DE102022106275A1 - Heel unit for a gliding board binding with reinforcement plate - Google Patents

Abstract

The present invention relates to a heel unit (10) for a gliding board binding, in particular for a touring binding, wherein the heel unit (10) is to be mounted on a gliding board surface which defines a gliding board plane (E), comprising a binding body (16), two essentially next to each other , on the binding body (16) arranged coupling pins (18) for engaging in recesses of a heel section of a gliding board shoe in order to fix the gliding board shoe on the heel unit (10), wherein the coupling pins (18) in a downhill position of the heel unit (10) in a gliding board longitudinal direction ( x), in particular forwards in a direction of travel, protrude from the binding body (16) and at least one of the coupling pins (18) can be moved relative to the other coupling pin (18) between a downhill position and a My release or entry position, and a Reinforcement element (30) in the form of a reinforcement plate (30) attached to the binding body (16) and extends substantially in a plane substantially orthogonal to the plane (E) of the gliding board, the reinforcement element (30) being set up to at least with a load acting on the coupling pins (18), in particular with a load in one direction (z) load acting on the coupling pins (18) substantially orthogonally to the gliding board plane (E) to form at least one contact portion (34) for contact with at least one of the coupling pins (18).

Description

The present invention relates to a heel unit for a gliding board binding, in particular for a touring binding, wherein the heel unit is to be mounted on a gliding board surface which defines a gliding board plane, comprising a binding body and two coupling pins arranged essentially next to one another on the binding body for engaging in recesses in a heel section of a Gliding board shoe in order to fix the gliding board shoe on the heel unit, the coupling pins protruding from the binding body in a downhill position of the heel unit in a longitudinal direction of the gliding board, in particular in a direction of travel forwards, and at least one of the coupling pins relative to the other coupling pin between a downhill position and a My -Release or boarding position is movable.

In particular, the heel units discussed in the present disclosure are heel units for touring bindings to be mounted on skis or touring skis. However, split boards (snowboards that can be divided longitudinally and whose halves can be used like touring skis) or the like can also be used as a gliding board to which a heel unit according to the present invention can be attached, so that the invention also relates to heel units for bindings of such gliding boards , although in the following, without restricting the subject matter of the invention, reference is mainly made to touring bindings.

Furthermore, it is pointed out that within the scope of this disclosure, terms such as "top", "bottom", "front", "rear", "sideways", "vertical", "horizontal", "vertical direction", "transverse direction", " Width direction”, “longitudinal direction” and the like refer to the view of a user with a shoe stepping into the heel unit mounted on the gliding board with the gliding board arranged in a horizontal plane (the gliding board plane) for ease of illustration.

A heel unit of this type is, for example, from DE 10 2011 079 210 A1 known. In the known heel unit, the coupling pins are mounted on the binding body. If a force is applied to the coupling pins, they are supported directly on the binding body. Such a force can be applied, for example, when driving, when the gliding board is hit by bumps or the like. In addition, when stepping into the heel unit, i.e. when coupling the gliding board shoe, high forces act on the coupling pins, which are guided directly into the binding body. During such a coupling process, the user usually presses on the coupling pins from above with the heel section of the gliding board shoe from a substantially vertical direction, with high forces arising. The coupling pins move away from one another due to a metal insert in the heel of the shoe, which has inclined surfaces on which the coupling pins slide outwards in a transverse direction of the gliding board. This means that a vertical movement of the gliding board shoe is converted into a horizontal movement of the coupling pins, with the binding body having to absorb the forces that arise. Conversely, in the event of a forward fall and the associated My release of the heel unit, a force acts in the opposite direction (from below) on the coupling pins, which in turn is introduced directly into the binding body, since the coupling pins are mounted directly on the binding body.

Due to a relatively small support or contact surface of the coupling pins on the binding body, which is usually made of plastic for reasons of cost and weight, relatively high forces act on the binding body at certain points. These forces act, for example, when stepping into the heel unit, when it is released, in particular a My release, and also when driving itself, since the sole of the shoe is usually not supported, but the gliding board shoe stands up on the coupling pins by means of the inserts in the area of the shoe heel and presses on the docking pins with the full weight of the user, which can be multiplied by hits, jumps or compressions. This often causes wear and/or defects on the binding body in the area where the coupling pins are mounted.

