EP0058848A1 - Ski-stick of adjustable length - Google Patents

Abstract

The tubes (1, 2), which can be pushed into one another, are provided with bolts (23) and several bolt latches (16, 17, 18). When shortening the stick, a spring (26) is tensioned. The extension of the stick is effected by the tensioned spring (26). The switch (24) is e.g. on the back of the ski pole grip (3). The bolt (23) is supported on the outer tube (2), and the bolt latches (16, 17, 18) are located on the inner tube (1, 1 '). The bolt latches are designed as a tube opening (16, 17) and as a support shoulder (18) on the end face. The bolt is provided on a rocker arm (22) which is spring-loaded (34) and is motion-connected to the changeover switch (24). The entire mechanism for length adjustment is located in the ski pole handle (3). This can be easily mounted on standard ski pole tubes (1). The ski pole is especially intended for cross-country skiers who, depending on the terrain, e.g. can be set to three different lengths while running, the length set in each case being fixed by positive locking of the tubes (1, 2) which can be pushed into one another. The bolt can be brought into such a central position from the engagement area of the bolt latches by means of the switch (24) that no locking occurs, so that a resilient ski pole is achieved.

Description

The invention relates to a ski pole, which is adjustable in length, with two telescopically displaceable tube sections, which can be fixed in their mutual position by a locking device, with an operating element on the ski pole handle for fixing the two tube sections or for releasing the fixing, whereby the actuating member can be reached from the fingers of the hand holding the ski pole, the locking device being designed as a bolt with a plurality of bolt latches, and a spring supported on one end on the inner tube section and on the other end on the outer tube section, which tends to axially push both tube sections apart .

Such a ski pole can be used on the one hand as a rigid ski pole with an adjustable length and on the other hand as a resilient ski pole. This is particularly interesting for a cross-country pole, because on the one hand the stick length can be adapted to the terrain and on the other hand the spring force stored in the stick as Feed aid can be used.

Such a ski pole is known from NO-PS 73 712. In this known ski pole (Fig. 4) the latch consists of elastically radially expandable tongues which are actuated by the actuating member via an axial rod. The latch catches consist of circumferential grooves. The actuator is designed as a push button. If the button is not pressed, the two pipe sections are locked together and there is a rigid ski pole with the length set in each case. As long as the button is pressed, the lock is released and there is a resilient ski pole. The disadvantage of this ski pole is that when the ski pole is used as a resilient cross-country pole to use the stored spring force as a feed aid, the operating button must always be kept depressed. Another disadvantage is that when the rigid ski pole is adjusted in length, the latch is not set to predetermined, e.g. can inevitably snap in two or three bolt latches if the ski pole is in motion, i.e. when resting on the ground, has reached the desired length. The stick can be adjusted from a resilient stick to a rigid stick and vice versa, and the rigid stick can be lengthened or shortened while running without impairing the running rhythm.

The aim is to create a ski pole with which the aforementioned disadvantages can be avoided.

The ski pole according to the invention is characterized in that the latch is present in the case of a two-armed rocker arm which is in the ski pole handle-bearing, outer tube section is mounted, that the rocker arm is spring-loaded, and that the bolt is attached to one rocker arm and the other Ki ^pp lever arm attacks the actuator.

• Fig. 1 einen Längsschnitt durch den oberen Teil eines Skistocks, der den Skistockgriff umfasst, in einer ersten Stellung des Betätigungsorgans,
• Fig. 2 die gleiche Darstellung wie in Fig. l, wobei sich das Betätigungsorgan in einer zweiten Stellung befindet,
• Fig. 3 ein zweites Ausführungsbeispiel des Skistocks, in der gleichen Darstellungsweise wie die Figuren 1 und 2, wobei sich das Betätigungsorgan in einer dritten Schaltstellung befindet,
• Fig. 4 eine Verbesserung am Skistock in schematischer Darstellung, wobei diese Verbesserung bei den Skistöcken nach den Fig. 1-3 vorhanden sein kann, wobei sich das Betätigungsorgan in einer ersten Stellung befindet, und
• Fig. 5 die Verbesserung nach Fig. 4, wobei sich das Betätigungsorgan in einer zweiten Stellung befindet.

Several exemplary embodiments of the subject matter of the invention are shown in the drawing. Show it:

• 1 shows a longitudinal section through the upper part of a ski pole, which includes the ski pole grip, in a first position of the actuating member,
• 2 shows the same representation as in FIG. 1, the actuating member being in a second position,
• 3 shows a second exemplary embodiment of the ski pole, in the same representation as FIGS. 1 and 2, the actuating member being in a third switching position,
• Fig. 4 shows an improvement on the ski pole in a schematic representation, this improvement may be present in the ski poles according to Figs. 1-3, with the actuator being in a first position, and
• Fig. 5 shows the improvement of Fig. 4, wherein the actuator is in a second position.

The ski pole has an inner tube section 1, which carries the snow plate and the ski pole tip at the lower end, not shown. There is also an outer tube section 2, which is only extends a little over the length of the ski pole grip. The ski pole grip comprises a shell 3 consisting of a plastic material, which is formed in several parts in practice, but is shown in one piece in the drawing for reasons of clarity. In the case of cross-country ski poles, this plastic shell 3 is at least partially preferably covered with suede, which is not shown. The outer tube section 2 is provided with a fitting 4 which has an outer contour according to the line 5. This fitting 4 has a cut surface 6. In the plan view of the ski pole, the fitting 4 has a U-shape, the two free leg ends in the drawing on the left and the two legs lying parallel to the drawing plane. These two legs are each provided with a bearing bore for receiving a journal 7. The bearing shell 3 is provided with a slot-like opening 8, at the mouth edge of which a sealing ring (not shown) can be attached.

