EP4032592A1 - Skibinding with a housing screwed in horizontal direction - Google Patents

Abstract

The present invention relates to a gliding board binding (10) for holding a shoe on a gliding board, the gliding board binding (10) having a binding body (20) which is designed to engage with the shoe, the binding body (20) having a housing (24 ) having at least two interconnected housing parts (26, 28) which are set up to receive between them a functional mechanism (30) of the gliding board binding, the two housing parts (26, 28) being connected by at least one connection arrangement (40, 42; 44, 46) are connected to each other, which comprises at least one first screw or pin connection (44, 46), one (26) of the two housing parts (26, 28) being an upper housing part (26) and the other (28) of the two housing parts (28, 26) is a lower housing part (28), the upper housing part (26) having a first section (50) which extends substantially parallel to a plane of the gliding board, and a second A section (52) extending substantially perpendicular to the plane of the gliding board, wherein at least one attachment point (44) for the first screw or pin connection (44, 46) is provided on the second section (52) of the upper housing part (26). , and wherein a mounting direction (X) of the first screw or pin connection (44, 46) is substantially parallel to the plane of the gliding board.

Description

The present invention relates to a gliding board binding for holding a shoe on a gliding board, the gliding board binding having a binding body which is set up for engagement with the shoe, the binding body having a housing with at least two housing parts connected to one another which are set up to take up a functional mechanism of the gliding board binding, the two housing parts being connected to one another by at least one connection arrangement which comprises at least a first screw or pin connection, one of the two housing parts being an upper housing part and the other of the two housing parts being a lower housing part.

A gliding board binding of this type is, for example, as a heel unit of a touring binding from the DE 10 2013 224 571 A1 known. The conventional heel assembly includes a housing having a lower housing and an upper housing formed as a cover. The housing cavity created therebetween houses a release mechanism which disengages the heel unit from the shoe when a force greater than a predetermined release force is applied to the heel unit through the shoe. The upper housing part is connected to the lower housing part by four screws, each with mounting directions running perpendicularly with respect to a plane of the gliding board.

In practical use of the known heel unit, it has been found that after a longer period of use of the heel unit, the screws connecting the two housing parts to one another sometimes loosen can occur, so that they have to be tightened regularly or, if necessary, wear of the thread can occur, which requires replacement of the housing. Such wear of the heel unit has been particularly noted when the heel unit was frequently used in a touring position in which two heel lifts attached to the upper housing part can be switched on to provide increased lower support of the heel section of the shoe, on which the shoe rests with each step down from above. With each step, there is a certain impact load on the upper housing part via one of the climbing aids, and thus the screw connection between the two housing parts is stressed.

Another strong load on the screws connecting the housing parts occurs in the case of a frontal release, also known as My release, in which a so-called FAV force acts upwards in a direction perpendicular to the plane of the gliding board. The heel section of the shoe, for example when a user falls forward, presses from below against coupling pins of the known heel unit in order to move them apart, and a force directed upwards from the plane of the gliding board acts on the upper housing part via the coupling pins. This puts a lot of strain on the screw connection, since one direction of the acting force corresponds approximately to the assembly direction of the screw connection, i.e. the direction of a screw axis. Such an axial load is unfavorable for screw connections.

Also with other heel units, for example heel units for downhill bindings, the connection between two housing parts of a housing can be subjected to repeated heavy loads during use.

Against this background, it is an object of the present invention to provide a gliding board binding, which wear in the area Can reduce connection between two housing parts of the housing and can absorb shock, triggering and / or other loads better and is still as inexpensive to produce.

The object on which the present invention is based is achieved by a gliding board binding for holding a shoe on a gliding board, the gliding board binding having a binding body which is designed to engage with the shoe, the binding body having a housing with at least two housing parts connected to one another, which are set up to receive a functional mechanism of the gliding board binding between them, the two housing parts being connected to one another by at least one connection arrangement which comprises at least a first screw or pin connection, one of the two housing parts being an upper housing part and the other of the two housing parts being a lower housing part, wherein the upper housing part comprises a first section which extends substantially parallel to a plane of the gliding board, and a second section which extends substantially perpendicular to the plane of the gliding board stretches, wherein at least one attachment point for the first screw or pin connection is provided on the second portion of the upper housing part, and wherein a mounting direction of the first screw or pin connection is substantially parallel to the plane of the gliding board.

