FI127515B - Footwear pin mechanism and footwear - Google Patents

Abstract

A shoe's nub mechanism comprises a body capsule having a cavity and a bottom wall (52), said bottom wall having an outer surface, and at least one slip guard (12) extending through the bottom wall, said slip guard having a tip (14) and a stem which extends into the cavity. Inside the cavity is a support piece for moving the slip guard in a first position where said tip is at a first distance from the bottom wall, and in a second position, where said tip is at a second distance from the bottom wall, expressed from the outer surface of the bottom wall. The second distance is substantially greater than the first distance. The support piece is arranged in the cavity to be immovable in the longitudinal direction of the cavity and the hub mechanism additionally has use means (30) for rotating the support piece relative to the body capsule.

Description

Footwear pin mechanism and footwear

BACKGROUND OF THE INVENTION The present invention relates to a stud mechanism for a footwear comprising a frame housing having a cavity and a bottom wall having an outer surface, an anti-slip barrier extending through at least one bottom wall having a toe and a heel a first distance from the bottom wall, and a second position, wherein said tip is a second distance from the outer wall of the bottom wall protruding, which second distance is substantially greater than the first distance. The invention further relates to a footwear having a stud mechanism according to the invention.

The adhesion of outdoor footwear to various substrates can be influenced by the embossing of the sole of the footwear and the material of the sole. In winter conditions, the fairway surfaces are often covered with ice or polant, whereby the sole properties of the base alone do not provide sufficient traction. To improve the grip of the footwear on slippery surfaces, a variety of stud solutions integrated with the sole of the footwear have been developed, which are normally hidden inside the sole, but can be moved from the sole to the extended position if necessary.

US2010 / 0199525 A1 discloses a shoe sole having inward and outward movable studs. The studs are arranged in studs having a support plate movable in an upward and downward direction. By moving the support plate, the pins are allowed to protrude from the pin housing and retract back into the pin housing. The pins are moved by manually rotating the handle provided on the heel of the shoe, which is connected to the stud plate support plate by a threaded rod mechanism. This type of pin transfer mechanism is complex in structure and prone to malfunction.

US 7926205, US 2011/0126426, US 4375729, EP 1621093 and US 6256907 disclose footwear having studs projecting from the bottom of the footwear. The transfer mechanism of the studs comprises a movable rigid plate, substantially the entire length of which is arranged in a cavity inside the sole of the footwear, the underside of which corresponds to the heel of the studs. When the plate is moved to the first position in the cavity, it pushes the tips of the studs from the bottom of the footwear. Similarly, when the disc is moved to another location in the cavity, the pins can retract back into the sole of the footwear without obstructing the disc. These solutions require a considerable amount of force to move the sheet inside the sole of the shoe between the sheet and the cavity walls, or

20155810 prh 05 -11- 2015 to overcome the itchy friction. The plate inside the sole of the footwear also stiffens the sole, thereby reducing the comfort of the footwear.

US 6125556 and US 4873774 disclose stud solutions in which the studs are located in cylinders in which fluid or air can be pumped by a manually operated pump. The air- and liquid-tight chambers of these solutions break easily when using shoes, whereby the stud mechanism loses its functionality.

It is an object of the invention to provide a stud mechanism for footwear and a footwear for reducing the drawbacks and drawbacks of the prior art.

The objects of the invention are achieved by a stud mechanism and a footwear characterized by what is disclosed in the independent claims. Certain preferred embodiments of the invention are set forth in the dependent claims.

BACKGROUND OF THE INVENTION The present invention relates to a stud mechanism for a footwear comprising a frame housing having a cavity and a bottom wall having an outer surface on the bottom wall and at least one non-slip barrier extending through the bottom wall having a toe and a heel. Inside the cavity is a support for moving the non-slip barrier to a first position wherein said tip is a first distance from the bottom wall and a second position wherein said tip is a second distance from the bottom wall protruding from the outer surface of the bottom wall. The second distance is substantially greater than the first distance. In the invention, the support member is arranged in the cavity immovably in the longitudinal direction of the cavity, and the stud mechanism further comprises actuating means for rotating the support member relative to the housing.

By the outer surface of the bottom wall is meant the surface which, in a shoe with a stud mechanism according to the invention, is positioned closest to the base on which the foot is walked. The tip of the non-slip extends out of the cavity through a hole in the bottom wall. In the first position, the non-slip barrier may remain completely inside the housing of the stud mechanism, so that its tip does not extend to the outer surface of the bottom wall. Alternatively, the tip of the non-slip bar in the first position may extend substantially in line with the outer surface of the bottom wall, or the tip of the non-slip bar in the first position may protrude slightly out of the plane of the outer surface of the bottom wall. It is essential that the tip of the non-slip barrier in the first position does not extend to the surface of the base when walking with the footwear of the invention with a stud mechanism along the base. It makes sense to put the non-slip position in the first position when the footwear is moving on an outsole,

20155810 prh 05 -11- 2015 with weaving surfaces inside the building. When the slip bar is in the second position, its tip protrudes clearly from the outer surface of the bottom wall. The tip of the non-slip barrier in the second position extends to the surface of the sole as the footwear with the stud mechanism of the invention is walked along the base. This non-slip position is appropriate when walking on slippery surfaces or surfaces.

