Classifications

• • A—HUMAN NECESSITIES
  • A43—FOOTWEAR
  • A43B—CHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
  • A43B5/00—Footwear for sporting purposes
  • A43B5/04—Ski or like boots
  • A43B5/0427—Ski or like boots characterised by type or construction details
  • A43B5/047—Ski or like boots characterised by type or construction details provided with means to improve walking with the skiboot
  • A43B5/0474—Ski or like boots characterised by type or construction details provided with means to improve walking with the skiboot having a walk/ski position
• • A—HUMAN NECESSITIES
  • A43—FOOTWEAR
  • A43B—CHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
  • A43B5/00—Footwear for sporting purposes
  • A43B5/04—Ski or like boots
• • A—HUMAN NECESSITIES
  • A43—FOOTWEAR
  • A43B—CHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
  • A43B5/00—Footwear for sporting purposes
  • A43B5/04—Ski or like boots
  • A43B5/0427—Ski or like boots characterised by type or construction details
  • A43B5/0452—Adjustment of the forward inclination of the boot leg
  • A43B5/0454—Adjustment of the forward inclination of the boot leg including flex control; Dampening means
  • A43B5/0456—Adjustment of the forward inclination of the boot leg including flex control; Dampening means with the actuator being disposed at the rear side of the boot
• • A—HUMAN NECESSITIES
  • A43—FOOTWEAR
  • A43B—CHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
  • A43B5/00—Footwear for sporting purposes
  • A43B5/04—Ski or like boots
  • A43B5/0496—Ski or like boots boots for touring or hiking skis

Definitions

• the invention relates to a ski boot comprising a locking device for blocking a rotational joint between a lower shell and a cuff of the ski boot.
• boots are typically equipped with a lower shell and a cuff that rotates around it.
• the lower shell wraps around the foot below the ankle, while the cuff wraps around the lower leg above the ankle.
• the articulation between the lower shell and the cuff allows for easy insertion of the foot into the boot and a natural gait, as the ankle joint is not restricted.
• the articulation between the lower shell and the cuff must be locked to effectively control the skis.
• locking devices also known as “ski-walk” systems. These devices consist of a hand-operated lever that allows the user to choose between two boot configurations. The first configuration, called “ski,” locks the joint between the cuff and the lower shell. The second configuration, called “walk,” unlocks the joint between the cuff and the lower shell.
• ski boots are subjected to particularly harsh conditions: they are exposed to very low temperatures and very high humidity. In addition, they are likely to sustain numerous impacts, especially if the user falls. Under these conditions, the locking mechanisms integrated into these boots are damaged too quickly. Once damaged, a locking mechanism can become even more difficult to operate and/or may no longer properly secure the cuff to the lower part of the shell in ski mode, or may even become completely unusable.
• the object of the invention is to provide a locking device that remedies the above disadvantages and improves upon known locking devices of the prior art.
• the invention aims to provide locking devices that are simple to manufacture, reliable, robust, easy to handle, and that allow the collar to be effectively locked against the bottom of the shell when in ski configuration.
• the bearing surface can be designed to come into direct contact with a receiving surface of the lever to move the lever to its locking position.
• the blade can be mounted to rotate freely around a first axis of rotation, the blade being intended to pivot around said first axis of rotation and to slide relative to the lever when the collar pivots relative to the bottom of the hull.
• the blade may include a first end and a second end opposite the first end, the blade being mounted movable in rotation about a first axis of rotation positioned at its first end, said bearing surface being positioned at its second end.
• the said bearing surface of the blade can be formed by an edge of the blade, in particular an upper edge of the blade.
• the lever can be free to rotate about a second axis of rotation between its locked and unlocked positions.
• the lever may include a receiving surface designed to make direct contact with the blade's bearing surface, the receiving surface being offset from the second axis of rotation.
• the transmission means may include a toggle mounted to rotate about a third axis of rotation, the toggle comprising a first bearing surface and a second bearing surface opposite the first bearing surface with respect to the third axis of rotation, the lever being configured to exert a bearing against the first bearing surface to rotate the toggle about the third axis of rotation, the second bearing surface being configured to exert a bearing against the blocking element to move the blocking element between its blocking position and its unlocking position.
• the transmission means may further include a return means, in particular a torsion spring, the return means comprising a first end and a second end opposite to the first end, the first end being in contact with the lever, the second end being in contact with the first bearing surface of the rocker, the return means being configured so as to be transiently energized when the lever is moved between its locking position and its unlocking position.
• a return means in particular a torsion spring, the return means comprising a first end and a second end opposite to the first end, the first end being in contact with the lever, the second end being in contact with the first bearing surface of the rocker, the return means being configured so as to be transiently energized when the lever is moved between its locking position and its unlocking position.
• the locking element can be mobile in translation parallel to a fourth axis between its locking position and its unlocking position, and the blade can move in a plane substantially perpendicular to the fourth axis when the collar pivots relative to the bottom of the hull.
