EP0114953A2 - Ski pole and snow rest therefor - Google Patents

Abstract

Ski pole with a ski pole and a snow support body, the snow support body being attached to a lower end region of the ski pole and at least partially designed as a shell body which is open at the bottom, the shell body having a deflection collar.

Description

The invention relates to a ski pole with a ski pole and a snow support body, wherein the snow support body is attached to the lower end region of the ski pole and is at least partially designed as a shell body open at the bottom.

As is well known, ski poles serve as auxiliary devices for improving balance, for changing direction and for supporting jumps in the terrain. Especially in so-called cross-country skiing, the ski poles are also used for powerful pushing off and for initiating and supporting forward gliding.

Known ski poles are constructed in such a way that they have a so-called snow plate at their lower end, an essentially circular, flat body which prevents the ski pole from penetrating too deeply into the snow.

The lower end of the ski pole is usually tapered more or less to prevent the ski pole from slipping away. The snow plate is usually arranged at a distance of a hand's width above the tapered lower end of the ski pole.

A ski pole has also already been proposed in which the ski pole tip is replaced by a shell body which is open at the bottom (cf. for example CH-PS 545 635). In the case of a ski pole according to this proposal, the risk is counteracted that the tapering lower end of the ski pole can lead to injuries, for example, in the event of a fall or other occasions. However, a ski pole according to this proposal still has various disadvantages, which can be seen not least of all from the fact that a ski pole according to this principle, namely with a shell body that replaces the ski pole tip and is open at the bottom, has not so far been used as yet it would have been desirable for security reasons. For example, the snow support body known from the above-mentioned publication is designed with the same wall thickness or an increasing wall thickness in the upper area. When the ski pole is placed on a relatively hard snow surface, there is a different behavior depending on the material properties of the snow support body. If, for example, the snow support body is made of a relatively hard plastic, the snow support body can only bend itself slightly, so that the skier only places the snow support body in sections on the snow surface on an uneven surface or when the skier pushes forward or backwards. At the same time, the skier feels a more or less strong distracting reaction force in his hand. If against that If the material of the snow support body is selected to be relatively soft, the snow support body will buckle uncontrollably when the load is off-center, depending on the special mounting conditions. Since in this case the edge area is also relatively soft in the same way, the snow support body can also bend completely, so that the edge of the shell body no longer sits on the snow surface, so the ski pole may not grip at all.

A safe placement and gripping is still not always satisfactorily possible with the known ski pole because, for example, the snow support body cannot be held on icy ground covered with a relatively thin layer of snow.

Based on the Std.d.Tech. The invention is based on the object of specifying a ski pole which, in the same way as the known, previously described ski pole, has a relatively low potential for injury, but with far better properties with regard to stability, slip resistance and at the same time also handiness.

The object shown is first and essentially achieved in that the shell body has a deflection sleeve. According to the invention, a defined location or zone is thus created in the shell body, which enables the ski pole to move, as it were, in an articulated manner relative to the part of the shell body located below the deflection collar. Even when the ski pole is placed or pushed off at an angle, it is thus ensured that the snow support body sits completely on the ground in an edge region. Also results from the deflection sleeve provided according to the invention in the hand of the Skier with a sloping touchdown or pushing off only a small, at least not annoying restoring force.

In principle, the deflection collar according to the invention can be designed in various ways. E.g. this could be strut-like connections, for example acting as spring bars, between the shell body and the ski pole, as well as a simple spiral spring with a corresponding spring constant. In an embodiment of the invention, however, it is preferably provided that the deflection sleeve is implemented as an area of reduced wall thickness integrated into the shell body. This embodiment proves to be advantageous since additional individual parts that are only adapted to this function are not required, no areas are created in which snow or ice can accumulate, which is generally perceived as annoying for reasons of weight, and overall this realization is particularly space-consuming - and saves weight. Compared to an overall rigid shell body, the design according to the invention has even more favorable properties in that, in the event of falls, improper handling when driving a lift and similar occasions, the shell body can follow articulated stresses in this area, so that it is also advantageous in terms of safety.

The ski pole according to the invention can now be designed in various ways. It is preferably initially provided that the shell body is designed to be rotationally symmetrical with respect to a central central axis. With regard to the external design of the snow support body, it is thereby achieved that the snow support body and thus the ski pole, as a result, cannot get caught or tilted. In addition, such a configuration of the snow support body also leads to relatively uniform reaction forces occurring when it is placed on the snow surface within the snow support body. A individual areas of the snow support body are not stressed by an increased leverage.