Against this background, the object of the present invention was to further develop a generically known heel unit for a gliding board binding, in particular for a touring binding, in such a way that less wear and/or defects occur, in particular on the binding body in the area where the coupling pins are mounted, and the heel unit is therefore more maintenance-friendly and is less prone to defects.

To solve this problem, the heel unit according to the invention also comprises a reinforcement element in the form of a reinforcement plate, which is arranged on the binding body and extends essentially in a plane essentially orthogonal to the plane of the gliding board, the reinforcement element being set up to act at least on the coupling pins load, in particular in the case of a load acting on the coupling pins in a direction essentially orthogonal to the plane of the gliding board, at least one To form contact portion for contact with at least one of the coupling pins.

An important aspect of the solution according to the invention thus lies in supporting the coupling pins on the reinforcement element when a force acts on the coupling pins, in particular in the direction essentially orthogonal to the plane of the gliding board. As a result, the force acting on the coupling pins can be introduced into the binding body via the reinforcing element and the binding body can be relieved. In this way, wear and tear on the binding body in the area where the coupling pins are mounted can be reduced and the heel unit is easier to maintain and less susceptible to defects.

To provide the at least one contact section, the reinforcement element can particularly preferably comprise at least one recess for the coupling pins, which is set up to form the at least one contact section for contact with at least one of the coupling pins. In particular, two recesses can be provided in the reinforcing element in the form of the reinforcing plate, one for each coupling pin. Recesses in the reinforcement element offer the advantage that the coupling pins can, for example, be accommodated in the respective recess and thus contact sections or support for the coupling pins on several sides or in different directions, for example downwards, upwards and/or to one or both pages, can be provided. Such a configuration can improve the stability of the heel unit and further reduce wear on the binding body.

In a preferred embodiment of the present invention, the heel unit can also comprise a base with a fastening arrangement for fastening to the surface of the gliding board, the binding body being rotatable about a release axis of rotation orthogonal to the plane of the gliding board, in particular for adjusting the heel unit between a downhill position and an Mz release position base is arranged. Due to the possibility of rotating the binding body relative to the base, the heel unit can be adjusted, for example, between the downhill position, in which the coupling pins arranged on the binding body protrude from the binding body in the longitudinal direction of the gliding board, and a walking position, in which the coupling pins do not point forward, in particular by e.g are twisted about 90° or about 180°, and so can no longer engage with the heel portion of the gliding board shoe, whereby the heel portion of the gliding board shoe coupled to a front unit of a touring binding can lift off the heel unit for walking.

In a further preferred embodiment of the present invention, the heel unit can further comprise a My release arrangement, which is set up to bias the at least one of the coupling pins towards its downhill position, and/or an Mz release arrangement, which is set up to close the binding body to bias towards its departure position. In the case of a so-called forward fall, a frontal release can thus be provided, which is also called My release. In a forward fall, a user of the heel unit falls forward, causing a downward force to act on the docking pins through the heel portion of the gliding board shoe. Sloping surfaces on an insert provided in the heel area of the gliding board shoe can be used to move the coupling pins, which are pretensioned towards one another by the My release mechanism, in a plane parallel to the gliding board plane in order to release the gliding board shoe. Additionally or alternatively, in the event of a fall and the shoe twisting sideways, a lateral release can be provided, which is also called Mz release. An Mz release can take place in particular by rotating the binding body in relation to the gliding board or a base attached to the gliding board about a release axis of rotation orthogonal to the plane of the gliding board. If the binding body together with the coupling pins are twisted sufficiently far from the downhill position in the lateral direction by an external force such as lateral impacts or the like, the heel section of the gliding board shoe can be released. In this way, a complete safety release, including frontal and side release, can be provided, which significantly increases the safety for a user of the heel unit.

Mz and My are release torques of gliding board bindings. My is the torque for release when torque is applied about a board transverse axis (Y-axis) when that torque exceeds a My release torque. The movement of the coupling pins relative to each other, which is necessary for triggering My, can take place, for example, against the prestressing force of compression springs arranged in the longitudinal direction of the gliding board, the prestressing force of which is transmitted to the coupling pins via inclined wedge surfaces of wedge elements in order to move them in a direction different from the direction in which the compression springs are arranged. in particular to bias towards each other, i.e. to generate a torque. In particular, but also torsion springs for Generation of the biasing force for the coupling pins possible, which can act directly on the coupling pins, for example. Mz is the torque for release upon rotation of the gliding board shoe in the gliding board binding and My is the torque upon forward lean, such as a forward fall. Accordingly, an Mz safety release ensures that the gliding board shoe is released from the gliding board binding when a torque acts around a Z axis, if this torque exceeds an Mz release torque. The Z-axis runs parallel to a release axis of rotation orthogonal to the plane of the gliding board. The Mz release mechanism is intended to provide such an Mz safety release in as defined a manner as possible.

