Board-shaped gliding.

专利摘要:
The invention relates to a board-like sliding device (1), comprising a sliding board body (2) on which sliding board body (2), a bottom (5) as a sliding surface (6) are formed. Furthermore, a stabilization device (13), comprising a first coupling element (14), a second coupling element (15) and a force transmission means (16), which force transmission means (16) is coupled to the two coupling elements (14, 15), wherein the first (14 ) and the second coupling element (15) spaced apart at a distance (18) on the upper side (7) of the sliding board body (2) are arranged. At least one of the two coupling elements (14, 15) of the stabilizing device (13) has a spring element, wherein the spring element (39) for applying a tensile force to the force transmission means (16) is formed, and wherein the force transmission means (16) in the resting state of the board-like Sliding device (1) is loaded by the tensile force of the spring element (39).
公开号:CH710570A2
申请号:CH01732/15
申请日:2015-11-27
公开日:2016-06-30
发明作者:Schaidreiter Johann
申请人:Atomic Austria Gmbh；
IPC主号:

专利说明:

The invention relates to a board-like gliding device, in particular ski or snowboard, as specified in claim 1.
From EP 2 138 208 A1 a ski is known, on which a stabilizing device is arranged on the upper side. The stabilization device comprises a first coupling element for fastening a power transmission rod to the top of the ski. At the opposite end of the power transmission rod, a second coupling element is arranged, which also connects the power transmission rod with the top of the ski. The power transmission rod is displaceable relative to the second coupling element, wherein a part of the power transmission rod protrudes into a chamber of the second coupling element. The chamber of the second coupling element is filled with a magnetorheological fluid, by which the mobility of the power transmission rod relative to the second coupling element and thus the damping behavior of the second coupling element can be influenced.
A disadvantage of the known from EP 2 138 208 A1 embodiment is the complicated structure and, consequently, an increased error rate and increased wear of the stabilization device.
The object of the present invention is to provide a board-like gliding device, wherein the driving characteristics are improved by a stabilizing device, wherein the stabilizing device is simple and durable, and has good stabilization properties.
This object of the invention is achieved by a board-type sliding device according to claim 1.
According to the invention a board-like gliding device, in particular ski or snowboard is provided which comprises the following components. A gliding board body having a front and a rear sliding board body end, on which gliding board body a bottom is formed as a sliding surface, and on which gliding board body is formed a top for receiving a binding device for releasably securing a sports shoe of a user. Furthermore, a stabilizing device comprising a first coupling element, a second coupling element and a force transmission means, which force transmission means is coupled to the two coupling elements, wherein the first and the second coupling element are spaced apart at a distance from each other at the top of the sliding board body. At least one of the two coupling elements of the stabilization device has a spring element, wherein the spring element is designed for applying a tensile force to the power transmission means, and wherein the force transmission means is loaded in the resting state of the board-like sliding device by the tensile force of the spring element.
An advantage of the inventive design is that the stabilization device by the spring element, which is integrated in one of the coupling elements, has the simplest possible structure. Thus, the error rate of the stabilization device is reduced since the simplest possible and robust individual components can be used for the construction of the coupling elements. In addition, the stabilization device described is as low maintenance, whereby the ease of use is increased. The fact that the power transmission means is loaded in the resting state of the board-like sliding device by the tensile force of the spring element, in addition, the stabilization properties of the stabilizing device can be improved. In particular, it can be achieved by the described stabilization device that the front sliding board body end and / or the rear sliding board body end does not over-spring to the underside. As a result, a swinging of the front sliding board body end and / or the rear sliding board body end or the resulting negative driving characteristics of the board-like sliding device can be reduced or avoided.
Furthermore, it may be expedient that the power transmission means is designed as a rotationally symmetrical pull rod. An advantage of a design of the power transmission means as a rotationally symmetrical pull rod is that it can be produced inexpensively and, moreover, can be installed well in the stabilization device. In particular, a rotationally symmetrical pull rod has the advantage that the installation position with respect to angular rotation about the axis of rotation need not be precisely aligned.
Further, it can be provided that the first coupling element is connected rigidly with respect to the longitudinal direction of the sliding board body with the power transmission means. The advantage here is that the first coupling element thus does not have to have a complicated internal structure, but can be constructed as simple as possible, whereby it may have a low mass in order not to negatively influence the driving characteristics of the board-like sliding device.
In an alternative variant, it may be provided that the second coupling element is rigidly connected to the power transmission means with respect to the longitudinal direction of the sliding board body. The advantage here is that the first coupling element thus does not have to have a complicated internal structure, but can be constructed as simple as possible, whereby it may have a low mass in order not to negatively influence the driving characteristics of the board-like sliding device.
In addition, it can be provided that the force transmission means comprises a cylinder in a coupling region with the first coupling element and the first coupling element has a receptacle for positive connection with the cylinder. The advantage here is that such a cylinder connection is very flexible, whereby an angular rotation of the first coupling element relative to the power transmission means can be well balanced. Such a cylinder connection moreover has high stability in the axial direction and can be produced in such a way that it is as free of play as possible when the axial force load is changing.
