EP3195906A1 - Talonniere ayant une configuration de marche - Google Patents

Talonniere ayant une configuration de marche Download PDF

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Publication number
EP3195906A1
EP3195906A1 EP16152428.5A EP16152428A EP3195906A1 EP 3195906 A1 EP3195906 A1 EP 3195906A1 EP 16152428 A EP16152428 A EP 16152428A EP 3195906 A1 EP3195906 A1 EP 3195906A1
Authority
EP
European Patent Office
Prior art keywords
heel
holder
ski
heel holder
region
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.)
Granted
Application number
EP16152428.5A
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German (de)
English (en)
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EP3195906B1 (fr
Inventor
Andreas Fritschi
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.)
Fritschi AG Swiss Bindings
Original Assignee
Fritschi AG Swiss Bindings
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 Fritschi AG Swiss Bindings filed Critical Fritschi AG Swiss Bindings
Priority to EP16152428.5A priority Critical patent/EP3195906B1/fr
Priority to US15/411,578 priority patent/US9901806B2/en
Publication of EP3195906A1 publication Critical patent/EP3195906A1/fr
Application granted granted Critical
Publication of EP3195906B1 publication Critical patent/EP3195906B1/fr
Active legal-status Critical Current
Anticipated expiration legal-status Critical

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Classifications

    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C9/00Ski bindings
    • A63C9/08Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings
    • A63C9/0807Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings for both towing and downhill skiing
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C7/00Devices preventing skis from slipping back; Ski-stoppers or ski-brakes
    • A63C7/10Hinged stoppage blades attachable to the skis in such manner that these blades can be moved out of the operative position
    • A63C7/1006Ski-stoppers
    • A63C7/1013Ski-stoppers actuated by the boot
    • A63C7/102Ski-stoppers actuated by the boot articulated about one transverse axis
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C7/00Devices preventing skis from slipping back; Ski-stoppers or ski-brakes
    • A63C7/10Hinged stoppage blades attachable to the skis in such manner that these blades can be moved out of the operative position
    • A63C7/1073Ski-brakes
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C9/00Ski bindings
    • A63C9/001Anti-friction devices
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C9/00Ski bindings
    • A63C9/006Ski bindings with a climbing wedge
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C9/00Ski bindings
    • A63C9/007Systems preventing accumulation of forces on the binding when the ski is bending
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C9/00Ski bindings
    • A63C9/08Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings
    • A63C9/084Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings with heel hold-downs, e.g. swingable
    • A63C9/0841Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings with heel hold-downs, e.g. swingable with a single jaw
    • A63C9/0842Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings with heel hold-downs, e.g. swingable with a single jaw the jaw pivoting on the body or base about a transverse axis
    • AHUMAN NECESSITIES
    • A63SPORTS; GAMES; AMUSEMENTS
    • A63CSKATES; SKIS; ROLLER SKATES; DESIGN OR LAYOUT OF COURTS, RINKS OR THE LIKE
    • A63C9/00Ski bindings
    • A63C9/08Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings
    • A63C9/084Ski bindings yieldable or self-releasing in the event of an accident, i.e. safety bindings with heel hold-downs, e.g. swingable
    • A63C9/0846Details of the release or step-in mechanism

