IT201700002063A1 - CURSOR FOR LIGHTNING CLOSURE - Google Patents

Description

SLIDER FOR ZIP CLOSURE

DESCRIPTION

The present invention relates to a slider for zipper, of the type usable for the coupling and uncoupling of two flaps of material forming part of a zipper and which are each equipped with a series of mutually engageable teeth.

As is known, prior art zipper sliders have converging shaped channels which together form a Y, and through which the two edges of material provided with teeth slide; the sliding of the cursor with respect to the edges of the material allows the engagement or disengagement of the opposing rows of teeth, depending on the sliding direction of the cursor.

For this purpose, the channels, which are obtained within the structure of the slider, have a convex course with respect to each other so as to spread the teeth of each row that slides inside and allow them to be inserted or inserted. disengagement (depending on the sliding direction).

The known cursors can be moved by the user through a puller, generally of an elongated shape.

The sliders for zip fastening according to the known art can be classified into two functional categories. The first category includes the sliders equipped with a safety stop designed to prevent the involuntary sliding of the slider and therefore the involuntary decoupling of the teeth. The second category includes sliders for zippers without such a safety catch.

The present invention relates exclusively to the first category mentioned above, ie sliders for zip fasteners equipped with a safety catch. The safety catch in the sliders for zip fasteners of the known art consists of an L-shaped element, hinged at one end of the L and which can partially enter the channel where the flaps of material of the zip slide at the other end. to mechanically interact with the zipper teeth preventing the slider from sliding.

In the sliders of the first category, the puller is also used to release the safety catch; in fact, the user, in order to release the safety catch, and allow the cursor to slide with respect to the material flaps of the zip, must first act on the puller and then proceed with the movement of the cursor.

For this purpose, the puller has a through hole in which the L defined by the safety stop is inserted with play.

The puller is therefore free to rotate with respect to the rest of the cursor between a position in which it is parallel to the edges of the material and a position in which it is inclined with respect to them.

In known sliders, to release the safety catch, it is generally necessary for the puller to be moved away from the rest of the cursor by the user through a rotation of the puller with respect to the cursor.

Currently, in some situations, handling, in particular the operations to release the safety catch of the zipper slider, are particularly difficult for the user.

In many cases, these operations to release the safety lock are made difficult by the position in which the cursor is located at the time when the user needs to act on it, for example when, for aesthetic or technical reasons , the same slider is partially hidden by fabric flaps which may make it necessary to move them before being able to easily act on the puller to move the safety stop of the slider.

In other cases, it is possible that the same user is in particular environmental and / or working conditions that require the use of gloves to protect the hands, which often make it difficult to grip the puller which in many cases has necessarily limited dimensions. .

A further and well-established drawback of the zipper sliders constituting the known technique is the risk of accidental hooking of the pull, given its elongated shape and its freedom of movement, with moving parts of machinery or with protruding parts of external structures.

Furthermore, in the prior art zipper sliders it is not possible to keep the safety catch in the active position in the absence of action by the user on the puller.

In this context, the technical task underlying the present invention is to remedy the aforementioned drawbacks.

In particular, the technical task of the present invention is to provide a slider for a zipper in which the release of the safety catch, and therefore the movement of the slider of the zipper, is facilitated with respect to sliders of the known art.

A further technical task of the present invention is to provide a slider for zip fastening which reduces the risk of hooking the slider with external elements.

It is still a technical task of the present invention to obtain the above at low costs and therefore compatible with the market context in which its application would be inserted.

The technical task and the aims indicated are substantially achieved by a slider for zip fastening in accordance with what is described in the attached claims.