Alternatively, it can be provided that the cylinder comprises a first threaded pin and the power transmission means in the coupling region has an internal thread for receiving the threaded pin. The advantage here is that thereby by rotation of the power transmission means relative to the first coupling element, the distance between the first coupling element and power transmission means can be healed, or the ball head can be well connected to the power transmission means. As a result, the damping properties of the stabilization device can be adjusted or adjusted. In addition, such a screw connection is less error-prone and easy to manufacture.
Also advantageous is an expression, according to which the second coupling element has a base plate in which a guide recess relative to the base plate slidable holding element is added, wherein the force transmission means is rigidly connected to the holding element, and that between the holding element and the base plate Spring element is arranged so that the holding element is supported with the interposition of the spring element on the base plate. The advantage here is that in such a construction of the second coupling element as few individual parts can be used in order to achieve a good damping behavior or stabilization behavior of the coupling element or the stabilizing device can. The second coupling element is not only functional by such a configuration beyond, but also less prone to error, low maintenance and inexpensive.
According to a development, it is possible that the holding element is connected by a screw to the power transmission means, wherein the force transmission means comprises a second threaded pin in a coupling region with the second coupling element and the retaining element has an internal thread for receiving the threaded pin. The advantage here is that thereby by rotation of the power transmission means relative to the second coupling element, the distance between the second coupling element and power transmission means can be adjusted, or the retaining element can be easily connected to the power transmission means. As a result, the damping properties of the stabilization device can be adjusted or adjusted. In addition, such a screw connection is less error-prone and easy to manufacture.
Furthermore, it may be expedient that the first and the second set screw have oppositely oriented thread. The advantage here is that thereby a large change in length of the effective length of the power transmission means can be achieved with only a small rotation of the power transmission means, whereby the adjustment range of the stabilization device can be increased.
Furthermore, it can be provided that the spring element is designed as an elastomer block, which also has a damping property in addition to the spring property. The advantage here is that the stabilization device has improved stabilization properties. In particular, the board-type sliding device can thus be damped in such a way that excessive swinging during driving can be prevented as far as possible. The use of an elastomer block also has the advantage that it is easy to manufacture and robust. Thus, the stabilizing device can achieve a long life and also be produced inexpensively.
According to a particular embodiment, it is possible that on the base plate in the region of the spring element, an adjusting body is formed, which is provided for acting on the spring element. By means of such an adjustment body, the stabilization behavior or damping behavior of the stabilization device can be influenced by biasing the spring element. Thus, the board-like sliding device can be adapted to the use by different users or slope conditions.
According to an advantageous development can be provided that in the guide recess of the base plate, a friction element is provided which acts with a predetermined normal force on the holding element such that in the direction of movement of the holding element, a frictional force is generated. The advantage here is that an additional damping in the stabilizing device can be generated by the friction element. As a result, the stability properties of the board-like sliding device can be additionally improved. In particular, vibrations can be further damped thereby, so that the smoothness of the board-like sliding device is increased.
In particular, it may be advantageous if the second coupling element is formed as a support element between the binding device and the sliding board body. As a result, the stabilization device can be integrated at least partially into the standard construction of the board-type sliding device. In this way it can be achieved that a small additional mass is arranged on the board-like sliding device by the stabilizing device. Thus, the weight of the board-like sliding device is not excessively increased by the stabilizing device, whereby it can be easily carried by the user. In addition, this embodiment has the advantage that the effective length of the stabilization device is as long as possible to improve the stabilization properties.
Furthermore, it may be expedient that the first coupling element is arranged in a region of the sliding board body in which the sliding board body has its greatest transverse extent. The advantage here is that thereby the stabilization properties of the stabilization device can be improved because the forces that occur when driving on the board-like sliding device in the region of the largest transverse extent of the board-like sliding device have a maximum. Thus, the force application point of the stabilization device can be superimposed as well as possible with the maximum of the occurring forces by this expression.
Furthermore, it can be provided that in each case a stabilizing device is arranged in the front end region and in the rear end region of the sliding board body. In this way it can be achieved that the board-like sliding device is stabilized as well as possible by a stabilizing device both in the front end region and in the rear end region. As a result, the driving characteristics of the board-type sliding device can be further improved.
Furthermore, it can be provided that the sliding board body, a protective cover is arranged, wherein at least portions of the power transmission means are covered by the protective cover. The advantage here is that the power transmission means can be protected by the protective cover against damage. This can be particularly advantageous in order to achieve a longevity of the stabilizing device or the board-like sliding device.
