IMPROVEMENT TO THE ANCHORING OF THE NON-SLIP MEMBER TO A SOLE PROVIDED WITH RETRACTABLE NON-SLIP MEANS, AND RELATED MANUFATURING METHOD

Description

[0001] The invention is defined by an improved non-slip device according to claim 1 and a method of manufacturing this device according to claim 7. Preferred embodiments are defined in the dependent claims.

[0002] The present invention relates to an improvement, and the related manufacturing method, of a non-slip device for a shoe sole of the type in which non-slip or skid-proof means such as nails or grappling hooks are provided, which are not fixed directly to the sole but to rigid or semi-rigid means which can be folded into grooves obtained in the sole itself.

[0003] More in particular, the invention relates to an improvement, and the related manufacturing method, relating to the anchoring of the support member of the non-slip means to the shoe sole, which will be referred below as a non-slip member for brevity, which can be used:

either in the non-slip device disclosed in Italian patent 102017000024298, where said non-slip means are fixed on overturnable rigid or semi-rigid members, preferably of semi-rigid plastic material, capable of transitioning from a first groove or recess obtained on said sole to a second groove mirror-symmetrical to the previous one where said grappling hooks are housed within appropriate cavities correspondingly obtained at the bottom of the grooves which accommodate said rigid members, and where the overturning/lifting of the support members (bars, arches or even more complex figures) occurs about axes coplanar with the sole, by means of pins protruding from opposite sides of a lower end thereof which are snap fastened into respective rotation seats obtained in cubes provided with mushroom pins which are fixed in special cavities obtained in the side sole of the grooves accommodating said support members of the non-slip means;

or with the non-slip device disclosed in patent EP 1 558 103, to the same Applicant, where said non-slip means are fixed on rigid or semi-rigid support members which are hinged like a flag to the sole so as to be liftable with respect thereto and which are rotatable by at least 180° with respect to an axis of symmetry thereof which is distinct from the axis of hinging/lifting with respect to the sole and not parallel thereto, so as to use a single groove to retract the face with the grappling hooks when these are not required to be in contact with the ground.

[0004] In both cases, the hinging /rotation seats of the non-slip member are not obtained in one piece with the member itself, but on auxiliary member, (in this case in the form of parallelepipeds or cubes) which are anchored as feet to the sole by virtue of a mushroom member with which they are provided, which is snap-fastened into a corresponding seat arranged for molding in the sole next to the groove where the overturnable support member is housed after overturning, without interfering with the integrity of the sole itself, avoiding that a simple twisting of the bottom causes the detachment and loss thereof.

[0005] However, it has been highlighted that any replacement, due to breakage, loss or abrasion due to accidental causes or wear resulting from constant and prolonged use of the overturnable non-slip member, is rather inconvenient, since many times the traction which allows extracting said overturnable member from the fixing seat, leaves a cube with the fixing mushroom thereof anchored to the sole. This is because, when it is necessary to intervene on the sole, forcing it elastically for the extraction, the greatest stress occurs precisely at the rotation seats of the overturnable non-slip member that are obtained in the cubes, which, not being integral with the body of the same overturnable member, can easily be detached therefrom, remaining anchored to the sole.

[0006] This obviously results in an extension of the replacement times, because the manual extraction of the cube from the housing seat thereof in the sole is also required.

[0007] It has also been highlighted that in the previous solutions a joint had been used, which forms the rotation and/or overturning seat of the non-slip member, which joint is provided with a double-headed through pin made of steel to allow the rotation of the non-slip member by 180° and, perpendicular thereto, another protruding pin made of steel which instead forms the 90° rotation axis of the same non-slip member: the mushroom couplings were thus inserted through this joint using special machines, after completing the entire system.

[0008] However, this solution is complicated and significantly increases the production times and costs.

[0009] CN 201 709 486 U discloses an improved non-slip device according to the preamble of claim 1.

[0010] It is a first task of the present invention to overcome all the drawbacks of the prior art mentioned above, providing that the member to be anchored to the sole of the non-slip member:

forms a single body with the means, such as the mushroom members, which allow fixing it to the sole itself; and

is connected in a non-disassemblable manner to the rigid or semi-rigid material member forming the rotation and/or overturning seat of the non-slip member, configuring for this purpose an innovative joint which forms a single body with the non-slip member, avoiding any possible splitting of the assembly.

