ITVR20120022A1 - HANDLING DEVICE FOR A HELMET TO MOVE A FIRST ELEMENT OF THE HELMET COMPARED TO A SECOND HELMET ELEMENT. - Google Patents

Description

HANDLING DEVICE FOR A HELMET TO MOVE A FIRST HELMET ELEMENT WITH RESPECT TO A SECOND HELMET ELEMENT

DESCRIPTION

The present disclosure generally refers to a handling device for a helmet. In particular, the present disclosure refers to a movement device for a helmet for moving a first element of the helmet with respect to a second element of the helmet. For example, in a helmet including a visor and a cap, the handling device is adapted to move the visor with respect to the helmet shell between a first operating position, for example an active and closed position in front of the user's face, and a second operating position, for example an inactive and open position, i.e. raised at the user's forehead. Alternatively, for example, in a helmet including a movable flap that closes an air intake or ventilation opening in the helmet, the movement device is adapted to move the movable flap, with respect to a remaining portion of the helmet, or is adapted to moving similar elements or parts of the helmet, such as a chin guard.

The aforementioned handling device therefore finds application in all protective helmets where there is a movement of parts.

In particular, with specific reference to a helmet with a visor, the need is known to carry out a roto-translation of the visor, that is to say to make a translation movement of the visor forward with respect to the cap, at the initial moment of opening the visor. visor from the closed position, and to follow the translation movement with a rotation movement to move the visor to the open position on the user's forehead. This roto-translation movement makes it possible to have a helmet in which the visor, the chin guard or the aforementioned movable flap is flush with the shell or a corresponding portion of the helmet when it is in the closed position, and the visor can be opened chin guard or the movable leaf in the open position without interfering with the overall dimensions of the shell during the opening movement.

The known handling devices, although advantageous from many points of view, are very complex to manufacture and are formed by numerous mechanisms and components, such as to make the helmet very expensive from a production point of view.

A technical problem underlying the present disclosure resides in providing a handling device for a helmet whose structure is simplified and with a reduced number of components, and / or to achieve further advantages. A technical problem underlying the present disclosure also resides in providing a helmet including such a device.

The technical problem is solved by providing a handling device for a helmet as defined in independent claim 1, a helmet including such device as defined in claim 12 and a method according to claim 15. Secondary characteristics of the object of the present disclosure are defined in the corresponding dependent claims.

In particular, according to the present disclosure, the rotation seat for pin has a first seat region adapted to receive an eccentric portion of the pin element and a second seat region, distinct from the first seat region and adapted to receive the portion eccentric of the pin element, in which the first seat region is in an angularly offset position about the axis of rotation of the pin element and linearly translated with respect to said second seat region, and in which the first seat region a first position of the pin element corresponds and a second position of the pin element corresponds to said second seat region, such that said second position of the pin element is a rotated and linearly translated position with respect to said first position, and vice versa. In other words, according to the present disclosure, the pin seat itself has two different seat regions which are in a reciprocal spatial relationship, with predefined angular offset and predefined linear offset, such that a movement of the eccentric portion of the pin element between the first seat region and the second seat region, and vice versa, causes a roto-translation of the pin element and therefore of the first element of the helmet connected to the pin element.

The first element of the helmet connected to the pivot element can be the helmet visor, or any other mobile element, such as for example a flap designed to close a ventilation opening, or a chin guard. The second element of the helmet can be the shell, or for example the chin guard, if the movable flap closes a ventilation opening of the chin guard.

In this way, when it is necessary to open the visor, the movable sash or the chin guard (first element) and a user begins to rotate the first element, a displacement of the eccentric portion of the pivot element occurs, thanks, for example , to the interaction between the cam element and the pin seat, for example from the second position to the first position. This displacement includes both a rotation of the eccentric portion and therefore the rotation of the movable element, as well as a linear displacement of the eccentric portion and therefore a linear displacement of the movable element, to compensate for the angular and linear offset of the first seat region with respect to the second. seat region.

Said angular and linear offsets of the first seat region with respect to the second seat region are designed so as to correspond, for example for a visor, to an outward advancement of the first element (visor, chin guard or movable flap), away from the second element (for example the cap), at the moment of opening, and a retraction towards the second element at the moment of closing.

It follows that when a user activates the movement of the first element, for example by imposing a rotation on the visor, the chin guard or the flap, a translation is obtained immediately, almost as a consequence of the rotation. In practice, the rotation of the pin in the seat of the pin is capable of causing a translation thereof between the two seat regions, such that the pin as a whole performs a roto-translation.

