WO2001090587A1 - Adjustable-length tube - Google Patents

Abstract

The invention relates to an adjustable-length tube (11) comprising the following: an external tube (13); an internal tube (12) which can be telescopically inserted into the external tube (13) for adjusting the tube length; a locking device (14) that is held on the insertion end of the internal tube (12) for fixing said internal tube (12) in the external tube (13), said device being configured as a spring-loaded pin (21) that can be engaged in orifices (41) of the external tube (13); a guide piece (16) located on the free end of the internal tube (12) that is positioned in the external tube (13) and a closure sleeve (36) on the end of the external tube (13) that receives the internal tube (12), the guide end (38) of said sleeve that extends beyond the end of the external tube having an internal diameter which approximates to the external diameter of the internal tube (12). The aim of the invention is to allow the stable positioning, devoid of play, of the internal and external tubes, even at their maximum extension. To achieve this, the insertion end of the guide piece (16) is provided with a radially elastic guide head (26), lying adjacent to the internal circumference of the external tube (13) at an axial distance from the spring-loaded detent pin (21).

Description

Title: Adjustable tube

description

The present invention relates to a length-adjustable tube according to the preamble of claim 1.

Length-adjustable tubes are used in a variety of ways, for example for ski or trekking poles as walking sticks, walking sticks or crutches, as tripods for film and photo equipment, as handles for household or garden areas, etc.

In such a length-adjustable tube known from AT-PS 319 829, the guide piece is a cylindrical component provided with an outer intermediate shoulder, which is held at one end in the inner tube and has a radial recess for the locking device on its other end region protruding from the inner tube provided in the form of the spring-loaded locking pin. Especially when the length-adjustable tube reaches its maximum

Length adjustment range is extended, there is no longer a relative stiffness between the two tube elements (inner tube and outer tube) despite the additionally leading end sleeve. Depending on the choice of material, rattling can occur within the outer tube due to a radial relative movement of the guide piece.

The object of the present invention is to provide a length-adjustable tube of the type mentioned at the outset, which enables a stable and play-free mounting of the inner rod and outer tube even in the region of the maximum in the extended length. To achieve this object, the features specified in claim 1 are provided in a length-adjustable tube of the type mentioned.

By means of the measures according to the invention, a guidance free of play and stable transverse to the axial direction is achieved in that the guide head is under radial prestress in the outer tube and is located away from the locking pin in such a way that it forms the free end of the inner rod.

A preferred embodiment of a radially acting preload of the guide head is given by the features according to claim 2 and / or 3.

A simple assembly of guide piece and locking pin with compression spring results from the features according to claim 4.

Refinements for the stationary holding of the guide piece in or on the inner rod result from the features according to claim 5, wherein the features according to claim 6 can expediently be provided, or through the features according to claim 7.

In another embodiment of the present invention, a shock absorber is provided between the guide piece and the inner rod, as the features according to claim 8 show.

Embodiments of the shock absorber connected to the guide piece result from the features of one or more of claims 9 to 14.

Further details of the invention can be found in the following description, in which the invention is described and explained in more detail with reference to the exemplary embodiments illustrated in the drawing. Show it :

Figure 1 in longitudinal section and broken

Representation of the connecting area of a length-adjustable tube according to a first exemplary embodiment of the present invention, for example for a stick,

2A and 2B the guide piece partly in side view and partly in section or an end view of the guide piece according to arrow IIB of FIG. 2A,

Figure 3 is a corresponding to Figure 1

Representation, however according to a second embodiment of the present invention provided with a shock absorber and

Figure 4 in a partially broken representation of the guide piece of the shock absorber according to Figure 3 with a first position of the damper rod.

The length-adjustable tube 11 or 11 'shown only in certain areas in the drawing has a tubular first or inner rod 12 and a second or outer tube 13, into which the inner rod 12 can be telescopically extended and retracted and gradually by a positive locking connection in a selected position is definable. The tubular inner rod 12 is provided with a locking device 14 or 14 ′, with the aid of which it can be fixed in the outer tube 13 such that both axial and torsional forces can be transmitted from the inner rod 12 to the outer tube 13 or vice versa. Inner rod 12 and outer tube 13 are, for example, metal tubes; it is also possible that Form inner rod 12 as a full carbon rod and outer tube 13 as a metal tube. The length-adjustable tube 11, 11 'is, for example, part of a ski, trekking or hiking stick.

