A sole structure for an article of footwear has a sole plate that may include a midfoot region, and also may include a forefoot region or a heel region. The sole plate may have a foot-facing surface with ridges extending longitudinally in the midfoot region and in the forefoot region or heel region. The sole plate may have a ground-facing surface with grooves extending longitudinally in correspondence with the ridges. A thickness of the sole plate from the foot-facing surface to the ground-facing surface may vary at a transverse cross-section of the sole plate through the ridges, or along a length of at least one of the ridges, or at both the transverse cross-section and along the length of the at least one of the ridges. The ridges may have crests at least some of which may extend non-parallel with one another in a longitudinal direction of the sole plate.

Heel dampening systems and footwear including the same. Articles of footwear include an upper and a sole assembly. The sole assembly includes at least an outsole and a heel assembly. The heel assembly includes a heel dampening system, an upper heel layer that includes a cushion aperture, and a lower heel layer. The heel dampening system includes a heel dampening layer configured to at least partially absorb an impact force and a cushioning projection that extends from the heel dampening layer and at least partially through the cushion aperture in the upper heel layer.

A shock absorbing device having at least one canted spring disposed between two members is described. When the members move toward each other, the one or more canted coil springs are canted and compressed. The shock absorbing device takes advantage of the unique force-displacement curve of canted springs and reduces bounce back.

A shock absorbing device having at least one canted spring disposed between two members is described. When the members move toward each other, the one or more canted coil springs are canted and compressed. The shock absorbing device takes advantage of the unique force-displacement curve of canted springs and reduces bounce back.

The present invention relates to a sole for sports shoes including a base or tread component, a top or midsole component and at least one intermediate or elastic cushioning component.

A high heel footwear including a heel tip assembly and a heel assembly. The heel tip assembly includes a top lift abutting against the heel, a rigid shaft member having a threaded portion, and a first wedge-lock feature configured to prevent the top lift from rotating. The heel assembly includes a threaded insert, a spring, a hollow insert, and a second wedge-lock feature. The threaded insert is received inside an opening formed in the heel to receive the threaded portion of the rigid shaft member. The spring is also received inside the opening and abuts against the threaded insert. The hollow insert abuts against the spring. The rigid shaft member passes through the threaded insert, the spring, and the hollow insert. The second wedge-lock feature locks with the first wedge-lock feature to retain the top lift on the end of the heel.

A high heel footwear including a heel tip assembly and a heel assembly. The heel tip assembly includes a top lift abutting against the heel, a rigid shaft member having a threaded portion, and a first wedge-lock feature configured to prevent the top lift from rotating. The heel assembly includes a threaded insert, a spring, a hollow insert, and a second wedge-lock feature. The threaded insert is received inside an opening formed in the heel to receive the threaded portion of the rigid shaft member. The spring is also received inside the opening and abuts against the threaded insert. The hollow insert abuts against the spring. The rigid shaft member passes through the threaded insert, the spring, and the hollow insert. The second wedge-lock feature locks with the first wedge-lock feature to retain the top lift on the end of the heel.

A sole structure of an article of footwear includes a foam element and a non-foam element with different compressibilities. The foam element is positioned adjacent to the non-foam element. The non-foam element may define a plurality of apertures, with ends of at least a portion of the apertures being located adjacent to a lower area of the foam element. The non-foam element may also form a protrusion that may be located in a central area of the non-foam element and extends into the foam element. In addition, a portion of the non-foam element that forms a side of the sole structure may define an indentation.

A sole structure of an article of footwear includes a foam element and a non-foam element with different compressibilities. The foam element is positioned adjacent to the non-foam element. The non-foam element may define a plurality of apertures, with ends of at least a portion of the apertures being located adjacent to a lower area of the foam element. The non-foam element may also form a protrusion that may be located in a central area of the non-foam element and extends into the foam element. In addition, a portion of the non-foam element that forms a side of the sole structure may define an indentation.

A support is configured such that a bulge is allowed to deform toward a deformation space due to the deformation space when the deformation space is in an open state, and that the bulge is allowed to deform upward and a buffer member is compressively deformed when the deformation space is in a closed state.