Definitions

  • the invention relates to an automatic heel unit for a ski binding, in particular a touring ski binding, comprising a heel holder for holding a ski boot in a heel region of the ski boot and a heel holder carrier.
  • the heel holder is movably mounted on the heel holder carrier along an adjustment path relative to the heel holder carrier.
  • the heel unit has a holding configuration in which the heel holder is in a holding position and the heel holder can cooperate with the heel region of the ski boot held in the ski binding such that the heel region of the ski boot is held in a lowered position.
  • the heel box further has a walking configuration in which the heel holder is in a walking position and the heel portion of the ski boot held in the ski binding is released from the heel holder and can be lowered toward the ski without being locked in the lowered position by the heel holder.
  • Heel machines of the technical field mentioned above are known. Their task is to ensure a reliable fixation of the heel area of the ski boot on the ski in a holding configuration.
  • Some such heel machines in order to increase the safety of the skier, also allow, starting from the holding configuration, a safety release in which the heel area of the ski boot is released. This may be, for example, a safety release in the forward direction or a lateral safety release.
  • the term "safety release" means that the automatic heel releases the heel area of the ski boot if the energy of a shock on the ski boot, the ski binding or the ski exceeds a predetermined value. It is irrelevant whether the heel unit is in the holding configuration or in another configuration after the ski boot is released. In the case of impacts whose energy does not exceed this value, the automatic heel keeps the heel area of the ski boot locked.
  • ski binding to which the heel machine belongs should fulfill.
  • downhill ski bindings are only used for downhill skiing and downhill skiing at ski lifts.
  • touring ski bindings are also used for walking on skis, in particular for ascending with the help of climbing skins attached to the skis.
  • Cross-country skiing is used for cross-country skiing and telemark bindings for skiing with telemark technique.
  • downhill ski bindings have only to ensure a reliable fixation of the ski boot on the ski in a so-called holding position and to allow entry into the ski binding in a so-called entry position or release position.
  • cross-country and Telemarkitatien usually have to hold the ski only pivotable about an axis aligned in the ski direction axis and to allow entry into the ski binding.
  • touring ski bindings such as downhill ski bindings must ensure a reliable fixation of the ski boot on the ski in the holding position and allow entry into the ski binding.
  • they have to go on skis or for the Rise the ski boot can pivot around a aligned in the direction of the ski axis.
  • touring ski bindings have a walking position in which the ski boot is pivotable about an axis oriented in the direction of the ski and pivotable in the heel area of the ski, as in cross-country skiing and telemark binding, whereby a joint movement between the ski boot and the ski is made possible for walking.
  • the heel counter may be in different configurations in the walking position of a touring ski binding, depending on the construction and type of touring ski binding. For example, it may be in its holding configuration, in its starter configuration, in a trip configuration, or in a go configuration.
  • an heel automat is additionally required with such a cross-country or telemark binding, by means of which the ski boot can be lowered in its heel area towards the ski, and which the heel area of the ski boot can walk can release in the walking position of cross-country or telemark binding.
  • Touring ski bindings in turn are subdivided into three types.
  • the first type of touring ski bindings comprises a ski boot carrier to which the ski boot is held by a toe and an automatic heel.
  • the ski boot carrier in the walking position of the touring ski binding with the ski boot held therein is pivotable relative to the ski, while the heel machine is in its holding configuration and locks the heel area of the ski boot lowered to the ski boot carrier.
  • the ski boot carrier in the holding position of the touring ski binding the ski boot carrier is locked in a substantially ski-parallel alignment, whereby the ski boot held on the ski boot carrier is also correspondingly fixed on the ski.
  • the heel box is again in its holding configuration and locks the heel area of the ski boot lowered to the ski boot carrier.
  • a representative member of this first type of touring ski bindings is, for example, in WO 96/23559 A1 (Fritschi AG Apparatebau).
  • the second type of touring ski bindings relies on ski boots with stiff soles.
  • the ski boot is pivotally mounted in his toe area in a skim-mounted front automat.
  • the heel counter is in In this case, in a distance adapted to a ski boot sole length distance from the front vending machine firmly attached to the ski.
  • the heel box In the holding position of the touring ski binding, he is in his holding configuration and locks the ski boot in the heel area.
  • the heel box In the walking position of the touring ski binding, however, the heel box is in its walking configuration.
  • the heel of the ski boot is released from the heel counter, so that the ski boot can be lifted off the ski and swiveled around the storage on the front automat. It is irrelevant whether this Chakonfiguration at the same time corresponds to a possibly provided entry or release configuration of the heel unit or not.
  • a representative member of this type of touring ski bindings is, for example, in EP 2 762 209 A2 (Marker Germany GmbH).
  • the third type of touring ski bindings like the first type, comprises a ski boot carrier on which the ski boot is kept in the walking position. For this purpose, a binding jaws is provided on the front of the ski boot carrier, while only one retaining element is provided on the rear of the ski boot carrier.
  • An heel machine which can fix the heel of the ski boot in the holding position of the touring ski binding on the ski, is not arranged on the ski boot carrier, but directly on the ski. Therefore, in this third type of toe binding in the walking position, the ski boot is fixed to the ski boot carrier by the front binding jaw and the holding member while the heel box is in its walking configuration. In contrast, in the holding position of the touring ski binding, the ski boot is held with its sole aligned essentially in parallel with the ski by the front binding jaw and the heel automats located in the holding configuration.
  • a representative member of this type of touring ski bindings is, for example, in CH 706 664 A1 (Fritschi AG - Swiss Bindings).
  • heel machines that have a holding configuration and a Gehkonfiguration and possibly a trip configuration or entry-level configuration, in touring ski bindings of the second and third type and possibly also in cross-country or Telemarkitatien needed.
  • FIG DE 10 2014 004 874 A1 An example of an automatic heel having a holding configuration and a walking configuration is shown in FIG DE 10 2014 004 874 A1 (Zoor) described.
  • This Heel breaker comprises a heel holder which is rotatably mounted about an axis oriented horizontally in the cross-machine direction. In the holding configuration of the heel unit, the heel holder is in a holding position. To adjust the automatic heel unit in a walking configuration, the heel holder is pivoted about the axis back to the top in his walking position. In this position, the heel holder is pivoted out of the path of movement of the heel area of the ski boot, so that the ski boot can be lowered down to the ski when walking.
  • Such heel machines have the disadvantage that their heel holder is located in the positions behind the top. As a result, such heel machines in the housing configuration occupy a large volume and are therefore not compactly constructed.
  • some heel machines also include a ski brake to prevent inadvertent skid sliding when the ski boot is not held in the heel counter.
  • a ski brake is for example in the WO 2009/105866 A1 (G3 Genuine Guide Gear Inc).
  • the disclosed ski brake comprises a tread as an actuator and two free arms.
  • the two free arms are each arranged laterally of the ski in a vertical longitudinal plane aligned in the longitudinal direction of the ski and may be aligned substantially parallel or at an angle to the ski longitudinal axis.
  • the arms are mounted about a horizontal axis oriented in the direction of the ski axis pivotally mounted on the heel unit.
  • the ski brake is in a braking position.
  • the two free arms are pivoted upwards so that they no longer extend beyond the sliding surface of the ski.
  • the ski brake is in a driving position.
  • the ski brake is moved to the braking position, when a space above the tread is free and the tread surface can be moved away from the ski up, the ski brake is biased by a spring from the driving position to the braking position.
  • the ski brake is moved in the holding configuration of the heel unit in the braking position when no ski boot is held in the heel unit and the Tread prevents movement upwards.
  • a hook which is hooked on the tread surface can hold the ski brake in the driving position despite the bias to the braking position. This prevents the ski brake from being moved to the braking position as soon as the heel of the ski boot is lifted off the heel counter when walking.
  • the hook is moved from the heel configuration to the hold configuration to a deactivated position by the adjustment of the heel counter.
  • ski brakes have the disadvantage that the ski brake occupies a large volume and thus can not be constructed compact.
  • ski binding systems For the description of ski binding systems, a (fictitious) ski is often used as the reference system, assuming that the binding is mounted on this ski. This habit is taken over in the present text.
  • ski longitudinal direction means along the orientation of the longitudinal axis of the ski.
  • skiparallel means aligned for an elongate object along the longitudinal axis of the ski.
  • ski-parallel means aligned parallel to the sliding surface of the ski.
  • ski direction means a direction transverse to the ski longitudinal direction, which, however, need not be oriented exactly at right angles to the longitudinal axis of the ski. Their orientation may also be slightly different from a right angle.
  • ski center means a center of the ski in the ski direction
  • ski manifest does not mean that it can move in relation to the ski.
  • some terms that do not contain the word “ski” refer to the reference system of the (fictional) ski.
  • front, “rear”, “top”, “bottom” and “side” refer to “front”, “rear”, “top”, “bottom” and “side” of the ski.
  • terms such as “horizontal” and “vertical” refer to the ski, with “horizontal” lying in a ski-parallel plane and “vertical” oriented perpendicular to this plane.
  • the term “height” refers to the distance measured in the vertical direction from an upper edge of the ski.
  • comparisons of the position of the heel holder in different positions of the heel holder refer to the center of gravity of the heel-holder.
  • the center of gravity is the mass-weighted mean of the positions of the mass points of the heel holder.
  • the statement that the heel holder is in a position further back or lower than in another position means that the center of gravity of the heel holder is in this position further back or lower than in the other position.
  • the object of the invention is to provide a the aforementioned technical field associated heel machines, which has a compact design.
  • the heel holder of the heel unit is in its position further back than in its holding position.
  • the heel holder is movable from its walking position to its holding position and back along a first portion of the displacement path, the heel holder extending from its position along the first range of Verstellwegs beyond its holding position from the first range of Verstellwegs up in one of the first area the adjustment is separate, adjoining the first region of the adjustment second range of the adjustment and back is movable.
  • the adjustment path corresponds to the traversable by the heel holder relative to the heel holder carrier way.
  • the indication of a position of the heel holder on the adjustment refers to the position of the center of mass of the heel holder on the adjustment.
  • the indication of a position of the heel holder on the adjustment also refers to the position of the center of mass of the heel holder on the adjustment, but in addition, the orientation of the heel holder relative to the heel holder carrier may also be included.
  • a movement of the heel holder on the adjustment path which includes a change in position of the heel holder within the adjustment, means that the heel holder is moved with its center of gravity according to the specified position change relative to the heel holder support.
  • the Specifying a movement of the heel holder thus means a movement of the heel holder, in which the center of mass of the heel holder is moved upward.
  • the adjustment of the heel holder may be linear or non-linear or have both linear parts and non-linear parts.
  • the first region of the adjustment path and the second region of the adjustment can be independent of each other linear or non-linear or have linear and non-linear parts.
  • linear it is meant that the center of gravity of the heel cup is moved along a line relative to the heel cup carrier when the heel cup is moved relative to the heel cup carrier. It is irrelevant whether the heel holder is additionally pivoted relative to the heel holder carrier or not and thus changes its orientation relative to the heel holder carrier or not.
  • non-linear means that the center of gravity of the heel cup does not move relative to the heel cup carrier when the heel cup is moved relative to the heel cup carrier. This is the case, for example, when the heel holder is rotated about its center of gravity relative to the heel holder carrier.
  • the linear parts of the first range of the displacement path and the second range of the displacement path may also be rectilinear or curved independently of one another or each have both rectilinear and curved sections. In the walking configuration, the heel portion of the ski boot held in the ski binding is released from the heel cup and can be lowered toward the ski without being locked in the lowered position by the heel cup.
  • the heel region of the ski boot held in the ski binding can be lowered towards the ski until it is supported in a lowered position either by an element of the heel piece or by the ski and prevented from further lowering.
  • the ski boot is not locked in the lowered position by the heel holder, but can be lifted off the heel counter or ski upwards again.
  • the heel holder is starting from the walking position along the first range of Verstellwegs beyond its holding position from the first range of Verstellwegs upwards in a separate from the first region of the adjustment, adjoining the first region of the adjustment second range of Verstellwegs and back.
  • "up" means that the heel holder immediately after the Transition from the first to the second region of the adjustment upwards away from the ski is movable. It is irrelevant whether the movement of the heel holder immediately after the transition from the first to the second region of the adjustment additionally has a lying in a plane in-plane component or not. In addition, it is irrelevant whether the heel holder is already in the first region of the adjustment is movable upwards or only in the second region of the adjustment is movable upwards.
  • the heel holder is starting from the walking position along the first region of the adjustment over its holding position from the first region of Verstellwegs essentially straight up in a separate from the first region of the adjustment, adjoining the first region of the adjustment, the second region the adjustment and back.
  • the heel holder is starting from the walking position along the first region of the adjustment over its holding position out of the first region of Verstellwegs up in a separate from the first region of the adjustment, adjoining the first region of the adjustment second range of Verstellwegs and movable back.
  • "separately" means that the second region of the adjustment path is formed without overlap with the first region of the adjustment path.
  • the heel retainer is moved along the second portion of the recline, this movement is not at the same time identical to movement of the heel retainer along a portion of the first portion of the recline.
  • the second region of the adjustment is subsequent to the first range of Verstellwegs.
  • the second area of the adjustment path is continuously connected to the first area of the adjustment path.
  • the heel holder is movable in a continuous movement from the first region of the adjustment path into the second region of the adjustment path and back.
  • the advantage of the solution according to the invention is that the heel holder is located in its position further back than in its holding position. This makes it possible to design the heel unit so that it occupies little space in the housing configuration. On the one hand, this increases the comfort of the skier when walking with the skis when the heel box is in the walking configuration. On the other hand, it will but also allows the heel machine to be designed more easily so that less snow can enter the heel cup when walking and block the heel mechanism mechanics due to icing.
  • the solution according to the invention has the advantage that the heel holder in its position can best be removed from the range of movement of the heel area of the ski boot while walking. This can reduce the risk that the heel holder in walking position hinders the heel area of the ski boot when walking, especially when snow or ice adheres to the heel area.
  • a further advantage of the solution according to the invention is that the heel holder can be moved in a simple manner from the first to the second region of the adjustment path, since it starts from the walking position along the first region of the adjustment path beyond its holding position out of the first region of the adjustment path at the top in a separate from the first region of the adjustment, adjoining the first region of the adjustment second range of the adjustment and back is movable. This facilitates the operation of the heel counter.
  • the automatic heel unit also enables a safety release to the front, a simple and reliably functioning safety release can be made possible by the heel holder, which can be moved beyond the first position of the adjustment path upwards into the second region of the adjustment path beyond its holding position. This can increase safety for the skier.
  • the heel holder is in its holding position in a transition region, particularly preferably in a transition from the first region of the adjustment to the second region of the adjustment.
