EP2036597A1 - Dispositif de reliure pour appareil de glisse de type planche - Google Patents

Dispositif de reliure pour appareil de glisse de type planche Download PDF

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Publication number
EP2036597A1
EP2036597A1 EP08006283A EP08006283A EP2036597A1 EP 2036597 A1 EP2036597 A1 EP 2036597A1 EP 08006283 A EP08006283 A EP 08006283A EP 08006283 A EP08006283 A EP 08006283A EP 2036597 A1 EP2036597 A1 EP 2036597A1
Authority
EP
European Patent Office
Prior art keywords
hold
base plate
disc
down disc
operating state
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP08006283A
Other languages
German (de)
English (en)
Inventor
Helmut Holzer
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Atomic Austria GmbH
Original Assignee
Atomic Austria GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Atomic Austria GmbH filed Critical Atomic Austria GmbH
Publication of EP2036597A1 publication Critical patent/EP2036597A1/fr
Withdrawn legal-status Critical Current

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    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C10/00Snowboard bindings
    • A63C10/02Snowboard bindings characterised by details of the shoe holders
    • A63C10/10Snowboard bindings characterised by details of the shoe holders using parts which are fixed on the shoe, e.g. means to facilitate step-in
    • A63C10/106Snowboard bindings characterised by details of the shoe holders using parts which are fixed on the shoe, e.g. means to facilitate step-in to the front and back of the shoe
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C10/00Snowboard bindings
    • A63C10/16Systems for adjusting the direction or position of the bindings
    • A63C10/18Systems for adjusting the direction or position of the bindings about a vertical rotation axis relative to the board
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C10/00Snowboard bindings
    • A63C10/24Calf or heel supports, e.g. adjustable high back or heel loops