At the lower end of the ski pole grip there is a clamping eccentric 11 which is mounted in a clamping bracket 12. The screwing used for tensioning the clamping bracket 12 also serves at the same time for mounting the clamping eccentric 11. It was mentioned at the beginning that the grip 3 is covered with suede. This suede can be pressed onto the grip shell 3 with the clamping clip 12, so that the suede cover is finished cleanly and securely at the bottom. The clamping eccentric 11 is used to clamp the two ends of the tape, not shown, which are provided for the hand in a loop, not shown. This loop is available in a known manner with every ski pole handle. The two mentioned bands of the loop ver run in a longitudinal channel 9, which lies between the shell 3 and the outer tube section 2. The loop then protrudes from the handle when there is an opening 10.

The locking device of the ski pole in the first exemplary embodiment according to FIGS. 1 and 2 is now explained below, with which the two mutually displaceable tube sections 1 and 2 can be fixed in their mutual position, in which case this fixing can be released again. The inner tube section 1 carrying the ski pole tip and the snow plate is fastened to a tubular handle insert 1 'by means of a screw 13. The handle insert 1 'and the outer tube section 2 are made of light metal and have a cross-sectional area (not shown) such that they form a groove and ridge anti-rotation device with respect to one another. A bearing bush 14 made of a plastic or brass is axially displaceably guided in the outer pipe section such that the inner pipe section 1, 1 'is held in a non-rotatable manner with respect to the outer pipe section 2. A bearing bush 15 made of brass or plastic is immovably inserted in the handle insert 1 '. The aforementioned components 1, 1 ', 14 and 15 are therefore immovably connected to one another and carry the ski pole tip and the snow plate at the right end of the ski pole, not shown. In the exemplary embodiment according to FIGS. 1 and 2, the inner tube section 1, 1 'is provided with three locking latches 16, 17 and 18. The two locking latches 16 and 17 are designed as an opening in the inner tube section 1, 1 ', and the locking latch 18 is designed as an end-side support shoulder in the bearing bush 15 and thus in the inner tube section 1, 1'. 2 clearly shows that this support shoulder 18 with respect to the longitudinal central axis of the components 1, 1 'and 15 is eccentric. The bolt latches 16, 17 and 18 lie one behind the other in the longitudinal extent of the inner tube section 1, but on both sides of the aforementioned longitudinal central axis. In the example, the bolt latch 17 can be a circular hole, and the bolt latch 16 is designed as an elongated hole with the same width as the diameter of the bolt latch 17.

The fitting 4 carrying the journal 7 is fastened to the outer tube section 2 by means of a screw 19. By means of this screw 19, a sleeve 20 is still held in the outer tube section 2. The sleeve 20 is provided with a bearing 21 for a two-armed rocker arm 22. A latch 23 is attached to one rocker arm and an actuator 24 engages the other rocker arm. The rocker arm 22 is mounted on the outer tube section 2 via the screw 19 and can assume the two tilted end positions shown in FIGS. 1 and 2 and an intermediate middle position, not shown in FIGS. 1 and 2, in which the rocker arm 22 is parallel to the longitudinal central axis of the outer tube section 2. At the end of the bushing 20 there is also a rubber buffer 25, which can consist, for example, of foam rubber, so that air bubbles are enclosed in cells. The support shoulder 18 connected to the inner tube section 1 can rest against this rubber buffer 25 (FIG. 1). Within the outer pipe section 2 there is a helical compression spring 26 which is supported at one end on the bearing bush 15 and thus on the inner pipe section 1. With its other end, the spring 26 is supported on the sleeve 20 and thus on the outer tube section 2. This helical compression spring tends to axially press the two pipe sections 1 and 2 apart, the end position shown in FIG. 2 and thus the greatest ski pole length is reached. Even in this state, the spring 26 is still biased. 1 shows the compressed position of the spring 26, the other end position, namely the shortest length of the ski pole, being reached. To limit the relaxation of the spring 26 and thus to limit the greatest length of the ski pole, a wire loop 27, which is articulated on the rocker arm 22 and is bent in a hairpin shape in the free end area 28, so that in the area 28 the wire loop 27 surrounds the screw 13 on both sides. The spring 26 can therefore only relax until the end 29 of the loop 28 abuts the screw 13. With the two end positions of the compression spring 26 shown in FIGS. 1 and 2, the ski pole length can be changed by 70 mm in one embodiment. In the longest position of the ski pole shown in FIG. 2, the latch 23 bears against the support shoulder 18 of the bearing bush 15. In the shortest position of the ski pole shown in FIG. 1, the latch 23 lies in the latch latch 16.