  • This has the advantage that the first region of the adjustment path is separated from the second region of the adjustment path by the retaining position.
  • the heel holder in its holding position is not in the transition or transition region from the first region to the second region of the adjustment path.
  • the heel holder can then be in its holding position For example, be within the first range, the second range or within any existing wider range of the adjustment.
  • the heel holder is in its walking position at one end of the first portion of the adjustment.
  • the heel holder is in its walking position at the same time at one end of the adjustment. This has the advantage that the heel holder is easily movable from its holding position in its walking position, since the walking position is clearly separated from the holding position of the heel holder. Alternatively, there is also the possibility that the heel holder is in its position within the first range of the adjustment.
  • the first region of the adjustment path comprises a vertical component. It is irrelevant whether the course of the first range of the adjustment when adjusting the heel holder from the walking position leads to the holding position up or down or both upwards as well as down. Regardless of the course of the first portion of the adjustment, the heel holder is in its position further back than in its holding position. In addition, the heel holder can be located in its position, regardless of the course of the first portion of the adjustment also higher or lower than in its holding position. Regardless of the course of the first portion of the adjustment, the heel holder in its position but can also be at the same height as in its holding position.
  • the advantage can be achieved that a particularly compact design of the heel piece is made possible.
  • the heel holder can be performed in the first region of the adjustment, for example, around an existing element of the heel counter and thereby be positioned to save space.
  • this can be made possible that the heel holder is positioned in the walking position higher or lower than in the holding position.
  • the first region of the adjustment path does not include a vertical component.
  • the first range of the adjustment is aligned horizontally.
  • the heel holder is in its position further down than in its holding position.
  • the position of the heel holder in its position is independent of the course of the first range of the adjustment. So it is irrelevant whether the course of the first range of the adjustment leads when adjusting the heel holder from the holding position to walking position down or both upwards as well as down. If the heel holder is lower in its position than in its holding position, this has the advantage that the heel holder can be arranged in a particularly space-saving manner on the heel counter in its walking position. This allows a particularly compact design of the heel unit.
  • the heel holder is in its walking position at the same height as in its holding position or higher than in its holding position.
  • the heel holder is movable from the second region of the adjustment path beyond its holding position out of the second region of the adjustment path downwards into the first region of the adjustment path.
  • the heel holder is thus moved immediately after the transition from the second to the first region of the adjustment in the first region of the adjustment down. It is irrelevant whether the movement of the heel holder immediately after the transition from the second to the first region of the adjustment additionally has a lying in a plane in-plane component or not. In addition, it is irrelevant whether the heel holder is already in the second region of the adjustment downwardly movable or only in the first region of the adjustment is movable downwards.
  • the heel holder is, starting from the second region of the adjustment path along the second region of the adjustment over its holding position out of the second region of the adjustment substantially straight down in the first region of the adjustment movable.
  • This offers the advantage that the heel holder of the skier is very easy to move from the second region of the adjustment in the first region of the adjustment.
  • the skier can do the Simply move the heel holder from the top to the bottom of the adjustment path from the top to the bottom using a hand or with a ski pole from the second area of the adjustment path.
  • the heel holder from the second region of the adjustment is not down, but in the horizontal direction or upwards from the second region of the adjustment in the first region of the adjustment is movable.
  • the first range of the adjustment is substantially linear. Accordingly, the center of mass of the heel holder is usually moved relative to the heel holder carrier when the heel holder is moved within the first range of the displacement relative to the heel holder carrier. Whether in this case the first region of the adjustment path has one or more restricted partial regions which are not linear, is irrelevant.
  • the heel holder with its center of gravity can be moved to a position in the first region of the adjustment path at which the heel holder is rotatable about its center of gravity before it is movable with its center of mass of this position along the first range of the adjustment. It is also irrelevant whether the linear parts of the first range of the adjustment path are straight or curved or have both rectilinear and curved sections.
  • a substantially linear first region of the adjustment path has the advantage that the heel holder can be moved easily and quickly along the first region of the adjustment path.
  • the first region of the adjustment path is linear. This has the advantage that the heel holder can be moved particularly easily and quickly along the first range of the adjustment, whereby the operation of the heel counter can be further simplified.
  • the second region of the adjustment is substantially linear. This has the advantage that the heel holder can be moved easily and quickly along the second area. It is irrelevant whether the second region of the adjustment path has one or more subregions which are not linear. It is also irrelevant whether the linear parts of the second region of the adjustment are straight or curved or have both rectilinear and curved sections. In a preferred variant, the second region of the adjustment path is linear. This has the advantage that the heel holder can be moved particularly easily and quickly along the second region of the adjustment path.
  • the automatic heel unit also allows a safety release and if in a safety release the heel holder is movable from its holding position along a linear portion of the second portion of the adjustment until the heel portion of the heel held in the heel unit is detached from the heel unit, is replaced by the linear portion of the second Range of the adjustment allows a fast and thus efficiently functioning safety release. This increases the safety for the skier.
  • the adjustment path is preferably continuously differentiable in a transition region from the first region to the second region.
  • the adjustment path in this transition region is also linear.
  • the adjustment path in the transition region from the first region to the second region can be rectilinear or curved.
  • the transition region can have no kink. This has the advantage that the heel holder is liquid and quickly movable from the first region of the adjustment in the second region of the adjustment and back. This makes the operation of the heel unit more comfortable for the skier.
  • the displacement in the transition region from the first region to the second region is not continuously differentiable, but has a kink. This is the case, for example, when the first region of the adjustment path adjoins the second region of the adjustment path horizontally or almost horizontally, while the second region of the adjustment path adjoins the first region of the adjustment path substantially vertically aligned.
  • the first region of the adjustment path preferably extends in a plane oriented vertically in the longitudinal direction of the ski. This means that if the heel holder moves around it along the first range of travel Center of gravity is pivoted, this pivoting movement takes place in this vertically oriented in the ski longitudinal direction plane. This has the advantage that the automatic heel unit can be constructed compact.
  • the second region of the adjustment path preferably extends in a plane oriented vertically in the longitudinal direction of the ski. This means that, if the heel holder is pivoted about its center of gravity during a movement along the second region of the adjustment path, this pivotal movement also takes place in this plane oriented vertically in the longitudinal direction of the ski. This also has the advantage that the automatic heel unit can be constructed compact.
  • both the first region of the adjustment path and the second region of the adjustment path extend in a plane oriented vertically in the longitudinal direction of the ski. This means that if the heel holder is pivoted about its center of gravity during a movement along the first or second region of the displacement, this pivotal movement takes place in this vertically oriented in the longitudinal direction of the plane. This has the advantage that the heel automat can be constructed very compact.
  • the entire or an area of the adjustment path extends in a plane which is at an angle to the vertically aligned in the ski longitudinal direction plane.
  • the automatic heel unit comprises an elastic element, by which the heel holder is biased toward its holding position at least in a partial region of the second region of the adjustment path adjoining the first region of the adjustment path.
  • This has the advantage that the heel area of the ski boot held by the heel holder can be pretensioned towards the holding position of the heel holder.
  • a safety release can thereby be provided by releasing the heel area of the ski boot from the heel unit in a safety release of the heel holder along the adjoining the first region of the adjustment portion of the second region of the adjustment of the holding position away from the elastic element generated bias is made movable. Accordingly, this can increase safety for the skier.
  • the elastic element comprises a spring for generating the bias voltage.
  • the elastic element can also be designed differently. It is irrelevant where the heel holder is in its holding position on the adjustment. It is also irrelevant whether the heel holder is also biased towards its holding position or not at least in a partial region of the first region of the adjustment path. Further, it is irrelevant whether the heel holder is biased in addition to its bias to its holding position in a further portion of the second region of the adjustment by the elastic member or by a separate, second elastic member in a different direction. If the heel holder, for example, has a release position, the heel holder may be biased in a further portion of the second portion of the adjustment to this release position. In this case, the bias voltage can be generated by the elastic element or by a separate second elastic element. This has the advantage that the heel holder remains in the release position and does not move unintentionally from its release position to its holding position.
  • the heel holder is not biased towards its holding position, but rather in another direction, at least in the partial region of the second region of the adjustment path adjoining the first region of the adjustment path.
  • the heel holder does not comprise an elastic element, by which the heel holder is biased at least in the adjoining the first region of the adjustment path portion of the second region of the adjustment.
  • the heel holder can be manually adjustable in this case, for example, in a desired position in this case.
  • the heel holder is biased towards its holding position by an elastic element in the partial region of the second region of the adjustment path adjoining the first region of the adjustment path, it is preferably in each position of the heel holder in FIG this partial region of the second region of the adjustment, the force generated by the elastic element aligned at an acute angle to an orientation of the second portion of the adjustment at the respective position of the heel holder.
  • the adjustment path in the subregion of the second region of the adjustment path adjoining the first region of the adjustment path is preferably linear.
  • the alignment of the adjustment path at the respective position of the heel holder in the subsequent to the first region of the adjustment second region of the displacement corresponds to a tangent, which is applied to the adjustment path at the respective position of the heel holder.
  • the elastic force generated by the elastic member for tensioning the heel holder to its holding position is not aligned parallel to the orientation of the adjustment at this position of the heel holder, but always at an acute angle, ie in one Angle greater than 0 ° and less than 90 ° to align the travel at this position.
  • the angle between the force and the orientation of the adjustment is the smallest angle between the direction in which the force acts and the given by the tangent and thus by a straight line alignment of the adjustment. Independently of this angle, the force generated by the elastic element can be transmitted directly or indirectly to the heel holder for tensioning the heel holder towards its holding position.
  • the force generated by the elastic element to tension the heel holder to its holding position at an angle in a range of 20 ° to 70 °, preferably in a range of 40 ° to 70 °, particularly preferably in a range of 50 ° to 70 ° to align the adjustment at the respective position of the heel holder aligned.
  • the force generated by the elastic element may be at an obtuse angle, i. is aligned at an angle of 90 ° or more, to an alignment of the portion of the second portion of the displacement at the respective position of the heel holder.
  • the power transmission from the elastic element to the heel holder preferably takes place indirectly via at least one intermediate element.
  • the intermediate element is a pawl.
  • a pawl may for example be mounted pivotably about an axis on the heel holder carrier and arranged between the elastic element and the heel holder.
  • the force generated by the elastic element for tensioning the heel holder to its holding position is preferably transmitted from the elastic element via the pawl on the heel holder.
  • one or more further intermediate elements are arranged between the elastic element and the pawl and between the pawl and the heel holder.
  • none of the at least one intermediate element is a pawl.
  • the heel holder is freely movable along the first region of the adjustment path. That is, the heel holder is along the first portion of the adjustment path without bias, d. H. without a force generated by an elastic element and acting on the heel holder force movable.
  • the heel holder is thereby movable only against a possibly existing frictional force along the first region of the adjustment.
  • This has the advantage that the heel automat can be easily constructed and manufactured inexpensively. It is irrelevant whether the adjustment is linear or non-linear in its first region, because the heel holder can be freely moved both in a translational movement as well as a rotational movement. It is also irrelevant whether the heel holder in the second region is fully or partially biased by an elastic element or whether the heel holder in the second region of the adjustment also free, d. H. without preload, is movable.
  • the heel holder is in its holding position on a transition from the first region of the adjustment to the second region of Verstellwegs and the heel unit comprises an elastic element through which the heel holder at least in a subsequent to the first region of the adjustment portion of the second region of the adjustment is biased towards its holding position
  • the heel holder is preferably from its position to its holding position and back along the first range of the adjustment without bias, d. H. without a force generated by an elastic element and acting on the heel holder force movable. This has the advantage that the heel piece is particularly easy to use.
  • the heel holder along the first region of the adjustment is not freely movable, but is biased, for example, to its holding position or to its walking position.
  • the automatic heel unit comprises a base element for mounting the heel unit on an upper side of a ski, wherein the heel holder support is arranged on the base element. It is irrelevant whether the heel holder carrier directly or indirectly, ie via at least one intermediate element, is connected to the base element. In addition, it is irrelevant whether the heel holder carrier is movably mounted on the base member or firmly connected to the base member or made in one piece with the base member. Regardless of the base element has the advantage that the heel holder carrier can be easily mounted on the ski.
  • the heel holder carrier is movable relative to the base member. This has the advantage that the position of the Heereshalteranis is adaptable to different sized ski boots.
  • the automatic heel unit has no such base element.
  • the heel holder has a hold-down structure for holding the heel portion of the ski boot held in the ski binding in the lowered position in the heel cup holding configuration. This has the advantage that the heel holder can optimally hold the heel area in the lowered position.
  • the hold-down structure is fixed, i. immovable, arranged on the heel holder. This has the advantage that a particularly stable hold of the ski boot held in the holding configuration in the automatic heel unit can be achieved. Alternatively, there is also the possibility that the hold-down structure is movably mounted on the heel holder.
  • the hold-down structure is formed in order to embrace the sole of the ski boot in the heel area at the top in the holding configuration of the heel piece, in order to cover the heel area of the ski boot held in the ski binding keep lowered position.
  • the hold-down structure is designed to engage in the holding configuration of the heel counter in a recess in the heel area of the sole of the ski boot to hold the heel portion of the ski boot held in the ski binding in the lowered position.
  • the heel holder advantageously has a heel support structure for supporting the heel region in a direction horizontal across the ski.
  • This has the advantage that the heel holder can securely hold the heel area of the ski boot.
  • the heel area of the ski boot is held securely even with large forces and vibrations. This increases the safety for the skier. It is irrelevant whether the hold-down structure and the heel support structure are separate structures or are formed by one and the same structure.