Definitions

  • the invention relates to a binding device for board-like gliding devices, in particular a snowboard binding, as indicated in the preamble of claim 1.
  • the WO 97/33664 A1 and the WO 00/04964 A1 disclose a snowboard binding in which the base plate for supporting the foot of a user can only be removed or removed with the aid of tools relative to the hold-down disc screwed to the snowboard.
  • delicate and complex disassembly work on the snowboard binding would be necessary in order to be able to remove the base plate from the snowboard.
  • the base plate with the circular hold-down disc or with the snowboard always remains mechanically connected.
  • a relative displacement between the hold-down disc and the base plate in the vertical direction to the top of the snowboard for an end user or dealer such bonds is not provided.
  • the radially adjustable to the circular hold-down disc slider elements make it with their teeth in the outer, opposite end portions only an as needed activatable and deactivatable against rotation of the base plate relative to the snowboard, wherein in the extended position of the slider elements rotational movement of the base plate relative to the central hold-down disc is blocked. In the retracted position of the slide elements, a change in the angle of rotation of the base plate relative to the longitudinal axis of the snowboard is then made possible. Although a comfortable or tool-free change in the angular position of the binding relative to the snowboard can be made with this known embodiment, a quick and uncomplicated removal or lifting of the base plate together with the components arranged thereon relative to the snowboard is not possible.
  • snowboard binding has a circular, rigidly connected to a snowboard hold-down disc, which comprises two radially adjustable to its center slide elements. These slide elements make in the extended position relative to the hold-down disc a rotation lock for the pivot bearing between the base plate and the hold-down disc. Between the outer edge portion of the circular hold-down disc and the edge portions around the corresponding opening in the base plate are rigid overlaps or stable retaining flanges formed, which permanently prevent a relative displacement of the base plate in the vertical direction to the top of the snowboard or in the vertical direction to the mounting plane of the binding device.
  • the protrusions formed in the circumferential section of the hold-down disc and in the edge section of the circular opening in the base plate form rigid overlaps or retaining lugs in the suitably assembled state, which results in a permanent lift-off barrier of the base plate relative to the hold-down disc. Also in this embodiment, therefore, a change or removal of the base plate relative to the snowboard is only possible by completely unscrewing and removing the hold-down disc from the snowboard.
  • a hold-down disc of this hold-down device is designed such that it can be positively coupled with pin-like projections on the upper side of the sliding board and relative to these pin-like projections in the vertical direction can be decoupled, so that remain only the peg-like projections on the sliding board when removing the disc-shaped hold-down device and the base plate from the sliding board ,
  • two comb or rake-like locking elements are provided in the hold-down device, which can engage behind the head of the peg-like projections either backlash, can engage behind with vertical play or can be decoupled from the pin-like projections.
  • an actuating lever which enables a limited increase of the hold-down disc relative to the base plate when taking an intermediate position, so that a change of the rotational angle position of the base plate relative to the hold-down disc is made possible.
  • this intermediate position which loosens the hold-down plate, a complete removal of the base plate from the sliding board is furthermore prevented.
  • a disadvantage is that this design requires a plurality of components with particularly low dimensional tolerances, whereby the creation of such a binding device is complicated or expensive.
  • the originating from the applicant AT 411 016 B describes a snowboard binding which has an intended for attachment to a snowboard, in plan view circular hold-down disk for a comparatively larger area base plate.
  • At least one slide element is formed on this hold-down disc, which engages in a retracted position from an extended position in which it overlaps or covers a transitional area between the hold-down disc and the base plate, in which the slide element does not overlap the transition area between the hold-down disc and the base plate or overlapped, and vice versa, is adjustable.
  • the at least one slide element forms in the extended position a lift-off of the base plate relative to the hold-down disc in the vertical direction to the support plane.
  • the base plate relative to the hold-down disc or from the snowboard can be lifted.
  • a setting and fixing device can be actuated without tools on the hold-down disc.
  • the base plate is raised at least slightly against the hold-down disc while inactive switched lift-off so that the teeth between the hold-down disc and the base plate is disengaged and is then the base plate in the desired Reset the angular position.
  • the resulting ease of use or ease of use is relatively high, but not yet sufficiently satisfactory for all users or situations.
  • the present invention has for its object to provide a binding device for board-like gliding devices, in particular a snowboard binding, which offers an increased level of ease of use and ease of use with respect to a variability of the rotation angle and also with respect to the simplest possible assembly and disassembly.
  • the three selectively selectable operating states of the setting and fixing device enable rapid and unambiguous or simplified handling of the binding device.
  • a user or operator of the binding device can select clearly predefined operating states selectively or specifically activate associated functions.
  • either a change or readjustment of the angle of rotation of the base plate can be made without the aid of additional tools or a lifting or removing the base plate relative to the sliding board body fix remaining hold-down disc are performed.
  • a separate adjustment state B is adjustable at the setting and fixing, in which a rotation of the base plate is made possible relative to the hold-down disc, without causing the base plate relative to the hold-down disc must be lifted mandatory.
  • one of them different or separate operating state C is adjustable, in which the base plate can be completely removed from the hold-down disc or from the snowboard.
  • a particular advantage lies in the fact that when taking the operating condition B, in which only the rotation is inactive, the lift-off remains active, so that accidental dropping or detachment of the base plate from the snowboard or against the hold-down disc is prevented. This is particularly advantageous if a change or readjustment of the rotation angle of the base plate during use of the binding device, in particular on a runway or in open terrain, to be performed.
  • the binding device according to the invention is not subject to the risk that, when the anti-twist device is deactivated, that is, when taking the second operating state B, in which a change in the rotational angle position of the base plate is made possible, accumulate or compress snow below the hold-down disc or below the base plate.
  • the second operating state B neither the hold-down disc, nor the base plate are lifted off the top of the gliding board body, but a nearly gap-free or play-free Ablage of the hold-down disc and the base plate with respect to the top of the gliding board body is maintained.
  • the base plate when taking the operating state B is not more than about 2 mm from the top of the sliding board body can be lifted.
  • the functionality and the functional reliability of the binding device can also be ensured if it is to be readjusted under adverse conditions of use or after icing.
  • the entire handling of the binding device with respect to the sliding board body pre-assembled hold-down disc is particularly simple and comfortable, so that even laymen or end users a readjustment of the binding device is easily possible.
  • the advantageous measures according to claim 2 ensures that even with an individually desired change in the angular position of the base plate during use of the binding device or outdoors under the base plate or hold-down disc hardly accumulate snow or ice can accumulate. As a result, increased functional reliability and reliability of the binding device is achieved.
  • the measures according to claim 3 result in a dual function for the at least one slide element on the hold-down disc, whereby the binding device can be constructed as inexpensively as possible.
  • Another advantage is also an embodiment according to claim 4, characterized in that only an actuator is formed, which acts both functionally on the anti-rotation and on the anti-lifting device.
  • the number of required components can thereby be kept as low as possible and, on the other hand, only one operating element is required, via which the operator can actuate the actuator accordingly.
  • a weight reduction of the binding device In addition to savings in components and manufacturing costs can also be achieved a weight reduction of the binding device.