• the locking element may include a lug
• the blade may include a first opening comprising a shape complementary to a shape of the lug, the lug cooperating with the first opening when the locking element is in the locking position.
• the locking device may include a housing intended to be attached to the collar or the bottom of the hull, the housing including a guide means for guiding the locking element in translation between its locking position and its unlocking position.
• the housing may further include at least one guide intended to guide the blade in translation relative to the housing when the collar pivots relative to the bottom of the shell.
• the locking element may include a first guide surface and the blade may include a second guide surface, the first guide surface cooperating with the second guide surface to guide the movement of the blade relative to the locking element when the locking element is in the unlocked position and the collar pivots relative to the bottom of the hull.
• the blade may include a groove, and said second guide surface may be formed by at least one edge of the groove.
• the locking element may include a first portion, in particular cylindrical in shape, adapted to cooperate with said first opening to block the rotational joint between the collar and the bottom of the hull when the locking element is in the locking position, and a second portion, in particular prismatic in shape, the second portion having at least one flat face forming a first guide surface cooperating with a second guide surface of the blade to guide the movement of the blade relative to the locking element when the locking element is in the unlocking position and the collar pivots relative to the bottom of the hull.
• the invention also relates to a method of automatically locking a rotating joint between the cuff and the lower shell of a ski boot as defined above, the locking method comprising pivoting the cuff relative to the lower shell so that the bearing surface of the blade interacts with the lever and moves the lever to its locking position.
• FIG 1 schematically illustrates a ski boot according to an embodiment of the invention.
• the ski boot is designed to enclose the foot and lower leg of a user and to be attached, in a removable manner, to a board, in particular a ski, for the practice of a snow sport.
• the ski boot 1 can be adapted for alpine skiing and/or ski touring.
• the X-axis represents the longitudinal axis of the ski boot.
• the X-axis is oriented from the heel area of a ski boot user 1 towards the toe area of the user, that is, in the direction in which a ski attached to the ski boot extends forward.
• the Y-axis represents the transverse axis of the ski boot.
• the Y-axis is oriented from left to right, with left and right defined from the user's perspective looking straight ahead.
• the Y-axis is thus approximately parallel to the axis of the user's ankle joint.
• the Z-axis represents the axis perpendicular to the X-axis and the Y-axis.
• the ski boot is assumed to rest on a horizontal surface via its sole.
• the Z-axis is then a vertical axis, oriented from bottom to top.
• the X, Y, and Z axes form an orthogonal coordinate system.
• the ski boot 1 comprises a lower shell 2 designed to enclose the user's foot, a cuff 3 designed to enclose the user's lower leg, and a rotational articulation means 4 between the lower shell 2 and the cuff 3.
• the rotational articulation means 4 is configured to allow rotation of the cuff 3 relative to the lower shell 2 around an axis of rotation Y0 parallel to the Y-axis.
• the axis of rotation Y0 is substantially aligned with an axis of rotation of the user's ankle.
• the axis of rotation Y0 passes, in particular, through the user's two medial and lateral malleoli.
• the ski boot 1 includes a set of tightening means 5A, 5B for tightening the ski boot around the user's foot and lower leg.
• Each tightening means 5A, 5B includes an operating device 6 fixed to a first flap of the lower shell or, respectively, of the cuff, and a fastening means 7 fixed to a second flap of the lower shell or, respectively, of the cuff.
• Each operating device 6 includes a tightening buckle 8 cooperating with the fastening means 7 to bring the first flap closer to the second flap and thus tighten the lower shell around the foot, or, respectively, to tighten the cuff around the lower leg.
• the fastening means 7 may, for example, include a ratchet.
• the ski boot 1 includes two tightening means 5A arranged on the lower shell and two tightening means 5B arranged on the cuff. Alternatively, the number of tightening means could be different.
• the bottom of the hull 2 and the collar 3 can be at least partially made of injected plastic material.
• the lower shell 2 includes a wraparound section designed to enclose the user's foot.
• the lower shell 2 also includes a front footplate 9A and a rear footplate 9B designed to cooperate with a fastening device for attaching the ski boot 1 to a snowboard.
• the lower shell 2 may further include various elements attached to or attached to the wraparound section.
• the lower shell 2 may optionally include a rear wall 58, also referred to as a "rear spoiler.”
• the rear wall 58 may be positioned in a recess formed at the rear of the wraparound section of the lower shell.
• the rear wall 58 may optionally be more flexible than the wraparound section and/or be hinged relative to the wraparound section.
• the ski boot 1 also includes a locking device 10 configured to lock the rotational joint between the lower shell 2 and the cuff 3.
• the locking device 10 allows the boot to be used either in a "walk" configuration, in which the rotational joint between the lower shell 2 and the cuff 3 is free, or in a "ski” configuration, in which the rotational joint between the lower shell 2 and the cuff 3 is locked.