In addition, it can be provided that the force transmission means is formed of a fiber-reinforced material. The advantage here is that the power transmission means thereby having the lowest possible mass as good as possible strength. This can help to increase the comfort in dealing with the board-like gliding device, especially when wearing the board-like gliding device.
Finally, it can be provided that a recess is arranged on the upper side of the sliding board body, in which the power transmission means is at least partially accommodated. The advantage here is that the power transmission means can be arranged to save space on the sliding board body through the recess.
For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
Each show in a highly simplified, schematic representation:<Tb> FIG. 1 <SEP> is a perspective view of a board-like sliding device;<Tb> FIG. 2 <SEP> is a plan view of a first embodiment of the board-type sliding device;<Tb> FIG. 3 <SEP> is a perspective view with a sectional view of a stabilizing device for the board-like sliding device;<Tb> FIG. 4 <SEP> is a sectional view of a further embodiment of the stabilization device;<Tb> FIG. Fig. 5 is a plan view of a board-like slider with a first coupling element under the binding device;<Tb> FIG. Fig. 6 is a plan view of a board-type slider with two stabilizers;<Tb> FIG. 7 is a plan view of a board-type slider with a stabilizer in the area behind the binding device;<Tb> FIG. 8 is a perspective view with a sectional view of a further embodiment of a stabilizing device for the board-type sliding device;<Tb> FIG. 9 <SEP> is a cross-sectional view of the sliding board body with power transmission means.
By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, wherein the disclosures contained in the entire description can be analogously applied to the same parts with the same reference numerals or the same component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and these position information in a change in position should be transferred analogously to the new situation.
Fig. 1 shows a perspective view of a board-like sliding device 1 which is formed in this embodiment as a ski. If the description of a ski is subsequently referred to in the description, the generic term of the board-type sliding device 1 or all embodiments contained therein is meant. In addition to the embodiment as a ski, the board-like sliding device 1 can also be designed in the form of a snowboard or in the form of a monoski.
The ski shown in Fig. 1 comprises a sliding board body 2 with a front sliding board body end 3 and a rear sliding board body end 4. Front and rear here refer to a direction of travel seen in the usual use of the ski.
The sliding board body 2 has an underside 5, which is designed as a sliding surface 6. The sliding surface 6 is that surface which, during operation of the ski, rests against the surface to be traveled, for example snow or ice. At the top 7 of the ski for receiving a binding device 8 is formed for releasably attaching a sports shoe of a user as needed. As can be seen in FIG. 1, the binding device 8 can have a front binding jaw 9 and a rear binding jaw 10.
As further seen in Fig. 1, it can be provided that the sliding board body 2 is bent in a front end portion 11 to the top 7. Such a bend is also referred to as ski tip. It can also be provided that a rear end region 12 of the sliding board body 2 is bent up to the upper side 7. The front end portion 11 and the rear end portion 12 are the vicinity of the front sliding board body end 3 and the rear sliding board body end 4, respectively.
As further apparent from Fig. 1, it is provided that the board-like sliding device 1, a stabilizing device 13 is arranged, which serves to improve the handling characteristics of the board-like sliding device 1. The stabilizing device 13 comprises a first coupling element 14 and a second coupling element 15. Furthermore, the stabilizing device 13 comprises a force transmission means 16 by means of which the two coupling elements 14, 15 are coupled together. The two coupling elements 14, 15 are both coupled to the top 7 of the sliding board body 2. It can be provided that fastening means 17 are used to connect the coupling element 14, 15 with the sliding board body 2. The fastening means 17 may be designed, for example, as connecting screws. Furthermore, it is also possible that the fastening means 17 are designed in the form of rivets or connecting bolts. Alternatively, it is also conceivable that the two coupling elements 14, 15 are connected by a positive connection, such as the inclusion in a slide, with the sliding board body 2.
In order to achieve the effect of the stabilizing device 13, it is provided that the two coupling elements 14, 15 are arranged at a distance 18 from each other. The distance 18 is in this case measured in the longitudinal direction 19 of the sliding board body 2. The size of the distance 18 is dependent on the total length of the sliding board body 2.
In addition, the distance 18 is dependent on the Skivorderteillänge 20, which extends from the front binding jaw 9 to the front sliding board body end 3. In particular, it can be provided that the distance 18 is between 20% and 90%, in particular between 50% and 80%, of the ski-part length 20.
FIG. 2 shows a plan view of a first embodiment of the board-type sliding device 1.
As can be seen from Fig. 2, it can be provided that the first coupling element 14 is arranged in a region 21 of the sliding board body 2, in which the sliding board body 2 has its greatest transverse extent 22. In this region 21 of the greatest transverse extent 22, a maximum of the load also occurs on the sliding board body 2, which is intercepted by the stabilization device 13. Characterized that the transverse extent of the sliding board body 2 seen over its length is different sizes, a waisting of the sliding board body 2, whereby different parts of the sliding board body 2 when driving through a curve are loaded differently by the weight of the user.
As can also be seen from FIGS. 1 and 2, it can be provided that the power transmission center! 16 is formed as a rotationally symmetrical pull rod 23. Alternatively, it can be provided that the power transmission means 16 has a polygonal cross-section, in particular a rectangular or a triangular cross-section. If the force transmission means 16 has a triangular cross-section, one side of the triangle is preferably arranged parallel to the upper side 7 of the gliding board body 2 and the tip of the triangle opposite this side avoids the upper side 7 of the gliding board body 2.