[0011] It is another task of the invention to overcome all the drawbacks of the prior art mentioned above, providing that the connection between the member anchored to the sole and the rigid or semi-rigid material member forming the rotation and/or overturning seat of the non-slip member, is obtained when they are molded, also incorporating by overmolding, from the same material from which said members are obtained, an appropriate innovative joint which allows molding a single body, preserving the freedom of movement of the different components, but avoiding an accidental splitting of the assembly.

[0012] The member anchored to the sole is thus not detachable from the non-slip member, even applying the elastic force to the sole required for the extraction of the latter.

[0013] According to a preferred embodiment of the invention, such a result is achieved by providing a joint molded from plastic material, provided with a first steel pin which protrudes above along the axis of symmetry thereof, intended to form the axis of rotation on which the non-slip member can rotate by 180° to be overturned, switching from the rest position to the operating position, while below said joint is provided with an eyelet-like perforated attachment forming the seat intended, in the subsequent overmolding, to shape the member anchored to the sole, with respect to the axis of rotation on which the joint can rotate by 90° with respect to the anchoring plane, and which is perpendicular to the aforementioned first axis of rotation by 180°, so that the non-slip member can travel a sufficient angular stroke, rising from the containment imprint to allow the complete overturning. With such a configuration, once molded, said joint is reloaded onto a mold which is unique for the entire structure and comprises the shapes of both the non-slip member and the member provided with the sole anchoring means, positioning said joint between the shape of the non-slip member, and that of said anchoring member.

[0014] According to a peculiar feature of the invention, a plastic material having a melting point different from that of the material from which the joint is made is used for the subsequent molding of the entire structure.

[0015] By molding the two members and simultaneously overmolding the joint, a structure is thus obtained in one piece, comprising the support member of the non-slip means, the aforementioned joint and the member provided with one or more fastening means for positioning and anchoring it on the shoe sole. The entire structure thus allows both lifting the non-slip member with respect to the member which anchors it in the containment imprint thereof obtained in the sole, and rotating the same non-slip member by 180° with respect to the same anchoring member, so as to overturn it when intending to switch from the operating position to the rest position, or vice versa. All the above while avoiding any accidental release. This is because the two different materials from which the pieces of the structure are made, for example, as described below, TPU and Nylon, not binding in any manner to each other, allow the parts, with overmolding, to be connected by means of the steel pin protruding from the joint which is embedded in the non-slip member, and through the formation of a horizontal axis, perpendicular to the previous one which connects the member anchored to the sole to the same joint, however leaving the parts free to rotate freely with respect to each other since there is no adhesion between the two materials forming them.

[0016] It should be noted that the materials from which the joint and the member anchored to the sole are made and which are indicated as a preferred exemplary embodiment herein are Nylon and TPU, but such a choice is not binding, since it is sufficient to use suitable plastic materials having different melting points and which do not bond together when overmolded.

[0017] The use of a joint as described and the subsequent overmolding allows:

avoiding the operation of loading the steel pin when molding the traditional joint, which is replaced by a pin obtained in the overmolding step, in one piece with the member anchored to the sole, with a reduction in both production times and costs;

eliminating the separate molding of the mushroom coupling means since the entire structure of the finished overturnable member, provided with said coupling means, is obtained when overmolding the joint from another plastic material having a different melting point, in the present case, Nylon with thermoplastic polyurethane TPU;

then eliminating the assembly of the mushroom couplings after completing the system; and

avoiding the accidental release of the mushroom couplings from the steel pin.

[0018] Further features and advantages of the present invention will become apparent from the accompanying drawings which illustrate, only by way of non-limiting example, a preferred embodiment thereof, where there are two mushrooms of the member anchored to the sole.