Further characteristics and advantages of the present invention will become more evident from the detailed description of some preferred, but not exclusive, embodiments of a slider for zipper illustrated in the accompanying drawings, in which:

- Figure 1 shows in an axonometric view from above, with some parts in transparency, a slider for zipper in accordance with a first embodiment of the present invention, in a first operating condition; Figure 2 shows the slider for zip fastening of Figure 1, in a second operating condition;

figure 3 shows the slider for zip fastening of figure 1 sectioned along the line III-III;

figure 4 shows the slider for zip fastening of figure 2 sectioned along the line IV-IV;

- Figure 5 shows in an axonometric view from above, with some parts removed, a slider for zipper in accordance with a second embodiment of the present invention, in a first operating condition;

figure 6 shows the slider for zip fastening of figure 5, in a second operating condition;

- Figure 7 shows in an axonometric view from above, with some parts in transparency, a slider for zipper in accordance with a third embodiment of the present invention, in a first operating condition; figure 8 the slider for zip fastening of figure 7, in a second operating condition; And

- figure 9 shows the slider for zip fastening of figure 7, sectioned along the line IX-IX.

With reference to the aforementioned figures, the reference number 1 globally indicates a slider for zipper made according to the present invention.

In its most general embodiment, the slider 1 for zip fastening object of the present invention first of all comprises a structure for engaging the teeth 2, similar in many aspects to the known ones.

In a per se known way, the structure of engagement of the teeth 2 defines an area of engagement of the teeth 3, in which the teeth of the two respective edges of material slide during use to be mutually engaged or disengaged.

In the illustrated embodiments, the tooth engagement structure 2 has an upper base 4 and a lower base 5.

The upper base 4 and the lower base 5 are preferably mainly flat plates facing each other, spaced apart and parallel to each other. The upper base 4 and the lower base 5 are also preferably symmetrical with respect to a plane of symmetry 6 perpendicular to them and oriented along a main direction of development 7 (which corresponds to the plane IV-IV of figure 2 and to the plane IX-IX of figure 7).

The lower base 5 and the upper base 4 are rigidly connected by means of a connection element 8 whose height corresponds to the distance between the upper base 4 and the lower base 5, and which extends perpendicularly to the upper base 4 and to the lower base 5.

Advantageously, two first guides 9 are associated with the lower base 5 and two second guides 10 are associated with the upper base 4. The first guides 9 have a substantially perpendicular development to the lower base 5 and have a first height with respect to the lower base 5.

The second guides 10 have a substantially perpendicular development to the upper base 4 and have a second height with respect to the upper base 4 and face the first guides 9.

The first guides 9 and the second guides 10 are preferably symmetrical with respect to a work plane 11, which in the illustrated embodiments coincides with the plane of symmetry 6.

Between each of the two pairs consisting of a first guide 9 and a second guide 10 facing each other, there is a passage slot 12 parallel to the upper base 4 and to the lower base 5.

The tooth engagement structure 2 therefore has two symmetrical slots with respect to the work surface 11.

Each passage slit 12, as in the known sliders, has a substantially constant height and such as to allow the sliding of the edges of material that carry the teeth and to prevent the passage of the teeth (in zip fasteners the teeth are thicker than the material to which they are attached).

In the illustrated embodiments, the area of engagement of the teeth 3 is that portion of empty space surrounded by the face of the upper base 4 facing the lower base 5, by the face of the lower base 5 facing the upper base 4, by the first guides 9 and by the second guides 10.

In use, the teeth of the two respective edges of material slide through the meshing region of the teeth 3 substantially along an engagement direction 13 to be mutually engaged or disengaged.

The engagement direction 13 lies in the aforementioned work surface 11 and is parallel to the upper base 4 and to the lower base 5.

The first guides 9 and the second guides 10 develop in such a way as to have a convexity facing the work surface 11, and approach each other along the grafting direction 13 in a direction called the grafting direction 14; in particular they are arranged and shaped in such a way as to spread the rows of teeth and allow their mutual engagement and disengagement. In correspondence with the area in which the first guides 9 and the second guides 10 are at the maximum mutual distance, a first edge 15 of the upper base 4, a second edge 16 of the lower base 5, a third edge 17 of the first guides 9 and a fourth edge 18 of the second guides 10 define an entry area 19 in correspondence with which, in use, the teeth enter which must gradually engage when closing the zip, and the teeth which have disengaged when opening the closure come out lightning.