According to an important feature of the present invention, the two housing parts are thus connected to one another by at least one first screw or pin connection with a horizontal assembly direction. The binding body of the gliding board binding is thus able to permanently absorb larger forces, in particular frontal release forces in the case of a so-called My release (torque about a Y-axis defined later) in the vertical direction and better transfer them to the housing parts. The connection arrangement thus created enables a structurally simple connection between the two housing parts that can be detached if necessary and is permanently wear-resistant, even after a long period of intensive use.

In other words, frontal deployment forces occurring during a My deployment, acting in a direction essentially perpendicular to the plane of the gliding board, also known as FAV forces, can be advantageously absorbed via the first screw or pin connection or introduced into the housing parts if these are essentially parallel to the having a mounting direction running in a sliding board plane. Thus, the durability of the gliding board binding can be further improved.

The mounting direction corresponds to an axial direction of a screw or pin axis. The screw or pin connection can have screws and/or pins or bolts, such as dowel pins, in particular knurled bolts.

At this point it is pointed out that terms such as "top", "bottom", "front", "rear", "sideways", "vertical", "horizontal", "vertical direction", "transverse direction" can be used within the scope of this disclosure. , "width direction", "longitudinal direction" and the like refer to the view of a user who has stepped with a shoe into the gliding board binding mounted on a gliding board with the gliding board arranged in a horizontal plane for ease of illustration.

Furthermore, it is pointed out that the term "gliding board" refers to any gliding board, such as skis, touring skis, snowboards, splitboards (snowboards that can be divided longitudinally into at least two parts, the individual parts of which can be used in the manner of normal skis), snowshoes or similar boards for walking or gliding on snow and ice. All of these items or parts thereof are considered to be gliding boards or parts of gliding boards within the meaning of this invention.

In an advantageous embodiment of the present invention, the connection arrangement can further comprise at least one second screw or pin connection, wherein an assembly direction of the second screw or pin connection differs, preferably by approximately 90 degrees, from the assembly direction of the first screw or pin connection. That is, the two housing parts can be connected to one another by at least two screw or pin connections with different assembly directions. The binding body of the gliding board binding is thus able to permanently absorb forces acting in different directions, such as lateral release forces (Mz release) via the second screw or pin connection and frontal release forces (My release) via the first screw or pin connection and better into the housing parts.

At least one attachment point for the second screw or pin connection can be provided on the first section of the upper housing part. In addition to the at least one attachment point on the second section of the upper housing part, which extends parallel to the plane of the gliding board, an additional attachment point can be provided on another section of the upper housing part, which extends in a different direction, to absorb forces acting in different directions. The stability of the arrangement can be further improved in this way. The upper housing part can in particular be a sheet metal part, preferably a bent sheet metal part.

The mounting direction of the second screw or pin connection can preferably be essentially perpendicular to a plane of the gliding board. With such an arrangement, lateral release forces occurring in a direction essentially parallel to the plane of the gliding board and/or impacts from the side can be advantageously absorbed via the second screw or pin connection or in the housing parts are introduced if they have an assembly direction running essentially perpendicularly to a plane of the gliding board.

In particular, the first screw or pin connection can have two screws or pins, the axes of which run essentially parallel to one another. Screws are easy to assemble and disassemble and also inexpensive. By using two screws with parallel screw axes, the strength of the connection between the housing parts can be improved, especially in the direction perpendicular to the screw axes.

The second screw or pin connection can also have two screws or pins, the axes of which run essentially parallel to one another. Screws are easy to assemble and disassemble and also inexpensive. By using two screws with parallel screw axes, the strength of the connection between the housing parts can be improved, especially in the direction perpendicular to the screw axes.

It is also considered particularly advantageous if the first screw or pin connection is a screw connection and has at least one screw which is passed through an opening in one of the two housing parts and is screwed into an opening in the other of the two housing parts. Such a screw connection can be implemented in a structurally simple and cost-effective manner and can be detached using a tool if necessary, for example for repairing or maintaining the functional mechanism accommodated in the housing.

In addition, the second screw or pin connection can preferably also be a screw connection and have at least one screw which is passed through an opening in one of the two housing parts and is screwed into an opening in the other of the two housing parts. As even if the first screw or pin connection is a screw connection, a screw connection for the second screw or pin connection can also be implemented in a structurally simple and cost-effective manner and can be detached using a tool if necessary.