In other words, to achieve a roto-translational movement of a visor or other first element of the helmet, a pivot element is associated with the first element of the helmet and a seat for pivot is associated with the second element of the helmet. This embodiment allows to obtain a very simple handling device since it can be obtained by means of a suitable design of the seat regions of the pin seat and of the respective angular offset and linear offset, as well as a corresponding design of the pin element and of the eccentric portion of the pin member.

Furthermore, this solution allows to obtain a direct correlation between the angular offset and the linear offset of the seat regions of the pin seat and the angular displacement and linear displacement of the pin element.

Complicated mechanisms are therefore avoided.

According to an aspect of the present disclosure, the pin seat acts as a counter-cam and allows the reciprocal angular and linear movement of the pin element in the pin seat. A rotation of the pin element is coordinated with a translation thanks to a cam / counter-cam interaction between the pin element and the pin seat. This means that at least between the eccentric portion of the pin element and the respective seat regions of the pin seat, there is a temporary interaction between parts, for example a contact, such that a thrust is established between the two elements such as to determine the displacement of the first element with respect to the second element.

In one embodiment, the rotation seat is shaped like a recess which is formed in a base body integrally associated with the second element of the helmet. In other words, the handling device comprises a base body, for example plate-shapes, on one face of which a recess is obtained which acts as a rotation seat for the pin element.

In some embodiments, the base body recess defines an edge or side wall in the base body. The side edge is suitably shaped to define the two seat regions that correspond to the two positions of the pin element and the respective second element.

For example, to facilitate movement of the eccentric portion between the first seat region and the second seat region, the edge or side wall defining said pin seat is a curved shaped edge.

Even more particularly, the first seat region corresponds to a respective concave profile of the lateral edge, and said second seat region corresponds to a respective convex profile of the lateral edge. That is to say that between the first seat region and the second seat region, the lateral edge of the recess has a substantially concave / convex course. It follows that to obtain the linear displacement of the eccentric portion, a variation of concavity / convexity of the lateral edge of the recess is exploited.

Furthermore, in some embodiments, in order to be able to control a movement of the pin element between the first position and the second position, the pin element comprises an eccentric appendage intended to be received in a third seat region having the function of stroke end, when the eccentric portion is in the second seat region, and in a fourth seat region also having the function of stroke end, when the eccentric portion is in the first seat region. These third seat region and fourth seat region can also be obtained by means of suitable shaping of the lateral edge of the recess defining the seat for the pin, in which this eccentric appendage interacts with the lateral edge of the recess.

In some embodiments, the handling device includes a retaining assembly to hold the pin element in the first position or in the second position, in order to avoid unwanted movement of the pin element from the position in which it is located; this is useful to ensure that the movement of the pivot element between the first position and the second position cannot occur spontaneously, but only under the control of the user. The retaining assembly includes, in some embodiments, an interaction element associated with the pin element, such as for example a tooth, and at least one counter-interaction element, associated with the pin seat. One and / or the other of the interaction elements and counter-interaction element can be an elastically deformable element, whose flexibility or elasticity is calibrated to allow the pin element to be retained in normal conditions in the absence of forcing (i.e. i.e. when the first element of the helmet is stationary with respect to the second element of the helmet in the open and / or closed condition), and to move the pivot element, by applying a slight forcing or pressure between the interaction element and the counter-element of interaction, when the first element of the helmet has to be moved in opening and / or closing with respect to the second element of the helmet.

Further advantages, characteristics and methods of use of the handling device, of the helmet and of the method according to the present disclosure will become evident from the following detailed description of some preferred embodiments, presented by way of non-limiting example.

However, it is clear that each embodiment of the object of this disclosure may present one or more of the advantages listed above; in any case, it is not however required that each embodiment have all the listed advantages simultaneously.

Reference will be made to the figures of the attached drawings, in which:

Figure 1 represents a partially sectional side view of a helmet including a handling device according to an embodiment of the present disclosure;

Figure 2 represents an enlarged scale view, on a first side, of a handling device according to an embodiment of the present disclosure in a first operating condition;

Figure 3 represents an enlarged scale view, on a first side, of a handling device according to an embodiment of the present disclosure in a second operating condition;

Figures 4-6 show schematic views, from a first side, of a handling device according to an embodiment of the present disclosure under subsequent operating conditions;

figure 7 represents an enlarged and partial scale view, from a first side, of a movement device according to an embodiment of the present disclosure;

Figure 8 represents an enlarged scale view, on a second side, of a handling device according to an embodiment of the present disclosure in an operating condition;

Figure 9 represents a further enlarged scale view, from a second side, of a handling device according to an embodiment of the present disclosure in an operating condition;

Figure 10 represents an axonometric view of a helmet including a handling device according to an embodiment of the present disclosure associated with a ventilation opening.