The actuating member 24 for the rocker arm 22 is designed as a cam disk which can be rotated about the bearing pin 7 and whose axis of rotation, namely the longitudinal axis of the bearing pin 7, is at right angles to the ski pole axis. The cam disk 24 is provided with four cams 30, 31 32 and 33. From Fig. 2 it can be seen that the cam 30 projects significantly beyond the immovable handle of the ski pole. With this rotated position of the cam disk 24, the cam 31 could in practice lie approximately flush with the grip shell 3. In the embodiment shown, the cam 31 protrudes only slightly beyond the grip 3 to the outside. 2 shows the one rotated end position of the actuating member 24, and in FIG. 3 the other rotated end position of the actuator 24 shown, the cam 31 projects significantly beyond the handle shell 3 to the outside. With this position of the actuating member 24, the cam 30 could in practice be approximately flush with the grip shell 3. 1 shows a middle position of the actuating member 24, both cams 30 and 31 projecting significantly beyond the grip shell 3. Since it has already been mentioned that the hand strap present in the ski pole grip protrudes outwards from the opening 10, that is to say in the drawings it lies above the ski pole grip, this loop facing the body of the skier, it can be seen that the actuating member 24 faces away from the loop and thus lies on the back of the ski pole grip. The actuating member 24 is in this case placed in the upper region of the ski pole grip in such a way that it lies in the region of engagement of the index finger of a hand carrying the ski pole. The two cams 30 and 31 are therefore intended to be pressed alternately into the interior of the ski pole grip by an operator. The other two cams 32 and 33 are always within the ski pole handle.

The rocker arm 22 is under the action of a rocker arm spring 34, one end of which is supported by a pin 35 on the fitting 4. The other spring end 36 rests on one arm of the two-armed rocker arm 2. The spring 34 tends to push the rocker arm 22 into the end position shown in FIG. 1. The actuating member 24 is connected in motion via the cams 32 and 33 to the rocker arm 22 and thus to the bolt 23 in order to bring the bolt 23 into or out of engagement with one of the bolt latches 16, 17 or 18. 1, the rocker arm spring 34 is still biased.

In the ersichtli from Fig. 2 Chen an end position of the actuator 24 (the cam 31 is pressed inside the ski pole grip), the rocker arm 22 is held locked by the cam 32 against the force of the rocker arm spring 34 in the end position shown in FIG. 2. This locking is achieved in that the force exerted by the spring end 36 on the rocker arm 22 in FIG. 2 generates a torque that rotates clockwise about the bearing pin 7. In this locked end position of the actuating member 24, the bolt 23 is held in the bolt latch designed as a support shoulder 18 in order to keep the ski pole locked in its longest state. The two telescopically displaceable pipe sections 1 and 2 are moved the farthest apart in this locked position. This bolt latch 18 is closest to the actuator 24.

In the central position of the actuating member 24 shown in FIG. 1 (both cams 30 and 31 lie outside the immovable grip shell 3), the rocker arm 22 is in a position lying between the two cams 32 and 33. In this position of the rocker arm 22, this is loaded by the rocker arm spring 34 by means of the bolt 23 in the bolt latch 16. As a result, the two pipe sections 1 and 2 are pushed into each other the most, so that the ski pole is the shortest.

If, in the exemplary embodiment according to FIGS. 1 and 2, the actuating member 24 is pressed into the other end position shown in FIG. 3, so that the cam 30 lies inside the immovable handle 3, the rocker arm 22 is countered by the cam 33 Force of the rocker arm spring 34 is pressed into a position approximately parallel to the longitudinal axis of the ski pole, so that the latch 23 is out of engagement with the Bolt latch 16 arrives and is therefore not in contact with component 1 '. Now the two pipe sections 1 and 2 are no longer locked together and the two pipe sections 1 and 2 can be telescopically displaced into one another in a spring-elastic manner.

The mode of operation of the exemplary embodiment shown in FIGS. 1 and 2 is explained below, reference being made to this FIG. 3 because of the third position of the actuating member 24 shown in FIG. 3 only to the extent that it is necessary to understand the mode of operation of the example according to FIGS Figures 1 and 2 is necessary. In the position of the ski pole shown in FIG. 1, the two pipe sections 1 and 2 have been most strongly displaced into one another, so that the ski pole is the shortest. The spring 26 has been most compressed. This shortest length of ski poles is maintained since the bolt 23 lies in the bolt latch 16 and as a result the two tube sections 1 and 2 are locked together. The actuator 24 is in its middle position. This position is maintained by the rocker arm spring 34. The ski pole shown in FIGS. 1 and 2 can be set to the three lengths "short""normal(middle)" or "long". In order to move from the "short" position shown in FIG. 1 to the "middle" position, the cam 30 is briefly pressed inwards by the actuating member 24 by the skier, as can be seen from FIG. 3. The skier hereby gives only one impulse, but no longer leaves his index finger on the cam 30. The bolt 23 comes out of the bolt latch 16 as a result of the impulse, so that the compression spring 26 can relax. The bolt 23 slides loaded by the rocker arm spring 34 along the wall of the component 1 'and snaps into the bolt latch 17. The ski stock now has its medium length. If the ski pole is to take its greatest length, the cam 31 of the actuating member 24 is pressed inwards, as shown in FIG. 2. The bolt 23 then disengages from the bolt latch 17 and is held locked in the position shown in FIG. 2. The stick is now the longest. The extension of the stick is thus carried out by the force of the spring 26. This spring can therefore be made relatively weak, and practice has shown that the force to compress the spring 26 into the position according to FIG. 1 is in the range of Should be 1 to 2 kp. This lengthening of the ski pole can be carried out by the cross-country skier, for example, when the ski pole has been lifted off the ground and is moved forward, before the ski pole is supported on the ground again.