  • the heel support structure is fixed, i. immovable, arranged on the heel holder. This has the advantage that a particularly stable hold of the ski boot held in the holding configuration in the automatic heel unit can be achieved. Alternatively, there is also the possibility that the heel support structure is movably mounted on the heel holder.
  • the heel support structure is preferably designed to laterally reach somewhat forwardly in the heel area of the heel unit to secure the heel area of the ski boot held in the ski binding to support a direction horizontally across the ski.
  • the heel support structure is designed to engage in the holding configuration of the heel piece in a recess in the heel area of the sole of the ski boot, around the heel area of the ski boot held in the ski binding in a direction horizontal transverse to the ski support.
  • the heel holder is a jaw. That is, the hold-down structure is configured to engage around the sole of the ski boot in the heel region at the top to hold the heel portion of the ski boot held in the ski binding in the lowered position, and that the heel support structure is configured to engage in the heel cup the heel configuration of the ski boot in the heel area to laterally reach around the heel area of the ski boot held in the ski binding to support horizontally across the ski in one direction.
  • This has the advantage that in the holding configuration of the heel unit a very stable hold of the heel area of the ski boot can be achieved.
  • the hold-down structure and the heel support structure are formed by the same structure.
  • these are two juxtaposed pins, which point in the holding position of the heel holder with their free ends substantially horizontally forward. This has the advantage that the heel holder can be constructed easily and compact. In these previously mentioned embodiments of the heel holder is irrelevant whether the heel holder is made in one piece or several pieces.
  • the automatic heel unit has a triggering configuration in which the heel holder is in a release position and the heel region of the ski boot is released by the heel holder.
  • the triggering configuration is also preferably used to position the heel area of the ski boot in the heel unit in order to be able to enter the heel counter.
  • the trigger configuration in which the heel holder is in its release position and the heel area of the ski boot is released from the heel holder, has the advantage of facilitating entry into the heel unit and removal from the heel unit with the heel portion of the ski boot. This increases the comfort for the skier.
  • the heel machine may continue to have an entry-level configuration.
  • the entry-level configuration can correspond to the triggering configuration or represent a separate configuration. It is irrelevant whether the entry-level configuration only serves to enter the heel area of the ski boot in the heel counter or whether it is possible to exit the heel counter with the entry-level configuration. Similarly, it is irrelevant whether the trigger configuration only the exit or both the exit from the Heel machines as well as the entry into the heel machines allows. In addition, it is irrelevant in which range of the adjustment path the heel holder is in the entry-level configuration. If the heel piece has an entry-level configuration that is different from the release configuration, the heel-hold in the heel-to-toe configuration of the heel piece is preferably in an entry position.
  • the entry position of the heel holder is used for getting in and the release position of the heel holder for getting off.
  • This has the advantage that the entry position of the heel holder can be optimized for the entry process and the release position of the heel holder on the exit process. This allows easy entry and exit and increases the comfort for the skier.
  • the automatic heel unit has no release configuration and no entry-level configuration.
  • the entry can be made with the heel area of the ski boot in the heel and the exit in any position of the heel holder.
  • the heel unit has a release configuration in which the heel holder is in its release position
  • the heel holder is preferably movable from its holding position to its release position and back along the second portion of the adjustment.
  • the second region of the adjustment can be linear or have both linear parts as well as non-linear parts. Regardless, the one or more linear portions of the second range of travel may be straight or curved. In addition, the linear portion (s) of the second region may include both rectilinear and curved portions.
  • the second region of the adjustment path can also have one or more further partial regions in which the heel holder is not biased or in another position such as in its release position. Regardless of this, the advantage achieved by the bias of the heel holder in the subsequent to the first region of the adjustment path portion of the second region of the adjustment to its holding position that a reliably functioning Safety release can be achieved.
  • a heel cup that is movable from its holding position to its firing position and back along the second range of travel has the advantage that the heel cup is easily moved from its holding position to its firing position and back ,
  • the triggering position of the heel holder is as best as possible separated from the position of the heel holder. This allows easy adjustment of the heel unit between the walking configuration, the holding configuration and the trip configuration. Accordingly, this allows easy operation of the heel unit and minimizes the risk of incorrect manipulation.
  • the heel holder is not movable along the second region of the adjustment in its release position and back.
  • the release position is preferably in an end region of the second portion of the adjustment path spaced from the holding position.
  • the heel holder is in its release position at a distance to the holding position of the heel holder. This has the advantage that the release position is clearly separated from the holding position. This facilitates the operation and use of the heel counter, since the risk of a false position of the heel holder is reduced.
  • the release position of the heel holder is not located in a spaced-apart end region of the second region of the adjustment path.
  • the release position may in this case, for example, be close to the holding position of the heel holder within the second range of the adjustment.
  • the automatic heel unit comprises a heel-holder guide device, by means of which the heel holder is mounted along the first region of the adjustment path relative to the heel-holder carrier from its holding position to its walking position and movable back on the heel-holder carrier.
  • This has the advantage that the heel holder stable on Heel holder carrier can be movably mounted. As a result, the automatic heel unit can be stably constructed in a simple manner.
  • the heel machine may not include such a heel holder guide device.
  • this can have the advantage that the heel piece can be built more easily.
  • the heel cup is advantageously both rotatably and slidably supported by the heel cup guide along the first portion of the adjustment path relative to the heel cup carrier from its holding position to its walking position. It is irrelevant whether the displacement in its first region is only linear and thus the center of mass of the heel holder is displaced during a rotation of the heel holder or whether the adjustment path in its first region has a non-linear portion in which the center of mass of the heel holder during a Rotation of the heel holder is not moved. Regardless, this has the advantage that the heel holder can be optimally positioned and aligned relative to the heel holder carrier in its holding position and in its walking position.
  • the heel holder is mounted by the heel holder guide device without rotation along the first region of the adjustment relative to the heel holder carrier from its holding position to its walking position and back.
  • the heel-holder guide means is preferably a heel-hold control by which the heel-holder is supported along the first portion of the adjustment path relative to the heel-holder support from its holding position to its posture and movable backward on the heel-holder support.
  • the heel holder guide device is not forced control of the heel holder, by which the heel holder along the first portion of the adjustment relative to the heel holder carrier from its holding position in its walking position and is movably mounted on the heel holder carrier.
  • the automatic heel unit comprises a heel cup guide means and has a firing configuration in which the heel cup is in a firing position and the heel area of the ski boot is released from the heel cup, and the heel cup is movable from its hold position to its firing position and back along the second range of the stroke;
  • the heel holder is preferably also supported by the heel holder guide means along the second portion of the displacement relative to the heel holder carrier from its holding position to its release position and movable back on the heel holder carrier. This also has the advantage that a guide of the heel holder along the second region of the adjustment can be achieved in a simple manner.
  • the heel holder is mounted by the heel holder guide device along the second displacement relative to the heel holder carrier from its holding position to its release position and back both rotatable and displaceable. It is irrelevant whether the adjustment in its second region is only linear and thus the center of mass of the heel holder is displaced during rotation of the heel holder or whether the adjustment in its second region has a non-linear portion in which the center of gravity of the heel holder at a Rotation of the heel holder is not moved. Regardless, this has the advantage that the heel holder can be positioned and aligned particularly advantageous both in its holding position and in its release position. This makes it easier to get on the heel counter and get out of the heel counter.
  • the heel holder by the heel holder guide device without rotation along the second region of the Adjustment is stored relative to the heel holder carrier from its holding position to its release position and back movable.
  • the heel counter comprises a heel-holder guide device by which the heel-holder is movably supported along the second displacement path relative to the heel-holder support from its holding position to its release position and back
  • the heel-holder guide device is preferably a positive control of the heel-holder, through which the heel holder is relatively along the second region of the adjustment to the heel holder carrier is stored from its holding position to its release position and movable back on the heel holder carrier.
  • the automatic heel unit additionally has an elastic element, by means of which the heel holder is biased toward its holding position, at least in a partial region of the second region of the adjustment path adjoining the first region of the displacement path, the force control makes it possible for the force generated by the elastic element directly or indirectly, even at an angle of more than 0 °, such as at an acute angle to the alignment of the adjustment at the respective position of the heel holder aligned with the heel holder, since the heel holder by the positive control safely on the second portion of Verstellwegs is held.
  • This has the advantage that the construction of the heel unit can be simplified. In particular, this can also be optimized at most by the automatic heel safety release enabled.
  • the heel holder guide device is not a forced control of the heel holder, by which the heel holder along the second portion of the adjustment relative to the heel holder carrier from its holding position to its release position and is movably mounted on the heel holder carrier.
  • the heel-holder carrier preferably comprises a groove which forms part of the heel-holder guide device.
  • the shape of the groove is irrelevant.
  • the groove may have the shape of a slot or also an arc be educated.
  • the groove of the heel holder guide means has the advantage that the heel holder can be easily stored on the heel holder carrier.
  • the heel holder guide device also comprises a pin arranged on the heel holder.
  • the pin may have any shape in cross section. For example, it can have a circular but also a quadrangular cross-section.
  • the heel holder may also include a plurality of pins. It is irrelevant whether the pins are formed as separate elements or whether the pins are connected to each other. For example, two pins can be connected to an axis.
  • the pin of the heel holder is advantageously guided in the groove of the heel holder carrier in a part of the adjustment.
  • This part can be in the first or in the second range of the adjustment path.
  • this part of the adjustment path can also be located both in parts in the first region of the adjustment path and in parts in the second region of the adjustment path.
  • a positive guidance can be formed in a simple manner with the guided in the groove pin.
  • the heel holder can be guided with its pins in the groove of the heel holder support such that the heel holder performs a translational movement or a rotational movement or both a translational movement as well as a rotational movement during a movement along the corresponding part of the adjustment.
  • the groove of the heel holder carrier and the pin of the heel holder offer the advantage that the heel holder is stored safely and easily on the heel holder carrier. This allows an inexpensive construction of the heel holder guide device. It is irrelevant whether the heel holder guide device comprises further elements for mounting the heel holder on the heel holder carrier.
  • the heel holder guide device comprises no groove and no pin.
  • the heel holder guide device can in this Case, for example, a rail or a lever joint assembly to guide the heel holder on the heel holder support.
  • the automatic heel unit comprises an actuating lever, by the actuation of the automatic heel unit of the holding configuration in the Gehkonfiguration and back is adjustable.
  • the heel holder is movable by the operating lever from its holding position to its walking position and back. This has the advantage that the automatic heel unit can be easily adjusted manually from the holding configuration to the walking configuration and back.
  • the heel strap is automatic preferably by actuation of the actuating lever from the holding configuration in the trigger configuration and back adjustable. This has the advantage that the automatic heel unit can be easily adjusted manually from the holding configuration to the release configuration and back.
  • the automatic heel unit does not include such an actuating lever.
  • the heel box preferably comprises an actuating lever guiding device for transmitting a movement of the actuating lever to the heel holder. This has the advantage that a movement of the manually operated operating lever is easily and safely transferable to the heel holder.
  • the actuating lever guiding device comprises a plurality of elements. These elements need not be located directly on the operating lever.
  • the actuating lever but also the heel holder and the heel holder carrier may comprise elements of the actuating lever guide device.
  • the actuating lever guiding device comprises an on Operating lever arranged cam and a recess arranged on the heel holder, wherein the cam of the actuating lever is guided in the recess of the heel holder.
  • the operating lever guide means preferably a movement of the operating lever is transferable to the heel holder, that the heel holder along the first portion of Verstellwegs relative to the heel holder carrier by the actuating lever from the holding position of the heel holder in the walking position of the heel holder and back is movable.
  • This has the advantage that can be moved easily and quickly between its walking position and its holding position by a manual operation of the operating lever of the heel holder.
  • the actuating lever guide means with advantage also for transmitting a movement of the actuating lever on the heel holder within the second region of the adjustment. This has the advantage that the heel holder can be easily and quickly moved between its holding position and its release position by the manual operation of the operating lever.
  • the operating lever guide means comprises a cam disposed on the operating lever and a recess disposed on the heel holder .
  • the recess on the heel holder preferably designed as a cam and the actuating lever preferably rotatably mounted on the heel holder carrier.
  • the heel unit allows a safety release. This has the advantage of increasing safety for the skier.
  • the heel unit has a release configuration
  • the heel unit is advantageously adjustable from the retention configuration to the deployment configuration upon a safety deployment.
  • the heel unit is after a safety trip in this trip configuration. This has the advantage that the automatic heel unit with the release configuration is specifically adaptable to the release process, thereby facilitating the release of the ski boot from the heel unit.
  • the heel unit can be adjustable from its holding configuration to a configuration in which the heel area of the ski boot is released, for example in the event of a safety release. Thereafter, the heel counter can be transferred, for example, back to the holding configuration or in the Chazan. This has the advantage that the heel machine can be constructed easily and inexpensively.
  • the heel unit advantageously allows a safety release in the forward direction.
  • the heel area of the ski boot can be released upward from the heel counter. This has the advantage that the heel area of the ski boot in a safety release due to a fall of the skier in the forward direction controlled by the heel counter can solve.
  • the automatic heel unit allows lateral safety release.
  • the heel area can be released laterally in a direction horizontally across the ski from the heel counter. This offers the advantage that, in the event of a lateral safety release due to a lateral fall or a skydiving of the skier, the heel area of the ski boot can be released in a controlled horizontal direction from the heel counter in the ski direction.
  • the heel unit allows both a safety release in the forward direction and a lateral safety release. This has the advantage that the safety for the skier can be additionally increased.
  • the automatic heel unit comprises a ski brake, which is adjustable between a braking position and a driving position and which is translationally movable relative to the heel holder carrier.
  • the ski brake performs a braking function in its braking position, while in its driving position it does not perform such a braking function.
  • Such a ski brake can also be used independently of the heel machine described above in an automatic heel unit comprising a heel holder carrier and a heel holder for holding a ski boot in a heel region of the ski boot. In this case, it may also have the features described below independently of the heel machine described above.