• the walk configuration the ski boot follows the natural articulation of the foot and leg, which facilitates walking.
• the walk configuration also makes it easier to insert or remove the foot from the boot.
• locking the joint allows for optimal transmission of forces from the foot and lower leg to the ski boot, enabling precise guidance of the ski attached to the boot.
• the locking device 10 is not simply a device for adjusting the angle of the cuff 3 relative to the bottom of the shell 2 in ski configuration. Unlike a cuff angle adjustment device, the locking device 10 is intended to be operated frequently during This is especially important for skiing, for example, when the boot is used several times a day. Therefore, the locking mechanism must be robust enough to withstand numerous locking and unlocking cycles, even in very low temperatures and/or when the boot is covered in snow or ice. The locking mechanism must also be ergonomically designed so that it can be operated by the user without removing their boots, gloves, or any special tools. Conversely, a device for adjusting the cuff's angle relative to the lower shell is intended for very occasional use, such as a single adjustment during the initial fitting of the boot.
• Such an adjustment device typically includes a tightening screw.
• the tightening screw is loosened with a screwdriver. This operation is intended to be performed in a workshop. The boot is not intended to be used with the tightening screw loosened.
• the locking device 10 can also be adapted to adjust the inclination of the collar relative to the bottom of the shell, in addition to its function of locking and unlocking the rotational joint between the collar and the bottom of the shell.
• the locking device comprises not a single ski configuration but at least two ski configurations in which the collar is locked relative to the bottom of the shell with two different inclinations.
• the locking mechanism 10 is located at the rear of the ski boot. It is schematically represented by a dotted rectangle on the figure 1
• the locking mechanism includes a lever 11 that protrudes partially towards the rear of the boot.
• Lever 11 is intended to be operated by the boot user, either directly with their hand or, optionally, with the tip of a ski pole.
• Lever 11 is movable. between a locked position and an unlocked position.
• the locked position corresponds to the ski configuration, that is, the configuration in which the rotating joint is locked.
• the unlocked position corresponds to the walk configuration, that is, the configuration in which the rotating joint is free.
• the unlocked position of lever 11 can correspond to a raised position, represented by a solid line on the figure 1
• the locking position of lever 11 can correspond to a lowered position, represented by dotted lines on the figure 1
• these two positions could be reversed, i.e. the locking position of the lever could correspond to a raised position, and the unlocking position could correspond to a lowered position.
• FIG. 2 The figure illustrates the lower shell 2 and the cuff 3 of the ski boot 1 without the tightening means 5A, 5B.
• the locking device 10 is housed at least partially in a protrusion formed at the rear of the cuff 3.
• the locking device 10 is, in particular, at least partially covered by an outer wall 12 of the cuff.
• This outer wall 12 includes an opening 50 through which the lever 11 passes, so as to remain easily accessible. The locking device 10 is thus protected from impacts and snow or ice projections by the outer wall 12.
• the locking device 10 comprises a mechanism 13 attached to the collar 3 and a connecting element, in the form of a blade 14, attached to the lower shell 2.
• the blade 14 is fixed to the lower shell 2 at its lower end and extends upwards. In the ski configuration, the blade 14 is locked in position against the collar 3 by the mechanism 13, which prevents the rotational joint between the collar and the lower shell.
• the blade 14 may be a rectangular plate whose upper end is inserted into the mechanism 13.
• the blade 14 may have an upper edge parallel to the transverse axis Y.
• the blade 14 extends generally upwards, parallel to an axis Z1.
• the axis Z1 may be substantially parallel to the vertical axis Z for a given orientation of the collar 3 relative to the bottom of the shell 2.
• the axis Z1 may form a non-zero angle with the vertical axis Z. This angle is preferably less than or equal to 30°.
• the blade 14 has a curved shape to ensure proper integration along the rear wall of the ski boot 1, as well as improved mechanical strength, particularly flexural strength.
• the blade 14 could also have a straight shape.
• the blade 14 comprises an upper portion 15 extending in a first plane and a lower portion 16 extending in a second plane parallel to the first plane and offset from it.
• the first and second planes can extend parallel to the vertical axis Z and the transverse axis Y for a given inclination of the cuff relative to the bottom of the shell.
• the first plane 15 is positioned further forward on the ski boot than the second plane 16.
• the first and second planes can be connected by an angled section.
• the angled shape of the 14 blade allows it to conform to the shape of the ski boot heel, resulting in a discreet and compact integration. This shape also allows for a lower positioning of the blade's lower end, enabling a greater range of rotation of the cuff relative to the bottom of the shell.
• the blade 14 is fixed to the bottom of the hull 2 by means of a rotational joint around a first axis of rotation Y1 parallel to the transverse axis Y.
• the lower part of the hull 2 comprises two protrusions 17, formed substantially in the heel area, and connected by an axis 18 extending along the axis of rotation Y1.
• the lower end of the blade 14 can simply be wound around the axis 18 to form the rotational link.