With reference to the attached figures, the reference number 10 indicates a handling device according to the present disclosure.

In particular, in the example of the figures, the handling device 10 is applied to a helmet 12 including a cap 14 for protecting the head of a user and a visor 16. The handling device 10 is intended to move the visor 16 with respect to the shell 14 of the helmet 12 with a rotational or oscillating movement around an X axis.

More specifically, two handling devices 10 are associated with the helmet 12, only one of which is visible in figures 1-9, arranged on opposite sides in correspondence with so-called temporal regions of the head of a user, i.e. in correspondence with the sides of the helmet 12 that protect the temporal zones of the user's head. The X axis extends between one temporal region and the other and is the same for both handling devices 10.

For the sake of simplicity, in the following of the present description only one movement device 10 is described, i.e. the one located in the right-hand area of the cap 14, or in other words the movement device 10 located in correspondence with the right temporal region of 'user. In Figures 1-7, the handling device 10 is seen from the internal side of the helmet 12, i.e. from the side connected to the shell 14, while in Figures 8-9, the handling device 10 is seen from the opposite side, i.e. i.e. from the connection side to the visor 16 on the outer side of the helmet 12.

Each movement device 10 is designed to move the visor 16 between a first operating position, or closed position, in which said visor 16 is in front of the user's face, with a protection function, to a second operating position, or open position. , in which the visor 16 is raised at the user's forehead. It is to be understood that the handling device 10 can be associated with any other element of the helmet, such as for example a chin guard or a movable flap intended to close a ventilation opening. For example, Figure 10 illustrates a helmet including a movable flap 116 intended to close a ventilation opening 115. The handling device 10, which is located under the flap 116 and is therefore not visible, is designed to move the flap movable 116 between an open position and a closed position, as for the visor 16.

In the following description, reference will be made in particular to the use of the movement device 10 to move the visor 16 (which represents said first element of the helmet) with respect to the shell 14 (which represents said second element of the helmet) with the sole purpose of simplify the exposure.

In the example illustrated, the handling device 10 comprises a base body 20, or support base or base, integrally associated with the shell 14 of the helmet, for example by means of screws 21, and arranged on the shell 14 and a pin element 24 which it is movable with respect to the base body 20.

In particular, the pin element 24 includes a first head portion 22 having a lanceolate and oblong shape, which is housed in a pin seat 25 obtained in the base body 20. In particular, the pin seat 25 is a recess made in the base body 20 on one side or face of the base body.

In some embodiments, the pin element 24 and the base body 20 are made of metal materials to ensure sufficient strength.

In other embodiments, the pin element 24 and the base body 20 are made, for example, of acetal resin, polycarbonate, ABS, or similar materials having adequate mechanical strength.

The pin element 24 is stably associated with the visor 16 and is integral in rotation with it. The connection between the pin element 24 and the visor 16 is obtained, in a known way.

For the connection with the visor 16, the pin element 24 includes a second portion of the head 23, opposite the first portion of the head 22, in the example of substantially rectangular shape (see figures 8-9).

As can be seen from the drawings, the pin element 24 includes a rotation shaft, generally indicated with the number 27, coaxial to the X axis of rotation of the visor 16, and an eccentric portion 26, or cam, eccentric with respect to the X axis and associated with the first head portion 22.

With reference to Figures 2-3, according to an aspect of the present disclosure, the pin seat 25 acts as a counter-cam for the eccentric portion 26 and includes a first seat region 30 adapted to accommodate said eccentric portion 26 and a second region of seat 32 adapted to receive said eccentric portion 26, in which the first seat region 30 is in an angularly offset and linearly translated position with respect to said second seat region 32. The angular offset of the first seat region 30 with respect to the second region of seat 32 is indicated with “a” in figure 3 and is around the axis of rotation X.

The linear or transverse offset of the first seat region 30 with respect to the second seat region 32, which, in the illustrated example is substantially on a horizontal plane, is indicated with "d" in Figure 3.

