43 612 A1 known.

The shown switches each include a switching actuator and a latch mechanism for fixing the current shift position. The detent position is by the introduction of a Aufzieh- or release movement overcome the switching actuator and a new locking position is taken after the switching movement. The holding force of the locking mechanism acts biased in the release direction Shifting force counteracts and thus secures the current gear position.

The switch in the DE 197 34682 A1 shows a latching mechanism with a prestressed locking element which engages with a latching nose in a corresponding latching contour and holds the selected switching position. This locking element is an elastic sheet metal part, which has on one side for the positive fastening a hook and is bent over on the other, free side to a locking lug.

In DE 100 43 612 A1 a switch with a locking mechanism made of plastic is shown. The locking element formed by an elastic tongue is under bias and also engages in a corresponding locking contour and thus fixes the switching position. This locking element engages in the locking contour, that the pawl can be moved to the elastic tongue only in the direction of the release contour. A switching movement in the release direction is made possible only after the locking element has been moved by a lifter from the locking contour.

Next the locking function has this switch still over an acceleration spring, which is tensioned during the release process and the cable reel, after lifting the latch by the lifter, in Release direction speeds up. This acceleration spring is as Bending spring executed and is by turning the switching actuator in the release direction biased. By biasing the acceleration spring is although the for increases the release operation on the rotary handle to be delivered switching power, but supports this is the endeavor, in both directions, as similar as possible Shifting forces.

The Although shown in the two patents switch are functional, however in terms of tunability of the switching behavior or adaptation and equalization of the switching forces required in both directions of rotation can be improved.

task The invention is to provide a switch mechanism, the a vote and approximation of the switching forces occurring in both directions allows as well uncomplicated and inexpensive can be produced.

The according to the characterizing ones Features of the claims proposed solution is suitable yourself for both Lever as well as for Rotary switch.

With This switch mechanism is the adaptation and approximation of required in both directions switching forces with inexpensive to produce components, achieved in particular with simple bending springs. The first spiral spring acts as a locking element and engages with a retaining contour in one corresponding locking contour. In this case, the locking element both on the switch housing be articulated to the cable reel and with its holding contour supported on the corresponding locking contour on the cable coil or on the switch housing. The second spiral spring acts as an acceleration spring, it becomes parallel to the locking element or over arranged and attached to the cable coil or the switch housing. The required spring forces or spring force curves are achieved by suitable material selection and spring dimensioning. The bending springs are very space-saving between switch housing and To arrange rope coil and can if necessary, simply against tougher ones or softer springs are replaced.

Special attention is paid to the procedure of the release process. On the one hand, the release torque should be adjusted to the Aufziehmoment, so be increased and, secondly, the release process should proceed as quickly as possible. This is achieved essentially with the acceleration spring, which cooperates with the latching element. The release process is initiated by a movement of the actuating element. With the actuating element and the lifter is moved, which slides over the acceleration spring and presses against the, in the direction of locking contour, biased locking element. The required switching force is in equilibrium with the sum of the dependent on the current Ausheberposition force of Be acceleration spring and the locking element. The switching force can be varied particularly easily by the definition of the force curve of the acceleration spring. If the release process continues, the acceleration spring and the latching element bend so far until the retaining contour of the latching element is pushed out of the latching contour. The acceleration spring and the locking element relax abruptly and accelerate or move while the cable reel, supported by the cable tension, in the unwinding. This unwinding movement is stopped only when the retaining contour of the locking element engages again in a new locking position on the locking contour and thus ends the release process. The Einklinkgeräusch the spring-biased locking element signals each reaching a new gear.

The Acceleration spring can over or positioned below the detent element. If one is special size Spring force is required even on both sides of the locking element acceleration springs to be ordered.

It However, is particularly advantageous, the acceleration spring on the To arrange latching element or between locking element and the lifter, while doing add up both spring forces in the release direction. In Aufziehrichtung, however, only the, against the locking contour on the switch housing directed biasing force of the locking element to be overcome. The to initiate the Aufschaltvorganges required Schaltbetätigungskraft is in essential from the currently present cable tensioning force, the to overcome the locking position required, from the spring force of the prestressed Locking element resulting holding force and the switching movement counteracting friction and breakout force together. The for the switching process required in the transmission switching power is usually effective only when the spring preload of the locking element is overcome and the Holding contour moved out of the locking contour. The to initiate the Release process required switching actuation force results from the one to be overcome spring forces the acceleration spring and the locking element and the overcoming the detent position required holding force. The acting in the release direction The force of the prestressed cable pull only works after the detent position is canceled.