  • the embodiment according to claim 5 or 6 ensures that the anti-rotation and the lift-off can be disabled separately or decoupled from each other. Nevertheless, only a single actuator is provided with which an optional deactivation of the rotation and the lift-off is accomplished. As a result, the complexity and weight of the binding device can be kept as low as possible.
  • the embodiment according to claim 8 or 9 prevents inadvertent skipping or skipping of safety-relevant operating states.
  • the reliability or security of use of the binding device is increased after the anti-rotation device is activated simultaneously or necessarily when the anti-lifting device is activated. Above all, this reliably prevents the anti-lifting device being activated, but the anti-rotation device is inactive when a base plate together with the components mounted thereon is mounted or fastened on the retaining plate or on the corresponding snowboard for later use.
  • the embodiment according to claim 10 offers the advantage that the hold-down disc can always remain rigid or unyielding connected to the sliding board body and the functionality of the optional activatable and deactivatable lift-off and optionally activatable and deactivatable anti-rotation exclusively via the at least one, relative to the hold-down disc adjustable slider element is accomplished.
  • an optional deactivation and activation of the anti-rotation lock is structurally simple and particularly robust.
  • the hold-down disc for example by means of conventional mounting screws can remain rigidly connected to the top of a corresponding sliding board body when a change in the angular position of the base plate is desired.
  • only the rotation is disabled when the second operating state B is taken.
  • the lift-off between the hold-down disc and the base plate remains active or upright unchanged.
  • the toothing and the holding extension are structurally and spatially separated, so that they are available for optimal dimensioning and arrangement or positioning. In addition, this ensures that a quick inspection of the function or the respective state of the lift-off can be made. Furthermore, it is clearly evident that when the lift-off is properly activated, in any case, the rotation is activated, since the lift-off and anti-rotation are in functional coupling. In particular, for the operator or user of the binding device, after checking the active state of the anti-lift device, there is the certainty that the base plate is held properly by the hold-down plate, i. In addition, also held against rotation and thus is safe to use.
  • the embodiment according to claim 16 achieves in an advantageous manner that even if the angles of rotation of the base plate are changed under difficult conditions, for example in deep snow or in a snow-covered sliding board or in a snowy bond, an accumulation of snow or ice below the base plate is avoided.
  • the angle of rotation of the base plate relative to the hold-down disc hardly the risk of accumulation of snow or ice below the base plate, after the base plate can remain directly on the top of the sliding board body when its rotation angle is to be changed.
  • the functionality or security of use of the binding device according to the invention can thereby be substantially increased after operator errors or carelessness or thoughtlessness in the operation of the binding device can not lead to critical safety defects at the binding device.
  • the base plate can also be easily placed by technically unexperienced operators on the hold-down disc or on the corresponding snowboard and are subsequently only the slider elements in the extended position to transfer, to build a reliable mechanical connection.
  • the necessary actions for carrying out an assembly or disassembly process and a setting process for the angle of rotation between the base plate and the hold-down disc are intuitive for a user recognizable or very quickly traceable.
  • the necessary hand grips are easily executable even when wearing gloves.
  • an actuator is provided which can transmit high forces in a simple design.
  • such an embodiment is robust and free from icing-prone joint joints.
  • such a drive mechanism can also be used to accomplish a stable or reliable locking of the setting and fixing device.
  • the over-dead-center position of this mechanical movement coupling can advantageously be utilized for a simple locking of the first operating state A.
  • Another advantage is an embodiment according to claim 22 or 23, since such a coupling mechanism can be constructed inexpensively and a reliable implementation of a rotational movement of the coupling disc can be achieved in a linear movement of the slide elements.
  • a force-to-displacement ratio is achieved, which enables a reliable locking of the setting and fixing device.
  • this is achieved in an advantageous manner that despite the same rotational widths or adjusting angle steps on the handle or coupling disc of the setting and fixing different positions for the coupled thereto slide elements can be achieved.
  • pairs or groups of slide elements can be formed which, in comparison to another pair or a different group of slide elements, cover other travel paths, in particular larger or shorter travel paths.
  • the slide elements moved by sliding guides can cover a comparatively shorter travel path during the transition from the second operating state B to the third operating state C than the second group of slide elements, which are preferably coupled via connecting rods to the setting and fixing device.
  • the adjustable via sliding guides slide elements favor the attachment of relatively large or numerous mounting holes for mounting screws, whereas the hinged via connecting rod couplings sliding elements reliable and simple locking the setting and fixing when taking the active position of rotation and while taking the Enable active position of the lift-off.
  • a handle which can take at least two positions.
  • an ergonomically convenient operating position can be taken, in which a comfortable and powerful operation of the actuator is possible.
  • the handle can take up a space-saving rest position, so that the most compact possible binding direction is created, which has hardly protruding parts. As a result, the risk of injury during the intended use of the binding device is minimized.
  • Another advantage is also an embodiment according to claim 29, characterized in that a rotational movement to be performed by the operator is converted into a linear movement for the slide elements and sufficiently large travel ranges by covering relatively small rotation angle ranges can be covered for the slide elements.
  • the respective operating conditions of the adjusting and fixing device by the respective rotational angle positions of the corresponding handle visually or evidently easily visible relative to the recess in the top of the hold-down disc, so that the respective operating state by the operator or user quickly and unmistakably can be detected.
  • an embodiment according to claim 30 is advantageous, since thereby the rotational mobility of the pinion or the coupling disc is indirectly limited.
  • the rotational angle range of the pinion or the coupling disc is limited by the limited adjustment paths of at least one slide element. Such a limitation of the rotation angle range is structurally particularly simple and robust implementable.
  • the development according to claim 31 is advantageous because even if the base plate and the hold-down disc were not positioned by the operator absolutely exactly to each other, an automatic alignment or a self-adjustment can occur.
  • the wedge effect of the slide elements during the transfer of the setting and fixing in the locking position or in the first operating state a proper alignment or a possible play-free coupling between the hold-down disc and the base plate is achieved.
  • blocking orders or the relative coupling between the hold-down disk and the base plate to be mounted can thereby be increasingly avoided after the wedge-like pointed slide elements can be comparatively reliably transferred into the planned positive engagement with the base plate.
  • Fig. 1 is a binding device 1 for releasably releasable connection of a gliding device, in particular a board-like sports device 2, illustrated with a sports shoe 3 in perspective.
  • the sports equipment 2 is formed by a so-called snowboard 4, on which the binding device 1 is to be mounted for releasable connection with a suitably formed snowboard shoe 5.
  • the binding device 1 comprises according to the illustrated embodiment, at least one coupling part 6, 7 for releasably releasable connection with at least one corresponding coupling part 8, 9 on the sports shoe 3.
  • the coupling parts 6 to 9 thereby form a tool-operated locking coupling 10 or a so-called “step -In-System” for comfortable and quick connection and detachment of sports shoe 3 and binding device 1.
  • the coupling parts 6, 7 of the binding device 1 can also be formed within the scope of the invention by at least one belt arrangement known per se. These known from the prior art belt assemblies have at least one band-shaped tension member with a buckle or other clamping device, with which the sports shoe 3 can be lashed in the binding device 1 and released for exit from the binding device 1 again.