Preferably, the second section of the upper housing may comprise two arms which extend downwardly from the first section of the upper housing, in particular at an angle of approximately 90 degrees with respect to the first section of the upper housing, in the direction of a sliding board plane, the the first screw or pin connection comprises two screws or pins and wherein a fastening point for a screw or a pin is provided at the distal ends of the two arms of the second section of the upper housing part. If the second section of the upper housing part comprises two arms, other components can be arranged between the arms, for example, to save space. In addition, two spaced-apart attachment points can be created by two arms, as a result of which the stability of the arrangement can be increased in a weight-saving manner.

It has proven particularly advantageous if one of the two housing parts is made from a metal material and/or the other of the two housing parts is made from a plastic material. A combination of a metal material and a plastic material results in a combination of weight and cost savings (plastic) on the one hand and stability (metal) on the other. It is envisaged that one housing part, in particular the lower housing part, is made of a plastic such as polyoxymethylene (POM) or glass fiber reinforced polyamide (PA-GF) and the other housing part, in particular the upper housing part, is made of steel, aluminum, titanium or Alloys thereof is made. In particular, a sheet metal material is considered.

The functional mechanism housed in the housing of the gliding board binding can basically be any mechanism of the gliding board binding that allows the gliding board binding to be adjusted to different operating states or otherwise ensures the intended function of the gliding board binding. For example, a release mechanism can be accommodated in the housing, which moves the binding body into a position for releasing the engagement with the shoe when a force is exerted on the binding body which exceeds a predetermined release force. Such a triggering mechanism can be part of a safety system which releases the shoe in the event of a fall and in this way prevents uncontrolled twisting or tilting of the gliding board from leading to dangerous overloading or even injury to the user. Alternatively or additionally, however, the functional mechanism can also be a mechanism for adjusting the gliding board binding between different functional modes.

In a further preferred embodiment of the present invention, the binding body can also comprise a housing cover which is attached to the upper housing part, the housing cover having at least one positive connection. In this case, the upper case may be interposed between the lower case and the case cover and act as a reinforcing member. In particular, the upper housing part can be in the form of a reinforcement plate. In this way, the stability of the arrangement can be further improved. Forces and/or impacts occurring during the use of the gliding board binding, which would stress the screw or pin connections along their force directions, can also be largely introduced into the positive connection, so that excessive stress and thus premature wear of the screw or pin connections are avoided can be.

The positive connection can comprise at least one projection which is provided on the housing cover and which engages with at least one depression which is provided on the first and/or the second housing part. With a projection and a depression of this type, the form-fitting connection can be realized with structurally simple means and low component costs.

In particular, the gliding board binding can be set up as a heel unit for a touring binding and can be adjusted between a touring position in which the heel unit releases the shoe and a downhill position in which the heel unit holds the shoe in place. One or two climbing aids can be provided on one of the two housing parts, so that when the shoe is placed on one of the climbing aids, a force acts on the housing part with every step. The wear-reducing connection arrangement of the present invention can then be used particularly effectively to reliably absorb the repeated impact loads. Due to the greater height of the climbing aid and the corresponding leverage effect when pressure or shock loads are exerted on the climbing aid, special demands are placed on the connection between the two housing parts, so that the advantages of the invention can be used particularly effectively here.

In addition, the binding body can have two coupling pins running at a distance essentially parallel to one another, which, at least in a downhill position of the gliding board binding, protrude from the binding body in a direction essentially parallel to a longitudinal axis of the gliding board and are designed to engage with a heel section of a shoe. If a second section of an upper housing part comprises two arms which extend downwards from a first section of the upper housing part in the direction of a gliding board plane, the coupling pins can be arranged in particular between the two arms of the upper housing part. One Heel unit with coupling pins designed in this way can be used with a large number of suitable touring shoes and has a secure holding engagement with the shoe as well as a reliable release behavior.

As already stated, the present invention provides a connection arrangement between two housing parts of a gliding board binding which has increased strength and reduced wear. As a result, the present invention also allows for the use of lighter and inherently weaker materials while maintaining acceptable strength and wear resistance properties.

Figur 1a

eine perspektivische Ansicht einer Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 1b

eine perspektivische Ansicht eines oberen Gehäuseteils der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 2a

eine Vorderansicht der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 2b

eine Vorderansicht des oberen Gehäuseteils der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 3a

eine Seitenansicht der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 3b

eine Seitenansicht des oberen Gehäuseteils der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 4a

eine Draufsicht der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

Figur 4b

eine Draufsicht des oberen Gehäuseteils der Gleitbrettbindung gemäß der bevorzugten Ausführungsform der vorliegenden Erfindung.