Further, the snow support body is preferably provided with a substantially straight ver in a cross-sectional view _- running flank region is formed, which includes the central axis of a flank angle. This flank angle is generally an acute angle, the downward-opening cavity of the snow support body being essentially defined by varying the angle and a width of the flank region.

If the determination "below" or "above" is given above and below, this is always chosen based on the observation of a ski pole in the normal position. "Down" means in the direction of the snow surface and "up" in the opposite direction.

A flank angle between the flank region and the central axis of about 70 ° has proven to be expedient with respect to the flank region. It is advantageous that at such an angle the cavity enclosed between the snow support body and a snow surface (seen as a body) is relatively flat, which already makes it relatively easy thin snow cover creates a compression effect, which increases the security of the ski pole against slipping.

In a further embodiment, which is also of importance independently, the flank region runs out into an edge region, the edge region with the central axis being one of the flanges angle angle deviating. In this regard, the central axis is usually a more acute angle, ie the edge region is offset from the central axis in relation to the flank region.

It has proven to be particularly expedient to design the edge region in such a way that it appears wedge-shaped in cross section, essentially tapering downwards. This means that with respect to an outer surface of a flank region, the transition of the flank region in the edge regions is shaped like a bead. This results in the compression effect already described when the ski pole is placed on a snow surface not only inside the snow support body, but also in the outer edge region. Even if the snow support body is only partially loaded, for example on a wave-like surface, not only does a partial contact of the snow support body with a snow body formed in the interior of the snow support body, but also a contact of the snow support body with the subsequent semicircle on outer compressed snow areas prevents the ski pole a move.

In a further embodiment, which is also of importance independently for significantly improved support properties, the snow support body is provided in the region of the central axis with a conical, downwardly projecting center shape. This center shape increases, for example, the contact surface of the snow support body on the snow body which forms in the downwardly open shape of the snow support body. and results in a central touchdown point, which is advantageous, for example, in uneven terrain. The center formation can have the shape of a double cone, with one further down in front standing pointed cone part has a smaller cone angle than a flat cone part adjoining at the top. Overall, however, the tip of the center formation is only formed so far downwards that when the snow support body is placed on a snow surface, the wall area always comes into contact with the snow surface first and essentially.

In a further advantageous embodiment, the snow support body is provided with an upwardly extending holding shaft for holding the ski pole. The bracket shaft is formed with a substantially cylindrical bracket opening.

As a special feature, a groove-like, (only) outwardly opening slot is provided in the holder shaft, which runs perpendicularly in the holder shaft. This slot proves to be advantageous, for example, in that it facilitates the insertion of the ski pole into the mounting shaft, as it were as a "target stretching range".

For this purpose, it is also expedient that the holder opening is designed to widen conically in an upper region, so that a ski pole can initially be inserted into the holder opening relatively easily and a considerable insertion resistance can only be overcome from a certain insertion depth.

It has proven to be particularly advantageous to design the mounting opening as at least partially protruding into the center shape. The lower end of the ski pole has a relatively small height in relation to the edge areas, which is typical for skiing occurring "work" of the ski pole, namely. a more or less strong deflection from the vertical, leads to an unloaded edge area not being lifted off from a snow surface or the like. The selected flank angle is also the cause of this success in a combinatorial manner.

In a further embodiment, which is also of importance in itself, a spiral spring element is integrated in the holding shaft in such a way that an axis of symmetry of the spiral spring element coincides with the axis of rotation of the snow support body. In addition to a certain support for the stability of the mounting shaft, the spiral spring element is very important with regard to the mounting of the ski pole in the mounting shaft. For this purpose, the coil spring element is selected with a diameter that one or more threads are at least partially exposed in the interior of the holder opening. The threads are expediently exposed in the conical region of the holder opening, while in the cylindrical region of the holder opening they are covered (if only slightly) by the inner surface of the holder opening.

When a ski pole is inserted into the bracket opening, the spiral spring element cuts thread-like gears into the ski pole, so that the ski pole is anchored in the bracket opening not only because of a press fit, but also because of a screw connection. With regard to this function, the spiral spring element can be made of aluminum, since important elastic properties are not important.

The shell body itself is furthermore preferably a plastic body, a plastic advantageously being found Polyethylene base, such as. B. Anitel EN 400 (Enka Werke) has proven to have a Shore hardness of 40 D.