On the basis of said spatial relationship between the first seat region 30 and the second seat region 32, the first seat region 30 corresponds to a first position of the pin element 24 and to said second seat region 32 corresponds a second position of the pin element 24, such that said second position is a rotated and translated position with respect to said first position.

Even more particularly, in the illustrated example, the first position of the pin element 24, when the eccentric portion 26 is in the first seat region 30, is designed to correspond to an advanced and angularly higher position with respect to the second position of the pin element 24, when the eccentric portion 26 is in the second seat region 32.

It follows that, in the example illustrated, the first position of the pin element 24, when the eccentric portion 26 is in the first seat region 30, corresponds to an opening condition on the forehead (in a linearly advanced position) of the visor 16.. second position, when the eccentric portion 26 is in the second seat region 32, a condition of closure of the visor 16 corresponds (in a linear position it retracts flush with the cap 14).

The correlation between the open position and the closed position of the visor 16 and the positions of the eccentric portion 26 of the pin element 24 in the seat 25 is visible in figures 4-6.

Even more particularly, to open or close the visor 16, a user acts as follows.

Initially, the visor 16 is, for example, in an open position on the forehead. Therefore, the eccentric portion 26 is located in the first seat region 30.

When the visor 16 is lowered, the eccentric portion 26 passes from the first seat region 30 to the second seat region 32, and the pin element 24 rotates to compensate for the angular offset between the two seat regions 30, 32, and a backward translation to compensate for the linear offset between the two seat regions 30, 32.

It follows that the visor 16 is retracted towards the cap and in the closed position it is flush with the cap 14.

Conversely, to open the visor 16, the eccentric portion 26 passes from the second seat region 32 to the first seat region 30, and the pin element 24 performs not only a rotation but also a forward translation, bringing the visor towards the outside, beyond the overall dimensions of the shell 14.

With reference to Figures 2-3, it can also be observed that the seat 25 for the pin is substantially a recess obtained in the base body 20, on one face of the base body 20.

The recess defines an edge or side wall 35 in the base body 20.

The side edge 35 is suitably shaped to define the first seat region 30 and the second seat region 32, i.e. the first seat region 30 and the second seat region 32 are defined by a shaping of the side edge 35 of the body base 20.

The profile of the lateral edge 35 is substantially concave-convex, with a flex, i.e. it includes a hollow-hump, between the first seat region 30 and the second seat region 32.

In particular, the lateral edge 35 has a concave profile, that is to say defining a depression or groove, in correspondence with the first seat region 30 and a slightly convex profile, that is to say defining a slight protrusion or ridge, in correspondence with the second region of headquarters 32.

Thanks to this concave / convex shape of the lateral edge 35 of the base body 20 it is possible to obtain a homogeneous and discontinuous roto-translation movement of the pin element 24.

With reference to figures 2-3, it can also be observed that the first head portion 22 of the pin element 24 comprises, in addition to the eccentric portion 26, a protruding eccentric appendage 36 which is arranged on the substantially opposite side of the X axis with respect to the eccentric portion 36, and interacts with further seat regions of the seat 25.

This appendage 36 has the function of interacting with the lateral edge 35 of the base body 20 both to guide the displacement of the pin element 34 from the second (backward) position to the first (advanced) position and to define a so-called limit switch for the movement of the pin element 24 in the two positions. In particular, the seat 25 comprises on the part substantially opposite to the rotation axis X, a third seat region 40 intended to accommodate the eccentric appendage 36, when the eccentric portion 26 is located in the second seat region 32, and a fourth seat region 42 intended to accommodate the eccentric appendage 36, when the eccentric portion 26 is located in the first seat region 30.

The third seat region 40 and the fourth seat region 42 are also defined by a concave shape of the edge 35. In fact, the edge 35 has respective concave depressions with the formation of shoulders 45, 46 in correspondence with the third seat region 40 and fourth region seat 42, said shoulders 45, 46 acting as a limit stop. In addition, the edge 35 between the third seat region 40 and the fourth seat region 42 is shaped so as to obtain a linear displacement of the pin element 24 when it is returned from the second (backward) position to the first (advanced) position.

With reference to Figures 7-9, it is also observed that the handling device 10 includes a retaining assembly 50 for holding the pin element 24 in the first or second position, avoiding an undesired movement of the pin element 24 from the respective first position or second position. To this end, the base body 20 comprises, on the side / face opposite to the seat 25 for the pin, a cavity 51 in which a spring 52 is housed, in the example a linear wave spring.