• the rotational link of the blade 14 allows the blade to follow the movement of the collar 3 when the latter pivots around the bottom of the hull 2 about the rotation axis Y0.
• the blade 14 pivots about the rotation axis Y1 in the frame of reference of the bottom of the hull 2, and translates along the axis Z1 in the frame of reference of the collar 3.
• the blade 14 is a single piece of metal.
• the blade 14 can be obtained by cutting and bending a metal plate.
• the mechanism 13 comprises a housing 19 attached to the collar 3.
• the housing 19 has an opening into which the blade 14 is engaged.
• the blade 14 is guided in translation within the housing 19 parallel to the axis along which the blade extends, i.e., parallel to the axis Z1.
• the blade 14 is free to slide within the housing 19 parallel to the axis Z1.
• the blade 14 is locked inside the housing 19.
• Figure 13 illustrates the locking mechanism 10, without the housing 19, with the locking mechanism in its ski configuration. It can be seen that the mechanism 13 comprises a locking element 20 movable parallel to an axis X1 between a locked position and an unlocked position.
• the axis X1 is perpendicular to the axis Z1.
• the axis X1 is perpendicular to the plane in which the upper part of the blade 14 extends, that is, perpendicular to the first plane 15.
• the locking position of the locking element 20 corresponds to the ski configuration of the locking device 10. In ski configuration, the locking element 20 cooperates with the blade 14 so as to prevent its sliding within the housing 19.
• the unlocking position of the locking element 20 corresponds to the operating configuration of the locking device 10.
• the locking element 20 is then positioned relative to the blade 14 so as to allow the blade 14 to slide inside the housing 19 and thus free the rotational joint between the collar and the bottom of the shell.
• the blade 14 includes a stop surface designed to cooperate with the locking element 20 to prevent the joint from rotating when the locking element is in the locked position.
• the locking element 20 includes a lug
• the blade 14 includes an opening 21 comprising a shape complementary to a shape of the lug.
• the opening 21 is a hole passing through the thickness of the blade 14.
• the upper edge 21A and the lower edge 21B of the opening 21 thus form the stop surface, which cooperates with the locking element 20 to prevent the joint from rotating when the locking element is in the locked position.
• other shapes can be considered for the locking element 20 and the opening 21.
• the locking element 20 also includes a first guide surface 22, and the blade 14 includes a second guide surface 23.
• the first guide surface 22 cooperates with the second guide surface 23 to guide the movement of the blade 14 relative to the locking element 20 when the locking element is in the unlocked position and the collar pivots relative to the bottom of the shell. This ensures proper positioning of the locking element 20 relative to the blade 14 under all circumstances.
• the locking element 20 thus combines a locking function for the blade 14 and a guiding function for the blade 14. Consequently, the locking device is easier to operate and more robust.
• the blade 14 is very well positioned relative to the locking element 20 when the locking device is moved into its locked configuration. This prevents the locking element 20 from colliding with an edge of the opening 21, which would make handling particularly difficult.
• the guide means allows for an opening 21 in the blade whose dimensions are precisely matched to the dimensions of the locking element 20. This ensures no play, or minimal play, between the collar and the bottom of the shell when the locking device is in its ski configuration.
• the blade 14 is also very well guided within the housing 19 when the locking device is in the operating position and the collar pivots around the bottom of the housing.
• the interaction of guide surfaces 22 and 23 ensures the lateral guidance of the blade within the housing. This prevents the blade 14 from coming into contact with a wall of the housing 19, and more generally with any element of the mechanism 13 that is not designed to come into contact with blade 14.
• the locking device is thus more robust and more durable.
• a locking device lacks any guiding means between the locking element 20 and the blade 14, the locking element is positioned much less precisely relative to the blade. In such a case, the opening in the blade must be larger to compensate for this less precise positioning. Consequently, in the locked configuration, there is more play between the locking element and the blade, and the collar is less securely locked in position relative to the bottom of the hull.
• the opening 21 can have dimensions adjusted to the dimensions of the locking element 20.
• the opening 21 does not need to be specially enlarged to allow the insertion or extraction of the locking element, as is the case, for example, when the locking element is movable between its locked and unlocked positions by a rotational movement or a more complex kinematic motion.
• the blocking element 20 is illustrated in more detail on the figure 5 It comprises several portions along the X1 axis: the locking element 20 includes, in particular, a first portion 24 designed to cooperate with the opening 21 to lock the rotational joint between the collar and the bottom of the shell when the locking element is in the locked position.
• the first portion 24 may include a shape complementary to the shape of the opening 21, in particular a cylindrical shape whose axis of revolution is parallel to the first axis X1.
• the opening 21 includes a circular shape whose diameter is slightly larger than the diameter of the cylindrical shape of the first portion 24 of the locking element.
• the difference in diameter between the circular shape of the opening 21 and the cylindrical shape of the first portion 24 may be, for example, less than or equal to 3 mm, preferably less than or equal to 2 mm, or even less than or equal to 1 mm.