In correspondence with the area in which the first guides 9 and the second guides 10 are at the minimum mutual distance, a fifth edge 20 of the upper base 4, a sixth edge 21 of the lower base 5, a seventh edge 22 of the first guides 9 and an eighth edge 23 of the second guides 10 define an outlet mouth 24 in correspondence with which, in use, the teeth that are engaged when closing the zipper come out and the teeth that must gradually disengage when opening the closure enter lightning.

The connecting element 8, as in known sliders, is preferably substantially symmetrical with respect to the work surface 11, and is positioned in such a way as to divide the inlet area 19 preferably into two equal parts, which each constitute an inlet 25 .

In general, the meshing area of the teeth 3, as in known sliders, consists of two channels converging to each other, which develop from the inlet openings 25, which are separated from the connecting element 8 and which, downstream of the connecting element 8 along the engagement direction 13 according to the engagement direction 14, join in a single channel which ends at the outlet 24 to form a Y-shaped channel as a whole.

The passage slits 12 advantageously extend from the inlet mouths 25 to the outlet mouth 24.

The zipper slider 1 then comprises a safety catch 26, connected in a movable way to the coupling structure of the teeth 2, preferably at least in a rotatable way.

The safety stop 26, in the illustrated embodiments, has (seen from the side) a substantially L-shape rotated by 90 °, where the L comprises a major side and a minor side.

The safety stop 26 in the illustrated embodiments is rotatably connected to the engagement structure of the teeth 2 in the free end part of the longer side of the L by means of a constraint 27.

The shorter side of the L, on the other hand, is not bound to the engagement structure of the teeth 2.

The safety stop 26 includes an engagement portion 28, which in the illustrated embodiments is obtained at the free end of the shorter side of the L.

The safety stop 26 can move with respect to the engagement structure of the teeth 2 between an operative position and a rest position.

In the operative position, the engagement portion 28 is inserted in the meshing area of the teeth 3, and in use prevents the sliding of the teeth with respect to the engagement structure of the teeth 2 in at least a first direction, which in the illustrated embodiments has the opposite direction to the aforementioned graft direction 14.

In the rest position, the engagement portion 28 is not inserted in the meshing area of the teeth 3 or is inserted in the meshing area of the teeth 3 less than when the safety stop 26 is in the operative position, and in use it allows the sliding of the teeth with respect to the engagement structure of the teeth 2 at least in the first direction 29.

In the preferred embodiments, the safety stop 26 can at least rotate with respect to the engagement structure of the teeth 2 according to a first axis of rotation 30, arranged perpendicular to the work plane 11.

In the preferred embodiments, the safety stop 26 is constrained to a support structure (which will be better defined below), which in the illustrated embodiments coincides with the upper base 4.

Advantageously, when the safety stop 26 occupies the rest position, the safety stop 26 is arranged with the greater side of the L substantially parallel to the direction of engagement 13 and the smaller side of the L arranged in a direction perpendicular thereto, with the part free end of the shorter side of the L inserted in the meshing area of the teeth 3.

Preferably, with reference to the engagement direction 13 and the engagement direction 14, the constraint 27 is located upstream of the engagement portion 28 of the safety stop 26.

Advantageously, the support structure (and the upper base 4 if the two do not coincide) has a passage hole 32 which extends up to the meshing area of the teeth 3, in which the shorter side of the L defined by the safety stop 26 to allow the engagement portion 28 of the safety stop 26 to reach the area of engagement of the teeth 3 when the safety stop 26 occupies the rest position.

The rest position and the operative position are advantageously delimited, respectively, by an end-stroke element 33 integral with the support structure and by the support structure itself.

The limit switch element 33, in the illustrated embodiments, comprises a wall element 34 and a tooth 35 protruding from the wall element 34. The wall element 34 extends substantially perpendicular to the support structure and is integral with the supporting structure. support and is positioned downstream of the engagement portion 28 of the safety stop 26 with reference to the engagement direction 13 and the engagement direction 14.

The protruding tooth 35 develops towards the safety stop 26 with development advantageously parallel to the support structure and of such length as to intercept the safety stop 26 (one of its protrusions 36 in the accompanying figures, see figure 8) when it arrives in the rest position .