The Approximation of for Both switching directions required switching forces is done by raising the switching force in the release direction, in particular by the gain of the Spring force of the locking element with an additional acceleration spring. A change the release force or its adaptation to the winding force can by simply replacing the acceleration spring against a others, with different spring characteristic, can be realized. Add the spring force of the acceleration spring and the spring force of the locking element at a switching movement in the release direction. They surrender over the Switching path, from the beginning of the switching movement to skip the detent position, a rising shift force curve. On the one hand depends on this Schaltkraftverlauf from the course of the Federspannweges, the ejector when sweeping the acceleration spring or the latching element performs. This Federspannweg can depending on the position of the pivot axis of the lifter or the constructive determination of the lift, a linear or take a progressive or degressive course. The contact path of the Aushebers is preferably designed so that the triggering point a greater contact force exists between the lifter and the acceleration spring and a increasing switching force curve in the release direction sets.

To the Others, the shift force course is decisive by the, from the interaction of the acceleration spring and the locking element resulting Spring force course influenced. With the targeted selection of an acceleration spring with appropriate spring characteristic of the spring force curve is set. By replacing and adjusting the acceleration spring of the Course of the switching actuation force be matched with simple means.

Of the inventive switch mechanism, in particular the use of simple bending springs and their joint attachment with the locking element on the cable coil or on the switch housing, allows easy tuning the release force required relative to the winding force. It results a compact and cost effective Switch assembly, suitable for both lever and rotary switches suitable. For the switching function, it does not matter if the bending springs of the Rope coil are held and the locking element in the locking contour on the switch housing engages, or whether the bending springs attached to the switch housing are and engages the locking element in a latching contour on the cable reel.

Summary the drawings

Based of four drawings will be an embodiment of the other explanation of the invention features shown:

1 shows in an exploded view the items of a rotary switch

2 shows a 3 D representation of the open rotary switch in the detent position

3 shows a 3 D representation of the open rotary switch with tensioned springs shortly after leaving the detent position

4 shows in a 3 D representation the attachment of the acceleration spring and the locking element on the cable reel

description a preferred embodiment

In 1 are shown in an exploded view of the essential components of a preferred embodiment with reference to a rotary switch. This switch is composed of the switch mechanism and the supporting components. The load-bearing components are the switch housing 1 with integrated handlebar clamp 2 and a cable pull receiver 3 as well as a handle carrier 4 , The switching mechanism is on the handle carrier 4 stored, the one-piece with the switch housing 1 connected is. The switching movement in the Aufziehrichtung is the actuator 5 positively via a takeaway 6 directly on the cable reel 7 transfer. The locking element 8th is designed as a spiral spring and angled at both ends. The one end is in a corresponding recording contour 9 at the cable reel 7 trapped. The locking element 8th is in the direction of locking contour on the switch housing 1 biased and has at the other end a holding contour 11 , which is supported in the locking position on the locking contour. In a switching operation in the mounting direction, the locking element slides 8th as long as the locking contour until the switching movement is completed. Then supports the locking element 8th or the cable coil prestressed by the cable tension in the release direction 7 again at the locking contour.

During the release process, the lifter presses 12 the locking element 8th out of the rest position. The lifter 12 is also with the actuator 5 rotatably connected and presses at a switching movement in the release direction, the locking element 8th out of the locking contour. Between locking element 8th and lifters 12 is an acceleration spring 13 arranged, which also in the receiving contour 9 at the cable reel 7 is inserted. The acceleration spring 13 is activated in this arrangement, only one switching operation in the release direction, while it is from the lifter 12 against the locking element 8th pressed. acceleration spring 13 and thus also the locking element 8th be from the lifter 12 until strained until the locking element 8th jumps out of the locking contour. The acceleration spring 13 assumes two functions, it specifically increases the switching actuation force in the release direction and accelerates after overcoming the detent position, the cable reel 7 , As the lifter 12 in addition to the spring force of the locking element 8th even the acceleration spring force opposes, the switching force increases significantly in the release direction. By selecting a suitable acceleration spring 13 the switching force in the release direction can be increased so far until the switching force is in the release direction in the desired relation to the winding force.

This switching mechanism allows a very space-saving, simple switch construction and is arranged around a central axis. This makes it particularly suitable for rotary switches. The simple bending springs and their joint attachment in a recording contour 9 at the cable reel 7 result in a particularly cost-effective switch. The arrangement of the bending springs between rope coil 7 and switch housing 1 also gives a compact switch design.

2 shows an open rotary switch in the locked position. The locking element 8th engages with its retaining contour 11 in the locking contour 10 and thus prevents accidental rotation of the prestressed in the release direction cable coil 7 , The acceleration spring 13 is above the locking element 8th is positioned and shared with this in the receiving contour 9 at the cable reel 7 held. The lifter 12 is due to the acceleration spring 13 at. When turning the actuator in the release direction of the lifter presses 12 against the acceleration spring 13 and this on the locking element 8th until the retaining contour 11 the locking element 8th from the locking contour 10 moved out. This relaxes the locking element 8th and the acceleration spring 13 , whereby the biasing force of the rope suspension 14 taken up and by the cable pull receiver 3 guided shift cable is still amplified and the cable reel 7 twisted in the release direction.