A structural body, which is essentially adapted to the shape of the shell body, can be provided integrated into the plastic body. While the structural body is arranged in the flank and edge area in the interior of the shell body, it is advantageous that it protrudes downward from the edge area in the form of an exposed attachment edge that is not enclosed by plastic. This provides an opportunity to form separate engaging edges that additionally support the ski pole being placed securely on a snow surface. For this purpose, the contact edges are preferably provided with a large number of sawtooth-like tips. However, these tips are not provided over the entire circumference of the edge region, but only in regions, extending over a total of approximately 2/3 of the circumferential length of the edge region.

When the deflection collar is implemented, the structural body is advantageously formed only in the flank region and the edge region, so that it is formed in the manner of a plate spring, with the exception of the edge region. Nevertheless, it is also conceivable that the structural body is also formed in the region of the deflecting collar, of course likewise capable of being bent to a large extent in this region.

In a further advantageous embodiment, the structural body is provided with recesses, in particular in the edge region, the flank region and the center formation (if provided) of the regions of the structural body associated with the snow support body. These recesses initially allow to produce the structural body with a relatively low weight, which is generally advantageous for the functionality of the ski pole, that is to say to enable the ski pole to be placed on a desired location as quickly and freely as possible. In addition, however, it has surprisingly been found that the recesses have a particularly favorable effect with regard to the embedding of the structural body in the plastic body. The plastic which is present throughout in the area of the recesses produces a rivet-like clamping of the plastic on the upper side of the structural body with the plastic on the lower side of the structural body. Therefore, the recesses are also present in the edge area, at least in the areas of the edge area in which a contact edge is formed, since the wedge-like configuration of the edge area described above naturally also causes certain reaction forces on the plastic and tries to push it back. The rivet-like clamping of the plastic also in these edge areas practically completely excludes the plastic from being detached from the structural body.

Insofar as the structural body is also formed in the area of the center formation, it essentially has the shape of an upwardly open structural body plate. A spiral passage is formed in a plate bottom of the structural body plate, which serves for the positive connection of the spiral spring element to the structural body. Furthermore, a coil spring stop is formed on an underside of the plate base, so that only a last gear of the coil spring can be screwed into the coil gear until it strikes the coil spring stop. The purpose of the positive connection of the coil spring to the plate base is there reached with and prevented excessive screwing.

Furthermore, the structural body is preferably also made of aluminum, like the spiral spring element. Hardening of the structural body initially proves to be advantageous with regard to the contact edges, which are thus largely protected against wear.

In particular, if the curing by the formation of a relatively strong aluminum oxide layer, for example in a layer thickness of 30 -. 50 .mu.m, or is implemented lasmaverfahren by Flarnmenbeschichtung in _P, however still a surprising effect results in view of the adhesion of the plastic to the structural body.

The aforementioned hardening processes roughen the surface of the structural body very significantly, which favors intensive adhesion of the plastic to the structural body.

Even if the snow support body has previously been described as part of a ski pole according to the invention, the teaching of the present invention is not directed only towards a complete ski pole. Rather, the present invention also relates to a snow support body alone, which can also be attached, for example, to the ski pole of a known ski pole in order to render the tip of the ski pole harmless in the known ski pole. Then, of course, the snow plate attached to such a ski pole can also be removed at the same time, since it is no longer required for the ski pole thus converted to function.

As an alternative to the configuration of the snow support body described above, it can also be expedient that the snow support body at least in its inner profile is approximately Hellellipseniform.

A slipping-on placement of the ski pole can also be significantly supported in that the downward-facing edge region of the snow support body has crenellated formations. For example, in the case of a plastic-only body, these crenellated formations can be provided in the same, or if a structural body is also provided, only in the structural body, or else in the structural body and the plastic body. When interacting with snow, the crenellated formations in particular also result in a stability of the ski pole according to the invention about its longitudinal axis. It is a further advantage of a snow support body designed in this way that it permits an increase in the adhesiveness of the ski pole according to the invention through the formation of crenellated formations, so that tapering formations in the edge region of the snow support body are not absolutely necessary. It has proven to be expedient to implement the crenellated formations by providing semicircular recesses which are regularly distributed over the circumference of the edge region in the edge region of the snow support body.

The snow support body can furthermore have an upwardly extending cylinder extension in the region of its central axis. The importance of this cylinder approach, which preferably has an end in the form of a hemisphere, lies first of all in a simple, centering fastening possibility for the spring element, which, as explained above, is provided in the holder shaft. However, the cylinder extension is also particularly suitable for attaching a mounting element which enables a downward-pointing element, which extends in the interior of the snow support body, to be fastened. In particular, this can be a tip comparable to a conventional ski pole tip. The attachment of such a tip in the interior of the snow support body still largely excludes the risk of injury from the surrounding snow support body, but can, in certain applications, result in a further improved slip resistance of the ski pole.