In the embodiments illustrated, the safety stop 26 has at least mainly a cross section (perpendicular to the work surface 11 and to the engagement direction 13) with an open U-shaped box-like profile rotated by 180 °.

The safety stop 26 advantageously has in the central part of the longer side of the L, a recess 37 facing the tooth engagement structure 2, so that between the safety stop 26 and the tooth engagement structure 2 a volume of space.

As said, the engagement structure of the teeth 2 can further comprise a support structure, which in the illustrated embodiments is constituted by the upper base 4; in other embodiments not shown, the support structure can also be a plate integral with the upper base 4 and fixed on the face of the upper base 4 opposite to that facing the lower base 5.

In accordance with the present invention, the slider 1 also has an activation volume 38 which is comprised between the engagement structure of the teeth 2 and the safety stop 26 when the safety stop 26 occupies the rest position.

The activation volume 38, in the illustrated embodiments, is a portion of free space which is located between the support structure and the safety catch 26 only when the safety catch 26 occupies the rest position and which is occupied by the safety catch 26 when this is in the operative position. For the sake of clarity, the activation volume 38 is indicated only in Figure 9, with a cross-hatching.

In other words, observing the safety stop 26 from the side (perpendicular to the work surface 11), the activation volume 38 can be identified in the increase in free area between the safety stop 26 and the engagement structure of the teeth 2 which is obtained at the recess 37 in the passage of the safety stop 26 from the operative position to the rest position.

The slider 1 also comprises disabling means 39 of the safety stop 26 which in turn comprise at least an actuator element 40 operatively associated with the safety stop 26 and means for moving 41 of the actuator element 40.

The actuator element 40 is movable between an disconnected position in which the actuator element 40 is outside the activation volume 38 and allows the safety catch 26 to remain in the operative position, and an engaged position in which the actuator element 40 is inserted in the activation volume 38 and keeps the safety catch 26 in the rest position preventing it from passing into the operative position.

In passing from the disconnected position to the inserted position, the actuator element 40 determines the displacement of the safety stop 26 from the operating position to the rest position.

In the embodiments of figures 5-9 there is only one actuator element 40, while in the embodiment of figures 1-4 there are two actuator elements 40 which act simultaneously on the safety stop 26 as will be explained below.

Advantageously, the actuator element 40 moves from and towards the activation volume 38 along a working trajectory 42 and has a tapered shape with a decreasing section and is arranged in such a way that in moving from the disengaged position to the engaged position its front part present the minor section.

In the illustrated embodiments the working path 42 of the actuator element 40 is a straight segment, but in other embodiments the working path 42 of the actuator element 40 can be a curve or a more complex line.

In the embodiments illustrated in Figures 1-6, the working path 42 of the actuator element 40 is perpendicular to the working plane 11, while in the embodiment of Figures 7-9 the working path 42 of the actuator element 40 is parallel to the plane working 11.

Preferably, when the actuator element 40 is in the inserted position, the actuator element 40 is interposed between the engagement structure of the teeth 2 and the safety stop 26, it is in contact with both so that the movement of the safety stop 26 from the position of rest in the operating position is mechanically impossible.

For this purpose the actuator element 40 advantageously has a sliding surface 43, parallel and in contact with the support structure, and a contact surface 44 advantageously inclined with respect to the sliding surface 43, so as to obtain the tapered shape of the actuator element 40.

In the preferred embodiment, the actuator element 40 substantially has the shape of a wedge.

The actuator element 40, moving along the working path 42 from the disengaged position to the engaged position, under the action of an external force, interacts mechanically with the safety stop 26 through the physical contact between the contact surface 44 of the element actuator 40 and the part of the safety stop 26 that delimits the recess 37.

In particular, in accordance with the preferred embodiments of the present invention, the actuator element 40, exploiting the principle of the inclined plane, is capable of deflecting an aliquot of the external force applied thereto, in a direction perpendicular to the support structure and with the direction going away from the tooth engagement structure 2.

Said portion of the external force, transmitted by the actuator element 40 to the safety stop 26, moves the safety stop 26, the latter being a weak body due to its constraint 27 and having the materials constituting the safety stop 26 and the actuator element 40 a sufficiently low deformability.