Fig. 3 shows a perspective view of the stabilizing device 13. In this view, the stabilizing device 13 is shown partially in section. As can be seen from FIG. 3, it can be provided that the first coupling element 14 comprises a base body 24. The main body 24 is that component of the first coupling element 14 which is fixed to the upper side 7 of the sliding board body 2 and is further coupled to the power transmission means 16. As can be seen from FIG. 3, it can be provided that the basic body 24 has fastening bores 25 by means of which it can be connected to the fastening board 17 with the sliding board body 2.
The main body 24 is preferably made of a material which has a low density and a high strength. As a result, the mass of the base body 24 can be kept as low as possible. Such materials are for example aluminum or plastics. Preferably, the base body 24 is made of a thermoplastic material by injection molding.
As further seen in Fig. 3, it can be provided that the power transmission means 16 in a coupling region 26 with the first coupling element 14 comprises a ball head 29. The first coupling element 14 may in this case have a receptacle 30 for the positive connection with the ball head 29.
The ball head 29 may comprise a first threaded pin 28 and the power transmission means 16 in the coupling region 26 have an internal thread 27 for receiving the threaded pin 28.
The receptacle 30 for the ball head 29 is preferably formed such that the ball head 29 is positively received in this, so that it is held in the longitudinal direction 19 of the sliding board body 2. By the execution of a ball head 29 and a corresponding receptacle 30 corresponding thereto can be made possible that a small angular rotation 31 between the power transmission means 16 and the base body 24 of the first coupling element 14 can be compensated. Thus, a flexible connection between the power transmission means 16 and the first coupling element 14 can be provided, wherein a tensile force 32 in the longitudinal direction 19 of the sliding board body 2 can be transmitted.
As further seen from Fig. 3, it can be provided that the second coupling element 15 has a holding element 33 which is coupled to the power transmission means 16. It can be provided that the power transmission means 16 in a coupling region 34 of the second coupling element 15 has a second threaded pin 35 which is screwed into an internal thread 36 of the retaining element 33.
The holding member 33 is preferably formed of a low-density and high-strength material such as aluminum.
Furthermore, it can be provided that the second coupling element 15 has a base plate 37 which is provided for attachment to the sliding board body 2. Again, it can be provided that mounting holes 25 are formed, which serve for fixing the base plate 37 on the sliding board body 2.
The base plate 37 is preferably made of a material having a low density and a high strength. As a result, the mass of the base plate 37 can be kept as low as possible. Such materials are for example aluminum or plastics. Preferably, the base plate 37 is made of a thermoplastic resin by injection molding, since this material can be produced well in a mass production manufacturing process.
3, it can be provided that in the base plate 37, a guide recess 38 is formed, in which the holding element 33 is received such that it is displaceable in the longitudinal direction 19 of the sliding board body 2. In order to apply the tensile force 32 to the power transmission means 16, it can be provided that in the second coupling element 15 a spring element 39 is arranged such that the holding element 33 is supported on the base plate 37 with the interposition of the spring element 39.
There are various embodiments of how such a support can be realized. In the embodiment of FIG. 3, a recess 40 is provided in the base plate 37 of the second coupling element 15, through which a
Approach to the guide recess 38 is formed. Corresponding thereto may be provided that in the holding element 33, a holding tongue 41 is formed, which projects in an L-shape with respect to a pulling portion 42 of the holding element 33.
It can be provided that the spring element 39 is arranged between the retaining tongue 41 and the recess 40 of the base plate 37, so that the spring element 39 can apply the tensile force 32 to the power transmission means 16. The spring element 39 may in this case be formed as an elastomer block, which also has a damping property in addition to the spring property. An elastomeric block also has the advantage that it is easy to produce in a serial production process.
Furthermore, it can be provided that an adjusting body 43 is formed, which is provided to act on the spring element 39. This can be influenced by the Einsteilkörper 43, the spring characteristic of the spring element 39. This can be implemented, for example, in that the adjusting body 43 is designed in the form of an adjusting screw, which presses the spring element 39.
Furthermore, it can be provided that in the region of the guide recess 38 a friction element 44 is arranged, which exerts a normal force 45 on the holding element 33. By the normal force 45, a frictional force 46 can be generated, which acts against movement of the holding element 33 in the longitudinal direction 19 of the sliding board body 2 and thus acts vibration damping. The friction element 44 may be designed for example as a rubber block.
As further seen in Fig. 3, a bottom 47 of the stabilizing device 13 is adapted to abut the top 7 of the slider 2. The top 48 of the stabilizing device 13 is visible to the outside. For this reason, it is advantageous if the stabilizing device 13 on the upper side 48 has as possible no openings in order to put an undesirable penetration of foreign bodies into the stabilizing device 13. For this reason it can be provided that the guide recess 38 and the recess 40 are introduced, starting from the bottom 47 in the base plate 37.
Similarly, the receptacle 30 for the ball head 29 may also be introduced from the bottom 47 into the base body 24 of the first coupling element 14. It can be provided that the individual elements of the stabilizing device 13 are arranged such that in the assembled state of the slider 2 and the stabilizing device 13, the power transmission means 16 is received positively in the first 14 and in the second coupling element 15 together with the ball head 29 and the holding member 33 , If the stabilizing device 13 is separated from the sliding board body 2, it can be provided that the force-transmitting means 16 can be removed from the first 14 or second coupling element 15.