In addition, the coupling pins can advantageously be set up to move in a direction essentially perpendicular to the longitudinal direction of the gliding board and essentially parallel to the plane of the gliding board or in a direction with a movement component in a direction essentially perpendicular to the longitudinal direction of the gliding board and essentially parallel to the plane of the gliding board and a movement component in a direction essentially perpendicular to the plane of the gliding board, so that a distance between the coupling pins increases. Movement of the docking pins away from each other releases the shoe in the event of a forward fall. An additional movement of the coupling pins away from each other and upwards lengthens a tripping distance and can advantageously prevent false trips due to impacts or the like.

In particular, it is considered that the reinforcement element is arranged in front of the binding body in the direction of travel, i.e. that the reinforcement element points in the direction of a heel of the gliding board shoe. As a result, the reinforcement element can interact directly with the coupling pins, which also protrude forward from the binding body in the direction of the shoe heel, and thus provide the at least one contact section for supporting the coupling pins when a force is applied. As a result, the stability and wear resistance of the heel unit, in particular of the binding body, can be further improved.

The binding body and the reinforcement element can preferably be connected to one another by means of a connection arrangement, the connection arrangement comprising a screw or pin connection, in particular with an assembly direction of the screw or pin connection running essentially parallel to the plane of the gliding board. 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. In particular, the screw or pin connection can include two or more screws, by means of which the reinforcement element is screwed to the binding body. The binding body of the gliding board binding is thus able to permanently absorb larger forces, in particular frontal release forces in the event of a My release (torque about a Y-axis) in the vertical direction. The connection arrangement created in this way enables a structurally simple connection between the reinforcement element and the binding body which can be detached if necessary and is permanently wear-resistant, even after a longer period of intensive use. In other words, when My is released, frontal release forces 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 binding body, especially if these have an im Has essentially parallel to the plane of the sliding board mounting direction. Thus, the resistance of the heel unit can be further improved.

As an alternative or in particular in addition to a screw or pin connection, the binding body and the reinforcing element can be connected to one another by means of a connection arrangement, with the connection arrangement comprising a form-fitting connection. Such a positive connection can be formed in particular by a positive connection between the binding body and the reinforcement element. In this way, the stability of the arrangement can be further improved. Forces and/or impacts occurring during the use of the heel unit, which would severely stress a possibly provided screw or pin connection, can also be introduced to a large extent into the form-fitting connection, so that excessive stress and thus premature wear of the screw or pin connections are avoided can be.

The form-fitting connection can comprise at least one projection on the binding-body side and at least one corresponding recess on the reinforcement element, wherein the recess on the reinforcement element is configured to accommodate the respective projection on the binding-body side essentially in a form-fitting manner. In particular, two projections can be provided on the binding body and, accordingly, two recesses in the reinforcement element. With a projection and a recess, the positive connection can be realized with structurally simple means and the stability of the arrangement can be further improved.

In a preferred embodiment of the present invention, the reinforcing element may be made of a material that differs from the material from which the binding body is made. In particular, the reinforcement element in the form of the reinforcement plate can be made of a more wear-resistant or harder material than the binding body. In this way, improved stability and wear resistance can be achieved while the cost of the heel unit and the weight of the heel unit remain low.

In this context, particular consideration is given to the fact that the binding body is made from a plastic material and the reinforcing element is made from a metallic material. A combination of a metal material and a plastic material entails a combination of weight and cost savings (plastic) on the one hand and stability and wear resistance (metal) on the other. It is envisaged that the binding body is made from a plastic such as polyoxymethylene (POM) or glass fiber reinforced polyamide (PA-GF) and the reinforcing element is made in particular from titanium, alternatively from steel or aluminum, or from alloys thereof. In particular, a sheet metal material is considered.

In a further preferred embodiment, the at least one recess can be set up to provide a guide for the coupling pins in order to limit the path of movement of the coupling pins towards and/or away from one another. Such a limitation can take place in particular by means of stops in each case in the transverse direction of the gliding board or in the y-direction inwards and outwards. In this way, a defined tripping path for a My trip can be achieved. In addition, wear and tear occurring on the binding body can be further reduced.