The amount of external force, in order to bring the safety stop 26 to the rest position, must perform a work sufficient to overcome friction and move the safety stop 26 to such an extent as to make the actuator element 40 occupy the inserted position so that, the safety stop 26 is unable to move in the direction from the rest position to the operative position.

In the preferred embodiments, the safety stop 26 moves in a plane parallel to the work surface 11, and depending on the type of constraint 27 with which it is connected to the support structure it can move in a purely translational, roto-translational or purely rotary.

In the illustrated embodiments, one or more appendages 45 are advantageously developed from the support structure designed to cooperate in defining the constraint 27 between the safety stop 26 and the support structure.

In the embodiment of figures 1-4, the free end part of the longer side of the L which defines the safety stop 26 is constrained to the appendages 45 so that the first axis of rotation 30 of the safety stop 26 can also perform a translation in direction substantially perpendicular to the support structure and limited in width.

The movement means 41 comprise at least one activation element 46, which, advantageously, in the embodiments of Figures 1-4 and 7-9 comprises at least one button, while in the embodiment of Figures 5-6 it comprises a connected operating ring 47 rotatably to the structure of engagement of the teeth 2 according to a second axis of rotation 48.

The movement means 41 can be activated manually by a user who can exert an external force on the activation element 46, and are associated with the actuator element 40 to consequently move it at least from the disconnected position to the inserted position.

The activation element 46 is movable between a deactivated position and an active position through the application of an external force by the user.

The deactivated position of the activation element 46 corresponds to a disconnected position of the actuator element 40, while the active position of the activation element 46 corresponds to an inserted position of the actuator element 40.

In some particularly preferred embodiments, the activation element 46 can advantageously be associated with the actuator element 40 rigidly (Figures 1-4 and 7-9).

In other embodiments, the movement means 41 can comprise a movable cam 49 operatively associated with the activation element 46 and with the actuator element 40, and the rotary movement of the movable cam 49 determined by the activation element 46 can determine the movement of the actuator element 40 at least from the disengaged position to the engaged position.

In some embodiments not shown, the movable cam 49 can be a linear cam, whose rectilinear movement determines the movement of the actuator element 40 at least from the disconnected position to the inserted position.

In particularly preferred embodiments (Figures 5-6), the movable cam 49 is instead integral with the aforementioned maneuver ring 47 in the rotation around the second rotation axis 48 and the rotation of the maneuver ring 47, with respect to the second axis of rotation. rotation 48, determines the movement of the actuator element 40 at least from the disengaged position to the engaged position thanks to the interaction with the movable cam 49.

In this case, the maneuver ring 47 can preferably rotate, with respect to the engagement structure of the teeth 2, by an activation angle around the second axis of rotation 48.

In the sliders 1 for zipper according to the present invention, the movement means 41 advantageously determine the bidirectional movement of the actuator element 40 from the disconnected position to the inserted position and from the inserted position to the disconnected position.

For this purpose, the movement means 41 can comprise elastic means 50, such as for example springs or elements with a predetermined deformability, operatively active on the actuator element 40 to bring the actuator element 40 into the disconnected position when the actuator element 40 is in a position other than the disconnected position and in the absence of external stresses on the activation element 46.

Said elastic means 50 can preferably act between the engagement structure of the teeth 2 and the actuator element 40, as in the embodiment illustrated in the accompanying figures 5 and 6, or between the engagement structure of the teeth 2 and the activation element 46 as in the embodiments illustrated in the accompanying Figures 1-4 and 7-9, or between the engagement structure of the teeth 2 and the safety stop 26 (solution not illustrated).

For the sake of simplicity, some specific embodiments of the following invention will be described separately and in greater detail below.

As regards the first embodiment illustrated in Figures 1-4, two activation elements 46 are provided, each consisting of a first button 51, rigidly connected to an actuator element 40. There are two specular actuator elements 40, wedge-shaped and arranged in such a way as to fit into the recess 37 on opposite sides of the L defined by the safety stop 26.

In this embodiment, the elastic means 50 act between each activation element 46 and the engagement structure of the teeth 2.