  • the ski brake comprises two arms with free ends and a bearing element, wherein the two arms are rotatably mounted on the bearing member about an axis relative to the bearing member to adjust the ski brake between its braking position and its driving position.
  • the axis is aligned horizontally, particularly preferably horizontally in the cross-machine direction.
  • the axle allows the free ends of the arms in the braking position to be lowered over the back of the heel unit when the ski brake is mounted on a ski Sliding surface of the ski can be pivoted out to perform a braking function and that the free ends of the arms can be lifted in the driving position up over the sliding surface of the ski so as not to perform such a braking function.
  • the formulation that the ski brake to the heel holder carrier is translationally movable that the axis is translationally movable relative to the heel holder carrier. It is irrelevant whether the storage element is also translationally movable relative to the heel holder carrier or not. It is also irrelevant whether the ski brake is in such a translational movement in its braking position or its driving position or is adjusted between its braking position and its driving position.
  • the automatic heel unit like the automatic heel unit described above, has a holding configuration in which the heel holder is in a holding position and the heel holder can cooperate with the heel region of the ski boot held in the ski binding such that the heel region of the ski boot is held in a lowered position
  • the automatic heel unit has a walking configuration in which the heel holder is in a walking position and the heel region of the ski boot held in the ski binding is released from the heel holder and can be lowered towards the ski without being locked in the lowered position by the heel retainer
  • the ski brake is preferably in the walking configuration of the heel unit in a walking position relative to the heel-holder support and in the holding configuration of the heel-breaker in a downhill position relative to the heel-holder support.
  • the ski brake is adjustable by adjusting the heel counter from its holding configuration to its walking configuration and back from its downhill position to its walking position and back. Regardless of this adjustability, the ski brake is preferably adjustable in its downhill position from its braking position and its driving position and back. In addition, the ski brake is preferably adjustable in its walking position from its braking position to its driving position.
  • the automatic heel unit comprises a brake holder, by means of which the ski brake can be locked in its walking position in the driving position.
  • the ski brake in the walking configuration of the automatic heel unit in which it is in its walking position, is adjustable from its braking position into its driving position and can be locked by the brake holder in its driving position.
  • the ski brake in its walking position is not adjustable from its presentation in its driving position, the ski brake is preferably brought by adjusting their departure position in their walking position in their driving position and locked in their driving position. It is irrelevant how the ski brake is adjustable from its departure position to its walking position. In addition, it is irrelevant whether the ski brake is in its downhill position before an adjustment from its departure position to its walking position in its braking position or in its driving position.
  • the ski brake is preferably movable relative to the base element.
  • the ski brake is preferably movable in translation relative to the base element.
  • the ski brake is displaceably mounted on the base element. This allows a compact design of the heel unit.
  • the ski brake comprises two arms and a bearing element, wherein the two arms are rotatably mounted on the bearing element about an axis relative to the bearing element, so preferably the bearing element is slidably mounted on the base member to achieve this advantage.
  • ski brake is not or otherwise mounted movably on the base element or that the ski brake is not movable relative to the base element or is fixedly arranged on the base element.
  • the automatic heel unit has a ski brake and, in addition, the heel holder is movably mounted on the heel-holder support along an adjustment path relative to the heel-holder support
  • the ski brake is preferably coupled to the heel holder of the heel-holder, whereby movement of the heel-holder along the adjustment path relative to the heel-holder carrier on a movement of the ski brake relative to the heel holder carrier is transferable. It is irrelevant whether the coupling of the ski brake with the heel holder takes place directly or indirectly via at least one intermediate element. In addition, “coupled” does not mean that the movement of the heel holder must be transferred unchanged to the ski brake and vice versa. Thus, the movement of the heel holder can be transmitted, for example, with a translation or with a reduction to the ski brake.
  • a ski brake thus coupled to the heel cup of the heel counter has the advantage that the position of the ski brake is adaptable to the position of the heel cup and vice versa. As a result, the operation of the heel counter can be facilitated.
  • the ski brake is coupled to the heel holder of the heel unit, whereby a movement of the heel holder along the first region of the adjustment path relative to the heel holder support is transferable to a movement of the ski brake relative to the heel holder support.
  • this coupling is preferably achieved by movement of the heel holder along the first range of travel from its position in FIG its holding position the ski brake adjustable from its walking position to its departure position and adjustable by a movement of the heel holder along the first range of the adjustment path from its holding position to its position the ski brake from its departure position to its walking position.
  • the ski brake advantageously comprises an actuating element for adjusting the ski brake from the braking position to the driving position.
  • the ski brake preferably has an elastic element for biasing the ski brake into its braking position. This has the advantage that the ski brake can be made automatically adjustable in the braking position if necessary.
  • the ski brake also has two arms, then the elastic element is advantageously formed by the two arms.
  • the two arms may be formed by the free ends of a wire or rod bar.
  • the bracket may for example be mounted on the actuating element and the two arms may be biased away from each other in order to bias the ski brake into the braking position via a suitably designed mounting of the arms.
  • the ski brake can be constructed compact.
  • an automatic heel unit with the ski brake can be constructed such that in the holding configuration of the heel unit, in which the ski brake is in the holding position, the ski brake with the actuating element can be supported against the sole of the ski boot held in the heel counter, to keep the ski brake in the driving position, and that the ski brake can be brought by the bias of the elastic member in the braking position as soon as the ski boot is released from the heel unit and thus the actuator is released from the sole of the ski boot.
  • an automatic heel unit with the ski brake can be constructed in such a way that the ski brake can be adjusted from the braking position to the driving position by actuating the actuating element with the sole of the ski boot in the holding configuration and possibly in the walking configuration of the heel piece.
  • the ski brake comprises no actuating element and no elastic element.
  • the automatic heel unit does not include a ski brake.
  • FIG. 1 shows an oblique view of an inventive heel unit 1 in a release configuration.
  • a line extending horizontally from front to back in the longitudinal direction through the automatic heel unit 1 runs in the FIG. 1 from top left to bottom right. This line runs parallel to the ski longitudinal direction of a ski, not shown here, on which the automatic heel unit 1 can be mounted.
  • In the figure on the top left corresponds to the heel counter 1 front.
  • the automatic heel unit 1 belongs to a ski binding, which in addition to the automatic heel unit 1 comprises a front-end machine, not shown here, and in which a ski boot can be held.
  • the ski boot can be held both in his toe area in the front automaton as well as with his heel area in the heel unit 1 or depending on the construction of the front vending machine only with his toe area about an axis oriented horizontally in the ski direction pivotally in the front vending machine.
  • the automatic heel unit 1 comprises a base plate 2, which serves as a base element for mounting the automatic heel unit 1 on an upper side of a ski. Furthermore, the automatic heel unit 1 comprises a heel holder carrier 3, a heel holder 4 for holding the heel region of the ski boot, an actuating lever 7, a climbing aid lever 30 and a ski brake 8 with a bearing element 10, an actuating element 11 and two arms 12.
  • the arms 12 are the ski brake 8 about an axis 9 relative to the bearing element 10 rotatably mounted on the bearing element 10.
  • the ski brake 8 is displaceably mounted with the support member 10 on the base plate 2 relative to the base plate 2 and thus translationally movable relative to the heel holder carrier 3, so that the axis 9 about which the two arms 12 of the ski brake 8 are rotatably mounted on the bearing element 10, relative to the heel holder carrier 3 is translationally movable.
  • the ski brake 8 is adjustable from a driving position to a braking position and back by the arms 12 are pivoted about the axis 9. In this case, the free ends of the arms extend in the braking position down over a sliding surface of the ski, while they are in the driving position above the sliding surface of the ski.
  • the heel holder carrier 3 is also mounted displaceably on the base plate 2 in the longitudinal direction of the ski. It can be seen in the longitudinal direction of the ski in different positions on the base plate 2 are positioned to adjust the heel counter 1 to different sized ski boots. In addition, it is biased by a spring, not recognizable here forward and can be moved against this bias slightly towards the base plate 2 to the rear. If the automatic heel unit 1 together with a front automatic machine forms a ski binding and is mounted on a ski, the automatic heel unit 1 can therefore compensate for a bending of the ski between the front automaton and the heel counter 1 occurring distance changes.
  • the heel holder 4 is movably mounted along an adjustment path relative to the heel holder carrier 3.
  • the heel holder 4 has two side walls and in its front region a connecting web 18 connecting the side walls.
  • a horizontally oriented axis 13 in a lower region of the side walls of the heel holder 4 is immovably connected to both side walls.
  • the automatic heel unit 1 also has a holding configuration in addition to the release configuration.
  • the operating lever 7 is in a holding position.
  • the heel holder 4 is in the holding configuration of the heel unit 1 in a holding position.
  • the heel holder 4 can cooperate in the holding position with the heel region of a ski boot, not shown here, held in the ski binding in a lowered position, so that the heel region of the ski boot is held in a lowered position.
  • the heel holder 4 comprises the connecting web 18, which forms a hold-down structure 5 which can hold down the heel area of the ski boot by being able to embrace the sole of the ski boot held in the heel unit 1 from behind in the heel area.
  • the heel holder 4 comprises in its front region below the connecting web 18 a heel support structure 6 which can support the heel region of the ski boot in a horizontal direction transverse to the ski by being able to engage in corresponding recesses in the heel region of the ski boot.
  • the heel support structure 6 can also be omitted or designed differently and, for example, laterally grip the sole of the ski boot in the heel region of the ski boot somewhat forward.
  • the heel unit 1 has a housing configuration.
  • the actuation lever 7 is in a first or second rise position.
  • the heel holder 4 is in a walking position, which differs from the holding position. In the walking position of the heel holder 4, the heel area of the ski boot held in the ski binding is released by the heel holder 4 and can be lowered towards the ski without being locked in the lowered position by the heel holder 4.
  • the heel holder 4 is movable from its position to its holding position and back along a first region of the adjustment. In this case, the heel holder 4 is in its walking position further back than in its holding position.
  • the first portion of the adjustment also includes a vertical component and the heel holder 4 is in its position also lower down than in its holding position.
  • the heel holder 4 is in its walking position at one of the holding position of the heel holder spaced end of the first portion of the adjustment, which also forms a first end of the adjustment.
  • the heel unit 1 can be moved from its holding configuration in its Gehkonfiguration and back.
  • the heel holder 4 can thereby be moved from its holding position into its walking position and back relative to the heel holder carrier 3 along the first region of the adjusting path.
  • the actuating lever 7 is also adjustable in a second rise position in which he serves as a climbing aid. The movement of the heel holder 4 along this first range of the adjustment is described in detail below.
  • the heel unit 1 has a triggering configuration.
  • the operating lever 7 is in a release position.
  • the heel holder 4 is in a release position, which differs from the holding position and the Gehgori.
  • the heel area of the ski boot is released from the heel holder 4.
  • the heel unit 1 can be moved from the holding configuration to the tripping configuration and back.
  • the heel holder 4 is moved from its holding position to its release position and back relative to the heel holder carrier 3 along a second region of the adjustment by the movement of the actuating lever 7.
  • the heel holder 4 In the release position, the heel holder 4 is located at one of the holding position spaced end of the second region of the adjustment, which also forms a second end of the adjustment. In contrast, in its holding position, the heel holder 4 is located on a transition from the first region of the adjustment path to the second region of the adjustment path. When the heel holder 4 is moved beyond its holding position into the second region of the adjustment path, starting from its position along the first region of the adjustment path, the heel holder 4 is moved into the second region of the adjustment path immediately after the transition upwards.
  • the automatic heel unit 1 In addition to the automatic heel unit 1 being able to be adjusted from the release configuration into the retaining configuration by a movement of the actuating lever, the automatic heel unit 1 can also be adjusted by depressing the front region of the heel holder 4 be adjusted with the heel area of the ski boot from its trigger configuration into its holding configuration. Furthermore, the automatic heel unit 1 can also be adjusted from its holding configuration into its release configuration by pushing up the heel holder 4 with the heel region of the ski boot held in the automatic heel unit 1, for example in the event of a safety release.
  • the hold-down structure 5 of the heel holder 4 is formed by the connecting web 18 of the heel holder 4.
  • the hold-down structure 5 in the form of a forward projecting part of the circle.
  • the heel support structure 6 is formed separately from the hold-down structure 5 and is located below it.
  • the heel support structure 6 comprises two forwardly projecting oblong projections seen in the vertical direction. At a lower end of these projections there is also a forwardly projecting tread spur 19. This can serve as a vertical stop when entering the automatic heel unit 1 in order to position the ski boot more easily in the automatic heel unit 1.
  • the tread spur 19 can be pushed down by the ski boot to move the automatic heel unit 1 from the deployment configuration to the retention configuration.
  • the automatic heel unit 1 comprises, as already mentioned, a ski brake 8, in which the arms 12 are mounted rotatably about the axis 9 relative to the bearing element 10 on the bearing element 10.
  • the two arms 12 are formed by the free ends of a bracket.
  • This bracket is not clearly visible in the figures, because the connecting piece of the bracket, by which the two arms 12 are connected to each other, is arranged in the actuating element 11, while the two free ends of the arms 12 point away from the actuating element 11.
  • the two arms 12 of the bracket are clamped to each other slightly clamped on the bearing element 10 so that they are biased.
  • This bias of the arms 12 is implemented by a corresponding shape of the bearing element 10 in a bias of the ski brake 8 from the driving position to the braking position.
  • the bearing element 10 allows that the arms 12 of the ski brake 8 are moved slightly further apart in the braking position than in the downhill position. Therefore, the bracket is slightly less in the braking position strongly biased as in the downhill position and accordingly has the tendency to adjust the ski brake 8 for relaxation from the downhill to the braking position.
  • the two arms 12 of the ski brake 8 are aligned substantially parallel to the ski and point with their free ends to the rear.
  • the two arms 12 in the driving position do not extend down over a sliding surface of the ski.
  • the arms 12 do not prevent the ski from sliding freely on the ground.
  • the front ends of the arms 12, which are interconnected by the bracket pivoted in the driving position of the ski brake 8 with the actuator 11 to the ski down to a height of the bearing element 10.
  • the arms 12, as already mentioned are pivoted down about the axis 9, so that the free ends of the arms 12 point obliquely rearwardly downwards and extend beyond the sliding surface of the ski.
  • the ski brake 8 can be held in its driving position by the actuating member 11 is prevented from moving upwards away from the ski. This can be done, for example, in the holding configuration of the heel unit 1 by a ski boot held in the heel counter 1.
  • the bearing element 10 of the ski brake 8 is slidably mounted in the longitudinal direction of the base plate 2. In this case, the bearing element 10 can be moved independently of the heel holder carrier 3 relative to the base plate 2. Accordingly, the bearing element 10 is translationally movable relative to the heel holder carrier 3 together with the axis 9.
  • the ski brake 8 is coupled to the heel holder 4, whereby the ski brake 8 can be moved by a movement of the heel holder 4.
  • the ski brake 8 is relative to the heel holder support 3 in a downhill position. In this departure position the ski brake 8 is adjustable from the driving position to the braking position and back.