In a further embodiment, it can be provided that on the underside 47 on the second coupling element 15, a securing tab 49 is arranged, which holds the holding element 33 on the second coupling element 15. The securing tab 49 may also be formed of aluminum.
Fig. 4 shows a sectional view of another embodiment of the stabilizing device 13, wherein again for the same parts the same reference numerals or component designations as in the preceding Fig. 3 are used. In order to avoid unnecessary repetition, reference is made to the detailed description in the preceding FIG.
In this embodiment, a head element 50 is provided in the region of the second coupling element 15, which is connected to the power transmission means 16. The connection between head element 50 and power transmission means 16 may be embodied, for example, in the form of a screw connection. Alternatively, it is also possible that the power transmission means 16 is connected by a material connection with the head member 50. The head element 50 can be designed, for example, as a disk with a round or rectangular cross section.
Furthermore, it can be provided that the spring element 39 is designed as a helical spring. The tensile force 32 is generated in that the head element 50 is supported on the base plate 37 of the second coupling element 15 with the interposition of the spring element 39. The guide recess 38 for guiding the power transmission means 16 may be realized for example in the form of a bore into which the power transmission means 16 is inserted.
Alternatively, it is also possible that the bore or guide recess 38 to the bottom 47 is open, so that the power transmission means 16 can be inserted from the bottom 47 in the second coupling element 15 without having to remove the head member 50.
Furthermore, as can be seen in the exemplary embodiment in FIG. 4, a cylinder 51, which is coupled to the power transmission means 16, may be formed in the region of the first coupling element 14. The connection between power transmission means 16 and cylinder 51 may be performed by a screw connection, so that by rotation of the power transmission means 16 relative to the cylinder 51, the distance in the longitudinal direction 19 can be varied. The receptacle 30 in the base body 24 of the first coupling element 14 is preferably formed in this embodiment, that the cylinder 51 is received in the base body 24 such that it is rotatably received by a Winkelverdrehung 31 with respect to a cylinder axis 52. Such a cylinder 51, which is received rotatably mounted around the cylinder 51 in the first coupling element 14, may also be referred to as a shaft.
FIGS. 5 to 7 show further possibilities for arranging the stabilizing device 13 on the sliding board body 2, again using the same reference numerals or component designations for the same parts as in the preceding FIGS. 1 and 2. In order to avoid unnecessary repetition, reference is made to the detailed description in the preceding Figs. 1 and 2 or reference.
As can be seen in Fig. 5, it can be provided that the second coupling element 15 is disposed below the binding device 8 and at the same time as a base
Serves for the binding device 8. Here, the power transmission means 16 is designed to be longer accordingly, whereby a larger area of the sliding board body 2 can be stabilized by the stabilizing device 13. In addition, by this measure, the largest possible area of the gliding board body 2 can be stabilized by the stabilizing device 13.
As schematically indicated in FIG. 5, it may further be provided that a protective cover 53 is provided which protects the force-transmitting means 16 against external force. The protective cover 53 can be designed, for example, in the form of scale-like nested portals, which are arranged relative to one another such that they yield flexibly to a deformation of the sliding board body 2. In particular, these portals may be arranged partially overlapping each other so that they form an effective protection for the power transmission means 16. In a further embodiment, it can also be provided that the individual portals or half-shells are spaced from each other, so that between the individual portals, a gap is formed through which, for example, snow can escape.
Furthermore, it can be provided that the protective cover 53 is formed such that between the protective cover 53 and power transmission means 16 a certain predetermined clearance or distance is formed. As a result, when the sliding board body 2 is subject to a great load stress, it can be achieved that the power transmission means 16 is brought into contact with the protective cover 53. By this mechanical stop can be achieved that the board-like sliding device 1 is given additional stability.
In a further, not shown embodiment variant can be provided that the first coupling element 14 is disposed in the vicinity of the binding device 8, and that the second coupling element 15 is disposed in the vicinity of the front sliding board body end 2.
In the exemplary embodiment according to FIG. 6, a stabilization device 13 is arranged both in front of the binding device 8 and behind the binding device 8. This can help to additionally stabilize the sliding board body 2, so that also the rear end portion of the sliding board body 2 is stabilized.
In the exemplary embodiment according to FIG. 7, a stabilization device 13 is arranged only in the region behind the binding device 8.
In all embodiments, it is possible that the first coupling element 14 either facing the binding device 8 or the binding device 8 is arranged facing away.
FIG. 8 shows a further embodiment of the stabilization device 13, which may be independent of itself, wherein the same reference numerals or component designations are used again for the same parts as in the preceding FIG. 3. In order to avoid unnecessary repetition, reference is made to the detailed description in the preceding FIG.
As can be seen in FIG. 8, it can be provided that the stabilization device 13 additionally comprises a second spring element 54, which is designed to apply a compressive force to the power transmission means 16. Thus, the sliding board body 2 can be additionally stabilized.