  • the binding device 1 comprises a largely planar base plate 11, which is supported via a hold-down disc 12 on the upper side 13 of the snowboard 4.
  • the base plate 11 may have an approximately shoe-sole outline in plan view.
  • the hold-down disc 12 for holding the base plate 11 or the entire binding device 1 on the snowboard 4 has an at least approximately circular outline in plan view.
  • a thickness of the wheel-like hold-down disc 12 corresponds approximately to a thickness of the base plate 11, a diameter 14 of the hold-down disc 12 may be 70 mm to 140 mm, preferably about 105 mm.
  • the base plate 11 has in its center region a circular or at least partially circular aperture 15 or a corresponding recess whose diameter substantially corresponds to the diameter 14 of the hold-down disc 12.
  • the hold-down disc 12 and the base plate 11 are at least partially inserted into each other via the opening 15 or the recess or form-fitting connectable.
  • the circular disc-shaped hold-down disc 12 forms in conjunction with the opposite breakthrough 15 and with the corresponding bore a need-locking and releasable pivot bearing 16 for the base plate 11 relative to the top 13 of the snowboard 4.
  • this pivot bearing 16 forms a substantially vertical to the base plate 11 and the top 13 of the snowboard 4 aligned axis 17, which extends parallel to the binding vertical axis or coincides with this.
  • the base plate 11 may be formed asymmetrically to a binding longitudinal axis 18 based on the sole shape of the sports shoe 3.
  • This binding longitudinal axis 18 preferably extends through the center of the hold-down disc 12 and is aligned substantially parallel to a contact surface 19 for the sports shoe 3.
  • the contact surface 19 for the sports shoe 3 on the base plate 11 can largely parallel to the top 13 of the snowboard 4 run or be aligned obliquely to the top 13 of the snowboard 4 for the realization of a so-called "canting".
  • the selectively lockable and releasable pivot bearing 16 between the hold-down disc 12 and the base plate 11 makes it possible to set different rotational angle positions of the binding device 1 relative to the snowboard 4.
  • the rotational angle 20 can be adjusted as desired from this angle position "Regular" to "Goofy” and vice versa via this rotary bearing 16.
  • pivot bearing 16 it is possible, via this pivot bearing 16, to align the binding longitudinal axis 18 from an orientation parallel to the longitudinal axis 21 to an orientation transversely or at right angles to the longitudinal axis 21.
  • the pivot bearing 16 is lockable and releasable but formed without a stop, so that an endless adjustment range for the rotation angle 20 of more than 360 ° is possible.
  • binding devices 1 of identical design or intended for the right and left foot are mounted on a snowboard 4.
  • a plurality of fastening screws 22 is provided which pass through the hold-down disc 12 and can be anchored in the snowboard 4 in order to support the binding device 1 on the upper side 13.
  • fastening screws 22 have also met the function of an adjusting means for the rotation angle 20 and for the pivot bearing 16 according to a known from the prior art training.
  • all fastening screws 22 for the hold-down disc 12 had to be loosened, the angle of rotation 20 of the base plate 11 should be set as desired and the fastening screws 22 tightened again with high torque.
  • auxiliary tools such as Screwdriver and took the work to be carried out in the previously known bindings relatively long changeover to complete.
  • FIG. 2 to 6 An improved embodiment of a hold-down disc 12 with a setting and fixing device 23 for the base plate 11 of a snowboard binding is shown.
  • This adjustment and fixing device 23 on the hold-down disc 12 makes it possible to change the rotation angle 20 without tools.
  • Fig. 1 - And a tool-less assembly and disassembly of the base plate 11 together with the components mounted thereon relative to a snowboard 4 execute.
  • the following descriptions of the Fig. 2 to 6 are in synopsis with Fig. 1 to read.
  • the improved adjusting and fixing device 23 between the hold-down disc 12 and the base plate 11 comprises at least one actuator or slide element 24, preferably at least two or four slide elements 24, 25.
  • the illustrated embodiment four slide elements 24, 25th formed, which are supported on the hold-down disc 12 and mounted relative to this adjustable.
  • the preferred paired, first slide elements 24 are starting from a fully or maximally extended position 26 - Fig. 3 in at least two comparatively withdrawn positions 27a Fig. 4 - and 27b - Fig. 5 - and vice versa adjustable.
  • the fully extended position 26 corresponds to a first active position, in which the adjusting and fixing device 23 via the slide elements 24, 25 ensures a rigid connection in all spatial directions between the hold-down disc 12 and the base plate 11.
  • the fully or maximally retracted position 27b of the slide elements 24, 25 corresponds to a completely inactive operating state of the setting and fixing device 23, in which a lifting of the base plate 11 relative to the hold-down disc 12 in a direction perpendicular to the top 13 of the snowboard 4 is made possible and in which operating state preferably also a change in the rotational angle 20 can be carried out.
  • the base plate 11 together with the components arranged thereon can be lifted and removed from the hold-down disk 12 or from the snowboard 4.
  • the slide elements 24, 25 allow a rotational movement of the base plate 11 relative to the hold-down disc 12 when taking the partially retracted position 27a, in particular taking a defined intermediate position between the two extreme positions 26 and 27b, a removal or lifting However, the base plate 11 relative to the snowboard 4 and against the hold-down disc 12 is prevented.
  • the first group of slide elements 24 overlaps or overlaps in their maximum position 26 extended relative to the hold-down disk 12.
  • the slide elements 24 define in their extended position 26 a positive connection with the base plate 11 or overlap these the base plate 11 in the edge portion to the circular aperture 15 at least in sections.
  • Geared end portions 30 of the second group of slide elements 25 engage in taking the maximum extended position 26 of the slide elements 25 in a corresponding toothing on the lateral surface 49 of the opening 15 in the base plate 11 a.
  • the base plate 11 has a from the bottom 31 to the top 32 continuously extending aperture 15, but it is of course also possible at the bottom 31 an adequate Form recess or depression.
  • the upper side 32 of the base plate 11 can thus be configured in a continuous or planar manner over a wide area.
  • all slide elements 24, 25 are supported exclusively on the hold-down disk 12 and are mounted so adjustably relative to the latter that they are in the maximum extended position 26.
  • the binding device 1 in particular the retaining disk 12, preferably comprises an adjusting device 34.
  • Fig. 6 With which a coupled adjustment of several, usually all, slide elements 24, 25 is possible.
  • an adjusting device 34 is formed, the synchronous adjustment of the slide elements 24, 25 in different or in opposite directions Directions allows, as this particular out Fig. 6 can be seen.
  • This adjusting device 34 may be formed by a arranged in the center of the hold-down disc 12 gear or pinion 35, which is in meshing drive connection with the slide elements 24, 25.
  • the pinion 35 is rotatably supported about an axis 37 extending through the center of the hold-down disk 12 and oriented perpendicular to its underside 36.
  • the pinion 35 is designed as a spur gear.
  • At distributed circumferential points of the pinion gear 35 engage toothed portions 38, 39 of the slide elements 24, 25 a.
  • These sections 38, 39 thereby represent a type of toothed rack, which run tangentially to the pinion 35 and engage in a form-fitting or meshing manner in this.
  • the slider elements 24, 25 and the rack-shaped portions 38, 39 are formed by one-piece, plate-like parts made of metal or plastic.
  • slide elements 24, 25 with the adjoining toothed sections 38, 39 by a composite component of metal and plastic, in particular of aluminum or steel with molded hard plastic elements.
  • slide elements 24, 25 are preferably adjustable in the radial direction to the hold-down disc 12. But it is also possible to adjust the slide elements 24, 25 in other or composite directions of movement relative to the hold-down disc 12.
  • the binding device 1, in particular the hold-down disc 12, comprises at least one spring means with which the slider elements 24, 25 are continuously pushed into the maximally extended position 26.
  • This at least one spring means can be formed by spring tongues on the slide elements 24, 25 or on the hold-down disc 12.
  • the spring means are preferably by at least one coil spring, formed in particular by cylindrical compression springs.
  • the adjusting and fixing device 23 between the hold-down disc 12 and the base plate 11 includes a locking toothing 40.
  • This activatable and deactivatable locking teeth 40 serves primarily for safe or high-strength determination of the selectively adjustable and fixable rotational angle positions or rotational angle 20 between the hold-down disc 12th
  • Such a locking toothing 40 is compared to a frictional coupling a highly stable anti-rotation 41 between the circular hold-down disc 12 and the base plate 11.