A thickness of the reinforcement element in the form of the reinforcement plate can particularly preferably be between 1 mm and 4 mm, in particular between 2 mm and 3 mm, preferably 2.5 mm. It has been found that such a board thickness, measured in particular in the longitudinal direction of the gliding board, brings with it an optimal ratio of weight to stability.

The initially formulated object of the invention is also achieved by a touring binding comprising a heel unit according to the present invention. With a heel unit according to the present invention, wear and tear on the binding body in the area where the coupling pins are mounted can in turn be reduced and the touring binding is easier to maintain and less susceptible to defects.

• 1 eine perspektivische Ansicht einer Ferseneinheit gemäß dem bevorzugten Ausführungsbeispiel der Erfindung in einer Abfahrtstellung,
• 2 eine Vorderansicht der Ferseneinheit aus 1 in der Abfahrtsstellung,
• 3 eine perspektivische Ansicht der Ferseneinheit gemäß dem bevorzugten Ausführungsbeispiel der Erfindung in einer Auslösestellung und
• 4 eine Vorderansicht der Ferseneinheit aus 3 in der Auslösestellung.

The invention is explained in more detail below using a preferred exemplary embodiment with reference to the accompanying drawings. Show it:

• 1 a perspective view of a heel unit according to the preferred embodiment of the invention in a downhill position,
• 2 Figure 12 shows a front view of the heel unit 1 in the departure position,
• 3 a perspective view of the heel unit according to the preferred embodiment of the invention in a release position and
• 4 Figure 12 shows a front view of the heel unit 3 in the release position.

With reference to 1 a heel unit denoted generally by 10 in the figures comprises a binding body 16 and two coupling pins 18 arranged essentially next to one another on the binding body 16 for engaging in recesses in a heel section of a gliding board shoe in order to fix the gliding board shoe on the heel unit 10. The heel unit 10 is to be mounted on a gliding board surface of a gliding board, not shown.

The gliding board surface defines a gliding board plane E. In relation to the gliding board plane E, there is also an X-axis (gliding board longitudinal direction or x-direction), which is oriented in the direction of travel of the gliding board and runs parallel to the gliding board plane E, and one orthogonal to the X-axis and parallel Y-axis running to the plane E of the gliding board (transverse direction or y-direction of the gliding board) and a Z-axis (vertical direction or z-direction) running orthogonally to the plane E of the gliding board.

The heel unit 10 may further include a base 12 having a mounting arrangement for attaching the heel unit 10 to the gliding board surface. In the present exemplary embodiment, such a fastening arrangement can be realized, for example, by means of fastening holes 14 for fastening screws.

The base 12 can be constructed in two parts, with a first base element 20, in particular in the form of a base plate 20, which for attachment to the gliding board, for example, the attachment ment arrangement for fastening by means of screws (corresponding bores 14 in the first base element 20), and with a second base element 22, in particular in the form of a longitudinally displaceable carriage 22, which can be attached to the first base element 20. The second base element 22 can be held on the first base element 20 so that it can be displaced in the x-direction in order to enable longitudinal positioning of the heel unit 10 for adaptation to a shoe size and/or a certain mobility of the heel unit 10 in relation to the gliding board along the X-axis in a predetermined manner allow dynamic range of motion.

In the preferred exemplary embodiment, the binding body 16 can be arranged on the base 12 so as to be rotatable about a release axis of rotation running parallel to the z-direction. In particular, in the preferred embodiment, such rotation of the binding body 16 with respect to the base 12 allows the heel unit to be adjustable between a downhill position and an Mz-release position and/or between a downhill position and a walking position.

According to the invention, the coupling pins 18 protrude from the binding body 16 when the heel unit 10 is in a downhill position in the longitudinal direction x, in particular in the direction of travel, and at least one of the coupling pins 18 is between a downhill position ( 1 and 2 ) and a My release or entry position ( 3 and 4 ) movable.