• one end of the first portion 24 may be chamfered to facilitate its insertion into the opening 21.
• first portion 24 of the locking element 20 and of the opening 21 could be considered, for example, a triangular, square, rectangular, polygonal, or ovoid shape.
• the locking element 20 and the blade 14 cooperating with the locking element could be different.
• These two elements could, for example, include raised or negative features, such as rack surfaces, designed to come into contact with each other when the locking element is in the locked position. More generally, each of the two elements could include a stop surface configured to prevent the corresponding element from sliding within the mechanism 13 when the locking element is in the locked position.
• the locking element 20 also includes a second portion 25 comprising said first guide surface 22.
• This second portion may include at least one flat face, preferably two opposing flat faces.
• the at least one flat face may extend parallel to the axis in which the blade 14 moves relative to the locking element 20, that is, parallel to the axis Z1. This face The plane is designed to bear against the blade 14 to guide the blade's movement relative to the locking element.
• the second portion 25 may have a prismatic shape, including a parallelepiped shape.
• the second portion 25 may be adjacent to the first portion 24 and may be positioned further forward on the ski boot.
• the blade 14 includes a groove 28.
• the groove 28 is an opening extending through the thickness of the blade and parallel to the axis along which the blade extends, i.e., parallel to axis Z1.
• the groove 28 is delimited by two lateral edges extending parallel to axis Z1.
• the length of the groove 28 along axis Z1 is adapted according to the amplitude of deflection of the collar relative to the bottom of the shell when the locking device is in the operating configuration.
• Said second guide surface 23 is formed by at least one of the two edges of the groove 28, in particular by both edges together, the two edges being designed to bear against the flat faces of the second portion 25 of the locking element 20.
• the distance separating the two edges of the groove 28 can be slightly greater than the width of the second portion 25 of the locking element 20 along the transverse axis Y.
• a clearance of less than or equal to 3mm, or even less than or equal to 2mm, or even less than or equal to 1mm can be provided between the edges of the groove 28 and the second portion 25 of the locking element 20.
• the groove 28 can open onto the opening 21.
• the assembly formed by the groove 28 and the opening 21 thus forms a single, closed-edge opening. whose shape resembles a keyhole. Blade 14 is therefore particularly simple to manufacture.
• the blade 14 could be provided without the groove 28, and the guidance between the locking element 20 and the blade 14 could be achieved differently.
• the blade 14 could have a U-shaped profile. The flanges of the U would be spaced slightly further apart than the diameter of the locking element, so that the locking element slides between these two flanges when the collar pivots relative to the bottom of the hull.
• the locking element 20 could have a shape substantially resembling an M. It would include a central portion for cooperating with the opening 21 and lateral flanges for bearing against the outer edges of the blade 14.
• the second portion 25 could have a different shape, for example, a cylindrical shape.
• the locking element 20 could have a conical or frustoconical shape, the base of the conical or frustoconical shape forming the first portion, and the tip of the conical or frustoconical shape forming the second portion.
• the blade 14 might not be rotationally mobile about the axis of rotation Y1. It could then, for example, have a certain degree of flexibility allowing the collar to pivot relative to the bottom of the hull about the axis of rotation Y0. The amplitude of rotation between the collar and the bottom of the hull could then be reduced. According to another embodiment, the blade 14 could be replaced by an assembly comprising several articulated parts.
• the housing 19 includes a guide means 26 suitable for guiding the locking element 20 in translation parallel to the axis X1.
• This guide means 26 is formed in particular by a sleeve whose shape corresponds to the profiled shape of the locking element 20.
• This guide means makes it possible to precisely control the translational movement of the locking element 20 along the axis X1, and thus to further limit any risk of jamming between the locking element and the blade 14.
• the locking element 20 can thus include a third portion 27, in particular cylindrical in shape, cooperating with the complementary shaped sleeve in the housing 19 to guide the locking element in translation parallel to the axis X1.
• a diameter of the third portion 27 could be strictly greater than a diameter of the first portion 24.
• the shoulder formed at the interface between the third portion 27 and the first portion 24 could thus come against the edge of the opening 21, which makes it possible to immobilize the blade 14 when the locking device is in ski configuration.
• the locking element 20 can be a single-piece unit, that is, an element formed from a single piece.
• the locking element 20 could, for example, be machined from a block of metal.
• the locking element could comprise several parts fastened together; the different portions 24, 25, and 27 of the locking element could, for example, be screwed or welded together.
• the locking element 20 is made of metal, so as to withstand the significant forces that a user may exert while alpine skiing.
• it could also be made of injection-molded plastic, in particular plastic reinforced with glass or carbon fibers to increase its strength.
• the housing 19 may have a generally parallelepiped shape.
• the housing 19 comprises two lateral sides 29 extending parallel to each other and connected by a wall 30 forming the bottom of the housing.