  • the locking teeth 40 and the rotation 41 locks in the active state, the actual pivot bearing 16 between the Hold-down disc 12 and the base plate 11.
  • the adjustment and fixing device 23 further comprises a deactivatable and deactivatable anti-lift device 42 as needed.
  • This anti-lift device 42 is preferably formed by at least one strip-like projection or holding projection 43 on the slider elements 24, 25, in particular on the first group of slider elements 24.
  • at least one holding extension 43 - in the exemplary embodiment shown, in each case two arcuate retaining extensions 43 - are formed on the end portion 29 of the slide elements 24 facing away from the pinion 35.
  • the at least one holding extension 43 on the slider elements 24 prevents lifting or detachment of the base plate 11 relative to the hold-down disc 12 bolted to the snowboard 4.
  • the setting and fixing device 23 is designed such that it can be converted into at least three selectively ingestible operating states A, B or C, as shown in the Fig. 3 to 5 was exemplified.
  • the adjusting and fixing device 23 is constructed in such a way that when taking the first operating state A - Fig. 3 -
  • the anti-rotation 41 and the anti-lift device 42 are active, so that a largely rigid or unyielding connection between the hold-down disc 12 and the base plate 11 is present.
  • the anti-rotation device 41 is also preferably inactive, so that fundamentally, even in the third operating state C, rotation of the base plate 11 relative to the hold-down plate 12 is possible.
  • the slide elements 24, 25 assume their maximum extended position 26, as shown in FIGS FIGS. 2 and 3 is exemplified.
  • the slide elements 24, 25, in particular the first group of slide elements 24, occupy a middle position, in particular a partially retracted or partially retracted position 27 in the hold-down disk 12, as shown in FIG Fig. 4 has been illustrated schematically.
  • the lift-off protection 42 is still active, while the rotation lock 41 is inactive.
  • the slider elements 24 take approximately the position 27b, as in Fig. 5 was exemplified. In this maximum retracted or retracted position of all slide elements 24, 25, the anti-rotation 41 and the lift-off 42 is inactive, so that the base plate 11 is rotated relative to the hold-down disc 12, but above all can be lifted or removed from this.
  • the three operating states A, B, C of the setting and fixing device 23 can be adjusted or changed at any time by a user of the binding device 1 or by an employee of a rental shop without having to use separate auxiliary tools, such as e.g. Screwdrivers are required.
  • the setting and fixing device 23 has three, if necessary, selectable setting options which are clearly recognizable and easily activatable for an operator of the hold-down plate 12 or the binding device 1.
  • the adjusting and fixing device 23 in each of its three operating states A, B, C remain at least temporarily.
  • the three operating states A, B, C define a type of switching states which are selectively selectable and persist permanently without the intervention of manual holding forces. That means it does not require it is that an operator of the binding device 1 or the setting and fixing device 23 must maintain the respective operating state A, B, C by continuous force on the setting and fixing device 23.
  • These operating states A, B, C thus correspond to selectively selectable working positions of the hold-down disk 12, which remain up until a further actuation or conversion of the setting and fixing device 23 by an operator.
  • the adjusting and fixing device 23 is associated with a locking device, which may comprise, for example, a known, resiliently biased detent tongue.
  • the adjusting and fixing device 23 forms via the pinion 35 and the toothed portions 38, 39 of the slide elements 24, 25 an actuator 44, which acts both on the anti-rotation 41 and on the anti-lift device 42. That is, a common actuator 44 is formed, which is motion-coupled with the anti-rotation 41 and also with the anti-lift device 42.
  • the actuator 44 for the slide elements 24, 25 is formed such that, although a simultaneous action on the anti-rotation 41 and the anti-theft device 42 takes place, the deactivation of the anti-rotation 41 and the deactivation of the anti-theft device 42 but offset in time, in particular before or lagging.
  • the setting and fixing device 23 from the operating state A - Fig.
  • the anti-rotation 41 is disabled (when taking the operating state B) and only subsequently the anti-lift device 42 deactivated (when taking the operating state C).
  • lift-off protection 42 is activated first (assuming operating state B) and subsequently additionally anti-twist device 41 is activated (assuming operating state A). This temporal offset or this temporal advance and lagging is thus dependent on the respective operating state change A, B, C or C, B, A.
  • the adjusting and fixing device 23 is designed such that, starting from one of its three operating states A, B, C, it can be transferred exclusively to a directly closest, in particular to a next higher and / or to a next lower operating state.
  • the adjusting and fixing device 23 can be switched from A to B and from B to C, from C to B and from B to A. It is likewise possible to change the operating state several times between two "adjacent" operating states A, B or B, C make.
  • the setting and fixing device 23 without the aid of tools, starting from the first operating state A in the second operating state B and subsequently in the third operating state C and starting from the third operating state C in the second operating state B and subsequently in the first operating state A can be transferred is.
  • the adjusting and fixing device 23 has at least one slide element 24, 25, which has a toothing 46 as a partial component of the anti-twist 41 in a first, lower plane 45.
  • This toothing 46 is designed as a straight toothing, which can be extended and retracted via the slide elements 24, 25 in the radial direction to the center point of the circular hold-down disc 12.
  • the toothing 46 is due to their design in the outer end portions 29, 30 of the slider elements 24, 25 relative to the base plate 11 variably positionable.
  • the teeth 46 for the rotation 41 and the at least one retaining extension 43 for the lift-off 42 are arranged in heights different levels 45, 47, wherein the holding extension 43 is preferably arranged for the lift-off 42 in the relatively higher plane 47.
  • the respective operating state of the lift-off safeguard 42 is immediately or obviously recognizable for an operator, whereby the safety of use can be increased or kept relatively high.
  • the adjusting and fixing device 23 has at least one slide element 24, 25, which forms a retaining extension 43 for positive retention of the base plate 11 in its front end remote from the center of the hold-down disc 12, wherein this holding extension 43 and the toothing 46th contributes to the creation of a reliable anti-rotation 41.
  • this holding extension 43 and the toothing 46th contributes to the creation of a reliable anti-rotation 41.
  • 25 is then also an optional and temporally offset activation and deactivation of the anti-rotation 41 and the lift-off 42 allows.
  • the wheel-like hold-down disc 12 has a lateral surface 48, which is at least partially cylindrical or frusto-conical. In kegelsturnpfförmörmige embodiment of the hold-down disc 12 at least forms the base of the conical body, the bottom 36 of the hold-down disc 12 from.
  • the lateral surface 48 of the hold-down disc 12 forms in cooperation with corresponding guide surfaces on the lateral surface 49 of the opening 15 in the base plate 11, the pivot bearing 16 for the base plate 11 relative to the hold-down disc 12. It is sufficient if either the opening 15 or the corresponding recess in the base plate 11 or the hold-down disc 12 at least partially circular or curved surfaces to create the pivot bearing 16.
  • the retaining disk 12 could also be designed as a circular polygonal body in plan view.
  • the hold-down disc 12 in the operating state C with maximum retracted slide elements 24, 25 has an approximately cylindrical or conical boundary or lateral surface 48 by the end sections 29, 30 of the slide elements 24, 25 close approximately flush with the lateral surface 48.
  • the slide elements 24, 25 in the operating state C do not project from the lateral surface 48 or only marginally.
  • the anti-rotation device 41 and the anti-lift device 42 are assigned a common, motion-coupling actuator 44 for the synchronous, temporally or functionally phase-shifted deactivation of the anti-rotation device 41 and the anti-lift device 42.
  • the anti-rotation 41 or anti-rotation 41 and the anti-lift device 42 with the common, central actuator 44 which is preferably via a handle 50 operable or actuated, activated and deactivated.
  • the actuator 44 is activated via the handle 50 so that the Lift-off 42 is activated in the first operating state A and also in the second operating state B and only in the third operating state C is inactive.
  • the actuator 44 can cause any ejection or retraction movements of the slide elements 24, 25.
  • the slide elements 24, 25 can be mounted translationally or rotatably adjustable and moved in the radial or tangential direction relative to the hold-down disc 12.
  • the locking toothing 40 preferably extends around the booklet 15 in the base plate 11.