The invention is explained in more detail below on the basis of a preferred embodiment of the present invention with reference to the attached drawings. Show in detail:

Figure 1a

Figure 14 is a perspective view of a gliding board binding in accordance with the preferred embodiment of the present invention.

Figure 1b

Figure 12 is a perspective view of an upper housing of the gliding board binding in accordance with the preferred embodiment of the present invention.

Figure 2a

Figure 12 is a front view of the gliding board binding according to the preferred embodiment of the present invention.

Figure 2b

Figure 12 is a front view of the upper housing of the gliding board binding in accordance with the preferred embodiment of the present invention.

Figure 3a

Figure 12 is a side view of the gliding board binding in accordance with the preferred embodiment of the present invention.

Figure 3b

Figure 12 is a side view of the upper housing of the gliding board binding in accordance with the preferred embodiment of the present invention.

Figure 4a

Figure 12 is a plan view of the gliding board binding in accordance with the preferred embodiment of the present invention.

Figure 4b

Figure 12 is a plan view of the upper housing of the gliding board binding in accordance with the preferred embodiment of the present invention.

As an example of a gliding board binding according to the present invention is in the Figures 1a , 2a , 3a and 4a a heel unit of a touring binding is shown adapted to engage and retain a heel portion of a touring boot (not shown) at two docking pins 12 . The heel unit 10 can be mounted on a gliding board, for example a touring ski, via a non-illustrated base, for example using screws. A binding body 20 is carried on the base, to which are attached the coupling pins 12 which hold the boot in a downhill position. Furthermore, a first 14 and a second 16 climbing aid can be arranged on the binding body 20, which can support the shoe from below in the touring position of the heel unit 10 at two different heights above the gliding board. The climbing aids 14, 16 can in particular be attached to the binding body 20 so as to be pivotable about a common axis and can be adjusted between active and passive positions by simply pivoting about the axis.

A gliding board plane runs along a surface of the gliding board and a gliding board longitudinal axis runs in the direction of travel of the gliding board. So is a next Figure 1a outlined coordinate system of the heel unit 10 is defined, in which an X-direction runs in the direction of the longitudinal axis of the gliding board, a Z-direction runs orthogonally to the gliding board plane upwards and a Y-direction runs orthogonally to the Z-direction and to the X-direction.

The binding body 20 includes a housing 24 which is composed of an upper housing part 26 and a lower housing part 28, the two housing parts 26, 28 receiving between them a release mechanism 30 which disengages the engagement between the heel unit 10 and the shoe when on a force exceeding a predetermined triggering force is exerted on the heel unit 10, in particular by twisting or tilting the shoe during a fall. The triggering mechanism may be a My (torque about the Y-axis) triggering mechanism which includes a spring arrangement which maintains the docking pins 12 in engagement with the shoe but which can be overcome upon application of a force in excess of the predetermined FAV triggering force to spread the coupling pins 12 apart and release the shoe upwards, i.e. in a direction of distance from the gliding board. The upper housing part 26 can be made of a metal material and in the present exemplary embodiment can in particular be in the form of a bent sheet metal part. The lower housing portion 28 may be made of a plastic material.

Furthermore, a vertical rotary bearing can be provided, on which the binding body 20 is rotatably mounted about a vertical axis of rotation running orthogonally to the plane of the gliding board. Such a rotation of the binding body 20 can on the one hand serve as an Mz release mechanism (torque about the Z axis) in order to release the shoe from the heel unit 10 in the event of a fall, if one of the shoes has a force exceeding a predetermined Mz release force is transmitted to the coupling pins 12 in a direction lateral to the longitudinal axis L of the sliding board (Y-direction). After the force of an Mz release spring has been overcome, the binding body 20 can then rotate sideways about the vertical axis of rotation, so that the coupling pins 12 are released from the shoe.

On the other hand, the rotation of the binding body 20 about the vertical axis of rotation can be used to manually adjust the heel unit 10, namely between a downhill position, in which the coupling pins 12 point forward and can hold a shoe, and a touring position, in which the coupling pins 12 do not face forward but release the heel portion of the shoe so that it can lift upwards with each step for walking. In such a touring position, the shoe is generally mounted pivotably on a front unit (not shown) about a pivot axis running in the Y-direction.