[0019] In the drawings, figures 1 to 5E relate to the systems in use according to the prior art:

Fig. 1 shows a first non-slip member of known type, in which a joint connected to the shoe sole through two separately molded mushrooms is present;

fig. 2 shows the two mushrooms manually assembled with the same joint as fig. 1, ready to be anchored to the sole in the operating position;

figs. 3 and 4 show the steps of extracting by traction the non-slip member in the previous figures from the fixing seat thereof on the sole, where the defect often found in practice is highlighted, that is one of the fixing mushrooms, not being integral with the rest of the structure, remains anchored to the sole, thus lengthening the replacement times;

fig. 5A is an exploded view of the different components forming the joint of another more recent non-slip member, showing the need for a complex and laborious assembly of the different components thereof, including a Nylon joint having a double-headed pin for a rotation of 180°, the insertion of a steel pin for a rotation of 90°, and the overmolding of a TPU arch as shown in fig. 5B showing a side elevation view of the non-slip member with the grappling hooks facing upwards;

fig. 5C shows a perspective view of the same non-slip member, before mounting the mushroom couplings shown in fig. 5D, and

fig. 5D finally shows a side elevation view of the non-slip member with the grappling couplings facing downwards after the manual assembly of the mushroom couplings;

fig. 6A is a view of the components forming the joint according to the present invention, where the joint is provided with an attachment with an eyelet on one side, while on the opposite side a portion of a double-headed pin protrudes for the 180° rotation of the non-slip member;

fig. 6B is a partially section view of the entire structure or complex according to the invention obtained by overmolding the joint in fig. 6A, from a plastic material having a different melting point than that of the material from which the joint is made, where the mushroom couplings are made, directly when molding the entire complex, of the same material that also makes the 90° rotation pin of the non-slip member;

fig. 6C is a perspective view of the same structure or complex as fig. 6B, with the non-slip member, the joint and the anchoring member which, only by way of non-limiting example, is provided with a single mushroom coupling;

fig. 6D is a side elevation view of the complex in fig. 6C, with the grappling hooks of the non-slip member facing downwards;

figs. 7 and 8 show how the removal of the non-slip member with grappling hooks according to the invention is easily executable with a simple traction which allows extracting it entirely from the fixing seat thereof, together with the fixing mushroom(s) since they are an integral part of a single structure;

figs. 9 and 10 show, in a different embodiment, the complex consisting of the non-slip member, the joint and the anchoring member in fig. 6, obtained in one piece after overmolding, when it is positioned in the housing imprint thereof in the sole, and, once lifted from the same imprint, partially rotated with respect to the member connecting it to the sole, respectively;
the following figures show the different steps of the method of manufacturing the non-slip member of the invention which can obviously take the most disparate forms, depending on the molds used. In particular:

fig. 11 shows a top plan view of a multi-imprint mold for molding the nylon joint, manually loading the double-headed steel pin for the 180° rotation, before molding it;

fig. 12 shows the nylon joint, including the steel pin, as it exits from the mold in fig. 11;

fig. 13 shows the nylon joint complete with pin reloaded on a multi-imprint mold of simple circular design before the TPU overmolding of the entire non-slip system;

fig. 14 shows the entire non-slip system complete with joint once the structural coating made of TPU has been overmolded on the nylon joint,;

figs. 15A and 15B show a vertical section plan view and a horizontal section elevation view of the structure or complex consisting of non-slip member, joint and anchoring member in fig. 14, respectively.

DETAILED DESCRIPTION OF THE INVENTION

[0020] As can be seen in figures 3 and 4, since the currently marketed solutions are not obtained in one piece, they have the serious drawback, apart from including several manual assembly steps, of detaching from each other if subjected to strong traction, whereby it often happens that, during replacement, some fixing members remain in place, and it is therefore necessary to intervene further with a considerable loss of time.

[0021] In fact, the joint 4 is made by inserting, in addition to the double-headed steel pin 6, another steel pin 8 which allows the 90° rotation and in which the mushroom couplings 25 are inserted through special machines after completing the system. However, this does not ensure the permanence in place under significant stresses which can lead to the release of the pin 8 from said mushroom couplings 25.

[0022] In order to avoid such a drawback, the views depicted in figures 6 onwards have been practiced, which show some embodiments of the present invention, only given by way of non-limiting example.