If the ski pole has its greatest length and is to be shortened, the following procedure is followed. The actuating member 24 is pressed inwards at the bottom, ie the cam 30 is pressed into the inside of the handle according to FIG. 3, so that the rocker arm 22 is held in a position parallel to the longitudinal axis of the ski pole by the cam 33. The ski pole is now supported on the ground via the pipe section 1 and the cross-country skier presses the pipe section 2 downward against the force of the spring 26. The bolt 23 held in the center of the pipe section 2 passes through the bearing bush 15 into the interior of the component 1 '. The actuator 24 is released so that it assumes its central position shown in FIG. 1 by the force of the spring 34. The bolt 23 thereby snaps loaded by the spring 34 into the bolt latch 17. If the ski pole is to be shortened still further, the same procedure is followed, ie the cam 30 is pressed inwards again, and at the same time the pipe is lowered cut 2 pressed against the force of the spring 26 down, that is supported on the ground. The bolt 23 now arrives in the bolt latch 16. The lengthening of the ski pole is therefore triggered only by impulse, ie by briefly pressing the cam 30, and is automatically effected by the spring 26. The ski pole is shortened against the force of the spring 26, so that the ski pole must therefore be supported on the ground in order to shorten it. The illustrated ski pole can be set to three lengths, each ski pole length being lockable and each locked position being releasable by means of the actuating member 24.

The illustrated ski pole can therefore be set to three lengths, the pipe sections 1 and 2 being locked in each ski pole length, so that a rigid ski pole but not a resilient ski pole results. This length adjustment of the ski pole can e.g. be very beneficial for a cross-country skier. The ski pole can then be adjusted the shortest in steep terrain, and the longest ski pole would then be used in sloping terrain. In the terrain, you can then use the ski pole with its medium length, whereby this medium length is the normal length of the ski pole, which the cross-country skier would also use if he used a non-adjustable ski pole. The ski stick, which is adjustable in three lengths, can also be used for alpine skiing, e.g. for rental floors, e.g. can be rented from a sports shop to different people and thus the length can be adapted to the respective skier.

The illustrated ski pole can, however, also be designed in a second exemplary embodiment shown in FIG. 3 in such a way that, in addition to the Ver position on fixed, ie lockable ski pole lengths is also resilient, so that the ski pole between its shortest position and its longest position is resilient. In this second exemplary embodiment, the latch catches are located on only one side with respect to the longitudinal central axis of the ski pole. There are only the two latch latches 17 'and 18'. A rocker arm 22 'carries a bolt 23'. If the latch 23 'is latched into the latch latch 17', the ski pole has its normal length. If the bolt 23 'is in the bolt latch 18', the ski pole has its greatest length. These two ski pole lengths have thus been formed again by locking the pipe sections 1 and 2, so that the ski pole is rigid in itself. A tubular component 1 ″, which has the two locking latches 17 ′ and 18 ′, is in turn fastened to the inner tube section by means of the screw 13. In the embodiment according to FIG. 3, a helical tension spring 26 'is used, which is therefore between the two pipe sections 1 and 2. One end of the spring 26 'is supported by pins 37 on the component 1 "and thus on the inner tube section 1. The other end of the spring 26' is supported on a push rod 38 which is mounted on the screw 19. Because this screw 19 is connected to the outer pipe section 2, the aforementioned spring end is supported on the pipe section 2. When the two pipe sections 1 and 2 are pushed together, the tension spring 26 'is tensioned. The position of the ski pole shown in Fig. 3 is not a rest position , because the compression spring 26 'is stretched to its maximum length, the component 1 "being in contact with the bearing body 20'. In the position shown in FIG. 3, the inner pipe section 1 is thus supported on the ground via its ski pole tip, not shown, or via its snow plate, and the cross-country skier presses the outer pipe section 2 against the Force of the spring 26 'at the bottom. If the force exerted by the cross-country skier ceases, the outer tube section 2 springs upwards (the ski pole takes up its greatest length), namely until the loop end 29 ′ abuts the screw 13. It has been shown in practice that this resilient length of the ski pole can be, for example, 70 mm. If this resilient cross-country ski pole is used, it should make running easier for the runner due to its springback; there should be a pushing movement against the ground. In order to achieve a noteworthy improvement here, the tension spring 26 'should be harder than the compression spring used in the first embodiment. It has been found in practice that the spring 26 'is so hard that a force of 2-14 kp should be applied in order to bring it into the maximum tensioned position according to FIG. 3.

