SE545261C2 - Free hub device with spring solution - Google Patents

Abstract

A free hub device with a locking member (2) with internally formed axial grooves (14) with an essentially v-shaped cross-section, the locking member forming a first and a second wedge surface ((14a or 14b respectively). A locking body holder (4) with rollers (5), which extends into the locking member. Two sliding rollers (6) with stops in the lock body holder to each roller they transfer the spring action from the spring element. 5).The lock body holder (4) is limitedly rotatable and can assume three setting positions relative to each other in which the wedge surfaces (14a and 14b) press the rollers (5) into engagement with the outer surface (30) of the hub (10) to prevent rotation of the hub in one direction (A), the second direction (B) and a third position in which the hub can rotate freely in both directions.

Description

1 Free hub device with spring solution. Technical area.

The present invention relates to a free hub device which has a mounting part, a first locking member, which is supported by and is torsionally connected to a mounting part and has a threaded center hole and internal, axial grooves, one side wall of which forms a first wedge surface, which has in the first locking ring member a circumferential direction decreasing distance to the geometric axis of the center hole; a locking body holder, which is limited rotatable stored in the center hole of the first locking ring member and supports at least two locking bodies, which project radially a distance from the locking body holder and extend into each of the grooves of the first locking member and which are movable radially inward against the essentially radially outwardly directed spring action ; and a hub, which is rotatably stored in the lock body holder coaxially with this and has a circular cylindrical outer surface for interaction with the lock bodies, whereby each lock body after turning the lock body holder in said one direction to a first turning position adjacent to the respective first wedge surface, as the opposite spring action presses the lock body radially inwardly into the lock body holder for engagement with the outer surface of the hub, whereby the hub is prevented from rotating in said one direction.

Background of the technology.

Free hub devices of this kind are known in many different designs, all of which function in such a way that the hub, when the locking bodies are in their first turning position, is prevented from rotating in one direction but can be rotated in the other direction.

Summary of the invention.

The aim of the present invention is to provide a free hub device which is so adjustable that it can optionally prevent the hub from rotating in one direction, can allow the hub to rotate in both directions, can prevent the hub from rotating in the other direction. A particular aim here is to create a free hub device, which is designed so that it is well suited to be mounted on e.g. a wheelchair to allow in 3 optional setting positions that the wheelchair can be driven forwards but not backwards, allow it to be driven forwards as well as backwards, allow it to be driven backwards but not forwards. A simple setting of these functions would greatly facilitate the maneuvering of the wheelchair. But can of course be used for other purposes, or used for one or two of the above functions.

This purpose is achieved according to the present invention with a free hub device, which is of the kind indicated at the outset and is characterized by the fact that the second side wall of the axial grooves formed in the first locking member forms a second wedge surface, which has a decreasing distance in the second circumferential direction of the first locking member to the geometric center hole shaft, whereby each locking body after rotation of the locking body holder in said second direction to a second turning position abuts against the respective second wedge surface, which, against said spring action, presses the locking body radially inwards in the locking body holder into engagement with the outer surface of the hub, whereby the hub is prevented from rotating in said second direction, while each locking body, when the locking body holder is in an intermediate rotational position between the first and the second rotational position, is kept out of engagement with the outer surface of the hub by said spring action, so that the hub is rotatable in both directions.

The purpose of the present invention is also to improve the design of the spring action which presses the locking bodies radially inwards.

In the most common solutions, the spring's length tolerances and spring pressure and position affect the function of the solution. The lock bodies are preferably made of rollers, with each roller there are two sliding rollers that transmit the spring action. In each sliding roller there is a bottom hole for the spring element itself.

In the lock body holder there are stops that define the position of the sliding rollers to provide a secure locking. These stops are machined in the same tension as the position of the locking rollers, which provides optimal position.

Brief description of the drawings. The invention will now be described in more detail with the help of an embodiment example and with reference to the attached drawings.

Fig.1 is an exploded view and shows a free hub device according to the present invention.

Fig. 2 Shows a free hub device with lock body holder, sliding rollers with spring elements with the hub inserted therein in the disengaged position.

Fig.3 Shows a free hub device according to Fig.1 in a first locking position. Fig.4 shows a free hub device according to Fig.1 in a second locking position Description of a preferred embodiment.

The free hub device shown in the drawings has a mounting part 1 in the form of a substantially rectangular steel plate. There is a large hole in the steel sheet, in the hole the locking device 2 is mounted by turning down the locking ring device which guides in the hole in the mounting part 1, the locking device 2 is held in place by the rivets 3 in the mounting part. The locking device also has four equally distributed axial grooves 14 along the inner circumference, which have - shapely cross-section with a v-angle of approx.14O degrees. One side wall of each groove 14 forms a first wedge surface 14a and its other side wall forms a second wedge surface 14b. In the center of the locking device is a threaded hole 18 around the hole there is a low elevation 17. The v-shaped grooves and the threaded hole are machined in the same tension which gives high accuracy.