[0023] With reference to such figures, the object of the invention is a structure consisting of:

a non-slip grappling-hook holder member 10, preferably made of TPU, thermoplastic polyurethane, which is an elastic material with a high resistance to abrasions and chemicals, in the form of bars, arches or even more complex figures, on which nails or grappling hooks 12 adapted to grip snowy and/or icy surfaces are distributed;

a nylon joint 14, in which a double-headed steel pin 15 is incorporated for the 180° rotation of the grappling-hook holder member 10, while at the opposite end 16, the same joint 14 is provided with an eyelet 18 forming the seat of the 90° rotation axle 26 of the member 24 fixed to the sole, which is instead perpendicular to the rotation axis of said grappling-hook holder member 10, as seen in the drawings, and

said member 24 anchored to the sole, made of TPU, i.e., of the same thermoplastic material as the non-slip member 10, adapted to be fixed to the sole through one or more fastening means integral therewith, such as the mushroom pins 25 shown in fig. 5D, which snap fasten into the corresponding seats arranged in the sole next to the groove where the overturnable support member is housed after overturning.

[0024] According to the present invention once the nylon joint 14 has been obtained by molding, this is reloaded onto a multi-imprint mold for molding the entire structure, positioning it with the steel pin 15 thereof on the non-slip member 10, so that it is hinged like a flag, while at the opposite end thereof, in the eyelet 18, a TPU axle 26 is formed by overmolding, which connects said joint to the anchoring member 24.

[0025] The joint 14 is thus made integral with both the non-slip grappling-hook holder member 10 and the member 24 anchored to the sole, obtained in one piece with the mushroom pins 25, without preventing the relative movements of one and the other, i.e., rotation and overturning, since there is no adhesion between nylon and TPU, as also occurs using any other selected pair of suitable plastic materials having different melting points, which do not bond to each other when overmolded.

[0026] Figures 11 onwards show the different steps of manufacturing the non-slip system of the invention, including:

a) first molding, (fig. 11) from plastic material, for example nylon, in a mold A, which in the case shown is multiple, the joint 14, manually loading the double-headed steel pins so that each joint 14 carries a protruding steel pin 15, while at the opposite end said joint is shaped as seen in fig. 12, so as to have a protruding attachment 16 with an eyelet 18 adapted to form, in a subsequent overmolding, the rotation center of the axle 26 obtained in one piece with the anchoring member 24 which is perpendicular to the rotation axis of the non-slip member;

b) providing a multi-imprint mold B arranged for simultaneously molding the non-slip member 10 and its member 24 anchored to the sole, complete with mushroom pins 25, with the interposition of said joint 14;

c) loading said joint 14 into said multi-imprint mold B, positioning it between the imprint of the non-slip member 10 and that of the member 24 anchored to the sole and carrying out the molding operation by selecting a plastic material having a different melting point than that from which the joint 14 is molded, also overmolding the same joint, so as to obtain the non-slip member 10, the member 24 anchored to the sole and the joint 14 forming a single structure obtained in one piece. It is thus avoided that the member 24 anchored to the sole, in one piece with the mushroom pins 25 thereof, is detachable from the non-slip member 10, even applying to the sole the elastic force required for the extraction of the latter, as seen in figs. 9 and 10, without preventing the relative movements of one and the other, i.e., rotation and overturning, since there is no adhesion between the materials forming them.

[0027] A preferred embodiment of the manufacturing has been described herein. It is apparent that several modifications and variations can be made by those skilled in the art, in particular in the number, position and shape of the fixing members carried by the member anchored to the sole, without departing from the scope of protection of the present invention, as defined by the claims as set out below.

Claims

1. An improved non-slip device for a shoe sole of the type in which non-slip or skid-proof means such as nails or grappling hooks are provided, such means being not fixed directly to the sole but to rigid or semi-rigid means that can be folded away into grooves provided in the sole, wherein each non-slip member (10) as well as its member 24) anchored to the sole and provided with its own snap fastening means (25) are connected to each other in a non-disassembled way by a joint (14), characterized in that the joint is provided with a double-headed steel pin (15) with a protruding end forming the axis of rotation about which the non-slip member (10) is rotatable through 180°, said joint being provided on the opposite side with a protruding attachment (16) having an eyelet (18) forming the 90° rotation center of the axle (26) of said member element (24) anchored to the sole, which is perpendicular to said steel pin (15) so that said anchoring member (24) cannot be separated from said non-slip member (10) even if an elastic force necessary for the separation from the latter is applied to the sole.