Fig. 9 shows a schematic representation of a cross section of the board-like sliding device 1 with a possible arrangement of the power transmission means 16. As can be seen in this embodiment, it can be provided that the top 7 of the sliding board body 2 has a recess 55 in which the force transmission means 16 is at least partially included. The recess 55 may be adapted to the shape of the power transmission means 16. If, for example, a force transmission means 16 with a round cross-section is used, then it may be expedient that the depression 55 also has a round shape, such as that of a half-shell. An advantage of this embodiment is that the power transmission means 16 can be arranged by the recess 55 space saving on the sliding board body 2. In addition, the power transmission means 16 can be protected by the arrangement in the recess 55 against environmental influences, such as force.
Further, as shown in FIG. 9, it can be provided that, in addition to the recess 55, the protective cover 53 is provided to receive the power transmission means 16 in the cavity formed by the recess 55 and the protective cover 53.
The stabilization device 13 shown in various embodiments serve to bias the front sliding board body end 3 and / or the rear sliding board body end 4 in the resting state of the board-type sliding device 1. This means that the front sliding board body end 3 and / or the rear sliding board body end 4 are pulled in the resting state of the board-like sliding device 1 by the stabilizing device 13 to the top 7 of the sliding board body 2. This may result in a shape of the sliding board body 2, which is similar to the shape of a rocker-shaped ski.
The resting state of the board-like sliding device 1 is that state or that shape of the sliding board body 2, which results when the board-like sliding device 1 rests with its bottom 5 on a flat surface and is not burdened by the weight of the user.
When driving with a board-like gliding device 1, in particular skis, when entering into a curve or when driving through a curve, the ski is tilted about the longitudinal direction 19 as a rotation axis, that is, the upper side 7 is turned sideways. By the weight of the user as well as by the sidecut of the ski, the front sliding board body end 3 and the rear sliding board body end 4 is bent towards the top 7 or towards the user upwards. In other words, the ski is deflected centrally when driving through a curve. When the ski is set straight again at the end of the curve, ie the upper side 7 is turned upwards, the front sliding board body end 3 and the rear sliding board body end 4 are again free of the load and spring back to the lower side 5 again. In the case of a quick change of curve and straight-ahead driving, the front 11 and / or the rear end region 12 may swing or hail. By stabilizing device 13, this hitting or swinging is limited by the fact that by means of the power transmission means 16 and the spring element 39 a hitting the bottom 5 is intercepted.
In particular, it can be provided that the sliding board body end 3, 4 is biased in the direction of the longitudinal center of the sliding board body 2 by the tensile force 32 of the spring element 39.
The embodiments show possible embodiments of the stabilizing device 13 and thus equipped board-type sliding device 1, which should be noted at this point that the invention is not limited to the particular embodiment variants shown, but also various combinations of the individual embodiments are possible with each other and this possibility of variation is due to the teaching of technical action by objective invention in the skill of those skilled in this technical field.
Furthermore, individual features or combinations of features from the illustrated and described different embodiments may represent for themselves, inventive or inventive solutions.
The task underlying the independent inventive solutions can be taken from the description.
All statements on ranges of values in the present description should be understood to include any and all sub-ranges thereof, e.g. is the statement 1 to 10 to be understood that all sub-areas, starting from the lower limit 1 and the upper limit 10 are included, ie. all subregions begin with a lower limit of 1 or greater and end at an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1, or 5.5 to 10.
Above all, the individual embodiments shown in FIGS. 1, 2, 3, 4, 5, 6, 7, 8 can form the subject of independent solutions according to the invention. The relevant tasks and solutions according to the invention can be found in the detailed descriptions of these figures.
For the sake of order, it should finally be pointed out that for a better understanding of the construction of the stabilizing device 13 and the board-type sliding device 1 equipped therewith, these or their components have been shown partly unassembled and / or enlarged and / or reduced in size.
[0084] List of Reference Numerals<tb> 1 <SEP> Board Type Slipper <SEP> 29 <SEP> Ball Head<tb> 2 <SEP> Gliding board body <SEP> 30 <SEP> Shot Ball head<tb> 3 <SEP> front sliding board body end <SEP> 31 <SEP> Angular rotation<tb> 4 <SEP> Rear sliding board body end <SEP> 32 <SEP> Traction<Tb> 5 <September> bottom <September> 33 <September> holding element<tb> 6 <SEP> Sliding surface <SEP> 34 <SEP> Coupling region second coupling element<tb> 7 <SEP> top <SEP> 35 <SEP> second grub screw<Tb> 8 <September> bonder <September> 36 <September> internal thread<tb> 9 <SEP> front binding jaw <SEP> 37 <SEP> Base plate second coupling element<tb> 10 <SEP> rear binding jaw <SEP> 38 <SEP> Guide recess<tb> 11 <SEP> Front end area <SEP> 39 <SEP> Spring element<tb> 12 <SEP> rear end region <SEP> 40 <SEP> deepening<Tb> 13 <September> stabilizing device <September> 41 <September> holding tongue<tb> 14 <SEP> first coupling element <SEP> 42 <SEP> train section<tb> 15 <SEP> second coupling element <SEP> 43 <SEP> Adjustment body<Tb> 16 <September> power transmission means <September> 44 <September> friction<Tb> 17 <September> fasteners <September> 45 <September> normal force<Tb> 18 <September> distance <September> 46 <September> friction<tb> 19 <SEP> Longitudinal direction of the gliding board body <SEP> 47 <SEP> Bottom stabilizing device<tb> 20 <SEP> Skivorderteillange <SEP> 48 <SEP> Top Stabilizer<tb> 21 <SEP> Largest Transverse Range <SEP> 49 <SEP> Safety Tab<Tb> 22 <September> transverse dimension <September> 50 <September> header<Tb> 23 <September> drawbar <September> 51 <September> Cylinder<tb> 24 <SEP> Main body first coupling element <SEP> 52 <SEP> Cylinder axis<Tb> 25 <September> mounting hole <September> 53 <September> protective cover<tb> 26 <SEP> Coupling area first coupling element <SEP> 54 <SEP> second spring element<Tb> 27 <September> internal thread <September> 55 <September> depression<tb> 28 <SEP> first set screw <SEP> <SEP>