  • the ski brake 8 is in a walking position relative to the heel holder carrier 3. In this walking position, the ski brake 8 is relative to the base plate 2 further back than in the downhill position. In addition, it is closer to the heel holder carrier 3 than in the downhill position. Even in the walking position, the ski brake 8 can be moved from the braking position to the driving position. However, it hooks in the walking position in a arranged on the base plate 2 brake holder when it is moved from the braking position to the driving position. As a result, it is locked in the walking position in the driving position and pivots despite bias in the driving position no longer in the driving position.
  • FIG. 2 shows a plan view of the heel unit 1 in the trip configuration.
  • the heel support structure 6 at the front of the connecting web 18 of the heel holder 4 can be seen.
  • the arranged below the projections tread spur 19 is clearly visible.
  • FIGS. 3a and 3b each show a side view of a vertically aligned in the ski longitudinal direction, extending through the heel unit 1 section, wherein the heel unit 1 is in the holding configuration. As a result, the construction of the heel unit 1 can be seen better.
  • FIG. 3a As seen in the cross-section, the cut runs centrally through the heel counter 1.
  • FIG. 3b As seen in the direction of the ski, the section is slightly offset behind the side wall of the heel holder 4 facing the observer.
  • the heel holder 4 is movably mounted in total over four bearing points on the heel holder carrier 3.
  • a first bearing point forms the axis 13 already mentioned, aligned horizontally in the transverse direction, and immovably connected to both sidewalls in a lower region of the side walls of the heel holder 4 FIG. 3a
  • the heel holder carrier 3 has a groove 14 designed as a slot in which the axis 13 is guided.
  • the oblong hole 14 comprises an upper, substantially vertical section and a lower, curved section adjoining the vertical section. This curved section runs with two curves from the top front to the bottom rear.
  • the axis 13 extends as a pin through the slot 14th formed groove in the heel holder carrier 3 and is along the shape of the elongated hole 14 relative to the heel holder carrier 3 movable up and down.
  • a second bearing point of the heel holder 4 on the heel holder carrier 3 forms a nose 15, which is arranged in the front upper region of the heel holder carrier 3 and on which the connecting web 18 of the heel holder 4 can be supported. Seen in the longitudinal direction of the ski forwardly protruding nose 15 of the heel holder carrier 3 extends in the direction of the ski direction over a central region of the width of the heel holder carrier 3.
  • the connecting web 18 of the heel holder 4 has in FIG. 3a shown cross-section an upper front-to-bottom downward slope, a middle vertical section and a lower, running from back to front below slope.
  • the nose 15 is depending on the position of the heel holder 4 on the upper slope, the lower slope or the vertical portion of the connecting web 18 at. Depending on whether the nose 15 therefore supports the heel holder 4 in a different orientation relative to the heel holder carrier 3 against further rotational movement with its upper portion about the axis 13 to the rear.
  • a third bearing point of the heel holder 4 on the heel holder carrier 3 is formed by the actuating lever 7.
  • the heel holder 4 has in its two side walls in each case a recess 16 which is open towards the center of the ski as viewed in the ski direction.
  • the recesses 16 each include an upper portion and a lower portion. These two areas each forward to a front, rounded tip of the respective recess 16, so that the recesses 16 in a vertical section through the heel holder 4 as in FIG. 3a seen to have a C-shape.
  • the operating lever 7 has a bow shape.
  • the areas of the two free ends of the bracket are each formed by a vertically oriented side wall.
  • a central region of these side walls of the actuating lever 7 is rotatably mounted on the heel holder support 3 about an axis 26 oriented horizontally in the transverse direction.
  • one side wall is located on the left and on the right of the heel holder carrier 3.
  • the two side walls each have a cam 17 projecting in the transverse direction from the respective side wall outwardly from the center of the ski has triangular cross-section.
  • these cams 17 are above, below or in front of the axis 27.
  • the cams 17 are each disposed within the recess 16 of the side walls of the heel holder 4.
  • the cams 17 are movable relative to the heel holder 4 within the recess 16. If the operating lever 7 is rotated about the axis 26, the cams 17 also perform a circular movement about the axis 26. In this case, the cams 17 are in each case either at the upper or at the lower region of the corresponding recess 16 and slide during a movement of the actuating lever 7 along the upper or the lower region of the recess 16 and presses the heel holder 4 thereby upwards or downwards.
  • the recess 16 on the heel holder 4 is thus formed as a cam. As a result, a movement of the actuating lever 7 can be transmitted to the heel holder 4. In the holding position of the heel holder 4 prevents the cam 17 a movement of the heel holder 4 relative to the heel holder support 3 down and a rotational movement of the heel holder 4 about the axis 13 forward.
  • the fourth bearing point of the heel holder 4 on the heel holder carrier 3 is formed by the actuating lever 7.
  • the two side walls of the actuating lever 7 each end face on a surface 27, which form the free ends of the arms of the bracket, through which the actuating lever 7 is formed.
  • these frontal surfaces 27 are aligned downward or forward to the ski tip.
  • Both surfaces 27 each interact with a arranged on the heel holder 4 web 28.
  • the two webs 28 are respectively arranged on the inside of the side walls of the heel holder 4 below the recesses 16, which are open towards the ski center as viewed in the transverse direction of the ski (see FIGS. 3b and 5b ). They are above the axis 13.
  • the heel holder 4 is movable through these four bearing points along the displacement relative to the heel holder carrier 3.
  • the slot 14 with the guided axis 13 of the first bearing point, the nose 15 of the heel holder support 3 with the connecting web 18 of the heel holder 4 of the second bearing, the recesses 16 of the heel holder 4 with the cam 17 of the operating lever 7 of the third bearing and the surfaces 27 of Operating lever 7 with the webs 28 of the heel holder 4 of the fourth bearing therefore form a heel holder guiding device, through which the heel holder 4 along the first portion of the adjustment of the heel holder 4 relative to the heel holder carrier 3 from its holding position to its walking position and back or from its holding position to its release position and movable back on the heel holder support 3 is stored.
  • the heel holder guiding device is a positive control of the heel holder 4.
  • the recesses 16 of the heel holder 4 with the cam 17 of the actuating lever 7 of the third bearing and the surfaces 27 of the actuating lever 7 with the webs 28 of the heel holder 4 of the fourth bearing also form an operating lever guide means for transmitting a movement of the actuating lever on the heel holder 4.
  • the operating lever 7 is coupled to the heel holder 4 by this actuating lever guiding device, so that a movement of the actuating lever 7 onto the heel holder 4 and, conversely, a movement of the heel holder 4 onto the actuating lever 7 can be transmitted.
  • FIGS. 3a and 3b is the heel unit 1 in the holding configuration and thus the heel holder 4 shown in its holding position.
  • the axis 13 is located in a central region of the slot 14, ie in a transition region between the upper vertical portion and the lower curved portion of the slot 14 (see FIG. 3a ).
  • the vertical portion of the connecting web 18 of the heel holder 4 abuts against the front side of the nose 15 of the heel holder carrier 3.
  • the heel holder 4 is thus inclined slightly forward with its upper portion and can not be rotated freely about the axis 13 with its upper portion to the rear.
  • the cam 17 of the actuating lever 7 at the upper region of the recesses 16 (see FIG.
  • the heel holder carrier 4 has, in its rear area and in the direction of the ski, a central recess with a circular cross section. A longitudinal axis of this recess forms an acute angle to the vertical seen from back to front.
  • a piston 21 is located in the recess. This is movably mounted and lies with its front on a pawl 23 at.
  • At the rear of the piston 21 includes a spring 20 as an elastic element. This spring 20 is supported with its front end against the piston 21 and with its rear end against a disc. The disc is fastened with a screw on the heel holder carrier 3. By this screw, the bias can be adjusted, with which the spring 20, the piston 21 is pressed against the pawl 21.
  • the piston 21 has on its front side an inwardly curved surface, which rests in the holding position of the heel holder 4 on a corresponding counter-curvature of the pawl 23.
  • the pawl 23 is pivotally mounted about an axis 22 on the heel holder carrier 3 and is located between the piston 21 and guided in the slot 14 axis 13. It has an arcuate portion with which it bears against the axis 13 while the axis 13 partially encloses ,
  • the axis 13 is in the holding configuration of the heel counter 1 at a transition between the upper vertical and the lower curved portion of the slot 14.
  • the heel holder 4 is in its holding position on a transition from the first region of the adjustment to the second Range of the adjustment path. Starting from the holding position, the heel holder 4 can be moved downwards into the first region of the adjustment path and vertically upwards into the second region of the adjustment path.
  • the heel holder 4 When the heel holder 4 is in a subsequent to the first portion of the adjustment portion of the second portion of the adjustment, the heel holder 4 is generated due to the force generated by the spring 20 and the piston 21 via the pawl 23 on the axis 13 and the force in the Essentially vertical positive guidance of the axis 13 in the slot 14 biased down to the holding position.
  • the longitudinal axis of the recess in which the spring 20 is formed forms an acute angle to the vertical from rear to front, at each position of the heel holder 4 in the partial region of the second region of the adjustment is the force generated by the spring 20 in one pointed angle aligned with an orientation of the second portion of the displacement at the respective position of the heel holder 4.
  • the ski brake 8 can be seen.
  • the ski brake 8 In the holding configuration of the heel unit 1, the ski brake 8 is in the downhill position. In this departure position the ski brake 8 is adjustable from a braking position to a driving position and back.
  • the ski brake 8 In the holding configuration of the heel unit 1, when a ski boot, not shown here, is held in the heel counter 1, the ski brake 8 is located as in FIGS FIGS. 3a and 3b shown in the driving position. In this are the arms 12 in a horizontal orientation and the free end of the arms 12 show horizontally to the rear.
  • the heel area of the ski boot which is not shown here, holds the actuating element 11 of the ski brake in a lower position so that the upper side of the actuating element 11 forms a surface with the bearing element 10.
  • the space above the actuating element 11 becomes free and the ski brake 8 can be adjusted from the driving position into the braking position.
  • the operating lever 7 In order to move the heel unit 1 from its holding configuration to its walking configuration, the operating lever 7 is moved from its holding position to its first walking position. This is done by the in the holding position obliquely backwards pointing upwards free end of the operating lever 7 is moved upward. As a result, the heel holder 4 is moved downwardly and rearwardly from its holding position to its walking position along the first range of the adjustment path. The heel holder 4 can be moved from its holding position to its walking position only on the first region of the adjustment, when the heel area of the ski boot is not used in the heel unit 1.
  • the heel holder 4 At the beginning of this movement of the heel holder 4 from its holding position down the connecting web 18 of the heel holder is located with its vertical portion on the Front of the nose 15 of the heel holder carrier 3 at. However, if the heel holder 4 is moved downwards so far that the vertical portion is no longer in contact with the front side of the nose 15, the upper slope of the connecting web 18 bears against an underside of the nose 15. In this part of the first range of the adjustment, the heel holder moves down and at the same time to the rear. The heel holder is thus movable from its holding position into its walking position with a curved linear movement along the first region of the adjustment path, but at the same time it is slightly tilted forwards with its upper region. The first region of the adjustment path extends in a vertically oriented in the ski longitudinal direction plane.
  • the heel holder 4 During the entire movement of the heel holder 4 from its holding position into its walking position and back along the first range of the adjusting path, the heel holder 4 is freely movable along the first region of the adjusting path.
  • the heel holder is thus without bias, d. H. movable without the force generated by the spring 20 and acting on the heel holder 4 force.
  • the reason for this is the shape of the pawl 23 and the position of the pawl 23 when the axis 13 is in the lower curved portion of the slot 14.
  • the pawl 23 is oriented so that the front portion of the piston 21 presses, by the force generated by the spring 20, on a shoulder of the pawl 23 which extends between the piston 21 and Axis 22 is located.
  • the force is aligned with the center of the axis 22.
  • no torque is generated on the pawl 23 and the arcuate portion of the pawl 23 does not transmit any force to the axle 13.
  • the heel holder 4 is thus not biased along the first range of the adjustment. It can therefore be moved manually by the actuating lever 7 or manually along the first range of the displacement.
  • FIGS. 4a-4c each show a side view of a vertically aligned in the longitudinal direction section through the heel unit 1 in the housing configuration.
  • the cut runs centrally through the heel counter 1.
  • the section is in Skiquerraum seen offset to the ski center by a side wall of the actuating lever 7.
  • the cut runs in Skiquerraum seen offset to the ski center behind the viewer facing side wall of the heel holder. 4
  • the operating lever 7 In the illustrated housing configuration of the heel unit 1, the operating lever 7 is in its first walking position and the free end of the operating lever 7 points vertically upwards.
  • the cams 17 of the operating lever 7 are in this position with two of its sides in the front, rounded rounded tip of the recesses 16 of the heel holder 4 (see Figure 4c ). As a result, the operating lever 7 is in a stable position.
  • the heel holder 4 in its walking position.
  • the connecting web 18 of the heel holder 4 is located with its upper slope on the underside of the nose 15 of the heel holder support 3.
  • the heel holder 4 is prevented from moving upwards and rotating about the axis 13 to the rear.
  • the front lower portion of the heel holder 4 abuts on the heel holder carrier 3, as seen in FIG FIG. 4a so that the heel holder 4 can not rotate about the axis 13 forward. Since the heel holder 4 is in a rear and lower position and the axis 13 at the lower end of the curved portion of the slot 14, the heel holder 4 can not be moved further back and down.
  • heel holder 4 is in its position further back and lower than in its holding position. Therefore, when the automatic heel unit 1 forms a ski binding together with a front automatic machine, the heel area of the ski boot held in the front automatic machine can be lowered towards the ski in the heel configuration of the heel unit 1 until it is supported either by the front area of the heel holder support 3 or by the bearing element 10 of the ski brake 8 and prevented from further lowering. In this case, the ski boot is not locked by the heel holder 4 in the lowered position, but can be lifted off the heel counter 1 up again.
  • the automatic heel unit 1 has on both sides of the heel holder support 3 between the heel holder 4 and the heel holder support 3 a cover 29 in order to cover the oblong hole 14 to the outside.
  • the covers 29 have an oval shape and are rotatably mounted on the axle 13. Thus, the covers 29 move with the heel holder 4.
  • the covers 29 are pushed backwards. They are each guided by a tab on the heel holder carrier 3.
  • the heel holder 4 is movable from its position along the first region of the adjustment path back to its holding position.
  • the operating lever 7 is moved from its first walking position to its holding position.
  • the free vertically upwardly facing end of the actuating lever 7 is moved from above to obliquely behind.
  • the cams 17 of the operating lever 7 pivot about the axis 26 upwards, wherein the cams 17 slide along the upper region of the recesses 16 of the heel holder 4 and thus push the heel holder 4 upwards. Therefore, when the operating lever 7 is moved from its first walking position to its holding position, the shaft 13 shifts upward along the lower curved portion of the long hole 14.
  • the upper slope of the connecting web 18 of the heel holder 4 is first guided along the underside of the nose 15 of the heel holder support 3 obliquely forward above. Shortly before the holding position of the heel holder 4, the heel holder 4 is moved so far forward that the front of the nose 15 of the heel holder support 3 rests against the central vertical portions of the connecting web 18 of the heel holder 4. The heel holder 4 thereby performs a movement along the first portion of the adjustment path upwards and forwards.
  • the heel holder 4 is upwardly beyond the first range of the adjustment path along the first region of the adjustment path beyond the first region of the adjustment path to the second region of the adjustment path which adjoins the first region of the adjustment path movable.
  • the adjustment of the heel holder 4 in a transition region from the first region to the second region no kink and is thus continuously differentiable.
  • the heel holder 4 is adjustable from the holding position along the second region of the adjustment in the release position. Such an adjustment can be made by pressing the Operating lever 7 done. But it can also be done in a manner enabled by the automatic heel 1 safety release in the forward direction. In this case, the energy which can be absorbed by the heel counter 1 in the event of a collision with the ski boot, the ski binding or the ski, before the safety release is triggered in the forward direction, depends on the force of the spring 20 and on the length of the first Range of Verstellwegs subsequent, vertically aligned portion of the second portion of the adjustment.