In a preferred embodiment of the pin mechanisms according to the invention, the support member has a first end, from which the first end is pivotally attached to the housing. The support member is thus rotated within the cavity relative to the first end within the limits of the volume of the cavity. Preferably, the support member has one end, and said actuating means comprises means for moving one end of the support member toward the bottom wall. As one end of the support piece is moved toward the bottom wall, the non-slip bar that engages with the support piece also moves in the direction of the bottom wall.

In another preferred embodiment of the stud mechanism according to the invention, the support member has a support surface which lies against the base of the non-slip barrier. Preferably, the support surface is located between the first end and the second end of the support body.

In yet another preferred embodiment of the pin mechanisms of the invention, said actuating members comprise a rotatable shaft within the cavity having a butt end such that one end of the support piece is between the butt end and the bottom wall. The shaft is rotatable to a first position where the butt head is at a first distance from the bottom wall and to a second position where the butt head is a second distance from the bottom wall. The second distance is substantially smaller than the first distance. In this embodiment, the shaft end of the shaft is pressed against the surface of the support member and forces one end of the support member to move toward the bottom wall as the shaft is rotated to another position. The bullet head may have at least one bumper roll which abuts against the support surface. This way, there is no sliding friction on the surface of the butt head and the support when rotating the shaft.

In yet another preferred embodiment of the stud mechanism of the invention, the actuating members comprise a pivoting lever extending outward of the housing to rotate the shaft. The swivel lever allows you to rotate the shafts to the desired position with your fingertips. Thus, the wearer of the footwear having a stud mechanism according to the invention can set the slide mechanism of the stud mechanism in any desired position.

20155810 prh 05 -11- 2015

Yet another preferred embodiment of the stud mechanism of the invention comprises locking means for locking said at least one non-slip bar in a second position.

Thanks to the locking member, the non-slip device remains in the protruding position from the bottom wall, even though a non-slip force is applied to the tip of the locking member in the direction of the cavity. Preferably, said locking members comprise a locking recess at one end of the support member for receiving the butt end of the rotated shaft in a second position. In this embodiment, the shaft is locked by means of locking means in a second position in which the support member is displaced towards the bottom wall by the butt head. The locking support thus prevents the sliding bar from moving towards the cavity.

In yet another preferred embodiment of the stud mechanism according to the invention, said actuating members further comprise a return means for moving the non-slip bar from the second position to the first position. Preferably, said non-slip bar has an elongated shaft and said return means is a helical spring disposed about the shaft. Alternatively, the return means may be a body of resilient material disposed between the support and the bottom wall, or a leaf spring disposed at the first end of the support at the interface between the support and the frame housing. It is also conceivable that the support member is made entirely or partially of resilient material and is rigidly attached at its first end to the housing. In this case, the support piece or part thereof acts as a recovery means itself.

The invention further relates to a shoe having an upper and a sole. In the footwear of the invention, the sole comprises a stud mechanism as described above. Preferably, said stud mechanism is provided in the sole of the sole of the footwear.

The heel is usually the thickest part of the sole of the foot, so it is easy to arrange a space for the stud mechanism. If the thickness of the base end portion is sufficiently large, it is possible to alternatively arrange the pin mechanism in the base end portion. Further, it is possible to arrange the pin mechanism in the bottom such that the first portion of its non-slip barriers is located in the base portion of the base and the second portion in the end portion of the base. It is also conceivable that two separate pin mechanisms are provided on the bottom, the first located in the base portion and the second in the end portion.

An advantage of the invention is that it is structurally simple and reliable.

A further advantage of the invention is that it does not stiffen the sole of the footwear, so the invention does not affect the comfort of the footwear.

20155810 prh 05 -11- 2015

The invention will now be described in detail. In the description, reference is made to the accompanying drawings, in which Fig. 1a is an exemplary top view of a stud mechanism of a footwear according to the invention; Fig. 1b is an exemplary bottom mechanism of Fig. top view and Figure 4 is an exemplary side view of a shoe according to the invention.

Fig. 1a shows, by way of example, a pivot mechanism of the footwear according to the invention, seen from above, and in Fig. 1b, the same pivot mechanism, from below. In the following, both pictures are explained simultaneously.