The holding element in the interior of the cylinder extension can in a simple manner, for example, be a tubular part having an internal thread, which is glued, welded or connected in some other way to the cylinder extension. In the same way that the studs of soccer shoes have to be replaced depending on the type of terrain, a ski pole tip can be provided so as to be exchangeable.

Further details of the invention result from the following description of the drawing, which only shows exemplary embodiments.

• Fig. 1 einen erfindungsgemäßen Skistock, teilweise geschnitten,
• Fig. 2 einen Querschnitt durch einen Schneeauflagekörper in alternativer Auführungsform;
• _Fig. 3 eine Darstellung des Schneeauflagekörpers gemäß Fig. 2 in vergrößertem Maßstab, wobei jedoch im wesentlichen nur der Halterungsschaft dargestellt ist;
• Fig. 4 eine Draufsicht auf den Gegenstand gemäß Fig. 3;
• Fig. 5 eine vergrößerte Darstellung des Randbereiches des Schneeauflagekörpers in einer Darstellung gemäß Fig. 1;
• _Fig. 6 eine Draufsicht auf den Strukturkörper in einem Schneeauflagekörper gemäß Fig. 1;
• _Fig. 7 eine Darstellung gemäß Fig. 6, geschnitten entlang der Linie VII-VII;
• Fig. 8 eine Draufsicht auf einen Strukturkörper eines Schneeauflagekörpers gemäß Fig. 2;
• Fig. 9 eine Darstellung gemäß Fig. 8, geschnitten entlang der Linie IX-IX .
• _Fig. 10 einen Querschnitt durch einen Schneeauflagekörper in weiterer alternativer Ausführungsform und
• _Fig. 11 eine ausschnittsweise Vergrößerung eines in Fig. 1₀ dargestellten Zylinderansatzes.

The attached drawing shows:

• 1 is a ski pole according to the invention, partially cut,
• 2 shows a cross section through a snow support body in an alternative embodiment.
• _F ig. 3 shows an illustration of the snow support body according to FIG. 2 on an enlarged scale, but essentially only the mounting shaft is shown;
• FIG. 4 shows a plan view of the object according to FIG. 3;
• FIG. 5 shows an enlarged representation of the edge region of the snow support body in a representation according to FIG. 1;
• _F ig. 6 shows a plan view of the structural body in a snow support body according to FIG. 1;
• _F ig. 7 shows a representation according to FIG. 6, cut along the line VII-VII;
• FIG. 8 shows a plan view of a structural body of a snow support body according to FIG. 2;
• Fig. 9 is an illustration of FIG. 8, cut along the line IX-IX.
• _F ig. 10 shows a cross section through a snow support body in a further alternative embodiment and
• _F ig. 11 is a sectional enlargement of a cylinder approach shown in Fig. 1 _0th

1 shows the snow support body 1 of a ski pole according to the invention, and partly a ski pole 23 connected to the snow support body 1.

As can first be seen in FIG. 1, the snow support body 1 consists of a shell body 2 with a mounting shaft 10 molded onto it.

A deflection collar 21 is integrated in the shell body 2, which is realized in the exemplary embodiment as a region of reduced wall thickness of the shell body 2. Fig. 1 can be seen that the deflection sleeve 21 appears through an annular recess in the interior of the shell body 2 to the outside, but on the (facing the skier) upper surface of the shell body 2 is not visible here.

Although a structural body 15, which is described in detail below and is integrated into a plastic body, is also provided in the exemplary embodiment according to FIG. 1, the ski pole according to the invention can also be implemented with a snow support body 1 made entirely of plastic.

The shell body is rotationally symmetrical with respect to a central central axis 3 and has an essentially straight flank region 4, which includes a flank angle α of approximately 70 ° with the rotational axis 3. The flank area 4 terminates in an edge area 5 which, with the central axis 3, includes an edge angle deviating from the flank angle. As can be seen from Fig. 2, the contact angle is. defined with respect to an average course of the edge region 5. However, in the exemplary embodiment the inner edge region 5 also runs in accordance with the edge angle β. The contact angle β is preferably approximately 20 °.

As can be seen in particular from FIG. 5, the edge region 5 is essentially wedge-shaped in cross section and tapers downwards.