3 shows the opened rotary switch shortly after leaving the locking position. The trained as a bending spring acceleration spring 13 and the locking element 8th be from the lifter 12 tense and while the holding contour 11 from the locking contour 10 pushed out. When the retaining contour 11 the catch contour 10 leaves, those relax from the lifter 12 tensioned acceleration spring 13 and the locking element 8th abruptly and thus accelerate the cable reel 7 , The retaining contour 11 the locking element 8th slides along the locking contour 10 until it dives back into the next recess and thus ends the switching movement again.

The 4 shows the arrangement of the acceleration spring 13 and the locking element 8th at the cable reel 7 , The rope reel 7 is attached during assembly on the handle support and rotatably mounted there. The acceleration spring 13 and the locking element 8th be in the receiving contour 9 at the cable reel 7 inserted or clamped there. For formschlüssi To secure the mounting, one end of both bending springs is bent by approx. 90 °. The other end of the locking element 8th is also bent over and forms the retaining contour 11 about which the locking element 8th and with it the cable reel 7 supported on the latching contour on the switch housing. The end of the spring-loaded cable is from the cable suspension 14 positively received. The spring force of the acceleration spring 13 is adjusted so that they together with the spring force of the locking element 8th give the desired Schaltbetätigungskraft in the release direction on the actuator, or there sets the desired switching power.

1

switch housing

2

handlebar clamp

3

cable recording

4

handle support

5

actuator

6

takeaway

7

cable reel

8th

locking element

9

Up Silhouette

10

catch contour

11

retaining contour

12

Lifters

13

acceleration spring

14

rope hanging

Claims (9)

Switching mechanism for actuating at least one multi-speed gearshift on a bicycle, comprising: - a switch housing ( 1 ) - a cable reel ( 7 ) with a cable - a locking device with a locking element ( 8th ) and a locking contour ( 10 ) - an acceleration spring ( 13 ) for accelerating the cable reel ( 7 ) in the release direction - a lifter ( 12 ) - and at least one actuating element ( 5 ), characterized in that the detent element ( 8th ) between cable coil ( 7 ) and switch housing ( 1 ) is arranged and for fixing the cable coil ( 7 ) with a holding contour ( 11 ) on a latching contour ( 10 ) and that during the release process, one of the actuating element ( 5 ) moving lifter ( 12 ) at least one acceleration spring ( 13 ) and the locking element ( 8th ) until the locking element ( 8th ) from the locking contour ( 10 ) pops out. Switch mechanism according to claim 1, characterized in that the acceleration spring ( 13 ) and the locking element ( 8th ) formed as a spiral spring and on one side of the cable coil ( 7 ), wherein the retaining contour ( 11 ) of the locking element ( 8th ) in a latching contour ( 10 ) on the switch housing ( 1 ) intervenes. Switch mechanism according to claim 1, characterized in that the acceleration spring ( 13 ) and the locking element ( 8th ) formed as a bending spring and on one side of the switch housing ( 1 ), wherein the retaining contour ( 11 ) of the locking element ( 8th ) in a latching contour ( 10 ) on the cable reel ( 7 ) intervenes. Switch mechanism according to claims 2 and 3, characterized in that the acceleration spring ( 13 ) and the locking element ( 8th ) and together from a receiving contour ( 9 ) and the acceleration spring ( 13 ) between lifters ( 12 ) and locking element ( 8th ) is arranged. Switch mechanism according to claims 2 and 3, characterized in that the acceleration spring ( 13 ) and the locking element ( 8th ) and together from a receiving contour ( 9 ) and the locking element ( 8th ) between lifters ( 12 ) and acceleration spring ( 13 ) is arranged. Switch mechanism according to claims 2 and 3, characterized in that the adaptation or increase in the release direction required Schaltbetätigungskraft via the acceleration spring ( 13 ) or optionally acceleration springs ( 13 ) are used with different spring force gradients. Switch mechanism according to claim 1, characterized in that the spring forces of the acceleration spring ( 13 ) and the locking element ( 8th ) add in the release process and by their relaxation, the cable coil ( 7 ) when the lock function is canceled. A switch mechanism according to claim 7, characterized in that the switching operating force generated during tensioning of the acceleration spring ( 13 ) and the locking element ( 8th ) by the movement of the lifter ( 12 ) arises in the release direction, increases until the cancellation of the detent position. A switch mechanism according to claim 7, characterized in that the course of the Schaltbetätigungskraft, during the tensioning of the acceleration spring ( 13 ) and the locking element ( 8th ) arises in the release direction, by the action of the lifter ( 12 ) on the acceleration spring ( 13 ) and the locking element ( 8th ) and or by the spring force curve of the acceleration spring ( 13 ) and the locking element ( 8th ) influenced or purposefully coordinated becomes.