  • the locking toothing 40 is at partial sections of the Formed lateral surface 49 of the cylindrical, optionally stepped perforation 15 formed.
  • the anti-lift device 42 for the base plate 11 against the hold-down disc 12 with respect to perpendicular to the plateau 19 extending directions.
  • the adjusting and fixing device 23 between the hold-down disc 12 and the base plate 11 thus comprises on the one hand the anti-rotation 41 and on the other hand, the anti-lift device 42nd
  • the handle 50 acts doing so on the pinion 35 such that a bidirectional rotation of the pinion 35 can take place about its axis 37.
  • the handle 50 is as in FIG Fig. 6 has been illustrated schematically, about a transverse to the axis 37 of the pinion 35 extending pivot axis 51 pivotally mounted or tilted.
  • the handle 50 in this case has a defined locking position 52, in which a rotational mobility of the pinion 35 and thus an adjustability of the slide elements 24, 25 is prevented or blocked.
  • This locking position 52 is defined by a largely flat or horizontal position of the strip or plate-like handle 50. When taking the locking position 52 thus extends the upper and lower flat side of the handle 50 substantially parallel to an upper surface 54 of the hold-down disc 12.
  • the pivot axis 51 of the handle 50 is associated with a longitudinal side edge of the plate or strip-like handle 50.
  • the handle 50 preferably has a half-moon or semicircular outline contour, as shown in FIG Fig. 6 has been illustrated schematically.
  • the handle 50 is preferably secured against rotation when it is in its locking position 52 in a recess 53 in the upper side 54 of the hold-down disk 12.
  • the outline contour of the recess 53 in the upper side 54 of the hold-down disc 12 at least partially corresponds to a contour of the handle 50 in its flat lying position, as shown in FIG Fig. 6 was exemplified.
  • the outline contours of the recess 53 and the handle 50 correspond to each other such that a positive embedding of the handle 50 can take place within the recess 53 when the rotational angle position and the alignment between the recess 53 and the handle 50 is substantially congruent, as shown in the Figures 2 and 6 is exemplified.
  • a locking position 52 or an actuating position By pivoting the handle 50 about the pivot axis 51 so either a locking position 52 or an actuating position is ingestible.
  • the strip or plate-like handle 50 When taking the operating position, the strip or plate-like handle 50 is aligned substantially vertically. A pivoting angle between the locking position 52 and the operating position of the handle 50 is approximately 90 °. In the folded-up operating position then a secure or ergonomic gripping the handle 50 and a smooth operation of the setting and fixing device 23 is possible.
  • the recess 53 and thus in approximately congruent coverage displaceable handle 50 are designed and positioned relative to each other, that the handle 50 exclusively in receipt of the first operating state A of the setting and fixing device 23, ie in a state in which the anti-rotation 41 and the lift-off 42 are activated, pivoted in the down , flat-lying locking position 52 can be transferred.
  • a recess 50 ', an opening or a side cut in the handle 50 serves as an aid for easier gripping of the handle 50 in the event of an operator provided for pivoting the handle 50, starting from the locking position 52 in the raised operating position.
  • a lateral indentation 50 'in the handle 50 which is formed on the pivot axis 51 opposite longitudinal side or side edge of the handle 50, a high pivoting of the handle 50, starting from the lying in the recess 53 locking position 52 in the raised operating position even when wearing gloves relatively easily be made.
  • the upper flat side of the handle 50 is flush or approximately flush with the upper surface 54 of the hold-down disc 12, so that with a corresponding sports shoe 3, which often has a paragraphless or a relatively planar sole, an unhindered entry into the binding device. 1 is possible.
  • an entry or suitable for use connection of a sports shoe 3, in particular a snowboard boot 5, with the binding device 1 is denied when the handle 50 is present in a position other than the locking position 52.
  • an entry into the binding device 1 is made more difficult or impeded if the strip-like or plate-like handle 50 is in its pivoted or approximately upright position and thus protrudes significantly in the vertical direction from the upper side 54 of the retaining plate 12.
  • the safety of use of the binding device 1 is increased.
  • Fig. 6 how best to look Fig. 6 can be seen, different types, in particular two types of slide elements 24, 25 are formed, which are provided to fulfill different tasks or task scopes.
  • fulfill or take over in the advantageous embodiment according to Fig. 6 all slide elements 24, 25, the function of a rotation 41, while individual slide elements, in particular the first type of slide elements 24, additionally fulfill the function of the lift-off 42 and can take over.
  • the two diametrically positioned to hold-down disc 12, the first slide elements 24 above the toothing 46 at least one holding extension 43, which extends in the radial direction of the hold-down disc 12 via the toothing 46 addition.
  • Fig. 1 - Can remain rigidly connected to the sports equipment 2 and the snowboard 4 via the fastening screws 22.
  • the base plate 11 is to be adjusted relative to the hold-down disc 12 according to the desired angle of rotation 20 and is subsequently only the anti-rotation 41 to be activated again by the slide elements 24, 25 in the extended position 26 -.
  • Fig. 3 - be made.
  • the hold-down disc 12 is a pre-assembled with the sports equipment 2 and the snowboard 4 factory or dealer side unit. Before the issue or before the sale or rental of sports equipment 2 is then only a corresponding base plate 11 with the respectively required or desired coupling parts 6, 7 - Fig. 1 - to put on and to lock.
  • Such a sports device 2 with the retaining plate 12 mounted thereon can be stored in a particularly space-saving manner on shelves or shelves.
  • this unit of snowboard 4 and hold-down disc 12 provided and in a simple manner with a corresponding in size and / or design and / or strength base plate 11 with the necessary additional elements arranged thereon like this one Fig. 1 be easily and quickly connected.
  • the base plate 11 already all, further required additional components - as at least in part Fig. 1 are visible - wear and already with the corresponding sports shoe 3, in particular with the respective snowboard boot 4, be coupled.
  • a so-called calf support can be counted, which is usually mounted on a headband or a so-called "heel-loop" of the binding device 1, as is apparent from Fig. 1 is apparent.
  • This calf support mainly serves to increase the pressure exerted by the user in the heel area on the sports equipment 2, or to be able to dose more sensitively. It is irrelevant whether the headband is designed as a separate element, as in Fig. 1 has been illustrated, or with the base plate 11 is an integral unit.
  • Fig. 7 is an advantageous embodiment of the first type or type of the slide elements, in particular of the slide element 24, shown in an oblique view from below.
  • the toothing 46 for the anti-rotation 41 is arcuate or designed as a circular segment and / or circular sector of a gear.
  • at least one retaining extension 43 protrudes, which fulfills the function of the anti-lifting device 42.
  • the toothing 46 and the holding extensions 43 are formed as an integral component, so that a relative adjustment between the toothing 46 and the holding extension 43 is not possible.
  • the toothed or rack-like section 38 is formed, which is designed to mesh with the pinion 35 in a meshing manner.
  • Fig. 6 - is provided.
  • At least one guide element 55 is preferably formed on the underside of the slide element 24, which supports an exact or planned guidance or displacement of the slide element 24.
  • These guide elements 55 act with corresponding guide elements 57 on a base plate 58.
  • Fig. 6 The hold-down disc 12 together.
  • strip-like elevations 59 are formed on the base plate 58, which can be displaced in sliding connection with the notches 56 on the underside of the slide elements 24 and / or 25 in order to form a linear guide 60.
  • This linear guide 60 is particularly advantageous because of the off-center or asymmetrically acting on the slider element 24, rack-like portion 38. Despite an off-center force acting on the slide element 24, therefore, a smooth as possible or clamp-free guidance for the slide element 24 and / or 25 is achieved.
  • the hold-down disc 12 comprises, in addition to the circular disk-shaped base plate 58, a circular disk-shaped cover plate 61 with preferably identical diameter. Between the base plate 58 and the cover plate 61, a receiving space for the slider elements 24, 25 and the pinion 35 is created, as best of Fig. 6 is apparent. In the interior of this receiving space, the slide elements 24, 25 and the pinion 35 are mounted such that the corresponding relative movements executed and the forces occurring in each case can be accommodated.
  • the pinion 35 is rotatable only within a limited rotation angle range 62.