The first buttons 51 have an elongated shape and are positioned symmetrically with respect to the work surface 11.

The first buttons 51 are movable along a direction perpendicular to the work plane 11 between an active position, in which the first buttons 51 have the maximum distance from the work plane 11 (Figure 1), and an active position, where the first buttons 51 have a minimum distance from the work surface 11 (figure 2).

In this embodiment, the elastic means 50 comprise four arms 52 of elongated shape and preferably rectangular cross section. Each of the two first pushbuttons 51 is connected to the tooth engagement structure 2 by means of two arms 52.

The arms 52 preferably have an elongated shape and a reduced cross section in such a way as to have a flexural deformability sufficient to allow the movement of the activation element 46 between the inactive position and the active position.

Said arms 52 have a first end and a second end. The first end of each arm 52 is fixed to one of the first pushbuttons 51, while the second end of each arm 52 is fixed to a connection element 53 constrained to the support structure.

The connection element 53 has a slot hole 54 in which a pin 55 integral with the support structure is inserted. Thanks to this slot hole 54, the connection element 53 can slide along the coupling direction 13 to facilitate the movement of the first buttons 51 in a direction perpendicular to the work surface 11 (Figure 2).

The external forces exerted on each of the first two buttons 51 move the first buttons 51 from the deactivated position to the active position and the actuator element 40 from the disengaged position to the engaged position, overcoming the resistance to bending deformation of the arms 52.

In the event that the action of said external forces ceases, the actuator elements 40 move from the engaged position to the disengaged position by releasing the elastic energy accumulated by the four arms 52 during the movement of the actuator element 40 from the disengaged position to the disengaged position. position entered.

As regards a second embodiment, to which the embodiment illustrated in figures 5 and 6 belongs, the activation element 46 is associated with the actuator element 40 in a non-rigid way, and the movement means 41 comprise a fixed movable cam 49 rigidly to the inner surface of the operating ring 47.

The movable cam 49 extends along an arc of circumference defined by the maneuver ring 47 whose length can correspond to part or all of the circumference of the maneuver ring 47 itself.

Hereinafter, this arc of circumference is called the activation arc, and the angle subtended by the activation arc, the activation angle.

At one end of the activation arc, the movable cam 49 has a minimum radial development towards the second rotation axis 48; the radial development towards the second axis of rotation 48 of the movable cam 49 then increases up to its maximum value by following the activation arc to the other end (counterclockwise around the second axis of rotation 48 in the attached figures).

In the illustrated embodiment, the actuator element 40 is rigidly connected to a maneuver shaft 56 parallel to the working path 42.

Said maneuver shaft 56 includes two ends, a first end rigidly connected to the actuator element 40 and a second end coupled to the movable cam 49 of the maneuver ring 47.

At a certain distance from the second end of the operating shaft 56, the operating shaft 56 has an abutment element 57 which is intended to oppose the expansion of a return spring 58.

The abutment element 57 in the preferred embodiments is a circular ring coaxial to the operating shaft 56.

The return spring 58 is positioned coaxially to the operating shaft 56 and acts between the abutment element 57 and a fixed contrast 59 integral with the coupling structure of the teeth 2, and has a shape such as to allow the sliding inside it of the 'maneuver shaft 56.

In particular, in the preferred embodiments the fixed contrast 59 can also be a ring coaxial to the maneuver shaft 56.

In the illustrated embodiment, the operating ring 47 is associated with the support structure in such a way that, when the actuator element 40 is in the disengaged position, the second end of the operating shaft 56 interacts with the movable cam 49 where this has minimal radial development (Figure 5).

From this position, following the rotation of the operating angle 47 of the activation angle around the second axis of rotation 48 (clockwise in the figures), the movable cam 49 pushes the second end 58 of the operating shaft 56 of the actuator element 40 inwards, and consequently brings the actuator element 40 into the inserted position, overcoming the resistance of the return spring 58 (Figure 6).

The rotation of the operating ring 47 from the inactive position to the active position allows a gradual elongation of the return spring 58 with a consequent sliding of the operating shaft 56 in the fixed contrast 59 and a movement of the actuator element 40 along the trajectory of work 42 from the engaged position to the disengaged position.