According to Figures 1 and 2, the

Locking device 14 is a one-piece guide piece 16 made of plastic. The guide piece 16 has a solid cylinder region 17, into which a radial blind hole 18 is machined, the length of which is greater than the radius of the solid cylinder 17. A helical spring 19 is inserted into the blind hole 18 and a detent pin 21 in this helical spring 19, which is seated with its approximately central collar 22 on one end of the helical spring 19. The free end region of the solid cylinder 17 is provided with two diagonally opposite radial blind holes 23, 24, the length of which is a fraction of the length of the blind hole 18. The guide piece 16 also has a guide head 26 at the front free end, which is hollow cylindrical and the outer peripheral surface 27 is spherical. The hollow cylindrical guide head 26 is provided with four axial slots 28 which are evenly distributed over the circumference. In this way, the guide head 26 is arranged radially elastic and at a sufficient axial distance from the locking pin 21. An axial shoulder 29 is provided between the solid cylinder 17 and the guide head 26. The outer diameter of the solid cylinder 17 corresponds to the inner diameter of the inner rod 12; the outer diameter of the guide head 26 is approximately equal to the outer diameter of the inner rod 12 at the end regions, while the maximum outer diameter of the radially movable, spherical outer surface 27 is somewhat larger than the outer diameter of the inner rod 12 and in particular somewhat larger than the inner diameter of the outer tube 13, so that the outer surface 27 abuts the inner surface of the outer tube 13 under radial prestress. The outer surface 27 can be designed like a friction lining. The guide piece 16 is inserted into the one insertion end of the inner rod 12 facing the outer tube 13 to such an extent that the axial shoulder 29 bears against the annular face of the inner rod 12. The spring-loaded locking pin 21 is snapped into a radial bore 31 of the inner rod 12 arranged at a corresponding point. The radial bore 31 is smaller in diameter than the collar 12 of the locking pin 21, so that the collar 22 bears against the inner surface of the inner rod 12 under the pressure of the helical spring 19. For the circumferential and axial fixing of the guide piece 16 in the inner rod 12, the inner rod 12 is shaped at the corresponding diagonally opposite points 32, 33 radially inward into the radial blind hole 23, 24, so that there is a positive locking.

The outer tube 13 is equipped at its end overlapping the inner rod 12 with a tube end sleeve 36. The tube end sleeve 36 has a sleeve part 37 which is pushed onto the outer tube 13 and is, for example, adhesive or fastened by means of an interference fit. A conical part 38 adjoins the sleeve part 37 in one piece, which overlaps the annular face 39 of the outer tube 13 in a form-fitting manner. Although the outer diameter of the conical part 38 is equal to the outer diameter of the sleeve part 37, its inner diameter is approximately equal to the outer diameter of the inner rod 12 to be inserted whose diameter is slightly larger than the outer diameter of the locking pin 21 of the locking device 14 held on the inner rod 12.

In an exemplary embodiment, not shown, in which an inner rod made of solid carbon material, for example, can be inserted in a length-adjustable manner, the guide piece 16 is stationary in one end of a pipe piece held, which is pushed with its other end onto the solid carbon rod and fixed in place. In this embodiment, the locking device in the form of the locking pin is included in the short pipe section mentioned.

If the inner rod 12 provided with the locking device 14 is inserted into the end of the outer tube 13 provided with the tube closure sleeve 36, the guide head 26 forming the free end is radially deformed somewhat, as a result of which the guide piece 16 is guided without play under radial prestress within the outer tube 13 , When the inner rod 12 is inserted into the outer tube 13, the locking pin 21 is pressed radially inward against the action of the spring 19, the locking pin 21 being inserted into the blind hole

18 dips so that the locking pin 21 dips into the outer tube 13. With the further insertion, the annular surface 42 of the conical part 38 reaches the outer circumference of the inner rod 12 in such a way that the inner rod 12 is guided in the tube closure sleeve 36 essentially without play. If the locking pin 21 reaches the area of a locking bore 41 of the outer tube 13, it becomes due to the action of the helical spring

19 pressed radially outward so that the locking pin 21 penetrates the locking bore 41. As a result, the inner rod 12 is fixed axially and circumferentially in the outer tube 13. It is understood that this' locking can take place in any locking bore 41. For simple latching, axially extending marking lines on the inner rod 12 and / or outer tube 13, which intersect the latching pin 21 or the latching bore 41, and / or a circumferential marking line on the inner rod 12, which intersects the latching pin axis, can be provided.