• the wall 30 extends against the blade 14.
• the housing 19 may be made of a plastic and/or metallic material.
• the locking device includes at least one guide, interposed between the housing 19 and the blade 14, configured to guide the sliding of the blade 14 relative to the housing 19.
• This at least one guide may comprise a material with non-stick properties, for example, fiber-reinforced plastic, such as PTFE-reinforced plastic.
• the at least one guide may be a separate part of the housing, or alternatively, be formed directly into the housing.
• the at least one guide comprises two guides 31, each cooperating with a lateral edge of the blade 14.
• the guides 31 are arranged on either side of the blade 14, inside the opening in the housing 19 within which the blade 14 slides.
• the guides 31 may each include shoulders bearing against edges of the housing so as to hold the guides in position relative to the housing.
• the wall 30 of the housing may advantageously include a second opening 32 for receiving one end of the locking element 20, in particular the second portion 25 of the locking element 20, when the latter is in the locked position.
• the locking element 20 is in its locked position, it is supported both by the guide means 26 of the housing 19 and by the edge of the second opening 32.
• the locking element 20 is thus supported on both sides of the blade 14.
• the support of the locking element 20 on both sides of the blade 14 ensures that the locking element 20 remains in a stable position.
• the locking element 20 therefore does not become misaligned under the significant force exerted by the user. Consequently, it is not at risk of being damaged. This prevents the mechanism 13 from being subjected to the forces generated by the user.
• the second opening 32 may optionally have a shape complementary to the shape of the second portion 25 of the locking element 20.
• the lever 11 includes a wing 33 projecting towards the rear of the ski boot.
• the wing 33 is intended to be manipulated by the ski boot user.
• the lever 11 also includes a shaft 34 extending parallel to the transverse axis Y.
• the shaft 34 cooperates with a first pair of openings 35 formed in the lateral sides 29 of the housing 19.
• the shaft 34 is in the form of a generally cylindrical tube projecting on either side of a body 51 of the lever 11. The lever 11 is thus rotatable relative to the housing 19 about an axis of rotation Y2 parallel to the transverse axis Y.
• the body 51 of the lever 11 includes at least one wall, preferably two walls 52A, 52B, of generally cylindrical shape whose axis of revolution corresponds to the axis of rotation Y2.
• Walls 52A and 52B are positioned respectively above and below wing 33.
• Walls 52A and 52B are positioned opposite the opening 50 formed in collar 3, regardless of the position of lever 11. More precisely, wall 52A is positioned opposite the opening 50 when lever 11 is in the lowered position.
• Wall 52B is positioned opposite the opening 50 when lever 11 is in the raised position. Walls 52A and 52B thus prevent snow, water or any other form of particle can enter the ski boot through the 50 opening.
• the shaft 34 could be held not by the housing 19 but directly by the collar 3. In this case, the dimensions of the housing 19 could be reduced. In particular, the lateral sides 29 of the housing could be shortened.
• at least one opening can be provided in the collar extending along the axis of rotation Y2.
• the shaft 34 can then be a separate element from the body 51 of the lever 11. The shaft 34 can then be inserted transversely through the openings provided in the collar 3 for this purpose and through the body of the lever 11.
• the lever 11 also includes stop surfaces 36, 37, designed to cooperate with walls of the collar 3 to limit the amplitude of rotation of the lever around the axis of rotation Y2.
• a first stop surface 36 bears against a wall of the collar when the lever is in the locked position.
• a second stop surface 37 bears against a wall of the collar when the lever is in the unlocked position.
• the lever 11 can be a monolithic element, for example, manufactured by plastic injection molding.
• the lever body comprising the wing 33 and the abutment surfaces 36, 37, can be a monolithic element, this monolithic element including an opening into which the shaft 34 is inserted.
• the lever 11 could also be manufactured differently and/or result from the assembly of several parts fixed together to form a single unit.
• the mechanism 13 allows the locking element 20 to be moved between its locked position and its unlocked position in a way particularly advantageous. This mechanism 13 will now be described in more detail with reference to figures 8 to 11 .
• the mechanism 13 includes a transmission means mechanically connecting the lever 11 to the locking element 20.
• the transmission means is configured such that moving the lever 11 to its locked position tends to move the locking element 20 to its locked position. Similarly, moving the lever 11 to its unlocked position tends to move the locking element 20 to its unlocked position.
• the transmission means comprises a rocker 38 mounted for rotation about a third axis of rotation Y3.
• the axis of rotation Y3 is parallel to the transverse axis Y.
• the rocker 38 comprises a first portion 39 extending above the axis of rotation Y3 and a second portion 40 extending below the axis of rotation Y3.
• the rocker pivots in a first direction about the axis of rotation Y3, the first portion 39 moves forward and the second portion 40 moves backward.
• the rocker pivots in a second direction about the axis of rotation Y3, opposite to the first direction, the first portion 39 moves backward and the second portion 40 moves forward.