Furthermore, the snow support body 1 is formed in the region of the central axis with a cone-like center formation 6 projecting downwards. It can be seen that the Zentrumsausformung 6 in the case of the embodiment of Fig. 2 has the shape of a double cone, in the case of the embodiment according _{to FIGS.} 1 just the shape of a simple cone. In the case of the double cone, there is a pointed cone part 7 projecting downwards and a flat cone part 8 adjoining upwards.

Overall, the center formation 6 is provided such that a tip 9 is formed so that it protrudes downward only to the extent that when the snow support body 1 is supported on a flat support surface only the edge region 5 is in contact with the support surface.

Furthermore, the snow support body 1 has a structural body 15 arranged essentially in the interior of the shell body 2, which is also shown in isolation in FIGS. 6, 7, 8 and 9. In the edge regions 5, the structural body 15 protrudes from the shell body 2 to form attachment edges 16. As can be seen, for example, from FIGS. 7 and 9, the contact edges 16 are not formed continuously, but only over approximately 2/3 of the circumferential length of the edge region 5.

The structural body 15 is further provided with recesses 17 which are partially elongated and partially circular.

In the area of the structural body 15 assigned to the center formation 6 of the shell body 2, in the case of the exemplary embodiment according to FIG. 2, the structural body 15 is formed as an upwardly opening structural body plate, as can be seen in particular from the sectional view according to FIG. 9. In a plate bottom 19 of the structural body plate 18, a spiral passage 20 is formed, which is used for the positive connection of the spiral spring element 13 described below with the structural body 15. A last gear of the spiral spring element 13 is to be introduced into the spiral gear 20, the end of the spiral spring element 13 then striking the spiral spring stop 20 provided on an underside of the plate base 19 after about one revolution.

In the case of the exemplary embodiment according to FIG. 1, on the other hand, the structural body 15 is formed in its upper region with an annular recess in order to be sufficiently light Ensure the possibility of movement of the deflection collar 21. In this case, it is advantageous to design the edge of the structural body 15 with an edge fold 24. This helps to prevent the plastic from tearing open at the transition from structural body 15 to plastic body.

The holder shaft 10 (FIG. 3) of the snow support body 1 is provided with an essentially cylindrical holder recess 11 which is designed to widen conically in its upper region.

In its lower region, the holder recess 11 extends into the center formation 6, which is not least possible, in the case of the exemplary embodiment according to FIG. 2, by the formation of the structural body plate 18.

Regarding the spiral spring element 13, it should also be pointed out that, in the case of the exemplary embodiment according to FIG. 1, it is, as it were, "free-floating" integrated in the holder shaft 10.

As already stated, the snow support body 1 is preferably a plastic body, while the structural body 15 and the spiral spring element 13 are made of aluminum.

The spiral spring element 13 which is positively connected to the structural body 15 is disposed in the support shaft 1 ₀ such that it is covered in the cylindrical part of the mounting opening 11 from the surface of the mount opening 11, however, individual passages 14 in the conical region of the posture opening are at least partially exposed.

Furthermore, the holder shaft 10 is equipped with a groove-like, outwardly opening slot 12 (cf. in particular FIG. 4).

In connection with Fig. 5 it can still be seen that the in Structures 17 provided formations 17 allow a rivet-like clamping of the plastic with the structural body 15.

In the exemplary embodiment according to FIG. 10, the snow support body 1 is essentially semi-elliptical in shape.

In this exemplary embodiment, crenellated formations 25 are provided in the downward-facing edge region 5 of the snow support body 1. The crenellated formations 25 result from semicircular recesses 26 provided at regular intervals in the edge region 5 of the snow support body 1.

In the exemplary embodiment according to FIG. 10, the snow support body 1 has a cylinder extension 22 in the area of the central axis 3. The cylinder extension 22 is closed at the top in the form of a hemispherical cap 27. The ski pole (not shown) is connected to the snow support body 1 in this case via the spiral spring element 13. The spiral spring element 13 overlaps the cylinder shoulder 22 in one end region. Here, the spiral spring element 13 can also perform a deflection and joint function, in which case it is then naturally formed from spring steel. In this exemplary embodiment, the spiral spring element 13 and the snow support body 1 are in a rubber or Vulcanized plastic body 28 (the Schalenkör ^p er 2 is therefore a metal body).

As can be seen in particular in FIG. 10, the rubber body 28 surrounds the shell body 2 with a thickness that decreases toward the edge region 5 of the shell body 2. In the area of the spiral spring element 13, the rubber body 28 is furthermore essentially cylindrical, so that overall an approximately bell-shaped cross section Shape.