2. The improved non-slip device for a shoe sole as claimed in claim 1, characterized in that non-slip members (10) and anchoring members (24) with their fastening means (25) and axle (26) are made by molding one piece by the same plastic material forming a overmolded single piece so that joint (14) is placed between them, said joint being molded by a plastic material having a different melting point from the overmolded piece, so as to make said joint (14) integral both with non-slip member (10) and member (24) anchored to the sole, however, without preventing the movements of both members to each other, i.e. rotation and overturning movements, as the materials of both members are unable to adhere to each other.

3. The non-slip device for a shoe sole as claimed in claim 2, characterized in that non-slip members (10) and anchoring members (24) with their fastening means (25) are molded by TPU (thermoplastic polyurethane) so as to form a single body by overmolding, joint (14) molded by nylon being placed between them so as to make it integral with both non-slip member (10) and member (24) anchored to the sole, however, without preventing the relative movements to each other, i.e. rotation and overturning movements, as the materials of both members are unable to adhere to each other because of nylon having a different melting point from thermoplastic polyurethane used in overmolding.

4. The non-slip device for a shoe sole as claimed in any preceding claim, characterized in that fixing means of member (24) anchored to the sole are shaped as one or more mushroom pins (25) that are fixed in suitable cavities provided in the sole on one side of the grooves housing the support members of the non-slip means.

5. The non-slip device for a shoe sole as claimed in claim 4, characterized in that the fixing means of member (24) anchored to the sole are shaped as a mushroom pin (25) axially aligned with attachment (16) of joint (14).

6. The non-slip device for a shoe sole as claimed in claim 4, characterized in that the fixing means of member (24) anchored to the sole is shaped as two mushroom pins (25) symmetrically positioned with respect to attachment (16) of joint (14).

7. A method of manufacturing the improved non-slip device according to claim 1 characterized by the following steps:

a) molding by plastic material a joint (14) bearing a protruding steel pin (15), said joint being provided at the opposite end with a protruding attachment (16) having an eyelet (18) and being able to form the rotation center of the axle (26) of anchoring member (24) which is perpendicular to the rotation axis of the non-slip member in the next overmolding;

b) providing a multi-imprint mold (B) arranged for the simultaneous molding both of non-slip member (10) and its member (24) anchored to the sole together with its fastening means (25) and axis (26), said joint (14) being placed therebetween;

c) inserting said joint (14) into said multi-imprint mold (B) and positioning the same between the imprint of non-slip member (10) and the imprint of fixing member (24) anchored to the sole, and carrying out the molding by selecting a plastic material having a melting point other than the material of joint (14), and overmolding such joint so as to produce an integral structure formed of non-slip member (10), member (24) anchored to the sole with relative fixing means (25), axle (26) and joint (14) in one piece, thus preventing member (24) anchored to the sole with its fastening means (25) from being separable from non-slip member (10) even if an elastic force necessary for the separation from the latter is applied to the sole, however, without preventing the movements of both members to each other, i.e. rotation and overturning movements, as the materials of both members are unable to adhere to each other.

8. The method of manufacturing the non-slip device as claimed in claim 7, characterized in that the material selected for molding joint (14) is nylon and the material for molding the whole structure is thermoplastic polyurethane (TPU).

Ansprüche

1. Verbesserte Anti-Rutsch-Vorrichtung für eine Schuhsohle der Art, bei welcher Anti-Rutsch-Vorrichtungen oder rutschsichere Vorrichtungen, wie zum Beispiel Spikes oder Krallen, bereitgestellt sind, wobei die Vorrichtungen nicht direkt an der Sohle befestigt sind, sondern an starren oder halbstarren Elementen, welche in Kerben, welche in der Sohle bereitgestellt sind, eingeklappt werden können,

wobei jedes der Anti-Rutsch-Elemente (10) sowie dessen in der Sohle verankertes Element (24), welches seine eigenen Schnappbefestigungsmittel (25) aufweist, durch ein Gelenk (14) in nicht zerlegtem Zustand miteinander verbunden sind,