  • the actuating lever 7 is moved from its first walking position to its triggering position.
  • the heel holder 4 is moved from its holding position to its release position.
  • the axis 13 of the heel holder 4 moves from the transition from the lower curved portion of the adjustment to the upper, substantially vertical portion of the slot 14 upwards in the upper, substantially vertical portion of the slot 14.
  • the heel holder 4 is doing after the transition from first in the second region of the adjustment substantially rectilinearly moved upward.
  • the axis 13 of the heel holder 4 pushes the pawl 23 upwards, so that it is pivoted about the axis 22 to the rear.
  • the piston 21 prestressed by the spring 20 no longer bears against the shoulder of the pawl 23, but against the arcuate region of the pawl 23.
  • the pawl 23 transmit a torque.
  • the heel retainer 4 continues to move upwardly along the second range of travel, the pawl 23 is further rotated rearwardly about the axis 22. Thereby pushes the arcuate portion of the pawl 23, the piston 21 to the rear above, so that the spring 20 is further compressed.
  • the heel holder 4 must first be moved to adjust from its holding position to its release position against the force generated by the prestressed spring 20 force along the adjoining the first region of the adjustment portion of the second portion of the adjustment.
  • the heel holder 4 is thus biased in this part of the second region of the adjustment by the spring 20 to its holding position.
  • the connecting web 18 of the heel holder 4 is supported with its vertical portion along the front of the nose 15 of the heel holder carrier 3.
  • the heel holder 4 is shifted so far that the connecting web 18 is moved with its vertical portion on the front of the nose 15 addition.
  • the heel holder 4 is located in a further subregion of the second region of the adjustment path.
  • the axis 13 in the slot 14 is slightly shifted down while the heel holder 4 is also pivoted about the axis 13 to the rear until the connecting web 18 with its lower slope on a Top of the nose 15 of the heel holder carrier 3 rests and the heel holder 4 is in its release position.
  • the piston 21 is moved over the pawl 23 again somewhat forward and the tension of the spring 20 is thereby reduced.
  • the heel holder 4 is biased after the pivoting movement to the rear to its release position. As a result, the heel holder 4 can not unintentionally release from its release position.
  • the heel holder 4 can not inadvertently out of its holding position and can not unintentionally release from its release position.
  • the automatic heel unit 1 by the prestressed spring 20 allows a safety release in the forward direction. In case of a fall, the energy acting on the ski boot, ski or ski binding is greater than the force generated by the prestressed spring 20 and biasing on the heel holder 4 to the holding position multiplied by the length of the vertical portion of the second portion of the adjustment, in which the Heel holder 4 is biased to the holding position, there is a safety release by the heel holder 4 is moved from its holding position to its release position. As a result, the heel area of the ski boot is released by the automatic heel unit 1.
  • Such a safety release of a heel counter with similar kinematics is also for example in the WO 96/23559 A1 (Fritschi AG Apparatebau).
  • the energy that can be absorbed by the heel counter 1 in a fall until it comes to a safety release, can be adjusted by the bias of the spring 20 by means of the screw in the rear end of the recess.
  • the movement of the heel holder 4 described above along the second range of the adjustment can be done by operating the operating lever 7 or by a safety release. If the heel holder 4 is moved from its holding position into its release position by the actuating lever 7, the free upward-pointing end of the actuating lever 7 is rotated downwards about the axis 26. As a result, the cams 17 of the operating lever 7 are pivoted rearwardly upwards. Thus, the tips of the cam 17 press upwardly and rearwardly to the upper portion of the recesses 16. As a result, the heel holder 4 is pushed so far up until the connecting web 18 is moved with its vertical portion on the front of the nose 15 addition.
  • the heel holder 4 pivots about the axis 13 to the rear until the connecting web 18 rests with its lower slope on an upper side of the nose 15 of the heel holder carrier 3.
  • the cams 17, which press the heel holder 4 not only upwards, but also to the rear due to the shape of the recesses 16 of the heel holder 4.
  • the heel holder 4 is thus substantially linearly movable along the second region of the adjustment path.
  • the automatic heel unit 1 of the holding configuration in the release configuration and back is adjustable.
  • the automatic heel unit 1 also enables a safety release in the forward direction by the pretensioned spring 20.
  • the heel unit 1 is adjustable through the heel area of the ski boot from that in the holding configuration to the release configuration.
  • the second portion of the displacement of the heel holder 4 extends in a vertically oriented in the longitudinal direction of the plane.
  • the heel unit 1 can be adjusted from the holding configuration to the release configuration upon a safety release.
  • the heel holder 4 is lifted upwards by the heel region of the ski boot held in the automatic heel unit 1 from its holding position along the partial region of the adjustment path adjoining the first region of the adjustment path.
  • the heel area of the ski boot no longer holds down the actuating element 11 of the ski brake 8. Since the actuating element 11 of the ski brake 8 is biased upward, the actuating element 11 pivots upward when lifting the heel portion of the ski boot.
  • the free ends of the arms 12 move down.
  • the ski brake 8 is thereby adjusted from the driving position to the braking position.
  • the braking position of the ski brake 8 is in Figure 5a - 5c seen.
  • the heel unit 1 can also be adjusted from its release configuration into its holding configuration by inserting the heel region of the ski boot into the heel unit 1. If, in this case, the heel area of the ski boot is lowered toward the ski, the heel holder 4 is also moved from its release position to its holding position. During such an insertion of the ski boot, the sole of the ski boot touches the top of the actuating element 11 of the ski brake 8 at some point and pushes it downwards. Characterized the free ends of the arms 12 are rotated about the axis 9 upwards in a horizontal orientation and the ski brake 8 is moved from the braking position to the driving position.
  • the ski brake 8 is coupled to the heel holder 4, whereby the ski brake 8 can be moved by a movement of the heel holder 4 from its departure position to its walking position and back.
  • the bearing element 10 of the ski brake 8 for this purpose a driver 24.
  • This driver 24 is arranged in a rear region of the bearing element 10.
  • the driver 24 has an upwardly facing formation, wherein the driver 24 performs under the heel holder 4 and seen in the longitudinal direction of the ski formation is behind the connecting web 18 of the heel holder 4. If the heel holder 4 is moved backwards and downwards from its holding position along the first region of the adjustment path, the heel holder 4 pulls over the connecting web 18 the formation of the Driver 24 and thus the storage element 10 to the rear.
  • the ski brake 8 is thereby moved translationally from its front downhill position to its rearward walking position. In this walking position, the ski brake 8 can be locked in the braking position by a brake holder arranged on the base plate 2. If the heel holder 4 is moved forward and upward from its position to its holding position along the first region of the adjustment path, the carrier 24 and the bearing element 10 are displaced forward by the heel holder 4. The ski brake 8 is thereby adjusted from its walking position to its departure position.
  • FIGS. 5a-5c each show a side view of a vertically aligned in the longitudinal direction section through the heel unit 1 in the release configuration.
  • the cut runs centrally through the heel counter 1.
  • FIG. 5b As seen in the cross-machine direction, the section extends to the center of the ski offset by a side wall of the actuating lever 7.
  • FIG. 5c on the other hand, as seen in the direction of the ski, the cut is offset to the center of the ski behind the side wall of the heel holder 4 facing the observer.
  • the actuating lever 7 In the release configuration of the heel unit 1, the actuating lever 7 is in its release position. In this case, the free end of the actuating lever 7 is aligned approximately horizontally.
  • the cams 17 of the operating lever 7 are located in this position in the rear upper portion of the recesses 16 of the heel holder 4. Since this rear upper portion of the recesses 16 falls backwards, prevent the cam 17, the heel holder 4 on a rotational movement about the axis 13 to the front , Next lie in the release position of the heel holder 4, the webs 28 of the heel holder 4 at a rear end of the surfaces 27 of the actuating lever 7 at.
  • the axis 13 is in the release position of the heel holder 4 in the upper vertical portion of the slot 14.
  • the pawl 23 is rotated about the axis 22 upwards and the piston 21 is in a rear upper position.
  • the spring 20 is compressed the most in comparison to the other positions of the heel holder 4 in the release position.
  • the lower slope of the connecting web 18 of the heel holder 4 at the top of the nose 15 of the heel holder support 3 can be seen in FIG. 5a , This is the heel holder 4 prevented from rotating about the axis 13 to the rear.
  • the covers 29 in the release position of the heel holder 4 cover the slot 14. Since the covers 29 are connected to the axle 13, they are moved with the heel holder 4 upwards when the heel holder 4 is moved from its walking position or from its holding position to its release position.
  • the automatic heel unit 1 is adjustable both with the operating lever 7 as well as the ski boot from the release configuration into the holding configuration.
  • the heel holder 4 is first lifted slightly with the axis 13 against the bias to its release position up and slightly pivoted about the axis 13 forward until the connecting web 18 of the heel holder 4 with its vertical portion at the front of the nose 15 of Heel holder carrier 3 is present.
  • the heel holder 4 is then located in the adjoining the first region of the adjustment portion of the second region of the adjustment and is biased to its holding position.
  • the free end of the actuating lever 7 is moved about the axis 26 upwards.
  • the actuating lever 7 presses with the surfaces 27 on the webs 28 of the heel holder 4 and thereby pivots the heel holder 4 first about the axis 13 forward and then moves the heel holder 4 down.
  • the axis 13 of the heel holder 4 thereby moves first slightly in the slot 14 upwards and then from top to bottom along the vertical portion of the slot 14. If a ski boot is inserted into the heel unit 1, the forward pivoting of the heel holder 4 to the Axis 13 of the heel holder 4 is guided from above on the heel area of the ski boot.
  • the heel region of the ski boot is inserted into the heel holder 4 so that the hold-down structure 5 and the heel support structure 6 of the heel support 4 can cooperate with the heel region of the ski boot.
  • the front portion of the heel holder 4 is down pressed.
  • the heel holder 4 is first pivoted forward with its upper portion until the entire heel holder 4 can be moved down to its holding position.
  • the upper region of the recess 16 presses on the cams 17 of the actuating lever 7, so that the actuating lever 7 is moved about the axis 26 from the release position to the holding position.
  • the heel holder carrier 3 is biased relative to the base plate 2 with a spring force to the front and can be moved against this spring force to the rear.
  • This makes it possible to compensate for changes in distance between a front automaton and the automatic heel unit 1, which can occur when a ski deflects.
  • a jamming of the ski boot between front and heel machine 1 is prevented when the rear and the front end of the ski are bent upwards. Accordingly, a reliable safety release is thereby made possible with the automatic heel unit 1 in all driving situations.
  • the mechanism with the spring for generating the bias of the heel holder support 3 forward is disposed below the slot 14 of the heel holder support 3 in the base plate 2.
  • FIGS. 6, 7 , and 8a each show a side view of a vertically oriented, running in the ski longitudinal section through the automatic heel unit 1 in the walking configuration and by the ski brake 8 in the driving position, the section in the ski direction seen runs centrally through the heel unit 1.
  • heel counter 1 When in FIG. 6 shown heel counter 1 is the operating lever 7 in its first walking position.
  • a first climbing aid in the form of an elongate climbing aid lever 30 is visible.
  • the latter is mounted rotatably about an axis 31 on the heel holder carrier 3.
  • the axis 31 is located in an upper region of the heel holder support 3 and seen in the ski longitudinal direction in front of the actuating lever 7.
  • the climbing aid lever 30 has a tread surface in the front region of its free end. In the housing configuration of the heel unit 1, the climbing aid lever 30 may have its free end as in FIG FIG. 7 be shown swung forward.
  • the tread surface of the climbing aid lever 30 is pivoted into the path of movement of the ski boot released by the heel holder 4, so that the heel area of the ski boot held in the front automatic machine is supported by the climbing aid lever 30 during a movement toward the ski and is prevented from moving further towards the ski.
  • the operating lever 7 can be used as a climbing aid.
  • the operating lever 7 with its free end as in the FIGS. 8a and 8b shown forward in the path of movement of the heel holder 4 released ski boot are pivoted to its second walking position.
  • the heel area of the ski boot held in the front automatic machine is supported by the actuating lever 7 during a movement toward the ski and is prevented from moving further toward the ski. Since the actuating lever 7 is located further up there than the climbing aid lever 30, the actuating lever 7 supports the ski boot further away from the ski than the climbing aid lever 30. He thus forms a higher riser than the climbing lever 30th
  • the climbing aid lever 30 rests with its upper side on an underside of the actuating lever 7. If the operating lever 7 is moved from its triggering position to its first walking position, the actuating lever 7 guides the climbing aid lever 30 so that in the first walking position of the actuating lever 7 the free end of the actuating lever 7 as well as the free end of the climbing aid lever 30 point vertically upwards. The climbing aid lever 30 rests with its upper side on the underside of the actuating lever 7. He is thus in a deactivated position.
  • FIG. 8b shows how FIG. 8a the heel unit in the walking configuration with the operating lever 7 in the second walking position.
  • the cam 17 of the actuating lever 7 is located in the second walking position of the actuating lever 7 at the lower region of the recess 16 of the heel holder 4.
  • the cam 17 of the actuating lever 7 thus moves from the front, rounded tip of the recess 16 of the The heel holder 4 is thereby not adjusted, but the heel holder 4 is held in the second walking position of the operating lever 7 by the cam 17 of the operating lever 7 down and on a rotational movement and a movement prevented upwards.
  • the invention is not limited to the automatic heel unit 1 described above.
  • the heel box it is not necessary for the heel box to include a base plate as described above.
  • the heel holder carrier is mounted directly on a possibly existing base plate.
  • the heel holder carrier for use in a touring ski binding of the first type mentioned above, the heel holder carrier, for example, as in the WO 96/23559 A1 (Fritschi AG Apparatebau) described be arranged on the sole support, which is pivotable in its front region about a horizontally oriented in the transverse direction axis.
  • an heel automat according to the invention can also be used for other ski bindings such as, for example, downhill bindings.
  • the heel holder support is biased forward relative to the base plate.
  • the heel machine can also be designed to be easily displaceable relative to the base plate in order to be able to adapt a distance between the front automatic machine and the heel counter to a size of a ski boot to be held.
  • the heel holder carrier is fixedly mounted on the base plate, wherein the heel holder carrier and the base plate can also be integrally formed as an element.
  • the invention may otherwise be carried out deviating from the heel machine 1 described above.
  • the first and the second region of the adjustment path can run differently than in a plane oriented vertically in the longitudinal direction of the ski.
  • the first region of the adjustment path can also comprise non-linear partial regions.
  • the first range of the adjustment does not necessarily include a vertical component. In this case, the first range of the adjustment leads horizontally to the rear.
  • the first range of the adjustment path comprises a vertical component, but the heel holder is not lower in its position than in its holding position. So there is also the possibility that the heel holder is in its walking position further up than in its holding position, as long as the heel holder is in its position further back than in its holding position.
  • the heel machine may have a different holding device than the described heel holder.
  • the heel support structure need not necessarily be formed separately from the hold-down structure.
  • the holding device does not comprise a hold-down structure for holding down the heel area of the ski boot or no heel support structure for supporting the heel area of the ski boot in a direction horizontal transverse to the ski.
  • a different elastic element than the spring 20 can be used in the heel unit.
  • the power transmission from the elastic element to the heel holder can be configured differently than via a pawl.
  • the storage of the heel holder on the heel holder carrier can be designed differently.
  • the heel holder may be mounted instead of four bearings, for example, only a bearing point on the heel holder carrier.
  • the heel counter does not necessarily have to have a heel-holder guide device
  • the heel-to-toe automaton does not necessarily have to have an actuating lever guide device.
  • the actuating lever does not necessarily have to be rotatably mounted on the heel holder carrier.
  • ski brake is not arranged on the base plate, but on the heel holder carrier or else on an element of the heel counter.
  • the heel machine is formed without a ski brake.
  • an heel strap which has a walking configuration in which the automatic heel unit assumes a compact shape.