In order to reinforce the binding body 16 or to protect it against wear, the heel unit 10 also comprises a reinforcement element 30 in the form of a reinforcement plate 30, which is 2 , a front view of the heel unit 10, can be better seen. The reinforcement plate 30 is arranged on the binding body 16 and extends essentially in a plane essentially orthogonal to the plane E of the gliding board. The reinforcement element 30 is set up for this purpose, at least in the event of a load acting on the coupling pins 18, in particular in the event of a load essentially orthogonal in a direction z to the gliding board plane E acting on the coupling pins 18 load to form at least one contact portion 34 for contact with at least one of the coupling pins 18. Such a contact section 34 ensures that the coupling pins are supported on the reinforcing element 30 when a force is applied to the coupling pins 18, in particular in the direction essentially orthogonal to the plane E of the gliding board are and the binding body 16 can be relieved. In this way, wear and tear on the binding body 16 in the area where the coupling pins 18 are supported can be reduced

Such a reinforcement plate 30 can in particular be made of a sheet metal material, such as preferably titanium, steel, aluminum or alloys thereof, while the binding body 16 can preferably be made of plastic. This allows the reinforcement plate 30 to support the binding body 16 with respect to forces acting on it and to protect it from wear. For this purpose, the reinforcement plate 30 is preferably arranged in front of the binding body 26 in the direction of travel x in order to be able to interact directly with the coupling pins 18 that protrude from the binding body 18 in the direction of travel x.

The reinforcement plate 30 can include at least one recess 32 for the coupling pins 18 which is configured to form the at least one contact section 34 for contact with at least one of the coupling pins 18 . In the preferred exemplary embodiment, the reinforcement plate 30 can include two recesses 32, one for each coupling pin 18. The contact sections 34 represent a type of stop for the coupling pins 18 and can directly absorb forces acting in the z-direction in particular and introduce them into the binding body 16.

In order to be able to absorb and distribute the acting forces even better, a form-fitting connection can be provided between the binding body 16 and the reinforcement element 30 . For this purpose, at least one projection 27, 29 can be provided on the binding body 16, which can be accommodated in at least one matching recess 37, 39 provided on the reinforcement element 30 in an essentially form-fitting manner. In the preferred embodiment, in particular two projections 27, 29 and two recesses 37, 39 can be provided. A lower 27 of the two projections on the binding body side can be provided, for example, in a mushroom-like shape with a section 28 widened in the y-direction. A resulting wider contact surface in the y-direction between the widened section 28 of the projection 27 of the binding body 16 and the recess 37 of the reinforcement plate 30 favors the introduction of the forces acting on the coupling pins 18 via the reinforcement plate 30 into the binding body 16, since the forces due to can be better distributed over the wider contact surface.

In order to also secure the reinforcement element 30 or the reinforcement plate 30 on the heel unit 10 in the x-direction, two screws 46 can be provided in the present exemplary embodiment which are passed through screw holes 36 in the reinforcement plate 30 and are screwed to the binding body 16 in a mounting direction essentially parallel to the plane E of the gliding board.

In the 3 and 4 1, the heel unit 10 of the preferred embodiment is shown in a My release or step-in position. During such an entry process, in which the gliding board shoe is coupled to the heel unit 10, the user presses with the heel section of the gliding board shoe from a substantially vertical direction onto the coupling pins 18. For example, through a metal insert in the shoe heel with sloping surfaces on which the coupling pins 18 slide off, the coupling pins 18 move essentially in the y-direction or in the y-direction with an additional movement component in the z-direction upwards away from one another. In the event of a forward fall and an associated My release of the heel unit 10, a force acts in the z direction from below on the coupling pins 18. Again, the coupling pins 18 are moved away from one another in the y direction by inclined surfaces provided on the gliding board shoe, as in FIG 4 is shown.

In addition, it can be seen that the two recesses 32 provide a kind of guidance for the coupling pins 18 during the movement that the coupling pins 18 perform during a My release or entry process, and thus the movement path of the coupling pins 18 towards one another and/or apart limit away. This is how the coupling pins 18 stand with reference to FIG 2 , in the downhill position of the heel unit 10, at a y-direction inner end or at an inner contact portion of the recesses 32, while with reference to FIG 4 , in the My release or entry position of the downhill position of the heel unit 10, at an outer end in the y-direction or at an outer contact section of the recesses 32. In this way, a defined triggering path for a My triggering can be achieved and the movement of the coupling pins 18 away from one another during a boarding process can be limited by stops provided on the reinforcement plate made in particular of a metallic material. This in turn can reduce wear on the binding body.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102011079210 A1 [0004]

Claims (14)