3 is as follows: If the cam 30 is pressed into the inside of the handle according to FIG. 3, only a momentary impulse is given, because the position of the actuating member 24 rotated in FIG. 3 is not stable, because the Spring 34 strives to press the actuator 24 into the stable position shown in FIG. 1. As long as the cross-country skier presses the cam 30 inwards with his finger, the rocker arm 22 'is held in the middle position shown in FIG. 3, so that the latch 23' is not in contact with the component 1 ''. The tensioned spring 26 'tends to extend the ski pole. If the actuating member 24 is released, the bolt 23 'is pressed against the component 1''by the rocker arm spring 34 and the ski pole is extended until the bolt 23' snaps into the bolt latch 17 '. The ski pole now has its normal length, the pipe sections 1 and 2 being rigidly locked together. If the cross-country skier wants to have the ski pole in its greatest length, he must continue to press the cam 30 inward according to FIG. 3 to relax the spring 26 '. The bolt 23 'then enters the bolt latch 18'. So if the cam 30 is released by the cross-country skier, the rocker arm spring 34 always rotates the actuating member 24 into the central position shown in FIG. 1, so that the bolt 23 'snaps into a bolt latch as it passes and remains in it until either again Cam 30 or the cam 31 according to FIG. 2 is pressed inwards. If the cam 31 is pressed into the position according to FIG. 2, the actuating member 24 is brought into a stable position, so that the actuating member 24 maintains its position shown in FIG. 2 even when the cam 31 is released, the latch 23 ′ in its position shown in Fig. 3 remains, so it can not snap into one of the bolt latches. The ski pole has thus become a resilient stick.

Both exemplary embodiments have in common that the actuating member 24 has only two stable positions, namely the positions shown in FIGS. 1 and 2. The position of the actuating member 24 shown in FIG. 3 is only maintained as long as the skier presses the cam 30 inwards with his finger. As soon as this effort is eliminated, the actuating member 24 returns to its central position shown in FIG. 1. What is different in the two exemplary embodiments, however, is the position of the bolt 23 'when the actuating member 24 has been pressed into the stable position according to FIG. 2. In the first embodiment according to Figures 1 and 2, the Rie is gel 23 here in a bolt latch 18, whereas in the second exemplary embodiment according to FIG. 3 the bolt 23 'is held out of the engagement area of a bolt latch. The use of a compression spring 26 or tension spring 26 'is not a different feature of the two exemplary embodiments, since both exemplary embodiments can in principle be equipped both with a tension spring or with a compression spring. Since a stronger spring is used in the resilient cross-country pole than in the case of a stick that can only be adjusted to fixed lengths, it is advantageous to design this stronger spring as a tension spring, since it cannot buckle and cannot rest against the outer wall. If the ski pole is only adjusted to several fixed lengths, the spring 26 can be relatively weak, since this spring only has to cause the two tube sections 1 and 2 to move apart automatically. For example, according to FIG. 3, it can also be said that a tension spring 26 'has proven itself in practice, which is preloaded at about 3 kp in the idle state. The tension spring 26 'can be screwed relative to its pin 37, which serves as support, so that the effective length of the spring can thereby be varied. As a result, more or fewer turns of the spring can be removed from the spring action.

It has been found in practice that with a ski pole designed as a cross-country pole, the position and shape of the actuating member is very delicate, since the ski pole should be able to be switched over by the cross-country skier at any time without impairing running. Instead of the illustrated embodiment of the actuating member as a rotatable cam disk 24, it can also be designed as a longitudinally displaceable pressure pin which, also lying on the back of the ski pole grip, moves transversely to the longitudinal axis of the ski pole bar and acts directly on the rocker arm 22. A head of the pressure pin projects more or less far from the bearing shell 3 and can be pressed more or less far into the interior of the ski pole handle against the force of a spring. When the pressure pin is moved in a straight line, the same is achieved as when the cam 30 is actuated according to FIG. 3, ie if the finger pressure is removed, the pressure pin is pressed outwards again into its rest position as in FIG. 1 by the spring mentioned. In order to achieve a locked position of the pressure pin as in Fig. 2, a long side of the pressure pin is provided with a locking groove which can be brought into engagement with an immovable locking cam by a slight movement of the pressure pin transversely to its length profile (i.e. in the longitudinal axis of the ski pole). The latter can be designed and arranged as a stationary pin like pin 7 or 35.

In a further exemplary embodiment, the aforementioned pressure pin can also be arranged rotated by 90 °, so that the elongated pressure pin now lies in the longitudinal axis or parallel to the longitudinal axis of the ski pole. The pressure pin is then no longer on the back of the ski pole grip, but on the head of the ski pole grip. A mechanical lever (not shown) for the movement connection then lies between the pressure pin arranged in this way and the rocker arm 22.

FIGS. 4 and 5 show an improvement which can be applied to the ski poles in FIGS. 1 to 3. It has been shown in practice that it is more expedient if the ski pole is provided with a preselection circuit. This means that the cross-country skier undertakes the desired actuation of the actuating member to adjust the ski pole, but that the ski pole does not have to be supported on the ground at the same time. For example, the cross-country skier can actuate the actuating member when the arm is swung forward; but it is only when the ski pole is subsequently pushed off the ground that the ski pole is converted. This does not affect the rhythmic movement during cross-country skiing.

In FIGS. 4 and 5, those components which correspond to the components shown in FIGS. 1 to 3 are provided with the same reference number, which has been expanded by one hundred.