An essentially circular cylindrical locking body holder 4, which is also shown in more detail in fig.2, supports four locking bodies in the form of rollers 5. The outer diameter of the locking body holder 4 is slightly smaller than the inner diameter of the locking member 2. The lock body holder 4 has on its side facing the locking member 2 a bottom plate with a central hole 20. The lock body holder 4 also has an inner rim 21 which surrounds the central hole 20 and whose inner diameter is larger than the diameter of the hole. The inner edge 21 is divided into four sections, which are evenly distributed in the circumferential direction and form openings 22 between them, the extent of which in the circumferential direction at the inside of the edge section is smaller than the diameter of the rollers 5. The lock body holder 4 also has an outer edge 23, which delimits the lock body holder 4 outwardly and which, together with the inner edge 21, defines an essentially annular groove 25 in the lock body holder. The outer edge 23, like the inner edge 21, is divided into four sections, which are evenly distributed in the circumferential direction and between them form openings 24, which are located in the middle of the openings 22 in the inner edge 21, the extent of the openings 24 in the circumferential direction at the outside of the outer edge sections is smaller than the 5 diameter of the rollers. The rollers 5 are placed in each of the pockets formed by the openings 22 and 24 in the edges 21 and 23. The rollers 5 are so placed in these pockets that their geometric axes are parallel to the geometric axis of the central holes 17 and 20. Sliding rollers with spring elements are placed in the annular groove 25. And each abuts at its ends against two rollers 5. The sliding rollers 6 are held in place and in the correct position by circular stops 16 from the outer edge 23 and the inner edge 21. The sliding rollers 6 can move inwards into pockets in the direction of the annular groove 25. The spring elements 7 are pushed into bottom holes in each sliding roller 6. The sliding rollers are positioned so that their geometric axes are parallel to the geometric axes of the center holes 17 and 20. An axially directed threaded hole 15 is formed in three of the four sections of the outer rib 23. Two sliding rollers with spring element 17 are easily mounted without the influence of the tolerances of the spring element. The lock body holder 4 all dimensions are processed in the same tension, which gives optimal dimensions.

The operating arm 8 is screwed into the three threaded holes of the lock body holder by means of 3 identical screws 9. The operating arm has a projecting part with a hole 13. The operating arm holds all Iås rollers 5 and sliding rollers 6 in place, however, so that the Iås rollers and sliding rollers 6 are easy to move. The entire lock body holder is now one unit without the rollers being able to come out. The spring holder 26 has a long groove in the spring arm. The projecting part of the operating arm 8 is pushed through the groove so that the spring element 27 is compressed and the hole 13 appears on the other side. The spring holder 26 is screwed into the mounting part 1 by means of screws in the holes 28. In the hole 13 a line can now be attached which transmits a movement from a control device which gives three equal positions. The spring element (which can be a compression spring) strives to turn the lock body holder 4 relative to the mounting part 1 and the locking member 2 to the one locking position.

A sleeve-shaped hub 10 has a first hub portion 29 whose outer circumference is substantially equal to the inner diameter of the inner rim 21. The first hub portion 29 circular cylindrical outer surface 30 cooperates with the rollers 5 in the lock body holder 4. The hub also has a second hub portion 31, which has a smaller outer diameter than the first hub portion 29 and which is divided into two halves by means of two diametrically opposite, axial slots 32. A coupling ring 11, which has two diametrically opposed radially inwardly projecting protrusions, is rotatably arranged on the second hub part 31. Between the hub 10 and the coupling ring, leaf springs can be arranged with the same protrusion as the coupling ring (not shown) if the function so requires. Both the lock body holder 4 and the hub 10 are rotatable stored on the part 34 of the sleeve-shaped bearing bolt 12. The bearing bolt is threaded into the passage 18 in the locking device 2 and also holds down the coupling ring 11. The bearing bolt is locked rotatably to the mounting part 1 and the locking device 2 by means of a nut on the back (not shown). In the bearing bolt there is a center hole for e.g. storage of a wheel.

Fig.2 Disconnected mode.

When the operating arm 8 with the help of the rope in the hole 13 is turned in the aforementioned second direction against the action of the spring element 27, the locking body holder 4, which is connected to the operating arm 8 in a torsionally fixed manner, is also turned to an intermediate turning position relative to the mounting part I in which the rollers 5 are located in the middle of the respective v-grooves 14 in the locking device 2 without abutting against any of the side walls of the groove. At the same time, the locking body holder 4 is still in its second mutually rotating position relative to the locking member 2 . The rollers 5 are hereby held by the sliding rollers 6 and the spring elements 7 out of engagement with the outer surface 30 of the hub 10, so that the hub can rotate in both directions A and B.

Furthermore, the circular stops 16 in the lock body holder on the outer edge and the inner edge, respectively, mean that the sliding rollers 6 cannot exert pressure through the spring elements 7 on the rollers 5. The rollers 5 are completely relieved, which means that the hub 10 rotates very easily in both directions.