Heel unit (10) for a gliding board binding, in particular for a touring binding, wherein the heel unit (10) is to be mounted on a gliding board surface which defines a gliding board plane (E), comprising: a binding body (16) and two substantially side by side, on the binding body ( 16) arranged coupling pins (18) for engaging in recesses of a heel section of a gliding board shoe in order to fix the gliding board shoe on the heel unit (10), the coupling pins (18) being in a downhill position of the heel unit (10) in a gliding board longitudinal direction (x), in particular forward in a direction of travel, protruding from the binding body (16) and at least one of the coupling pins (18) can be moved relative to the other coupling pin (18) between a downhill position and a My release or entry position, characterized by a reinforcing element (30 ) in the form of a reinforcement plate (30) which is arranged on the binding body (16). and extends substantially in a plane substantially orthogonal to the plane (E) of the gliding board, the reinforcement element (30) being set up to do so, at least in the case of a load acting on the coupling pins (18), in particular in the case of a load substantially in one direction (z). load acting orthogonally to the gliding board plane (E) on the coupling pins (18) to form at least one contact section (34) for contact with at least one of the coupling pins (18). heel unit (10) after claim 1 , characterized in that the reinforcing element (30) comprises at least one recess (32) for the coupling pins (18), which is adapted to form the at least one contact section (34) for contact with at least one of the coupling pins (18). heel unit (10) after claim 1 or 2 , further comprising a base (12) with an attachment arrangement (14) for attachment to the surface of the gliding board, wherein the binding body (16), in particular for adjusting the heel unit (10) between a downhill position and an Mz release position, in order to achieve a position relative to the plane of the gliding board (E ) orthogonal release axis of rotation is rotatably arranged on the base (12). A heel unit (10) according to any one of the preceding claims, further comprising a My trip arrangement arranged to bias the at least one of the coupling pins (18) towards its downhill position, and/or an Mz release arrangement which is set up to pretension the binding body (16) towards its downhill position. Heel unit (10) according to one of the preceding claims, characterized in that the coupling pins (18) are set up to move substantially in a direction (y) substantially perpendicularly when moving between the downhill position and the My release or step-in position to the longitudinal direction of the gliding board (x) and essentially parallel to the gliding board plane (E) or in a direction with a movement component in direction (y) essentially perpendicular to the gliding board longitudinal direction (x) and essentially parallel to the gliding board plane (E) and a movement component in one direction ( z) to move away from each other essentially perpendicularly to the gliding board plane (E), so that a distance between the coupling pins (18) increases. Heel unit (10) according to one of the preceding claims, characterized in that the reinforcing element (30) is arranged in front of the binding body (16) in the direction of travel (x). Heel unit (10) according to one of the preceding claims, characterized in that the binding body (16) and the reinforcing element (30) are connected to one another by means of a connecting arrangement (27, 29, 36, 37, 39, 46), the connecting arrangement being a screw - or pin connection (36, 46), in particular wherein a mounting direction of the screw or pin connection (36, 46) runs essentially parallel to the sliding board plane (E). Heel unit (10) according to one of the preceding claims, characterized in that the binding body (16) and the reinforcing element (30) are connected to one another by means of a connection arrangement (27, 29, 36, 37, 39, 46), the connection arrangement having a form-fitting compound (27, 29, 37, 39). heel unit (10) after claim 8 , characterized in that the positive connection (27, 29, 37, 39) comprises at least one projection (27, 29) on the binding body side and at least one corresponding recess (37, 39) on the reinforcing element (30), the recess (37, 39 ) is set up on the reinforcing element (30) to receive the respective projection (27, 29) on the binding body side in an essentially form-fitting manner. Heel unit (10) according to one of the preceding claims, characterized in that that the reinforcing element (30) is made of a material which differs from the material from which the binding body (16) is made. heel unit (10) after claim 10 , characterized in that the binding body (16) is made of a plastic material and the reinforcing element (30) is made of a metallic material. Heel unit (10) according to one of the preceding claims, characterized in that the at least one recess (32) is adapted to provide a guide for the coupling pins (18) to guide the movement path of the coupling pins (18) towards and/or away from each other to limit. Heel unit (10) according to one of the preceding claims, characterized in that the thickness of the reinforcement element (30) in the form of the reinforcement plate (30) is between 1 mm and 4 mm, in particular between 2 mm and 3 mm, in particular 2.5 mm. Touring binding comprising a heel unit (10) according to any one of the preceding claims.

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