A sole structure for an article of footwear includes an outer fabric layer and an inner chassis that is more rigid than the fabric layer. The fabric layer includes a plurality of fabric protrusions and the inner chassis includes a plurality of chassis protrusions that correspond to the fabric protrusions. Both the fabric protrusions and the chassis protrusions extend into cleat members of the sole structure.

An apparatus includes a heel section, a mid-foot section, and a toe section. The heel section, the mid-foot section, and the toe section collectively have a geometric shape having a first slope of a polarity along an inner edge of the apparatus from the toe section to the heel section and a second slope of the polarity along the inner edge of the apparatus to an outer edge of the apparatus at the toe section.

Golf shoes having improved constructions are provided. The golf shoes include upper, midsole, and outsole sections. The upper may be made of a soft, breathable leather material. The midsole includes an upper region formed from a first material such as a foamed ethylene vinyl acetate (EVA); and a lower region formed from a second material such as a foamed ethylene vinyl acetate (EVA), wherein the materials have different hardness levels. A fiber-reinforced composite plate may be disposed in the midsole. The outsole contains different traction members arranged in a precise geometric structure that helps provide improved stability and traction.

A traction element arrangement for a sole structure of an article of footwear is described. Traction elements of a first group are associated with a lateral side of the sole structure. Traction elements of a second group are associated with a medial side of the sole structure. Traction elements of the second group include medial rotational traction elements that have a plurality of stud elements arranged in a circular grouping. Stud elements may be aligned laterally across the sole structure with traction elements of the first group. Stud elements may be aligned longitudinally across the sole structure to be arranged in different configurations along an outside medial side or an inside medial side.

A shoe may include an upper and a sole structure. The upper may include a shell and first, second, third, and fourth sets of tensile restraints. Each of the sets may have one or more tensile restraints extending over and/or through a corresponding portion of the shell. The shell may be engaged with the sole structure and define an interior void configured to receive insertion of a user's foot. The first, second, third, and fourth sets of tensile restraints may be configured so that, upon securing of one or more structures to tighten the upper and connect the sets of tensile restraints, two linear axes of tension with anchors located in the forefoot and heel region extend diagonally across the article from one side to the other.

A shoe sole (100) comprising a bottom surface, the bottom surface having a front array (110) of ground engaging formations having a first height or depth, and a rear array (120) of ground engaging formations having a second height or depth, the rear array of ground engaging formations generally located at a heel portion of the sole, wherein the first height or depth is greater than the second height or depth.

In traction cleat and receptacle system in a shoe outsole, unauthorized cleats are prevented from connection to a receptacle by a projection in the receptacle cavity and a recess in the cleat attachment stem for receiving the projection. A locking arrangement includes an annular array of twelve locking teeth on a boss surrounding the receptacle cavity, wherein every fourth tooth has a steeper side angle to in cooperate with mating cleat locking posts. A cylindrical shroud prevents the locking posts from damaging the outsole material during cleat rotation.

An article of footwear includes an upper and a sole connected to the upper. The sole includes a plurality of cleat mounts. A plurality of cleats is releasably connected to the cleat mounts of the sole. Each of the plurality of cleats includes a mount coupling and a plurality of legs connected to the mount coupling. The mount coupling is configured to engage one of the plurality of cleat mounts and releasably connect the cleat to the sole. The plurality of legs includes at least one lateral leg having a first hardness and at least one medial leg having a second hardness, the first hardness greater than the second hardness.

A sole plate for an article of footwear includes a foot-receiving surface and a ground-facing surface disposed opposite each other. A stiffness enhancing, ground-engaging cleat extends from the ground-facing surface of the sole plate. The ground-engaging cleat includes a first lug and a second lug. The first lug has a first foundation attached to the sole plate, and a first flex-limiting portion connected to the first foundation. The second lug has a second foundation attached to the sole plate, and a second flex-limiting portion connected to the second foundation. The first flex-limiting portion and the second flex-limiting portion contact each other in response to dorsiflexion of the sole plate equal to at least a predetermined flex angle, to increase a bending stiffness of the sole plate.

Adjustable traction is provided in a traction cleat by selectively restricting or not the amount of flexure permitted for a dynamic traction element on the cleat. Restricting flexure is alternatively achieved by an adjustably positionable ring or by rotating the cleat to align the dynamic element with different shoe sole topographical features. A dual locking post is provided to reduce the surface area required on the cleat hub for locking structures. The cleat is formed in a two shot molding process that permits elongations of the dynamic traction elements without sacrificing the integrity of the cleat structure.