The ski pole has an inner tube section 101, i.e. the actual pole. There is also an outer tube section 102 that is part of the handle. In the outer pipe section 102 there is a bushing 120 with a bearing 121 for a two-armed rocker arm 122. One rocker arm carries a bolt 123. On the outer pipe section 102 there is a fitting 104, on which a rocker arm spring 134 is supported. This rocker arm spring 134 is supported with its other end on the other arm of the rocker arm 122. An actuator 124 is pivotable about a bearing journal 107 mounted in the fitting 104. The actuating member 124 is designed as a cam disk and has cams 132 and 133 which can come into engagement with the rocker arm 122. The inner tube section 101 is provided with three locking latches 116, 117 and 118 '. The ski pole still has a grip shell 103 made of plastic. Up to this structure, the ski pole shown schematically in FIGS. 4 and 5 corresponds to the design of the ski pole according to FIGS. 1 to 3. The deviations of the ski pole according to FIGS and 5 compared to the ski pole of Figures 1 to 3 explained. The actuator 124 has a different design. The actuating member 124 has only a single manually operated cam 42. There are therefore no longer two cams corresponding to cams 30 and 31 in FIGS. 1 to 3. In Figures 4 and 5, only two different positions of the actuator 124 are shown. 4, the rocker arm 122 lies in a recess 41 between the two cams 132 and 133. 5, the rocker arm 122 is acted on via the cam 132. A third position, not shown, of the actuating member 124 would now be conceivable, in which the rocker arm 122 is acted on via the cam 133. This latter type of actuation can be present in one embodiment of the Skistokkes; however, an embodiment is also possible in which this third position of the actuating member 24 is not used and thus cannot be assumed by a built-in lock. In the case shown, the actuator 124 should therefore only be able to assume the two positions shown. The ski pole shown in FIGS. 4 and 5 is provided with a spring-elastic preselector 39. This is designed as a leaf spring. This leaf spring 39 is attached to the rocker arm 122 at the point 40. The preselector 39 is thus present in the rocker arm associated with the actuator 124. It can also be said that the preselector 39 is located between the actuator 124 and the bolt 123. The rocker arm 122 is constantly pressed against the actuating member 124 by the rocker arm spring 134 via the preselector 39. The actuating member 124 can assume the two fixed positions shown in FIGS. 4 and 5 in the manner of a snap switch.

The spring-elastic pre-selection element 39 has the effect that the actuating element 124 can be moved into a changed position without this having to result in an immediate adjustment of the rocker arm 122. In Figures 4 and 5, the rocker arm 122 is in the same position, although the actuator 124 is in two different positions. The position of the rocker arm 122 shown in FIG. 5 is of course only maintained as long as the inner tube section 101 exerts such a rightward force on the bolt 123 which exceeds the force stored in the spring 39. The aforementioned force exerted by the inner tube section 101 on the bolt 123 is brought about by the spring 26 or 26 ', which is shown in FIGS. 1-3. This spring tends to move the two pipe sections 101 and 102 axially apart. If the ski pole shown in FIG. 5 is supported on the ground, this spring force is counteracted, so that the rocker arm 122 is switched over by the force of the leaf spring 39, so that the bolt 123 disengages from the bolt latch 117. In the stick according to FIGS. 4 and 5 there is a push rod 138 which acts on a tension spring as in the example according to FIG. 3. If this tension spring is again significantly harder than the compression spring explained with reference to FIGS. 1 to 2, then the ski pole shown in FIGS. 4 and 5 can be used in two ways. One as a short stick, in which the two pipe sections 101 and 102 are completely shifted into one another and the bolt 123 lies in the bolt latch 117, with the actuating member 124 in the position according to FIG. 4, and the other time as a resilient stick, whereby the rocker arm 122 is approximately parallel to the push rod 138, so that the bolt 123 is outside the engagement area of the bolt latch le 117 and the actuator 124 is in the position shown in FIG. 5.

The following explains how the switching of the ski pole according to FIGS. 4 and 5 takes place. In Fig. 4, the actuator 124 is pushed down in the longitudinal direction of the ski pole, which means a desired short rigid pole. If this stick is supported on the floor, the two pipe sections 101 and 102 are increasingly shifted into one another. The rocker arm 121 is provided with a run-up ramp 43 upstream of the bolt 123 for the inner tube section 101. The end face of the pipe section 101 facing the run-up ramp 43 meets the ramp 43, so that the rocker arm 122 is pivoted clockwise against the force of the spring 134, so that the pipe section 101 can reach the position according to FIG. 5. In this position, the bolt 123 is snapped into the bolt latch 117, the actuator having the position shown in FIG. 4. Now there is a short, rigid ski pole. If the resilient ski pole is desired, the actuating member 124, viewed in the longitudinal direction of the ski pole, is pivoted upward into the position according to FIG. 5. The preselection organ 39 has been activated in this way, because the ski pole itself has not yet been converted, since the bolt 123 is held in the bolt latch 117 by the strong tension spring. Only when the stick according to FIG. 5 has been supported on the floor are the two pipe sections 101 and 102 relieved of stress by the intermediate strong tension spring in such a way that the rocker arm 122 is pivoted clockwise by the force of the leaf spring 39, so that the latch 123 disengages comes with bolt latch 117. Now the locking is released and the two pipe sections 101 and 102 can be moved against each other against the force of the strong tension spring (like the tension spring 26 'in FIG. 3), so that there is a resilient ski pole.