In the embodiment of Figures 5 and 6, the rotation of the maneuver ring 47 by an angle greater than the activation angle is prevented by a first limit switch 60 integral with the support structure and positioned flush with the internal surface of the ring. maneuver 47, and by a second limit switch 61 integral with the support structure and positioned flush with the internal surface of the maneuver ring 47 against which it abuts. As regards the third embodiment illustrated in Figures 7-9, the activation element 46 is rigidly associated with the actuator element 40 and the activation element 46 consists of a single second button 62 with a contrast spring 63 positioned between the second button 62 and the tooth engagement structure 2.

In the embodiment of figures 7-9, the actuator element 40 has a working path 42 parallel to the work plane 11 and to the direction of engagement 13.

The length of the contrast spring 63 of the second button 62 can vary between an extended length and a compressed length.

When the contrast spring 63 has the extended length the second button 62 is in the deactivated position, while when the contrast spring 63 has the compressed length the second button 62 is in the active position.

The rigid connection between the activation element 46 and the actuator element 40 is made by means of two elongated side bars 64 rigidly connected to the actuator element 40 and the activation element 46.

Following the application of an external force on the activation element 46, the activation element 46 passes from the deactivated position to the active position and the actuator element 40 from the not inserted position to the inserted position overcoming the opposition of the contrast spring 63.

In the event that the action of the external force ceases, the actuator element 40 moves from the engaged position to the disengaged position by releasing the elastic energy accumulated by the contrast spring 63.

With regard to a fourth embodiment not shown, the activation element 46 can always consist of a maneuver ring 47 connected in a rotatable manner to the engagement structure of the teeth 2 according to a second axis of rotation 48 perpendicular to the support structure.

In this embodiment, however, the actuator element 40 can be rigidly fixed to the maneuver ring 47, eccentrically with respect to the second axis of rotation 48, and the rotation of the maneuver ring 47 with respect to the second axis of rotation 48 can determine the movement of the actuator element 40 between the disconnected position and the inserted position along a trajectory which extends over an arc of circumference centered on the second axis of rotation 48.

The various embodiments of the present invention can be further characterized based on the position of the actuator element 40 on the support structure at the disconnected position of the actuator element 40.

The actuator element 40 in fact, in correspondence with the disconnected position, in some embodiments (Figures 1-6) can be positioned outside the portion of space present between the recess 37 of the safety stop 26 and the support structure when the safety catch 26 is in the operative position; in other embodiments (figures 7-9) the actuator element 40 on the other hand, in its disconnected position can occupy this space between the recess 37 of the safety stop 26 and the support structure.

The present invention achieves important advantages.

The slider 1 for zip fastening object of the present invention allows the safety stop 26 to be positioned in the rest position with greater ease than known sliders, even in those conditions mentioned above in which it is necessary to use gloves by the user, to limit the risk of accidental coupling of the cursor 1 with elements of the external environment. Furthermore, at least in some embodiments, it is possible that the user can keep the safety stop 26 in the rest position without the need to maintain a constant action on the slider 1, returning the safety stop 26 to the operating position at will. at a later time.

Finally, it should be noted that the present invention is relatively easy to produce and that also the cost connected with its implementation is not very high.

The invention thus conceived is susceptible of numerous modifications and variations, all falling within the scope of the inventive concept that characterizes it.

All the details can be replaced by other technically equivalent ones and the materials used, as well as the shapes and dimensions of the various components, may be any according to requirements.