权利要求:
Claims (18)
[1]
1. Board-like gliding device (1), in particular ski or snowboard, comprising:a sliding board body (2) having a front (3) and a rear sliding board body end (4) on which sliding board body (2) has a lower side (5) as a sliding surface (6), and on which sliding board body (2) has an upper side (7) for receiving a binding device (8) for releasably securing a sports shoe of a user as required;and a stabilization device (13) comprising a first coupling element (14), a second coupling element (15) and a force transmission means (16), which force transmission means (16) is coupled to the two coupling elements (14, 15), wherein the first (14) and the second coupling element (15) at a distance (18) from each other at a distance from the top (7) of the sliding board body (2) are arranged, characterized in thatat least one of the two coupling elements (14, 15) of the stabilizing device (13) comprises a spring element (39), wherein the spring element (39) is designed for applying a tensile force to the force transmission means (16), and wherein the force transmission means (16) at rest of the board-like sliding device (1) by the tensile force of the spring element (39) is loaded.
[2]
2. Board-like sliding device according to claim 1, characterized in that the force transmission means (16) is designed as a rotationally symmetrical pull rod (23).
[3]
3. board-like sliding device according to claim 1 or 2, characterized in that the first coupling element (14) with respect to the longitudinal direction (19) of the sliding board body (2) is rigidly connected to the power transmission means (16).
[4]
4. board-like sliding device according to claim 1 or 2, characterized in that the second coupling element (15) in relation to the longitudinal direction (19) of the sliding board body (2) is rigidly connected to the power transmission means (16).
[5]
5. board-like sliding device according to claim 4, characterized in that the force transmission means (16) in a coupling region (26) with the first coupling element (14) comprises a cylinder (51) and the first coupling element (14) has a receptacle (30) for positive locking Having connection with the cylinder (51).
[6]
6. board-like sliding device according to claim 5, characterized in that the cylinder (51) comprises a first threaded pin (28) and the force transmission means (16) in the coupling region (26) has an internal thread (27) for receiving the threaded pin (28).
[7]
7. board-like sliding device according to one of the preceding claims, characterized in that the second coupling element (15) has a base plate (37) in which in a guide recess (38) relative to the base plate (37) displaceable holding element (33) is received, said the force transmission means (16) is rigidly connected to the holding element (33), and in that the spring element (39) is arranged between the holding element (33) and the base plate (37), so that the holding element (33) with the interposition of the spring element (39) is supported on the base plate (37).
[8]
8. board-like sliding device according to claim 7, characterized in that the holding element (33) by a screw connection to the power transmission means (16), wherein the force transmission means (16) in a coupling region (34) with the second coupling element (15) has a second Grub screw (35) and the holding element (33) has an internal thread (36) for receiving the threaded pin (35).
[9]
9. board-like sliding device according to claim 8, characterized in that the first (28) and the second set screw (35) have oppositely oriented thread.
[10]
10. board-like sliding device according to one of the preceding claims, characterized in that the spring element (39) is designed as an elastomer block, which in addition to the spring property also has a damping property.
[11]
11. Board-like sliding device according to one of claims 7 to 10, characterized in that on the base plate (37) in the region of the spring element (39) an adjusting body (43) is formed, which is provided for acting on the spring element (39).
[12]
12. board-like sliding device according to one of claims 7 to 11, characterized in that in the guide recess (38) of the base plate (37) a friction element (44) is provided which with a predetermined normal force (45) on the holding element (33) acts, that in the direction of movement of the holding element (33) a frictional force (46) is generated.
[13]
13. Board-type gliding device according to one of the preceding claims, characterized in that the second coupling element (15) is designed as a support element between the binding device (8) and the gliding board body (2).
[14]
14. Board-like sliding device according to one of the preceding claims, characterized in that the first coupling element (14) in an area (21) of the sliding board body (2) is arranged in which the sliding board body (2) has its greatest transverse extent (22).
[15]
15. Board-like sliding device according to one of the preceding claims, characterized in that in the front end region (11) and in the rear end region (12) of the sliding board body (2) each have a stabilizing device (13) is arranged.
[16]
16. A board-type sliding device according to one of the preceding claims, characterized in that a protective cover (53) is arranged on the sliding board body (2), wherein at least partial sections of the force-transmitting means (16) are covered by means of the protective cover (53).
[17]
17. Board-type gliding device according to one of the preceding claims, characterized in that the force transmission means (16) is formed of a fiber-reinforced material.
[18]
18. A board-type sliding device according to one of the preceding claims, characterized in that on the upper side (7) of the sliding board body (2) a recess (55) is arranged, in which the power transmission means (16) is at least partially accommodated.