dadurch gekennzeichnet, dass das Gelenk einen Doppelkopf-Stahlbolzen (15) mit einem vorstehenden Ende, welches die Drehachse, um welche das Anti-Rutsch-Element (10) um 180° verdrehbar ist, bildet, aufweist, wobei das Gelenk an den entgegengesetzten Seiten einen vorstehenden Ansatz (16), welcher eine Öse (18), welche die 90°-Drehmitte der Achse (26) des in der Sohle verankerten Elements (24) bildet, aufweist, aufweist, welcher lotrecht zum Stahlbolzen (15) angeordnet ist, sodass das verankerte Element (24) nicht vom Anti-Rutsch-Element (10) getrennt werden kann, sogar wenn eine Federkraft, welche zur Trennung vom Letzteren notwendig ist, auf die Sohle ausgeübt wird.

2. Verbesserte Anti-Rutsch-Vorrichtung für eine Schuhsohle nach Anspruch 1, dadurch gekennzeichnet, dass Anti-Rutsch-Elemente (10) und Verankerungselemente (24) mit deren Befestigungsmitteln (25) und der Achse (26) durch Spritzgießen eines Bauteils aus demselben Kunststoffmaterial zum Bilden eines einzigen aufgeformten Bauteils derart gebildet sind, dass das Gelenk (14) zwischen diesen angeordnet ist, wobei das Gelenk aus einem Kunststoffmaterial spritzgegossen ist, welches einen anderen Schmelzpunkt aufweist, als das aufgeformte Bauteil, um das Gelenk (14) sowohl in das Anti-Rutsch-Element (10) als auch in das in der Sohle verankerte Element (24) zu integrieren, ohne jedoch die Bewegungen der beiden Elemente zueinander, das heißt Dreh- und Klappbewegungen, zu behindern, da die Materialien der beiden Elemente nicht aneinander haften können.

3. Anti-Rutsch-Vorrichtung für eine Schuhsohle nach Anspruch 2, dadurch gekennzeichnet, dass Anti-Rutsch-Elemente (10) und Verankerungselemente (24) mit deren Befestigungsmitteln (25) aus TPU (thermoplastischem Polyurethan) spritzgegossen sind, um durch Aufformen einen einzigen Körper zu bilden, das aus Nylon spritzgegossene Gelenk (14) zwischen diesen angeordnet ist, um es sowohl in das Anti-Rutsch-Element (10) als auch in das in der Sohle verankerte Element (24) zu integrieren, ohne jedoch die Bewegungen der beiden Elemente zueinander, das heißt Dreh- und Klappbewegungen, zu behindern, da die Materialien der beiden Elemente nicht aneinander haften können, weil Nylon einen anderen Schmelzpunkt aufweist als das thermoplastische Polyurethan, welches zum Aufformen verwendet wird.

4. Anti-Rutsch-Vorrichtung für eine Schuhsohle nach einem der vorstehenden Ansprüche, dadurch gekennzeichnet, dass Befestigungsmittel des in der Sohle verankerten Elements (24) die Form eines oder mehrerer Pilzzapfen (25), welche in geeigneten Hohlräumen, welche in der Sohle an einer Seite der Vertiefungen, welche die Stützelemente der Anti-Rutsch-Mittel aufnehmen, bereitgestellt sind, aufweisen.

5. Anti-Rutsch-Vorrichtung für eine Schuhsole nach Anspruch 4, dadurch gekennzeichnet, dass die Befestigungsmittel des in der Sohle verankerten Elements (24) als ein Pilzzapfen (25) ausgebildet sind, welcher axial auf den Ansatz (16) des Gelenks (14) ausgerichtet ist.

6. Anti-Rutsch-Vorrichtung für eine Schuhsole nach Anspruch 4, dadurch gekennzeichnet, dass die Befestigungsmittel des in der Sohle verankerten Elements (24) als zwei Pilzzapfen (25) ausgebildet sind, welche in Bezug auf den Ansatz (16) des Gelenks (14) symmetrisch angeordnet sind.