In the exemplary embodiment shown in FIG. 3, the locking device 14 'provided on the length-adjustable tube 11' is likewise provided with a guide piece 16 'which engages in the blind hole 18 Coil spring 19 and the locking pin 21 receives. The guide piece 16 'is not provided with the short radial blind holes 23, 24 but with an axial threaded blind hole 25 which is incorporated in the solid cylinder 17 and ends in front of the blind hole 18. The guide piece 16 'is surrounded by a tube section 30, the outer and inner diameter of which corresponds approximately to that of the inner rod 12 and whose length is approximately equal to the length of the full cylinder 17 of the guide piece 16'. The pipe section 30 has a radial bore 31 'through which the locking pin 21 penetrates under the action of the helical spring 19. The further features of the guide piece 16 ′ are the same as those of the guide piece 16.

The guide piece 16 'is not directly connected to the inner rod 12 but via a shock absorber 45. A damper rod 46 is screwed at one end into the axial blind hole 25 of the guide piece 16 'and is held securely by a lock nut 47 which lies against the solid cylinder 17. The shock absorber 45 also has a sliding bushing sleeve 48 made of plastic, which is axially and circumferentially fixed, for example notched, pressed in and / or glued, at its end region 51 provided with a blind hole 49 in the inner rod 12. The opposite end of the sliding bushing sleeve 48 is provided with a collar 52 which bears against the annular face of the inner rod 12.

Starting from the bottom of the blind bore 49, three pairs of diagonally opposite grooves 53, 54 and 55 are provided in the sliding bushing sleeve 48, which extend axially along the sliding bushing sleeve 48 and are arranged uniformly distributed over the inner circumference of the sliding bushing sleeve 48. Since three pairs of grooves are provided in this exemplary embodiment, they are each offset by 60 ° to one another. The pairs of grooves 53, 54, 55 have different axial lengths, the grooves of each pair being the same length. It is understood that the distribution of the lengths of the grooves 53, 54, 55 can be arbitrary.

The damper rod 46, which is cylindrical in cross section, is guided axially displaceably in the sliding bushing sleeve 48. At the end portion facing away from the guide piece 16 ', the damper rod 46 has a stop in the form of the lock nut

47 is provided, between which and the collar 52 of the sliding sleeve 48, a compression spring element 56 is arranged, which is a compression coil spring in the embodiment. The end of the metallic damper rod 46, which is located within the sliding bushing sleeve 48, is provided with a transverse bore 57 in which a bolt 58, which penetrates the damper rod 46 and projects on both sides, is held loosely. This cross bolt 58 is in its dimensions

(Length and diameter) such that it can be held in the blind bore 49 during rotation and guided in the pairs of grooves 53, 54, 55. By relative axial movement of the damper rod 46 within the bush sleeve

48 slide the cylindrical ends of the cross bolt 58 in one of the pairs of grooves.

In the illustration in FIG. 4, the transverse bolt 58 is pressed against the base of the grooves 53 under the tension of the compression spring 56. In this state, the compression spring 56 is close to its relaxation state, ie it has a small output spring force, so that a relatively large spring travel is possible for shock absorption. If the damper rod 46 is moved by an axial relative movement of the two rod or tube parts 12 and 13 in the direction of arrow A with respect to the sliding bushing sleeve 48, the cross bolt 58 passes from the grooves 53 into the blind hole 49, in which state the damper rod 46 by relative Twisting (in the circumferential direction) of the two rod or tube parts 12, 13 can be freely rotated to each other over 360 °. In the exemplary embodiment, a rotation of ± 60 ° takes place in an area above the pair of grooves 54 or the pair of grooves 55. When the two rod or tube parts 12, 13 are released axially, the cross bolt 58 comes into one of these pairs of grooves 54 or under the action of the compression spring 56 55 to the bottom. In the case of the introduction of the cross pin 58 into the shortest pair of grooves 55, the compression spring 56 is almost completely tensioned, ie it has a large output spring force, so that the length-adjustable tube 11 'has only minimal damping. If the transverse pin 58 is inserted into the grooves 54 of medium length, a damping characteristic of the shock absorber 45 which is harder than the starting position is achieved.