• the rotation axis Y3 extends approximately halfway up the rocker 38 along the vertical axis Z. However, this position of the rotation axis Y3 can be adjusted to adapt the leverage effect produced by the rocker 38.
• the mechanism 13 includes a shaft 41 extending along said axis of rotation Y3 between the two lateral sides 29 of the housing.
• the shaft 41 extends between a second pair of openings 42 provided in the lateral sides 29, in particular below the The first pair of openings 35.
• the shaft 41 is thus supported by the housing 19.
• the shaft 41 also passes through a central opening provided in the rocker arm 38.
• the rotational movement of the rocker arm 38 about the axis of rotation Y3 can be obtained by a relative rotation between the rocker arm 38 and the shaft 41 and/or by a relative rotation between the shaft 41 and the housing 19.
• the shaft 41 advantageously includes securing means, in particular enlarged ends, configured to hold the shaft 41 securely to the housing 19.
• the enlarged end can, for example, be formed by crimping.
• the shaft 41 could consist of two parts assembled together, each part comprising an enlarged portion.
• the rocker 38 interacts with the lever 11 via a return means, namely a torsion spring 43.
• the torsion spring 43 comprises a first end 44 in contact with a bearing surface 45 of the lever 11, and a second end 46, opposite its first end 44, in contact with a first bearing surface 47 of the rocker 38.
• the bearing surface 45 of the lever 11 takes the form of a U-shaped housing, profiled along the transverse axis Y, and within which the first end 44 of the torsion spring 43 is located. The first end 44 is thus held securely against the lever 11.
• the first bearing surface 47 of the rocker 38 takes the form of an opening passing through the first portion 39 of the rocker. It is therefore understood that the lever 11 is configured to exert pressure against the first support surface 47 of the rocker 38 via the torsion spring 43, and thus rotate the rocker 38 around the axis of rotation Y3.
• the torsion spring 43 comprises a set of coils defined around an axis parallel to the transverse axis Y.
• the torsion spring 43 is designed to be subjected to torsional stress.
• the maximum compression state of the spring is Torsion is achieved when the distance between the bearing surfaces 45 and 47 is minimal. This configuration can be achieved when the bearing surfaces 45 and 47 are aligned with the rotation axes Y3 and Y2.
• the torsion spring 43 is thus configured to be transiently under tension when the lever is moved between its locked and unlocked positions.
• the locked and unlocked positions of the lever correspond to states of least tension in the torsion spring 38 and are therefore stable positions.
• some tension remains in the torsion spring when the lever is in the locked or unlocked position, so as to prevent the lever 11 from floating. This residual tension is achieved by the bearing surfaces 36 and 37 against the walls of the collar.
• the rocker 38 further includes a second bearing surface 48 opposite the first bearing surface 47 with respect to the axis of rotation Y3.
• the second bearing surface 48 is configured to bear against the locking element 20 to move the locking element between its locked and unlocked positions. More precisely, the lower end of the rocker 38 is engaged in a recess 49 formed in the locking element.
• the second bearing surface 48 therefore corresponds to the end of the rocker 38 pressed into the recess 49.
• the recess 49 can advantageously be formed in the third portion 27 of the locking element 20.
• the recess 49 can, for example, be a blind hole of cylindrical shape. The edges of the recess 49 can be flared to facilitate the pivoting movement of the rocker 38.
• the rocker 38 could comprise a rounded toothed portion, provided with a plurality of radially extending teeth, and the locking element could comprise a rack portion cooperating with the rounded toothed portion.
• the locking element could include a protrusion projecting from a cylindrical body of the locking element 20 and the lower end of the rocker could include a recess cooperating with this protrusion.
• the locking device 10 operates as follows.
• the user wishes to switch from ski mode to walking mode, they raise the wing 33, which rotates the lever around the axis of rotation Y2.
• This causes the contact surface 45 of the lever 11 to move towards the rear of the ski boot, bringing the contact surface 45 closer to the first contact surface 47 of the rocker 38.
• the torsion spring 43 is then tensioned until it reaches a maximum tension value corresponding approximately to the midpoint of the wing 33's travel between its lowered and raised positions.
• the contact surface 45 then moves away from the first contact surface 47 again, and the tension of the torsion spring 43 decreases once more.
• the torsion spring 43 transmits the force applied to the lever 11 to the rocker 38.
• the first portion 39 of the rocker 38 moves forward.
• the collar pivots relative to the bottom of the shell, causing the blade to move back and forth within the housing.
• This back-and-forth movement is guided both by the interaction of the guide surfaces 22 and 23, and by the interaction of the two guides 31 with the edges of the blade 14.
• the locking element 20 remains precisely positioned relative to the blade 14 during walking, which subsequently facilitates re-locking the locking device.
• the locking operation can be performed similarly by lowering the wing 33 of lever 11.
• Two scenarios are possible.