7. Verfahren zum Herstellen der verbesserten Anti-Rutsch-Vorrichtung nach Anspruch 1, gekennzeichnet durch die folgenden Schritte:

a) Spritzgießen eines Gelenks (14), welches einen vorstehenden Stahlbolzen (15) trägt, aus Kunststoffmaterial, wobei das Gelenk an den entgegengesetzten Enden eines vorstehenden Ansatzes (16), welcher eine Öse (18) aufweist und in der Lage ist, beim nächsten Aufformen die Drehmitte der Achse (26) des Verankerungselements (24), welches lotrecht zur Drehachse des Anti-Rutsch-Elements angeordnet ist, zu bilden;

b) Bereitstellen einer Form mit mehreren Prägungen (B), welche für das gleichzeitige Spritzgießen sowohl des Anti-Rutsch-Elements (10) als auch des zugehörigen, in der Sohle verankerten Elements (24) zusammen mit den Befestigungsmitteln (25) und der Achse (26) eingerichtet ist, wobei das Gelenk (14) dazwischen angeordnet wird;

c) Einfügen des Gelenks (14) in die Form mit mehreren Prägungen (B) und Anordnen desselben zwischen dem Abdruck des Anti-Rutsch-Elements (10) und dem Abdruck des in der Sohle verankerten Befestigungselements (24), Ausführen des Spritzgießens durch Auswählen eines Kunststoffmaterials, welches einen anderen Schmelzpunkt aufweist als das Material des Gelenks (14), und Aufformen des Gelenks zum Erzeugen einer einstückigen Struktur gebildet aus dem Anti-Rutsch-Element (10), dem in der Sohle verankerten Element (24) mit den entsprechenden Befestigungsmitteln (25), der Achse (26) und dem Gelenk (14) in einem Stück, wodurch verhindert wird, dass das in der Sohle verankerte Element (24) mit seinen Befestigungsmitteln (25) vom Anti-Rutsch-Element (10) getrennt werden kann, sogar wenn eine elastische Kraft, welche für die Trennung vom Letzteren notwendig ist, auf die Sohle ausgeübt wird, ohne jedoch die Bewegungen der beiden Elemente zueinander, das heißt Dreh- und Klappbewegungen, zu behindern, da die Materialien der beiden Elemente nicht aneinander haften können.

8. Verfahren zum Herstellen der Anti-Rutsch-Vorrichtung nach Anspruch 7, dadurch gekennzeichnet, dass das zum Spritzgießen des Gelenks (14) gewählte Material Nylon ist und das Material zum Spritzgießen der gesamten Struktur thermoplastisches Polyurethan (TPU) ist.

Revendications

1. Dispositif antidérapant amélioré pour semelle de chaussure du type dans lequel sont disposés des moyens antidérapants tels que des clous ou des crochets de préhension, de tels moyens n'étant pas fixés directement à la semelle mais à des moyens rigides ou semi-rigides qui peuvent être repliés dans des rainures ménagées dans la semelle, dans lequel chaque élément antidérapant (10) ainsi que son élément (24) ancré à la semelle et muni de ses propres moyens de fixation par encliquetage (25) sont reliés entre eux de manière non démontée par un raccord (14), caractérisé en ce que le raccord est muni d'une goupille en acier à double tête (15) avec une extrémité saillante formant l'axe de rotation autour duquel l'élément antidérapant (10) peut tourner sur 180°, ledit raccord étant muni, sur le côté opposé, d'une fixation saillante (16) présentant un œillet (18) formant le centre de rotation à 90° de l'axe (26) dudit élément (24) ancré à la semelle, qui est perpendiculaire à ladite goupille en acier (15) de sorte que ledit élément d'ancrage (24) ne puisse être séparé dudit élément antidérapant (10) même si une force élastique nécessaire à la séparation de ce dernier est appliquée à la semelle.

2. Dispositif antidérapant amélioré pour semelle de chaussure selon la revendication 1, caractérisé en ce que les éléments antidérapants (10) et les éléments d'ancrage (24) avec leurs moyens de fixation (25) et axe (26) sont réalisés en moulant une pièce par le même matériau plastique formant une pièce unique surmoulée de sorte que le raccord (14) soit placé entre eux, ledit raccord étant moulé par un matériau plastique présentant un point de fusion différent de la pièce surmoulée, de manière à rendre ledit raccord (14) solidaire à la fois de l'élément antidérapant (10) et de l'élément (24) ancré à la semelle, sans toutefois empêcher les mouvements des deux éléments l'un par rapport à l'autre, à savoir des mouvements de rotation et de retournement, étant donné que les matériaux des deux éléments ne peuvent pas adhérer entre eux.