Fig.3 First locking direction The initial position of the free hub device is shown, in which the operating arm via the locking body holder 4 is held by the spring element 27 in a first turning position relative to the mounting part 1. In the first turning position of the locking body holder 4, the rollers 5 rest against the respective wedge surface 14a. The wedge surfaces 14a press the rollers 5 against the sliding rollers 6, the spring elements 7 affect the rollers radially inwards into the lock body holder 4 to engage with the hub 10 casing surface 30, whereby the hub is prevented from rotating in said one direction A. 4 sliding rollers leave their respective stops 16a on the inner rim and outer rim and transfer the entire force of the spring element to the rollers 5. 4 sliding rollers remain against the stops 16b on the inner rim and the outer edge and prevents the spring elements from interfering with the roller's 5 locking function. In the initial position of the free hub device, the hub 10 can thus rotate in said direction B but is prevented from rotating in said direction A.

Fig.4 Second locking direction.

On continued rotation of the operating arm 8 in said second direction B past the disengaged position fig.2, the lock body holder reaches a second rotation position relative to the mounting part 1 in which the rollers 5 abut against the respective second wedge surface 14b on the locking member 2. The wedge surfaces 14b press against the slide rollers 6s spring element 7 action on the rollers radially inwards in the lock body holder 4 to engage with the outer surface 30 of the hub 10, whereby the hub is prevented from rotating in said one direction B. 4 slide rollers leave their respective stops 16 b on the inner edge and the outer edge and transfer the entire force of the spring element to the rollers 4 slide rollers 6 remain against the stops 16a on the inner edge and the outer edge and prevents the spring elements from interfering with the locking function of the roller 5. In the second position of the free hub device, the hub 10 can thus rotate in said direction A but is prevented from rotating in said direction B.

Claims (1)

1.l. Free hub device Which has a mounting part (1) and a circular cylindrical locking ring member (2) supported by and torsionally connected to the mounting part (1) and having a threaded central hole and internal axial grooves (14), one side wall of which forms a first wedge surface (l4a) , which in the locking ring member's first rotational position in the circumferential direction (A) has a decreasing distance to the geometric axis of the central thread, whose second side wall forms a second wedge surface (l4b) which has in the locking ring member's second rotational position in the circumferential direction (B) decreasing distance to the central thread's geometric axis. An essentially circular cylindrical lock body holder (4) which is rotatably mounted in the lock ring member (2) via a bearing bolt (12) which is threaded in the threaded center hole of the lock ring member and supporting at least two lock bodies in the form of rollers (5) which project radially a piece from the lock body holder ( 2) and extends into each of the grooves (14) of the locking ring means and which against a substantially radially outwardly directed spring action Transmitted by sliding rollers (6) are movable radially inward, and a hub (10) having a circular cylindrical outer surface (3 O) for the interaction with the rollers (5) both the lock body holder and the hub are stored on the bearing bolt (12) which is threaded into the locking ring member (2). For each roller (5), between an outer edge (23) and an inner edge (21) of the lock body holder (4), two guide rollers (6) with an intermediate first printed edge (7) are arranged. The first printed wire (7) is mounted in the bottom hole in the slide rollers so as not to interfere with the function of the slide rollers (6). The lock body holder (4) is limitedly rotatable so that it can assume a first rotational position in the circumferential direction (A), a second rotational position in the circumferential direction (B) and an intermediate position. The first pressure force (7) in the lock body holder's intermediate rotation position affects the sliding rollers (6) against each of its stops (16a, 16b) forming between the outer and inner edges (2l, 23), whereby the sliding rollers (6) rest against each of its own rollers (5) which occupy a position out of engagement with the hub's outer surface (3 O) so that the hub is rotatable in both directions. Whereby the rollers (5) when turning the lock body holder (4) to a first turning position in the circumferential direction (A) rest against the first wedge surface (14a) and the casing surface (30) of the hub (10) at the same time that each roller (5) affects a sliding roller ( 6) leaves its stop (16a) the first compression spring (7) acts and transfers the full force of the first compression spring to the roller so that the hub can only rotate in a first direction. The rollers (5) at the second rotational position of the lock body holder (4) in the circumferential direction (B) rest against the second wedge surface (l4b) and the casing surface (30) of the hub (10) at the same time that each roller (5) influences a sliding roller (6) to leave its stop (l6b) the first compression spring (7) acts and transfers the entire force of the first compressed] edem to the roller so that the hub can only rotate in a second direction. . Free hub device according to claim 1, in which a second pressure spring (27) is arranged on the spring holder (26) which presses on the operating arm (8) which in turn is firmly connected in the lock body holder (4) in order to bias the lock body holder (4) in said one rotational position in the circumferential direction (A) in such a way that it assumes its first rotational position, in which each roller (5) abuts against the respective first wedge surface (14a). . Free hub device according to claim 2 where a rope and an adjustment device can set the free hub device in the said three positions. The rope is attached to a hole (13) in the operating arm (8) projecting part and which is connected to the lock body holder (4) which transfers the movement to the lock body holder (4)-