In practice, the base body 20 has on a first side or face the seat 25 for the pin, and, on another side or face, the cavity 51 for the retaining assembly 50, and in particular, in the illustrated example, for linear wave spring 52.

The spring 52 is defined by means of an adequate profile and, in the illustrated embodiment, comprises in particular three waves, defining as many two lateral bumps 53, 55 and a central bump 54 and respective two intermediate depressions, and is positioned in the cavity 51, in so that it can be flexed in a direction orthogonal to the direction of the rotation axis X of the pin element 24.

The spring 52 is adapted to interact with an interaction element associated with the pin element, which in the example of realization is a tooth 56, having a rounded profile in the example.

The tooth 56 and the linear wave spring 52 are reciprocally arranged and designed so that when the eccentric portion 26 is in the first seat region 30, the tooth 56 is stably housed in one of the two depressions between two bumps, for example between the two bumps 53, 54 of the spring 52, and, when the eccentric portion 26 is in the second seat region 32, the tooth 56 is stably housed in the other depression between the other two bumps, for example between the two bumps 54 , 55 of the spring 52. In practice, the tooth 56 acts as an interaction element and the spring as an interaction counter-element. The profile of the spring 56 thus allows the interaction element to be retained in normal conditions in the absence of forcing (i.e. when the visor 16 of the helmet is stationary with respect to the cap 14 in the open and / or closed condition) both in the first position and in the second position, and to prevent unwanted movements of the visor 16. A single spring 52 is thus used to stop the pin element 24 in the two positions.

In fact, when the visor 16 of the helmet has to be moved to open and / or close, and the pin element 24 is moved between the first position and the second position and vice versa, the tooth passes from one position to another, deforming the profile of the spring and counteracting the elastic force of the latter. After passing, thanks to the elastic return of the spring 52, it re-positions itself in its original position, again retaining the tooth 56 of the pin element 24.

This elastic configuration of the retention assembly allows for a smooth and cushioned movement of the visor during opening and closing operations.

The handling device of the present disclosure has been described up to now with reference to its preferred embodiments. It is to be understood that other embodiments may exist which pertain to the same inventive core, all falling within the protection scope of the claims set out below.

Claims (19)