THE ASSIGNED

Ing. Simone Ponchiroli (Register of Prot. N.1070BM)

Claims (13)

CLAIMS 1. Zipper slider, for the coupling and uncoupling of two flaps of material that are part of a zipper and are each equipped with at least one set of teeth, the teeth of the two flaps being mutually engageable, comprising: a tooth engagement structure (2) defining a tooth meshing area (3), in which the teeth of the two respective edges of material slide during use to be mutually engaged or disengaged; a safety stop (26) movably connected to the tooth engagement structure (2) and comprising an engagement portion (28), said safety stop (26) being able to move with respect to the tooth engagement structure between an operative position and a rest position; in said operating position, the engagement portion (28) being inserted in the tooth meshing area (3), in order to prevent the sliding of the teeth with respect to the tooth engagement structure in at least a first direction (29); in said rest position, the engagement portion (28) being not inserted in the teeth meshing area (3) or inserted in the teeth meshing area (3) less than when the safety stop (26) is in the operative position, for in use allowing the sliding of the teeth with respect to the tooth engagement structure at least in the first direction (29); deactivation means (39) of the safety stop (26) which comprise at least one actuator element (40) operatively associated with the safety stop (26); only when said safety stop (26) occupies the rest position in said slider 1 is an activation volume (38) which is included between the tooth engagement structure (2) and the safety stop (26) can also be identified; characterized by the fact that: said deactivation means (39) further comprise movement means (41); from the fact that said actuator element (40) is movable between an off position in which the actuator element (40) is outside the activation volume (38) and allows the safety stop (26) to remain in the operative position and an inserted position in which the actuator element (40) is inserted in the activation volume (38) and keeps the safety stop (26) in the rest position preventing it from passing into the operative position; and by the fact that said movement means (41) comprise at least one activation element (46), can be activated manually by a user and are associated with the actuator element (40) to move it at least from the disconnected position to the inserted position. 2. Slider for zipper according to claim 1 wherein said actuator element (40) moves to and from the activation volume (38) along a working path (42) and has a tapered shape with decreasing section along a line of development that goes from the disengaged position to the engaged position. 3. Slider for zip fastening according to claims 1 or 2 wherein when the actuator element (40) is in the inserted position the actuator element (40) is interposed between the tooth engagement structure (2) and the safety stop (26), is in contact with both and the movement of the safety stop (26) from the rest position to the operative position is impossible. Zipper slider according to any one of claims 1 to 3 wherein said safety catch (26) is connected to the coupling structure in a rotatable way and can rotate between the rest position and the operative position according to a first axis rotation (30). 5. Cursor for zipper according to claim 4 when it depends on 2 in which the working path (42) of the actuator element (40) is parallel to said first axis of rotation (30). 6. Zipper slider according to claim 4 when it depends on 2 in which the working path (42) of the actuator element (40) is perpendicular to said first axis of rotation (30). Zipper slider according to any one of claims 1 to 6, wherein said activation element (46) comprises an operating ring (47 which is rotatably connected to the engagement structure of the teeth 2 according to a second axis of rotation (48). 8. Zipper slider according to any of claims 1 to 7 wherein said activation element (46) is rigidly associated with the actuator element (40). Zipper slider according to any one of claims 1 to 7, wherein said moving means (41) comprise a movable cam (49) operatively associated with the actuator element (40), and in which the movement of said movable cam (49) determines the movement of the actuator element (40) at least from the disengaged position to the engaged position. 10. Slider for zip fastening according to claims 7 and 9, in which said movable cam (49) is integral with the operating ring (47) in rotation around the second rotation axis (48) in which said operating ring (47 ) can rotate with respect to the tooth engagement structure (2) by an activation angle around the second rotation axis (48), and in which the rotation of the operating ring (47) with respect to the second rotation axis (48) it determines the movement of the actuator element (40) at least from the disengaged position to the engaged position. 11. Slider for zipper according to any one of claims 1 to 10, in which said movement means (41) determine the movement of the actuator element (40) from the disengaged position to the engaged position and from the engaged position to the disengaged position. Zipper slider according to any one of claims 1 to 11, wherein said moving means (41) comprise elastic means (50) operatively active on the actuator element (40) to bring the actuator element (40) to the position disengaged when the actuator element (40) is in a position other than the disengaged position and in the absence of external stresses on the activation element (46). 13. Slider for zip fastening according to claim 12 wherein said elastic means (50) act between the tooth engagement structure (2) and the actuator element (40), or in which said elastic means (50) act between the tooth engagement structure (2) and the activation element (46), or in which said elastic means (50) act between the tooth engagement structure (2) and the safety stop (26).