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  • Footwear And Its Accessory, Manufacturing Method And Apparatuses (AREA)
EP16152428.5A 2016-01-22 2016-01-22 Talonniere ayant une configuration de marche Active EP3195906B1 (fr)

Priority Applications (2)

Application Number Priority Date Filing Date Title
EP16152428.5A EP3195906B1 (fr) 2016-01-22 2016-01-22 Talonniere ayant une configuration de marche
US15/411,578 US9901806B2 (en) 2016-01-22 2017-01-20 Automatic heel unit with walking configuration

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP16152428.5A EP3195906B1 (fr) 2016-01-22 2016-01-22 Talonniere ayant une configuration de marche

Publications (2)

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EP3195906A1 true EP3195906A1 (fr) 2017-07-26
EP3195906B1 EP3195906B1 (fr) 2018-12-26

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EP (1) EP3195906B1 (fr)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3714952A1 (fr) * 2019-03-29 2020-09-30 MARKER Deutschland GmbH Dispositif de freinage
EP3851174A1 (fr) 2020-01-16 2021-07-21 Fritschi AG - Swiss Bindings Butée avant pour une fixation de ski
EP4173682A1 (fr) 2021-10-28 2023-05-03 Fritschi AG - Swiss Bindings Fixation de ski, en particulier fixation de ski de randonnée

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102016006850A1 (de) * 2016-02-17 2017-08-31 Reinhold Zoor Schischuhalter mit schwenkbarem Trittsporn
US11484774B2 (en) * 2020-01-09 2022-11-01 Salewa Sport Ag Heel unit with climbing aid for an alpine touring binding

Citations (11)

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DE2900239A1 (de) * 1978-01-05 1979-07-12 Tmc Corp Sicherheitsskibindung
US4428597A (en) * 1980-11-07 1984-01-31 Tmc Corporation Heel holder for a safety ski binding
WO1996023559A1 (fr) 1995-02-01 1996-08-08 Fritschi Ag Apparatebau Fixation de ski
DE102004040788A1 (de) * 2004-08-23 2005-11-03 Rottefella A/S Fersenabstützvorrichtung für einen Langlauf-Skischuh
WO2009105866A1 (fr) 2008-02-29 2009-09-03 G3 Genuine Guide Gear Inc. Unité talon pour fixation de randonnée en montagne
EP2656884A1 (fr) * 2012-04-25 2013-10-30 MARKER Deutschland GmbH Fixation de ski légère avec une sécurité de déchaussement accrue
DE102012208915A1 (de) * 2012-05-25 2013-11-28 Salewa Sport Ag Ferseneinheit mit Steighilfe und Bremsanordnung
CH706664A1 (de) 2012-06-15 2013-12-31 Fritschi Ag Swiss Bindings Skibindung.
EP2762211A2 (fr) * 2013-02-01 2014-08-06 MARKER Deutschland GmbH Talonnière dotée d'un chariot, d'un déclenchement transversal et d'un levier auxiliaire
EP2762209A2 (fr) 2013-02-01 2014-08-06 MARKER Deutschland GmbH Talonnière avec levier auxiliaire
DE102014004874A1 (de) 2014-04-04 2015-10-08 Reinhold Zoor Fersenautomat mit intregrierter Steighilfe

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Publication number Priority date Publication date Assignee Title
US6382641B2 (en) * 1998-05-19 2002-05-07 K-2 Corporation Snowboard binding system with automatic forward lean support

Patent Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE2900239A1 (de) * 1978-01-05 1979-07-12 Tmc Corp Sicherheitsskibindung
US4428597A (en) * 1980-11-07 1984-01-31 Tmc Corporation Heel holder for a safety ski binding
WO1996023559A1 (fr) 1995-02-01 1996-08-08 Fritschi Ag Apparatebau Fixation de ski
DE102004040788A1 (de) * 2004-08-23 2005-11-03 Rottefella A/S Fersenabstützvorrichtung für einen Langlauf-Skischuh
WO2009105866A1 (fr) 2008-02-29 2009-09-03 G3 Genuine Guide Gear Inc. Unité talon pour fixation de randonnée en montagne
EP2656884A1 (fr) * 2012-04-25 2013-10-30 MARKER Deutschland GmbH Fixation de ski légère avec une sécurité de déchaussement accrue
DE102012208915A1 (de) * 2012-05-25 2013-11-28 Salewa Sport Ag Ferseneinheit mit Steighilfe und Bremsanordnung
CH706664A1 (de) 2012-06-15 2013-12-31 Fritschi Ag Swiss Bindings Skibindung.
EP2762211A2 (fr) * 2013-02-01 2014-08-06 MARKER Deutschland GmbH Talonnière dotée d'un chariot, d'un déclenchement transversal et d'un levier auxiliaire
EP2762209A2 (fr) 2013-02-01 2014-08-06 MARKER Deutschland GmbH Talonnière avec levier auxiliaire
DE102014004874A1 (de) 2014-04-04 2015-10-08 Reinhold Zoor Fersenautomat mit intregrierter Steighilfe

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3714952A1 (fr) * 2019-03-29 2020-09-30 MARKER Deutschland GmbH Dispositif de freinage
EP3851174A1 (fr) 2020-01-16 2021-07-21 Fritschi AG - Swiss Bindings Butée avant pour une fixation de ski
EP4173682A1 (fr) 2021-10-28 2023-05-03 Fritschi AG - Swiss Bindings Fixation de ski, en particulier fixation de ski de randonnée

Also Published As

Publication number Publication date
EP3195906B1 (fr) 2018-12-26
US20170209769A1 (en) 2017-07-27
US9901806B2 (en) 2018-02-27

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