类似技术:

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DE202009004953U1|2010-11-25|Self-closing device and pullout guide

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AT408950B|2002-04-25|SKI, ESPECIALLY ALPINE

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AT406124B|2000-02-25|SKI SETUP

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DE3529183A1|1986-02-27|SAFETY BINDING FOR SKIS

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DE202005020331U1|2006-03-02|Recording device for a foot or for a shoe on a sports equipment

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AT507579A1|2010-06-15|SCHI OR SNOWBOARD WITH A PLATE-TYPE POWER TRANSMISSION ELEMENT

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EP2151266A1|2010-02-10|Glideboard

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AT514895B1|2019-12-15|Binding support plate for connecting a ski binding to a ski and also equipped ski

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AT398381B|1994-11-25|VIBRATION DAMPING DEVICE

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DE2656543A1|1978-03-23|Furniture hinge with adjustable base - has non-load bearing adjustable sliding piece on arm end for aligning door hang

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EP0965368B1|2004-08-04|Vibration damper for skis

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DE2601951A1|1977-07-21|Ski with spring mounted sole plate - has spherical recess in sole plate end to match boss screwed to ski

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DE102005004203A1|2006-07-13|Torque support bearing for drive unit of motor vehicle has at least one coupling element prestressed against bearing component by flexible element

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DE102014104160B3|2015-05-07|Improved axle suspension for longboards

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AT378897B|1985-10-10|Ski boot

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WO1998046313A1|1998-10-22|Snowboard

同族专利:

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公开号 | 公开日

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DE102015224648A1|2016-06-16|

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FR3029797B1|2019-09-06|

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CH710570B1|2019-06-28|

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AT516678A1|2016-07-15|

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FR3029797A1|2016-06-17|

引用文献:

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公开号 | 申请日 | 公开日 | 申请人 | 专利标题

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FR2654635B1|1989-11-22|1992-03-13|Salomon Sa|

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FR2678517B1|1991-07-04|1993-10-15|Salomon Sa|IMPROVEMENT FOR SKI DAMPING DEVICE.|

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FR2709071B1|1993-08-20|1995-10-27|Salomon Sa|Advanced ski provided with elastic devices to oppose and / or absorb flexural stresses.|

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FR2932693A1|2008-06-24|2009-12-25|Rossignol Sa|IMPROVEMENT FOR SNOWBOARD BOARD ON SNOW|

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法律状态:
2016-07-29| PCAR| Change of the address of the representative|Free format text: NEW ADDRESS: OTHMARSTRASSE 8, 8008 ZUERICH (CH) |

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2018-12-14| AZW| Rejection (application)|

优先权:

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申请号 | 申请日 | 专利标题

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ATA50914/2014A|AT516678A1|2014-12-16|2014-12-16|Board-like gliding device|

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