Both My and Mz release mechanisms can be adjustable by compressing respective My and Mz release springs to a greater or lesser extent in order to adapt to different user weights and sole lengths.

The two housing parts 26, 28 are connected by at least one connection arrangement 40, 42; 44, 46 connected to one another, which comprises at least one first screw or pin connection 44, 46. A mounting direction X of the first screw or pin connection 44, 46 runs essentially parallel to the plane of the gliding board, as in FIGS figures 3b and 4b you can see. As a result, FAV forces occurring when My is triggered can be absorbed by the first screw or pin connection 44, 46 in a particularly advantageous manner.

In the preferred embodiment of the present invention, the first screw or 44, 46 is a screw connection 44, 46 and has at least one screw 46 which passes through an opening 44 of one 26 of the two housing parts 26, 28 and into an opening of the other 28 of the two housing parts 28, 26 is screwed. In addition, the first screw or pin connection 44, 46 has two screws 46 or pins, the axes of which run essentially parallel to one another.

The upper housing part 26 is in the figures 1b , 2 B , 3b and 4b shown and is formed in the present embodiment as a bent sheet metal part.

The connection assembly 40, 42; 44, 46 can also include at least one second screw or pin connection 40, 42, the mounting direction Z of which is preferably about 90 degrees different from the mounting direction X of the first screw or pin connection 44, 46. In the illustrated embodiment, the mounting direction Z runs the second Screw or pin connection 40, 42 substantially perpendicular to a plane of the gliding board, as in Figure 3b can be seen. In the exemplary embodiment, the second screw or pin connection 40, 42 is a screw connection 40, 42 and has at least one screw 42 which is passed through an opening 40 in the upper housing part 26 and is screwed into an opening in the lower housing part 28. In addition, in the exemplary embodiment, the second screw or pin connection 40, 42 has two screws 42 or pins, the axes of which run essentially parallel to one another.

How particularly in the figures 1b and 3b As can be seen, the upper housing part 26 comprises a first section 50, which extends essentially parallel to a plane of the gliding board, and a second section 52, which extends essentially perpendicular to the plane of the gliding board. There is at least one attachment point in the form of a through hole 44 for the first screw or pin connection 44, 46 on the second Section 52 of upper housing part 26 is provided. In addition, at least one attachment point in the form of a through hole 40 for the second screw or pin connection 40, 42 can be provided on the first section 50 of the upper housing part 26.

In the preferred embodiment of the present invention, the second section 52 of the upper housing part 26 includes two arms 54 which extend perpendicularly downwardly from the first section 50 in the direction of the plane of the gliding board. The first screw or pin connection 44, 46 can comprise two screws 46 or pins, with a screw 46 or pin attachment point 44 being provided at the distal ends of the two arms 54 of the second section 52 of the upper housing part 26, respectively.

As in the Figures 1a and 2a As can be seen, the coupling pins 12 can be arranged in the Y-direction between the two arms 54 of the upper housing part 26 .

In the preferred exemplary embodiment, the binding body 20 can also include a housing cover 60, which can be fastened to the binding body 20, in particular the upper housing part 26, for example by means of the second screw or pin connection 40, 42. However, another connection such as a plug connection is also possible. The housing cover 60 can have at least one form-fitting connection 62, 64. The positive connection can include a projection 62 which engages in a fitting recess 64 which can be formed on one of the two housing parts 26 , 28 , in particular on the upper housing part 26 . In the specific exemplary embodiment, a projection 62 is provided on both sides of the housing cover 60 in the Y direction. In a downhill position of the heel unit 10, these protrude downwards in the Z direction from the housing cover 60 and can thus absorb loads, such as impacts in the Y direction or forces acting in the Y direction during an Mz deployment, in a structurally advantageous manner.

