A sole structure for an article of footwear includes a plate made of a polymeric material and a plurality of cleats each made of a metallic material. Each of the cleats is overmolded onto the plate. Each of the cleats includes an internal portion and an external portion coupled to the internal portion. The external portion is disposed outside the plate. The internal portion is disposed inside the plate. The internal portion includes a lattice framework. The lattice framework defines a plurality of holes. The plate partly extends through the holes of the lattice framework to secure the plurality of cleats to the plate.

A sole structure for an article of footwear includes a plate made of a polymeric material and a plurality of cleats each made of a metallic material. Each of the cleats is overmolded onto the plate. Each of the cleats includes an internal portion and an external portion coupled to the internal portion. The external portion is disposed outside the plate. The internal portion is disposed inside the plate. The internal portion includes a lattice framework. The lattice framework defines a plurality of holes. The plate partly extends through the holes of the lattice framework to secure the plurality of cleats to the plate.

The present disclosure provides a footwear technology system including a multilayer shoe sole system. The multilayer shoe sole insert can include a lower outsole layer, a midsole layer, and an upper insole layer, wherein the midsole layer includes a plurality of pins extending from the bottom surface of the midsole layer, wherein the pins engage with the pin holes in the outsole layer. The system can include a dynamic upper foot retention system that moves in harmony with the foot's optimal natural movement. The dynamic upper foot retention system can include a top component connecting the lace area to the sole system, and back component that connects the upper heel area to the sole system, wherein when the laces are tightened, the force is directed towards the heel securing the foot to the shoe without forcing the arch down or constricting the raising of the foot arch.

The present invention is embodied in a mounting standard for mounting a cleat assembly to a shoe sole having a curved underside portion and a plurality of mounting holes. The mounting standard is configured so that the cleat assembly can be moved forward or rearward with respect to the curved underside portion of the shoe sole without significantly affecting the distance between the cleat assembly and a user's foot. The present invention is also embodied in a shoe configured to receive a user's foot, the shoe comprising a shoe sole and a mounting standard.

A footwear with a fluid which flows through integral chambers and passageways within the sole in which additional traction elements may be selectively and forcedly deployed and retracted. Valves on the footwear in combination with a control system, control the flow of the fluid allowing the user to choose between a range of traction deployment options to suit the needs of the user.

Components for articles of footwear and athletic equipment including a foam are provided. The foam portion of the components and articles include a composition which includes a thermoplastic copolyester, the composition having a foam structure. A polymer layer is provided on at least on surface of the foam portion. The polymer layer can control or reduce the water uptake of the foam portion. Methods of making the compositions, foams, and components are provided, as well as methods of making an article of footwear including one of the foam components. In some aspects, the foams and foam components can be made by injection molding, or injection molding followed by compression molding.

A sole structure for an article of footwear with an upper and a top portion attached to the upper. The sole structure can include an outsole with a front portion, a middle portion, and a rear portion. The front portion and the middle portion of the outsole can be attached to the top portion. A front spacing can be defined between the front portion of the outsole and the top portion, and a rear spacing can be defined between the rear portion of the outsole and the top portion. Further, the sole structure can include at least one of a spike, a tooth, or a barb extending from a bottom surface of the outsole.

An article of footwear may include an outsole having an opening extending from a top face of the outsole to a ground-contacting face of the outsole, and a traction member disposed within the opening in the outsole. The traction member has a protruding portion and flange portion extending from an upper end of the protruding portion. The flange portion is secured to the top face of the outsole.

An article of footwear may include an outsole having an opening extending from a top face of the outsole to a ground-contacting face of the outsole, and a traction member disposed within the opening in the outsole. The traction member has a protruding portion and flange portion extending from an upper end of the protruding portion. The flange portion is secured to the top face of the outsole.

An outsole for an athletic shoe that includes a heel section and a forefoot section. The heel and forefoot sections are on the outer surface of the outsole. The forefoot section includes a tread pattern that provides first and second ground friction forces. The first ground friction force promotes rotation in a first rotational direction about a rotation point of the forefoot section. The second ground friction force restricts rotation in a second rotational direction about the rotation point. The second rotational direction is opposite of the first rotational direction and the second ground friction force is greater than the first ground friction force.