  • the start and end values of this rotation angle range 62 in each case define the first operating state A and the third operating state C. Between these start and end values of the entire rotation angle range 62, the second operating state B is defined. It is favorable if the rotational angle range 62 of the pinion 35 is limited by a minimum stop 63 and a maximum stop 64 for at least one of the slide elements 24, 25 at the ends of the maximum displacement path of the slide elements 24, 25.
  • an inclined surface 65 may be formed which extends obliquely or inclined to the bottom 31 and the top 32 of the base plate 11.
  • the end portions 29 the slider elements 24 with the holding projections 43 in cross-section wedge-shaped. Characterized a wedge effect is achieved during the extension of the slide elements 24, through which a possible backlash-free mounting of the base plate 11 can be effected.
  • the outwardly tapering wedge shape of the outer end portions 29 of the slider elements 24 also offers the advantage that even if the base plate 11 is not aligned and positioned absolutely exactly against the hold-down disc 12, the slider elements 24 reliably transferred to the proper position can be.
  • Fig. 8 and 9 is another embodiment of a hold-down disc 12 for the base plate 11 of a binding device 1 - Fig. 1 - illustrated.
  • a hold-down disc 12 for the base plate 11 of a binding device 1 - Fig. 1 - illustrated.
  • the same reference numerals are used and the preceding descriptions are mutatis mutandis to the same parts with the same reference numerals transferable.
  • This hold-down disc 12 has a central actuator 44 for the slide elements 24, 25, said actuator 44 each couple a pair of slide elements 24 and a pair of slide elements 25 via technically different drive mechanisms.
  • This actuator 44 which is a part of the setting and fixing device 23, has a rotatably mounted coupling disk 66 which is rotatably mounted about an axis 37 extending through the center of the hold-down disk 12.
  • This coupling disc 66 is articulated on at least one of its peripheral portions with at least one coupling rod or connecting rod 67.
  • the corresponding joint axis runs parallel to the axis 37.
  • the end remote from the coupling rod 66 of the connecting rod 67 is coupled via a further articulated connection with the slider element 24.
  • a connecting rod coupling is performed, wherein the hinge axes extend in the end portions of the connecting rod 67 parallel to the axis 37. In this case, a rotational movement of the coupling disc 67 is converted to the axis 37 via these connecting rods 67 in a linear adjustment for the slide elements 24.
  • the two diametrically opposed first slide elements 24, which also function as lift-off protection 42, are connected in a connected manner via a respective connecting rod 67 with the centrally positioned, rotatably mounted coupling disk 66.
  • the coupling disk 66 is preferably only within a limited rotation angle range 62. Fig. 6 - Which is less than 360 °, bidirectionally rotatable. An endless rotation of the coupling disc 66 is thus not required to achieve the required for the slider elements 24 travel.
  • the further pair of slide elements 25 of a total of four slide elements 24, 25 on the hold-down disc 12 is connected in a motion-connected manner to the central coupling disc 66 via a slide guide 68 in each case.
  • the adjusting and fixing device 23 comprises a further, technically different coupling mechanism, according to which the rotatably mounted coupling disc 66 is connected via at least one slide guide 68 and guided there through a sliding block 69 with at least one further slide element 25.
  • each sliding element 25 is a respective sliding guide 68 and a respective sliding block 69 is formed in order to achieve a movement coupling between the coupling disc 66 and the slider element 25.
  • two diametrically opposed and radially to hold-down disc 12 adjustable slide elements 25 are coupled by means of link guides 68 and sliding blocks 69 with the central coupling disc 66.
  • the slotted guide 68 which is preferably formed on or in the slide elements 25, is preferably arcuately curved.
  • the slide guide 68 is preferably composed of a plurality of different radii or the slide guide 68 has a varying pitch relative to the desired direction of adjustment of the slide elements 25. It is thereby achieved that within the same or constant rotational angle steps or adjustment ranges of the setting and fixing device 23, in particular the coupling disc 66, varying or different travel paths or step sizes for the slide elements 25th to adjust. This means that within the entire rotational angle range of the coupling disk 66, varying travel ranges or actuating speeds for the slide elements 25 are set, although the coupling disk 66 covers the same or constant rotational angle steps. As a result, an optimum path / force ratio for the setting and fixing device 23 at the transition between the respective operating states A, B, C -. Fig. 6 - be achieved.
  • a total of four distributed over the peripheral region of the hold-down disc 12 arranged slide elements 24, 25 are formed, wherein a first pair of slide elements 24 respectively via connecting rods 67 to the central actuator 44 and the second pair of slide elements 25 via slide guides 68 with the common actuator 44th , in particular with the rotatably mounted coupling disc 66, is motion-connected.
  • This combination of two technically different drive mechanisms has the advantage that an ideal compromise between the limited space available for the slide elements 24, 25 within the hold-down disc 12 and between sufficient strength or stability of the respective guides or slide elements 24, 25 can be achieved.
  • the hold-down disc 12 a plurality of holes, in particular at least six openings may have, via which the hold-down disc 12 by means of fastening screws 22 fixed or rigid with the top 13 of a sliding board body - Fig. 1 - can be screwed.
  • the hold-down disc 12 can be prepared for mounting on snowboards with different mounting interfaces.
  • a total of six boreholes or apertures can be attached to the hold-down disk 12, and nevertheless a sufficiently high strength or robustness of the hold-down disk 12 or of the slide elements 24, 25 can be achieved by using the two different types of drive for the slide elements 24, 25.
  • a relatively space-saving or space-optimized drive kinematics is created by the slotted guides 68 in order to extend and retract the slide elements 25 as required.
  • the drive concept with the connecting rods 67 for the slide elements 24 requires comparatively more space or more freedom of movement.
  • this drive mechanism is a reliable and simple locking of the adjusting and fixing device 23 in the maximum extended position of the slide elements 24, 25, in particular when taking the operating state A, so the locking position - Fig. 3 -, achievable.
  • the top of the cover plate 61 is at least partially provided with a cover layer 70 of a soft elastic or elastomeric material.
  • This cover layer 70 increases the slip resistance of a supported on the hold-down disc 12 sports or snowboard shoe 5, as in Fig. 1 was exemplified.
  • an adjustment and fixing device 23 which has at least one adjustable on the hold-down disc 12 slide member 24, 25, which in its remote from the center of the hold-down disc 12 end portion 30 a toothing 46 as a component of the rotation 41 has.
  • This toothing 46 is a function of the operating state A, B or C of the adjusting and fixing device 23 with a locking toothing 40 around the opening 15 in the base plate 11 - FIG. 3 to FIG. 5 - Optional in and disengaged.
  • the corresponding toothing 46 at the front end 30 of the at least one slide element 24, 25 perpendicular to the contact plane 19 - Fig.
  • the adjusting and fixing device 23 is designed such that the tooth flanks 71 of the at least one slide element 24, 25 upon receipt of the second operating state B - Fig. 4 - At least flush with the lateral surface 48 of the hold-down disc 12 or against the lateral surface 48 of the hold-down disc 12 toward the center of Hold-down disc 12 are positioned back.
  • this operating state B is a rotation of the base plate 11 - Fig. 4 - allows relative to the continuously rigid or always immovably fixed to the top 13 of a sliding board body hold-down disc 12. It is essential that in this second operating state B, in which the rotation lock 41 is deactivated, the lift-off 42 remains active and a vertical relative displacement between the hold-down disc 12 and the base plate 11 is not required or not possible.
  • the base plate 11 and the hold-down disc 12 can always be as full as possible on the upper side 13 of a sliding board body, in particular a snowboard 4 -.
  • Fig. 1 - remain if a change in the angular position of the base plate 11 is desired or made by taking the second operating state B.
  • the setting and fixing device 23 is designed such that when assuming the second operating state B - Fig. 4 - The pivot bearing 16 between the hold-down disc 12 and the base plate 11 with respect to a rotatability of the base plate 11 relative to the hold-down disc 12 within the horizontally extending contact plane 19 -. Fig. 1 - is released. However, an adjustment of the base plate 11 in the vertical direction relative to the support plane 19 or in the vertical direction relative to the hold-down disc 12 is prevented at least approximately backlash by the still active lift-off 42 prevents lifting of the base plate 11 relative to the top 13 of a sliding board body.