The stud mechanism has a plastic molded housing 50 having a bottom wall 52, a side wall 54 and a removable lid 56. The lid 56 is secured to the sidewall of the housing by screw mounting 58. The bottom wall 52 has two holes each with a base and a tip 14 extending outwardly from the housing housing with two pointed spikes. The frame housing has a cylindrical portion on one side with a pivoting lever 30 at one end, the pivoting lever adjusting the position of the non-slip members of the stud mechanism as described below. The stud mechanism is intended to be molded into the heel of the sole of the footwear so that the stud mechanism is substantially encircled throughout the sole material.

Figures 2a and 2b show, by way of example, a cross-sectional view of the pin mechanism of Figures 1a and 1b. Fig. 3 is a top plan view of the pin mechanism of Figs. 2a and 2b with the cover 56 of the housing 50 removed. In the following, all the above pictures will be described at the same time. Inside the housing, there is a cavity 9 defined by a bottom wall 52, a side wall 54, and a lid 56. The longitudinal direction of the cavity is substantially the same as the direction of the housing and the bottom wall. Inside the cavity is a support piece 15 having a first end 19 and a second end 20. The first end of the bottom wall has two securing lugs 53 between which

20155810 prh 05 -11- 2015 The first end of the bracket is fitted. At the first end of the support piece is a pivot shaft 55, the ends of which extend into the slots formed in the mounting brackets for the pivot axis. The axis of rotation can rotate in the slots of the mounting lugs about its longitudinal axis. On the hollow side of the housing cover 56, there are support brackets 31 having a curved-wall notch surrounding the pivot axis, thereby preventing the pivot axis from protruding from the slot of the mounting lugs.

The portion between the first and second ends of the support member has two recesses which open towards the bottom wall 52 of the housing. The bottom of the recesses has a flat support surface 16. The bottom wall has, at the recesses, holes 57 fitted with a slip bar 12 in the form of a pin. with its base inside the cavity and its tip outside the cavity. Two sharp spikes have been machined at the tip of the non-slip barrier. Around the hole, on the cavity side of the bottom wall 52, there is a support collar 59 which supports the non-slip bar in the lateral direction and prevents it from tilting in the hole. The slip bar can move between the first position shown in Figure 2a and the second position shown in Figure 2b in the direction of its longitudinal axis in the hole 57 and the support collar. Surrounding the non-slip arm and support collar is a helical spring 20 in its form, which retains its first end to the bottom wall 52 and its second end to the support surface 16.

At one end of the housing, there is an axis 24 having a first end extending through a side wall 54 on a first side of the housing 50 and a second end pivotally attached to the side wall on the other side of the housing. Outside the housing, at the first end of the shaft is a pivot lever 30 for rotating the shaft. Inside the cavity, half of the shaft length is a projection 26 which rigidly engages its first edge with the shaft 24. The free second edge of the projection is branched into two butt ends 27 each provided with a bumper 28. At the other end of the support settle. The free face of the butt face has a groove-locking recess 29 for receiving the butt end 27 and the butt end roller 28.

In Fig. 2a, the two non-slip barriers 12 of the stud mechanism according to the invention are in a first position where the non-slip barriers are for the most part inside the cavity 9. Only the tip of the non-slip and a very small part of the arm of the non-slip extends outside the cavity. The tip of the non-slip bar is the first distance

20155810 prh 05 -11- 2015 from the bottom wall 52. The support member inside the cavity is then in a first position where it is pushed by the return member 22 as close as possible to the cover 56 of the housing 50 within the configurations of the cavity 9. Between the support piece 15 and the bottom wall 52, there is a space at the recess where the sliding tongue 12 can retract. The non-slip bar is supported at its base 13 on the support or at the other end of the recovery means such that the movement of the non-slip base follows the movement of the support surface. The shaft 24 is in a first position in which the projection 26 engaging it is positioned substantially parallel to the cover 56 against the cover.

When it is desired to cause the non-slip protrusions to protrude more from the inside of the housing, the shaft 24 is rotated by rotating the pivot lever 30 to the second position shown in Fig. 2b where the projection 26 is substantially perpendicular to the cover 56. As the shaft rotates, the bumper rollers 28 at the projection butt end 27 roll along the butt face 61 of the support piece and press one end of the support piece toward the bottom wall. Thanks to the hinged fastening by means of the rotary axis 55, the support member 15 can rotate from the position shown in Figure 2a to the second position shown in Figure 2b. In this position, the surface facing the bottom wall of the other end of the support member will engage or at least be very close to the bottom wall. The support surfaces 16 of the support body pivoting into the second position press the bases 13 of the non-slip barriers 12 and push the non-slip barriers in the direction of the bottom wall, whereby the non-slip tips 14 protrude from the plane of the outer surface of the bottom wall 52.