The cylinder extension 22 also has a mounting element 30 with which a downward-directed element can be detachably fastened in the cylinder extension 22 and thus in the snow support body 1. This element can e.g. B. be a tip. The cylinder extension 22 or the holding element 30 is expediently provided with an internal thread 31, so that the tip to be fastened, for example, is to be screwed into the cylinder extension 22.

The features of the invention disclosed in the above description, the drawing and in the claims can be essential both individually and in any combination for realizing the invention in its various embodiments.

REFERENCE CHARACTERISTICS

• 1 snow support body 1
• 2 shell bodies
• 3 central axis 3
• 4 flank area 4
• 5 edge area, 5
• 6 Center formation 6
• 7 pointed cone part 7
• 8 flat cone part 8
• 9 tip 9
• 10 holder shaft 10
• 11 bracket opening 11
• 12 slot 12
• 13 spiral spring element 13
• 14 gear 14
• 15 structural body 15
• 16 touch edge 16
• 17 recess 17
• 18 structural body plate 18
• 19 plate bottom 19
• 20 spiral spring stop 20
• 21 deflection collar 21
• 22 cylinder extension 22
• 23 Ski pole 23
• 24 edge cover 24
• 25 crenellated formations 25
• 26 semicircular shapes 26
• 27 hemisphere
• 28 rubber body
• 29 cavity
• 30 mounting element
• 31 internal thread 31
• 32 α flank angle 32
• 33 β _R andwinkel 33
• 34 34
• 35
• 36 36
• 37 37
• 38 38
• 39 39
• 40 40
• 41 41
• 42 42
• 43 43
• 44 44
• 45 45
• 46 46
• ₄₇ 47
• 48 48
• 49 49
• 50 50
• 51 51
• 52 52
• 53 53
• 54 54
• 55 55
• 56 56
• 57 57
• 58 58
• 59 59
• 60 60
• 61 61
• 62 62
• 63 63
• 64 64
• 65 65

Claims (15)

1. Ski pole with a ski pole and a snow support body, wherein the snow support body is attached to a lower end region of the ski pole and is at least partially designed as a downwardly open shell body, characterized in that the shell body (2) has a deflection collar (21). 2. Ski pole according to claim 1, characterized in that the deflection sleeve (21) is realized as an area of reduced wall thickness integrated in the shell body (2). 3. Ski pole, in particular according to claim 1 or 2, characterized in that the shell body (2) has a cross-sectional representation of a substantially straight flank region (4) which includes an acute flank angle (α) with a central axis (3). 4. Ski pole, in particular according to claim 3, characterized in that the flank region (4) ends in an edge region (5) and that the edge region (5) with the central axis (3) one of the flank angle (

) different contact angle (

) includes. 5. Ski pole according to claim 4, characterized in that the edge region (5) is substantially wedge-shaped in cross-section tapering downwards. 6. Ski pole, in particular according to one of claims 1 to 5, characterized in that the snow support body (1) in the region of the central axis (3) is formed with a cone-shaped downward projecting center formation (6). 7. Ski pole according to one of claims 1 to 6, characterized in that the snow support body (1) has an upwardly extending mounting shaft (10) of the mounting of the ski poles with a substantially cylindrical mounting opening (11). 8. ski pole, in particular according to claim 7, characterized in that in the holding shaft (10) a coil spring element (13) is integrated such that an axis of symmetry of the coil spring element (13) coincides with the central axis (3). 9. Ski pole according to one of claims 1 to 8, characterized in that the snow support body (1) is a plastic body. 10. ski pole, in particular according to claim 9, characterized in that a substantially to the shape of the shell body (2) adapted structural body (15) is provided, and that the structural body (15) in the edge region (5) of the shell body (2) one has exposed attachment edge (16) not enclosed by plastic. 11. Ski pole according to claim 10, characterized in that the structural body (15) only in the flank region (4) and the edge region (5) is formed. 12. Ski pole according to one of claims 1 to 11, characterized in that the snow support body (1) is rotationally symmetrical to the central axis (11). 13. Ski pole according to one of claims 1 to 12, characterized in that the snow support body (1) is approximately semi-elliptical in profile. 14. Ski pole according to one of claims 1 to 13, characterized in that the snow support body (1) in the region of the central axis (3) has an upwardly extending cylinder extension (22). 15. Ski stick according to one of claims 6 to 14, characterized in that in the center formation (6) and / or in the cylinder extension (22) a downward element, for example. A ski stick tip, is to be fastened.

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