Claims (15)

Gliding board binding (10) for holding a shoe on a gliding board, wherein the gliding board binding (10) has a binding body (20) which is designed to engage with the shoe, wherein the binding body (20) has a housing (24) with at least two interconnected housing parts (26, 28) which are set up to accommodate a functional mechanism (30) of the gliding board binding between them, wherein the two housing parts (26, 28) are connected to one another by at least one connection arrangement (40, 42; 44, 46) which comprises at least a first screw or pin connection (44, 46), and wherein one (26) of the two housing parts (26, 28) is an upper housing part (26) and the other (28) of the two housing parts (28, 26) is a lower housing part (28), characterized in that the upper housing part (26) comprises a first section (50) which extends essentially parallel to a plane of the gliding board and a second section (52) which extends essentially perpendicular to the plane of the gliding board, at least one attachment point (44) for the first screw or pin connection (44, 46) being provided on the second section (52) of the upper housing part (26), and wherein an assembly direction (X) of the first screw or pin connection (44, 46) is essentially parallel to the plane of the gliding board. Gliding board binding (10) according to Claim 1, characterized in that the connection arrangement (40, 42; 44, 46) further comprises at least one second screw or pin connection (40, 42), wherein a mounting direction (Z) of the second screw or pin connection (40, 42) is different, preferably about 90 degrees different, from the mounting direction (X) of the first screw or pin connection (44, 46). A gliding board binding (10) according to claim 2, characterized in that at least one attachment point (40) for the second screw or pin connection (40, 42) is provided on the first portion (50) of the upper housing part (26). Gliding board binding (10) according to Claim 2 or 3, characterized in that the assembly direction (Z) of the second screw or pin connection (40, 42) is essentially perpendicular to a gliding board plane. Gliding board binding (10) according to one of the preceding claims,
characterized in that the first screw or pin connection (44, 46) comprises two screws (46) or pins whose axes are substantially parallel to one another. Gliding board binding (10) according to one of Claims 2 to 5, characterized in that the second screw or pin connection (40, 42) has two screws (42) or pins, the axes of which run essentially parallel to one another. Gliding board binding (10) according to one of the preceding claims,
characterized in that the first screw connection (44, 46) is a screw connection (44, 46) and has at least one screw (46) which passes through an opening (44) in one (26) of the two housing parts (26, 28) is passed through and is screwed into an opening of the other (28) of the two housing parts (28, 26). Gliding board binding (10) according to one of Claims 2 to 7, characterized in that the second screw or pin connection (40, 42) is a screw connection (40, 42) and has at least one screw (42) which can be screwed through an opening (40 ) one (26) of the two housing parts (26, 28) is passed through and is screwed into an opening of the other (28) of the two housing parts (28, 26). The gliding board binding (10) according to any one of the preceding claims, characterized in that the second section (52) of the upper housing part (26) comprises two arms (54) which extend from the first section (50) of the upper housing part (26), in particular at an angle of approximately 90 degrees with respect to the first portion (50) of the upper housing part (26), extending downwardly towards a plane of the gliding board, the first screw or pin connection (44, 46) comprising two screws (46) or pins and wherein a fastening point (44) for a screw (46) or a pin is provided at the distal ends of the two arms (54) of the second section (52) of the upper housing part (26). Gliding board binding (10) according to one of the preceding claims, characterized in that one (26) of the two housing parts (26, 28) is made of a metal material and/or the other (28) of the two housing parts (28, 26) is made of a plastic material is made. Gliding board binding (10) according to one of the preceding claims, characterized in that a release mechanism (30) is housed in the housing (26) which moves the binding body (20) into a position for releasing the engagement with the shoe when a force is applied the binding body (20) is exerted, which exceeds a predetermined release force. Gliding board binding (10) according to one of the preceding claims, characterized in that the binding body (20) further comprises a housing cover (60) which is attached to the upper housing part (26), the housing cover (60) having at least one positive connection (62 , 64). Gliding board binding (10) according to Claim 12, characterized in that the at least one positive connection (62, 64) comprises at least one projection (62) which is provided on the housing cover (60) and which engages with at least one depression (64). occurs, which the first and / or the second housing part (26, 28) is provided. Gliding board binding (10) according to one of the preceding claims, characterized in that the gliding board binding (10) is set up as a heel unit (10) for a touring binding and can be adjusted between a touring position, in which the heel unit (10) releases the shoe, and a downhill position , in which the heel unit (10) holds the shoe in place. Gliding board binding (10) according to one of the preceding claims, in particular according to Claim 9, characterized in that the binding body (20) has two coupling pins (12) which run at a distance essentially parallel to one another and which, at least in a downhill position of the gliding board binding (10), protrude from the binding body (20) in a direction essentially parallel to a longitudinal axis of the gliding board and are designed to engage with a heel section of a shoe, in particular wherein the coupling pins (12) are arranged between the two arms (54) of the upper housing part (26).

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