Landscapes

  • Footwear And Its Accessory, Manufacturing Method And Apparatuses (AREA)
  • Sheet Holders (AREA)
  • Orthopedics, Nursing, And Contraception (AREA)
EP08006283A 2007-09-12 2008-03-31 Dispositif de reliure pour appareil de glisse de type planche Withdrawn EP2036597A1 (fr)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
AT0142707A AT505715B1 (de) 2007-09-12 2007-09-12 Bindungseinrichtung für brettartige gleitgeräte

Publications (1)

Publication Number Publication Date
EP2036597A1 true EP2036597A1 (fr) 2009-03-18

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Application Number Title Priority Date Filing Date
EP08006283A Withdrawn EP2036597A1 (fr) 2007-09-12 2008-03-31 Dispositif de reliure pour appareil de glisse de type planche

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US (1) US8052157B2 (fr)
EP (1) EP2036597A1 (fr)
AT (1) AT505715B1 (fr)

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FR3077990A1 (fr) * 2018-02-20 2019-08-23 Black Line Dispositif de reglage de l'orientation d'une fixation de chaussure sur une planche de surf des neiges

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KR100829144B1 (ko) * 2007-06-15 2008-05-13 황보석건 스노우보드 바인딩의 각도조절용 디스크
AT505715B1 (de) * 2007-09-12 2012-02-15 Atomic Austria Gmbh Bindungseinrichtung für brettartige gleitgeräte
ES1077542Y (es) * 2012-05-24 2012-11-08 Bascunana Juan Miguel Bernal Fijación para tabla de deslizamiento.
US8870212B2 (en) * 2012-08-10 2014-10-28 Noyes Britt Bouche, Inc. Electromagnetically lockable rotating binding for a sportboard or the like
US9149711B1 (en) 2014-11-14 2015-10-06 The Burton Corporation Snowboard binding and boot
US9220970B1 (en) 2014-11-14 2015-12-29 The Burton Corporation Snowboard binding and boot
US10179272B2 (en) 2014-11-14 2019-01-15 The Burton Corporation Snowboard binding and boot
JP6153685B1 (ja) * 2017-04-11 2017-06-28 株式会社 Jp Tight スノーボードビンディング用プレート
CN111249080B (zh) * 2020-02-25 2022-04-12 米伦医疗科技(苏州)有限公司 助行器手柄
AU2021221821B1 (en) * 2021-08-25 2022-10-20 DLT Group Pty Ltd Two Position Mount for a Snowboard Binding

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EP0432588A2 (fr) * 1989-12-13 1991-06-19 Alfons Burtscher Fixation de surf de neige
FR2743306A1 (fr) 1996-01-04 1997-07-11 Duret M & Fils Perfectionnement pour dispositif de fixation d'une chaussure sur une planche a neige
WO1997033664A1 (fr) 1996-03-13 1997-09-18 Fardie Kenneth W Mecanisme de fixation pour planche a neige
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WO2019162617A1 (fr) * 2018-02-20 2019-08-29 Black Line Dispositif de reglage de l'orientation d'une fixation de chaussure sur une planche de surf des neiges
US11376486B2 (en) 2018-02-20 2022-07-05 Black Line Mechanism for adjusting the orientation of bindings on a snowboard

Also Published As

Publication number Publication date
US20090194956A1 (en) 2009-08-06
AT505715A1 (de) 2009-03-15
US8052157B2 (en) 2011-11-08
AT505715B1 (de) 2012-02-15

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