In Figure 2b, the non-slip barriers are as far as possible protruding from the frame housing in a second position with their tips 14 at a second distance from the bottom wall. The second distance is substantially greater than the first distance shown in Figure 2a. The bumper rollers 28 in the shaft-related projection then abut the locking recess 29 in the bumper surface. The compressed resilient means 22 pushes the support body toward the cover 56 with spring force, thereby allowing the bumper rolls to remain firmly pressed into the locking recess. This locks the projection butt end in place and prevents unintentional rotation of the shaft 24.

When it is desired to move the non-slip barriers back to the first position, the shaft 24 is rotated by rotating the pivoting lever 30 to the first position, whereby the return means 22 returns the support and the associated non-slip bar to the first position. The position of the non-slip barriers can thus be adjusted simply by turning the pivoting lever 30 on the outside of the housing to a suitable position.

Figure 4 is an exemplary side view of a footwear according to the invention. The footwear has a sole 100 and an upper part attached to the upper surface of the sole

102. The sole is made by casting on any suitable moldable base material such as rubber, plastic, silicone or a combination of the above materials. During the casting step of the sole, a stud mechanism according to the invention is molded inside the sole so that the mechanism is substantially completely enclosed by the sole material. Outside the outer surface of the base, the pivoting mechanism leaves a pivoting lever 30 which can be rotated so that the sliding bar 12 can be pivoted from the base surface or concealed within the base.

The sole of the footwear can also be manufactured separately so that a suitable space is provided in the sole for a pin mechanism to be installed later. In this case, the pin mechanism is placed in the space created for it and secured to the base, for example by gluing. Finally, the sole with a stud mechanism is attached to the upper of the footwear, after which the footwear is finished. The space in the sole 15 can be formed to open up to the surface facing the upper of the footwear, whereby the stud mechanism on the sole remains within invisible parts of the footwear in the finished footwear.

Some of the preferred embodiments of the stud mechanism and the footwear according to the invention have been described above. The invention is not limited to the solutions described above, but the inventive idea can be applied in various ways within the scope of the claims.

Claims (12)

1. The shoe mechanism of a shoe comprising a body capsule (50) having a cavity (9) and a bottom wall (52), said bottom wall having an outer surface, at least one slip guard (12) extending through the bottom wall (52), which has slip protection A tip (14) and a stem (13) extending into the hollow (9), inside the hollow (9) a support piece (15) for moving the slip guard (12) in a first position, wherein said tip (14) is at a first distance from the bottom wall (52), and in a second position, wherein said tip (14) is at a second distance from the bottom wall (52), expressed from the outer surface of the bottom wall (52), which is substantially greater than the first Characterized in that the support piece (15) has a first end and a second end and the support piece (15) is arranged in the hollow (9) to be motionless in the longitudinal direction of the hollow and the hub mechanism furthermore has use means for rotating the support piece (15) in relative to the body capsule (50) for moving the other end (20) of the support piece (15) toward the bottom wall (52), which use means comprises a rotatable shaft (24) Within the hollow (9), said shaft having a buffer end (27), such that the other end (20) of the support piece (15) is between the buffer end (27) and the bottom wall (52), and the shaft (24) can be rotated in a first position, where the buffer end (27) is at a first distance from the bottom wall (52), and in a second position, where the buffer end (27) is at a second distance from the bottom wall (52), which second distance is substantially smaller than the 20 first distance. The hub mechanism according to claim 1, characterized in that the support piece (15) is pivotally attached at its first end (19) to the body capsule (50). Nubbing mechanism according to any one of claims 1-2, characterized in that the support piece (15) has a support surface (16) which projects against the stem (13) of the slip guard (12). 25 4. A hub mechanism according to claim 3, characterized in that the support surface (16) is on the piece between the first end (19) of the support piece (15) and the second end (20). The hub mechanism according to any of claims 1-4, characterized in that at least one buffer roller (28) is provided at the buffer end (27). 6. Nubbing mechanism according to any of claims 1-5, characterized in that they Said use means comprises a pivot crank (30) extending beyond the body capsule (50) for rotating the shaft (24). 7. Nubbing mechanism according to any of claims 1-6, characterized in that it comprises reading means for reading said at least one slip guard (12) in a second position. 8. Nubbing mechanism according to claim 7, characterized in that said reading means 5 comprises a reading cavity (29) at the other end of the support piece (15) for receiving the buffer end (27) of the shaft (24) rotated to the second position. The nub mechanism according to any of claims 1-8, characterized in that said use means further includes a return means (22) for moving the slip guard (12) from the second position to the first position. 10. Nubbing mechanism according to claim 9, characterized in that said slip guard (12) has an elongated shaft and said return means (22) is a coil spring adapted around the shaft. 11. A footwear having an upper part (102) and a bottom (100), characterized in that said bottom (100) comprises a hub mechanism according to any of the claims 1-10. Footwear according to claim 11, characterized in that said nub mechanism is arranged in the heel portion of the footwear bottom (100).