• the first scenario the locking element is positioned exactly opposite the opening 21 when the wing 33 is pivoted downwards.
• This scenario occurs if, at the moment lever 11 is operated, the inclination of the collar relative to the bottom of the shell corresponds exactly to the inclination of the "ski" configuration.
• the locking element 20 enters the opening 21 without striking the blade 14, and the movement of the locking element from the unlocked position to the locked position is immediate.
• the first portion 24 of the locking element is positioned in the opening 21 of the blade, and the second portion 25 is positioned in the second opening 32 formed in the wall 30 of the housing.
• This configuration of the locking device is illustrated in particular on the figure 12
• the precise fit between the locking element 20 and the opening 21 allows for effective and firm locking of the rotational joint between the cuff and the lower shell.
• This provides the user with a rigid ski boot that efficiently transmits their impulses for alpine skiing and reduces the risk of injury, particularly to the knees.
• the locking element 20 is not positioned exactly opposite the opening 21 when the wing 33 is pivoted downwards.
• This situation occurs if, when lever 11 is operated, the inclination of the collar relative to the bottom of the shell does not exactly match the inclination of the "ski" configuration.
• the locking element 20 remains in the unlocked position while the lever 11 is in the locked position.
• the locking element 20 then bears against the blade 14, and the torsion spring 43 remains under tension.
• the flat faces 53 framing the second prismatic portion 25 then bear against the blade 14 on either side of the groove 28.
• the blade 14 can still slide freely relative to the locking element 20.
• the force exerted by the torsion spring 43 on the locking element 20 may generate increased friction when the blade 14 slides. However, this friction remains negligible and/or imperceptible to the user.
• the locking element 20 positions itself opposite the opening 21.
• the torsion spring 43 can then relax at least partially, and the locking element 20 can move to its locked position.
• the locking device then changes from its armed configuration to its locked configuration.
• the blade 14 further includes a bearing surface 55 intended to interact with the lever 11 to automatically move the lever 11 towards its locking position, i.e. to rotate the lever 11 around the axis of rotation Y2 towards its locking position.
• the blade 14 is movable in translation relative to the collar 3, and therefore relative to the lever 11 which is fixed in rotation at the collar.
• the invention thus proposes to use the mobility of the blade 14 relative to the collar to exert an action on the lever.
• the bearing surface 55 of the blade is therefore intended to interact with the lever 11, in particular to come into direct contact with a receiving surface 56 of the lever 11 when the lever is in the unlocked position.
• the receiving surface 56 is positioned on the trajectory of the bearing surface 55 of the blade, when the blade 14 moves relative to the collar and the lever is in the unlocked position.
• the direct contact between the blade 14 and the lever 11 is notably illustrated in the Figure 10 .
• the bearing surface 55 corresponds to an upper edge of the blade 14, or even to a horizontal edge delimiting an upper edge of the blade on its rear face.
• the bearing surface 55 is therefore positioned at the level of an upper end of the blade 14, that is to say the end of the blade opposite the axis of rotation Y1.
• the receiving surface 56 is formed on the body 51 of the lever 11.
• the body 51 of the lever 11 may advantageously include a flat surface 57 on which the receiving surface 56 is formed.
• This flat surface 57 extends parallel to the blade 14 when the lever is in the locked position.
• the flat surface 57 forms a non-zero angle A1 with the axis in which the blade 14 extends when the lever is in the unlocked position.
• the angle A1 may, for example, be between 30° and 60°, in particular approximately 45°.
• the receiving surface 56 is offset relative to the axis of rotation Y2 of the lever 11.
• an offset d1 between the surface of The distance between the receiving surface 56 and the axis of rotation Y2, measured parallel to the axis X1 can be at least 5 mm, or even at least 10 mm.
• the wing 33 and the receiving surface 56 can be diametrically opposed, that is to say that the axis of rotation Y2 can extend between the wing 33 and the receiving surface 56.
• the lever 11 can be made of plastic and the blade 14 can be made of metal.
• the bearing surface 55 can be chamfered, polished, or even curved.
• the lever could also be made of metal.
• the user simply tightens the 5B fastening means and tilts their lower leg forward to move the locking device from its armed configuration to its skiing configuration, i.e., a configuration in which the collar is locked against rotation relative to the lower shell.
• the user thus obtains automatic locking of the rotational joint between the cuff and the lower shell as soon as they have tightened the cuff's tightening means 5B.
• the user therefore does not need to manually move lever 11 to its locking position. This action is performed automatically when putting on the boot and inserting the foot. The user is thus assured of the correct locking of the joint between the cuff and the lower shell, and can ski safely.
• the locking device 10 comprises a limited number of components. It is therefore simple to manufacture, compact, and lightweight.

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• 2024
  • 2024-06-25 FR FR2406806A patent/FR3163534A1/fr active Pending
• 2025
  • 2025-06-17 EP EP25183443.8A patent/EP4670549A1/de active Pending

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