A short rigid stick and a resilient stick have been explained with reference to FIGS. 4 and 5 and when using a strong spring, preferably a tension spring. With a different arrangement of the bolt latches and the bolt, a long rigid stick can also be achieved in this way. If a weak spring is used, which is only used to change the pole to the different lengths and not to use the spring energy when cross-country skiing, then e.g. a short rigid stick, a medium-length rigid stick and a long rigid stick are formed. The bolt 123 can lie on both sides of the rocker arm, so that the bolt latches in FIGS. 4 and 5 are then also present in the lower wall of the tube section 101. By means of the ramp 43, the ski pole can be made lighter, since with the same total length of the ski pole, the tube sections 101 and 102 can be moved axially further apart, that is, they can themselves be shorter, since the rocker arm 122 in the position according to FIG 4 can, so to speak, be threaded into the pipe section 101. The rocker arm 122 is pivotable about the pin 119.

In a further embodiment, not shown, the resilient preselector could itself be formed by the rocker arm 122. In this case, the rocker arm 122 itself is designed as a leaf spring. The separate leaf spring 39 then no longer has to be present. If the rocker arm 122 itself is a leaf spring, then one leaf spring arm carries the bolt 123 and the other leaf spring arm lies in the area of engagement of the actuating member 124.

It has been shown in practice that when the ski pole is designed with the strong spring (tension spring), as explained in the examples according to FIGS. 3-5, and thus a springy ski pole is achieved, the following disadvantage must not occur. If you work with such a strong spring, in which a force in the range of 2 - 14 kp has to be applied in order to bring it into the maximum tensioned position according to FIG. 3, then this great spring force acts on the bolt and the bolt latch in the fixed position of the two pipe sections. These horses ^g force can now lead over time to wear of the locking catch, which is formed so as opening of a thin tube section for reasons of weight as possible, 1, or one hundred and first Such wear would result in the hole serving as a bolt latch in this inner tube section no longer remaining sharp, so that there is a risk that the bolt 23 'or 123 would accidentally slip out of the respective bolt latch, ie out of engagement with the bolt latch is coming. This unwanted adjustment of the ski pole must be prevented. It has proven useful for this if the bolt and the bolt latch are shaped in such a way that the bolt located in the bolt latch positively engages behind the inner tube section 1 or 101 (actual ski pole). This can be achieved in a simple manner if, for example, the bolt latch 117 present as a circular hole in FIG. 4 merges into a slot, not shown, which extends somewhat in the direction of the bolt latch 118 'and if the bolt 123 is simultaneously provided with a thickened head , which is on the latch 123 facing away from the rocker arm 122. The latch 123 would then have a neck section with a reduced diameter and a thickened head section. With the thickened head section, the bolt 123 enters the bolt latch 117 and by axially pushing the two pipe sections 101 and 102 apart by the spring mentioned the neck section then extends from the latch 123 into the aforementioned slot, so that the thickened head section from the latch 123 engages behind this slot. Now the bolt 123 can only be brought out of engagement with the bolt latch 117 when the inner tube section 101 is moved to the left in FIG. 4, ie when the ski pole is supported on the ground and the force of the strong tension spring 26 'mentioned (FIG 3) is overcome. Such a design of the bolt latch 117 with the slit adjoining it is known in the case of fittings on wooden beds, with which the side drawers are connected to the top drawer and the foot drawer.

It has also been shown in practice that when the ski pole is designed with a weak spring (e.g. compression spring) according to FIGS. 1, 2, 4 and 5, the position of the actuating member 124 in the position according to FIG. 5 is not desirable since the cross-country skier must make an unusual movement with his index finger by pressing the actuating member 124 upwards. To avoid this, the position of the actuating element shown in FIG. 5 can be avoided in a further exemplary embodiment, and the actuating element 124 pivoted in the position according to FIG. 4 can only be pivoted into this position in which the cam 133 on the rocker arm 122 acts. This position of the actuator 124 is not a rest position, so it is only taken as long as the finger acts on the actuator 124, as in the position of the actuator 24 shown in FIG. 3. In this position the actuator 124 is desired by the cross-country skier that the length of the ski pole should be changed, i.e. from an existing short position to a long position or from an existing long position to a short position. If an adjustment from an existing short position to a long position is desired, this extension is used immediately through the existing spring 26 (Fig. 1, 2) performed. The cross-country skier must then immediately release the actuating member 124, which then returns to the rest position shown in FIG. 4, so that the latch 123 can snap into the respective latch latch in the long position of the ski pole. If the ski pole is adjusted from an existing long position to a short position, the ski pole is of course only shortened when the pole is used, ie when the ski pole is supported on the ground. When the inner and outer pipe sections have been increasingly pushed into one another against the force of the spring 26, the cross-country skier must release the actuating member 124 again so that it returns to the position shown in FIG. 4 and the latch 123 can snap into the respective latch latch. If the cross-country skier forgets to let go of the actuating member 124 in time, the bolt 123 is not released for snapping into the respective bolt latch and the desired shortening of the ski pole is not carried out. In order to avoid that the desired shortening of the ski pole does not occur, ie if the actuating member 124 is not released in time when the cam 133 is working, the inner tube section 101 can be provided with a nose, not shown, which is embossed, for example, from the wall of this tube section 101 and between the two latch latches 116 and 117 in the way of latch 123. So if the bolt 123 could not snap into the bolt latch 116 because the actuator 124 was not released by the cross-country skier in time, the ski stick only returns a little to its long position until the bolt 123 bears against the aforementioned nose. This nose mentioned thus had a stop shoulder for the bolt 123 on the right in FIG. 4. When the next stick is used, when the inner tube section 101 is supported on the ground, the inner tube portion 101 is moved to the left in FIG. 4, so that the bolt then 123 can snap into the latch latch 116.