According to variants not shown, for better or more defined engagement of the mechanism, the cross section of tubes running into one another can be ovalized or polygonal or elliptical, the guide parts having a corresponding non-circular cross section.

Claims

claims Length-adjustable tube (11), with at least one outer tube (13) and an inner rod (12) which can be telescopically inserted into the outer tube (13) to adjust the tube length, with one at the insertion end of the inner rod (12) locking device (14) for fixing the inner rod (12) in the outer tube (13) in the form of a spring-loaded pin (21) which can be locked in bores (41) of the outer tube (13), with one on the outer tube (13) arranged free end of the inner rod (12) held guide piece (16) and with an end sleeve (36) provided on the inner rod (12) receiving end of the outer sleeve (36), the projecting end of the outer tube end (38) one of the outer diameter of the inner rod (12) has essentially the same inner diameter, characterized in that the guide piece (16) at its insertion end with one on the inner circumference of the outer tube (13) provided radially elastic guide head (26) and is provided at an axial distance from the spring-loaded locking pin (21). Pipe according to claim 1, characterized in that the guide head (26) is provided with a spherical outer contour (27) which is essentially flush at both ends with the outer circumference of the inner rod (12). Pipe according to claim 1 or 2, characterized in that the guide head (26) is provided with axial slots (28) which are preferably uniformly distributed over the circumference. Pipe according to at least one of the preceding claims, characterized in that the guide piece (16) is provided at its end region (17) facing away from the guide head (26) with a radial bore (18) for receiving the locking pin (21) acted upon by a compression spring (19). Pipe in which the inner rod (12) is tubular, according to at least one of claims 1 to 4, characterized in that the guide piece (16) with its end region (17) containing the locking pin (21) is held stationary in the tubular inner rod (12) is. Pipe according to claim 5, characterized in that the guide piece (16) is notched in the tubular inner rod (12) at preferably two diametrical locations (32, 33). Pipe in which the inner rod (12) is made of solid material, according to at least one of Claims 1 to 4, characterized in that the guide piece (16) is held stationary in a pipe piece with its end region (17) containing the locking pin (21), which in turn is held stationary on the inner rod (12). Pipe according to at least one of claims 1 to 4, characterized in that the guide piece (16) is connected at its end region (17) containing the locking pin (21) to one end of a shock absorber (25), the other end of which to the inner rod (12 ) is held. Pipe according to claim 8, characterized in that a damper rod (46) of the shock absorber (45) is attached at one end to the guide piece (16) and at the other side penetrates a sliding bushing sleeve (48) attached to the inner rod (12) and that between the inner rod (12) and Guide piece (16) a compression spring element (56) surrounding the damper rod (46). Pipe according to claim 8 or 9, characterized in that the damper rod (46) can be fixed in and with respect to the sliding bushing sleeve (48) in different axial positions. Pipe according to claim 10, characterized in that the damper rod (46) on its in the sliding sleeve (48) arranged end is provided with a locking element (58) which can be releasably locked in this by relative rotation of the damper rod (46) relative to the sliding sleeve (48). Pipe according to claim 11, characterized in that the latching element is formed by a bolt (58) projecting radially beyond the damper rod (46) and in that the sliding bushing sleeve (48) is arranged around the inner circumference and is of different lengths and has axial guide grooves (53, 54, 55), in which the bolt (58) can optionally be received. Pipe according to claim 12, characterized in that the guide grooves (53, 54, 55) extend from the inner end of a common inner circumferential recess (49) in the sliding bushing sleeve (48) and in that the bolt (58) of the damper rod (46) is rotatable in the inner circumferential recess is. Pipe according to claim 12 or 13, characterized in that three pairs of guide grooves (53 to 55) of different lengths are provided over the inner circumference of the sliding bushing sleeve (48).