CLAIMS 1. Handling device (10) for a helmet (12) for moving a first element (16) of the helmet (12) with respect to a second element (14) of the helmet (12), in which said handling device (10) includes a pivot element (24) for pivoting the first element (16) of the helmet with respect to the second element (14) of the helmet around a rotation axis (X), and a rotation seat (25) for pivot, in which the pin element (24) is arranged at least partially, in which said pin element (24) includes an eccentric portion (26) or cam, and said seat (25) includes a first seat region (30) adapted to accommodate said eccentric portion (26) in a first position of the pin element (24), and a second seat region (32) adapted to receive said eccentric portion (26) in a second position of the pin element (24), in which the first seat region (30) is in an angularly offset position around the rotation axis (X) and linearly translated with respect to to the second seat region (32), such that the second position of the pin element (24) is angularly offset around the rotation axis (X) and linearly translated with respect to the first position of the pin element (24) , and viceversa. Movement device (10) according to claim 1, wherein the eccentric portion (26) is configured to cooperate with the rotation seat (25) causing a displacement of the pin element (24) from the first position to the second position , in correspondence with an angular displacement of the first element (16) with respect to the second element (14) around the axis of rotation (X). Handling device (10) according to claim 1 or 2, comprising a base body (20) fixed to the second element (14) of the helmet, in which the base body (20) has a recess delimited by an edge or lateral wall (35), said recess defining said seat (25) for the pin and acting as a counter-cam for said eccentric portion (26). Handling device (10) according to claim 3, wherein the edge or side wall (35) is shaped to define said first seat region (30) and said second seat region (32). 5. Handling device (10) according to claim 4, wherein the edge or side wall (35) has a respective concave profile to define said first seat region (30) and a convex profile to define said second seat region ( 32). 6. Handling device (10) according to any one of the preceding claims, in which the pin element (24) comprises an eccentric appendix (36) received in the seat (25) for the pin and able to be placed in further areas of the seat of rotation (25), and in which the eccentric appendage (36) is configured to cooperate with the rotation seat (25) causing a displacement of the pin element (24) from the second position to the first position, in correspondence with a displacement angular of the first element (16) with respect to the second element (14) about the axis of rotation (X). 7. Handling device (10) according to claim 6, wherein the seat (25) for pin comprises a third seat region (40) intended to accommodate the eccentric appendage (36), when the first eccentric portion (26) is it finds in the second seat region (32), and a fourth seat region (42) intended to accommodate the eccentric appendix (36), when the first eccentric portion (26) is located in the first seat region (30). 8. Handling device (10) according to claim 7, in combination with claim 3, 4 or 5, wherein the lateral edge (35) defining the seat (25) defines a first shoulder (45) in correspondence with the third region seat (40) with a limit switch function for the second eccentric portion (36) and a second shoulder (46) in correspondence with the fourth seat region (42) with a limit switch function. Handling device (10) according to any one of the preceding claims, comprising a holding assembly (50) for holding the pin element (24) in the first position and / or in the second position, said holding assembly (50) including an interaction element (56) associated with the pin element (24) and at least one counter interaction element (52, 54) associated with the pin seat (25). 10. Handling device (10) according to claim 9, in which one and / or the other between the interaction element and the counter interaction element is an elastically deformable element. Moving device (10) according to claim 9, in which the interaction element is a tooth (56) and the counter interaction element comprises a spring (52) and in which the tooth (56) is adapted to deform a spring profile opposing an elastic force of the spring (52) in correspondence with a passage of said pin element (24) between the first position and the second position and vice versa, and in which, when the pin element (24) is in the first position and / or in the second position, the spring (56) is in the original rest position and holds the tooth (56) of the pin element 24. Helmet (12) including a handling device (10) according to any one of the preceding claims 1 to 11. Helmet (12) according to claim 12, including a visor (16) and / or a chin guard, wherein the visor (16) or the chin guard is said first element of the helmet. Helmet (12) according to claim 12, including a movable flap (116) adapted to close a ventilation opening (115), in which said movable flap (116) is said first element of the helmet. 15. Method for moving a first element (16) of a helmet with respect to a second element (14) of the helmet, said method comprising the steps of - associating a pin element (24) to the first element (16), in which said pin element (24) comprises an eccentric portion (26) with respect to an axis of rotation (X) of the pin; - associating a rotation seat (25) for pin to the second element (14), in which said seat for pin includes a first seat region (30) adapted to accommodate said eccentric portion (26) and a second seat region (32) ) adapted to receive said eccentric portion (26), and in which said second seat region (32) is displaced linearly and angularly offset around the axis of rotation (X) with respect to the first seat region (30); - position the pin element (24) at least partially in the seat (25) in a first position in which the eccentric portion (26) is located in the first seat region (30); - move the pin element (24) to a second position in which the eccentric portion (26) is located in the second seat region (32); wherein when the eccentric portion (26) of the pin element (24) passes from the first seat region (30) to the second seat region (32) or vice versa, the pin element (24) performs a rotation for compensate for an angular offset between the second seat region (32) and the first seat region (30), as well as a translation to compensate for a linear offset between the second seat region (32) and the first seat region (30). Method according to claim 15, wherein the linear displacement is a forward or backward displacement of the first element (16) of the helmet (12) with respect to the second element (14) of the helmet (12), to respectively distance or bring the first element (16) of the helmet (12) from / to the second element (14) of the helmet (12). Method according to claim 15 or 16, wherein the first element (16) of the helmet is a visor (16), a chin guard or a movable flap (116) of the helmet, and in which in the first position, when the eccentric portion (26) is located in the first seat region (30), corresponds to an opening condition of the visor (16), of the chin guard or of the movable flap (116) and in which, to the second position, when the eccentric portion (26) is located in the second seat region (32), there is a condition of closing the visor (16), the chin guard or the movable flap (116). Method according to any one of claims 15 to 17, wherein the eccentric portion (26) moves between said first seat region (30) and said second seat region (32) by interacting with a lateral edge (35) of the seat (25), said lateral edge (35) being shaped and defining the first seat region (30) and the second seat region (32). Method according to any one of the preceding claims 15 to 18, wherein the pin element (24) is retained in said first position and / or in said second position by interaction between an interaction element (56) associated with the pin element (24) and a counter-interaction element (52, 54) associated with the seat (25) for the pin, and in which one and / or the other between said interaction element (56) and counter-element interaction element (56) are elastically deformable elements such that when the pin element (24) passes from the first position to the second position or vice versa, one and / or the other between said interaction element (56) and against -interaction element (52, 54) undergo an elastic deformation.