Claims (16)

1. Ski pole, which is adjustable in length, with two telescopically displaceable tube sections (1, 2), which by a locking device (23, 16, 17, 18, or 23 ', 17', 18 ') in their mutual Position can be fixed, with an existing on the ski stick handle actuator (24) for fixing the two pipe sections (1, 2) or for releasing the fixation, the actuator (24) being accessible from the fingers of the hand holding the ski stick, the fixing device as Bolt (23 or 23 ') is formed with a plurality of bolt latches (16, 17, 18 or 17', 18 ') and a spring ((1) supported on one end on the inner tube section (1) and on the other end on the outer tube section (2) 26, or 26 '), which strives to axially push both pipe sections (1, 2) apart, characterized in that the bolt (23, or 23') in a two-armed rocker arm (22 or 22 ') is present in the outer tube section (2 ) is mounted that the rocker arm is spring-loaded, and that the bolt is attached to one rocker arm and the actuating member (24) engages the other rocker arm. 2. Ski stick according to claim 1, wherein the bolt (23, or 23 ') on the outer tube section (2) and the bolt latches are on the inner tube section (1), characterized in that the bolt latches (16, 17, 18, or 17 ', 18') lie one behind the other in the longitudinal extent of the inner tube section (1), and that the bolt (23 or 23 ') is motionally connected to the actuating member (24) to move the bolt in or out of on gripped with one of the latch latches to bring. 3. Ski pole according to claim 1, characterized in that the actuating member (24) and thus also the rocker arm (22, or 22 ') in three different positions, namely two end positions (Fig. 2,3) and an intermediate middle position ( Fig. L) are movable, and that a rocker arm spring (34) is in all three rocker arm positions in the tensioned state. 4. Ski stick according to claim 2, characterized in that the bolt latches (17 ', 18') are on only one side with respect to the longitudinal central axis of the inner tube section (1) (Fig. 3). 5. Ski stick according to claim 2, characterized in that there is at least one locking latch (16, 17, 18) on both sides of the longitudinal central axis of the inner tube section (1) (Fig. 1,2). 6. Ski stick according to claim 2, characterized in that the bolt latches (16, 17, 18, or 17 ', 18') both as an opening (16, 17, or 17 ') of the wall of the inner tube section (1,1 ', or, l' ') and as an end support shoulder (18 or 18') are formed in the inner tube section. 7. Ski stick according to claim 1, characterized in that the actuating member (24) is designed as a rotatable cam disc, the axis of rotation (7) of which is perpendicular to the ski pole axis and that the cam disc has at least four cams (30, 31, 32, 33), wherein two cams (30, 31) alternately project an immovable part (3) of the ski pole grip to the outside, and are intended to be pressed alternately into the interior of the ski pole grip by an operator. (Figs. 1-3). 8. Ski pole according to claim 3, characterized in that the one end position of the actuating member (24) can be locked with the rocker arm (22 '), that in this end position of the actuating member the latch (23') is disengaged from the latch latches (17 ', 18 ') is held so that both pipe sections (1, 2) can alternately be pressed together against the force of the spring (26') and pressed apart again by means of the stored spring force (Fig. 3). 9. Ski pole according to claim 3, characterized in that the one end position of the actuating member (24) with the rocker arm (22) can be locked, that in this end position of the actuating member the bolt (23) is held in that bolt latch (18) which Actuator (24) is closest to keep the ski pole in its longest state. (Fig. 2). 10. Ski stick according to claim 3, characterized in that in the central position of the actuating member (24) the bolt (23) by means of the rocker arm spring (34) is held in a bolt latch (16 or 17). (Fig. L). 11. Ski stick, which is adjustable in length, with two telescopically displaceable tube sections (101, 102), which can be fixed in their mutual position by a locking device (123, 116, 117, 118 '), with an actuator on the ski stick handle (124) for fixing of the two pipe sections (101, 102) or for releasing the fixation, the actuating member (124) being accessible from the fingers of the hand holding the ski stick, the fixing device as a bolt (123) with a plurality of bolt latches (116, 117, 118 ') is formed and wherein there is a spring (26, 26 'in FIGS. 1-3) which is supported on one end on the inner tube section (101) and on the other end on the outer tube section (102) and tends to axially both tube sections (101, 102) apart, characterized in that between the actuating member (124) and the bolt (123) there is a resilient preselection member (39) (Fig. 4.5). 12. Ski stick according to claim 11, characterized in that the preselecting member (39) is designed as a leaf spring. 13. Ski stick according to claim 1 and 11, characterized in that the preselection member (39) is present in the rocker arm associated with the actuating member (124). 14. Ski stick according to claim 1 and 11, characterized in that the rocker arm (122) is provided with an upstream of the bolt (123) ramp (43) for the inner tube section (101). (Fig. 4.5). 15. Ski stick according to claim 11, characterized in that the actuating member has two fixed positions, which it can assume in the manner of a snap switch (Fig. 4.5). 16. Ski stick according to claim 11, characterized in that the bolt (123) in a two armed rocker arm (122) is present, which is designed as a leaf spring, and that one leaf spring arm carries the bolt (123) and the other leaf spring arm lies in the engagement area of the actuating member (124), so that the spring-elastic preselection member is formed by the rocker arm itself.

Images