3. Dispositif antidérapant pour semelle de chaussure selon la revendication 2, caractérisé en ce que les éléments antidérapants (10) et les éléments d'ancrage (24) avec leurs moyens de fixation (25) sont moulés par TPU (polyuréthane thermoplastique) de manière à former un seul corps par surmoulage, le raccord (14) moulé par nylon étant placé entre eux afin qu'il fasse partie intégrante à la fois de l'élément antidérapant (10) et de l'élément (24) ancré à la semelle, sans toutefois empêcher les mouvements relatifs de l'un par rapport à l'autre, à savoir des mouvements de rotation et de retournement, étant donné que les matériaux des deux éléments ne peuvent pas d'adhérer entre eux en raison du nylon présentant un point de fusion différent du polyuréthane thermoplastique utilisé dans le surmoulage.

4. Dispositif antidérapant pour semelle de chaussure selon une quelconque revendication précédente, caractérisé en ce que les moyens de fixation de l'élément (24) ancré à la semelle ont la forme d'une ou plusieurs goupilles champignon (25) qui sont fixées dans des cavités appropriées ménagées dans la semelle d'un côté des rainures logeant les éléments de support des moyens antidérapants.

5. Dispositif antidérapant pour semelle de chaussure selon la revendication 4, caractérisé en ce que les moyens de fixation de l'élément (24) ancré à la semelle ont la forme d'une goupille champignon (25) alignée axialement sur la fixation (16) du raccord (14).

6. Dispositif antidérapant pour semelle de chaussure selon la revendication 4, caractérisé en ce que le moyen de fixation de l'élément (24) ancré à la semelle a la forme de deux goupilles champignon (25) positionnées symétriquement par rapport à la fixation (16) du raccord (14).

7. Procédé de fabrication du dispositif antidérapant amélioré selon la revendication 1, caractérisé par les étapes suivantes :

a) le moulage par matériau plastique d'un raccord (14) portant une goupille en acier saillante (15), ledit raccord étant muni à l'extrémité opposée d'une fixation saillante (16) présentant un œillet (18) et pouvant former le centre de rotation de l'axe (26) de l'élément d'ancrage (24) qui est perpendiculaire à l'axe de rotation de l'élément antidérapant dans le surmoulage suivant ;

b) la fourniture d'un moule multi-empreintes (B) conçu pour le moulage simultané à la fois de l'élément antidérapant (10) et de son élément (24) ancré à la semelle avec ses moyens de fixation (25) et son axe (26), ledit raccord (14) étant placé entre ceux-ci ;

c) l'insertion dudit raccord (14) dans ledit moule multi-empreintes (B) et le positionnement de celui-ci entre l'empreinte de l'élément antidérapant (10) et l'empreinte de l'élément de fixation (24) ancré à la semelle, et la réalisation du moulage en sélectionnant un matériau plastique présentant un point de fusion autre que le matériau de raccord (14), et le surmoulage d'un tel raccord de manière à produire une structure intégrée formée de l'élément antidérapant (10), de l'élément (24) ancré à la semelle avec des moyens de fixation relatifs (25), de l'axe (26) et du raccord (14) en une seule pièce, empêchant ainsi l'élément (24) ancré à la semelle avec ses moyens de fixation (25) d'être séparable de l'élément antidérapant (10) même si une force élastique nécessaire à la séparation de ce dernier est appliquée à la semelle, sans toutefois empêcher les mouvements des deux éléments l'un par rapport à l'autre, à savoir des mouvements de rotation et de retournement, étant donné que les matériaux des deux éléments ne peuvent pas adhérer entre eux.

8. Procédé de fabrication du dispositif antidérapant selon la revendication 7, caractérisé en ce que le matériau sélectionné pour mouler le raccord (14) est du nylon et le matériau pour mouler l'ensemble de la structure est du polyuréthane thermoplastique (TPU).

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