A crampon includes a crampon base for fitting to an underside of an item of footwear, such as a shoe or a boot. A harness extends from the crampon base and may be attached to the crampon base using rivets. The harness and the crampon base define a space for receiving the item of footwear. The crampon base comprises at least one cleat assembly with a cleat base embedded within the crampon base. One or more spikes extend from the cleat base.

A method for forming a plate includes attaching a first strand portion to a flexible substrate to form a first layer on the substrate and positioning a second strand portion on the first layer to form a second layer on the first layer in a plurality of discrete regions on the substrate. The method also includes positioning a plurality of traction elements into corresponding cavities formed into a first mold surface and positioning the substrate on the first mold surface to change a shape of the substrate. At least one of heat and pressure is applied to the first strand portion, the second strand portion, the substrate, and the traction elements to conform the substrate to the shape of the first mold surface and form the traction elements into the substrate at each of the discrete regions. The method also includes incorporating the substrate into an article of footwear.

A method for forming a plate includes attaching a first strand portion to a flexible substrate to form a first layer on the substrate and positioning a second strand portion on the first layer to form a second layer on the first layer in a plurality of discrete regions on the substrate. The method also includes positioning a plurality of traction elements into corresponding cavities formed into a first mold surface and positioning the substrate on the first mold surface to change a shape of the substrate. At least one of heat and pressure is applied to the first strand portion, the second strand portion, the substrate, and the traction elements to conform the substrate to the shape of the first mold surface and form the traction elements into the substrate at each of the discrete regions. The method also includes incorporating the substrate into an article of footwear.

A stitched article includes a substrate and a first strand portion formed from a bundle of fibers. The substrate has a first region and a second region. The first strand portion is attached to the substrate in the first region and in the second region via a series of stitches formed with a thread and forms a first layer on the substrate. The article has a first concentration of the stitches in the first region along a first length of the strand portion and a second concentration of the stitches different than the first concentration in the second region along a second length of the first strand portion.

A stitched article includes a substrate and a first strand portion formed from a bundle of fibers. The substrate has a first region and a second region. The first strand portion is attached to the substrate in the first region and in the second region via a series of stitches formed with a thread and forms a first layer on the substrate. The article has a first concentration of the stitches in the first region along a first length of the strand portion and a second concentration of the stitches different than the first concentration in the second region along a second length of the first strand portion.

The present invention is directed toward an article of footwear that effectively reduces rotation the article of footwear during a golf swing. The article of footwear includes an upper and a sole structure, where the sole structure is comprised of a midsole, a first outsole, and a second outsole. The article of footwear includes a forefoot region, a midfoot region, and a hindfoot region. The first outsole is coupled to both the midsole and the second outsole, while the second outsole is disposed between the midsole and the first outsole. The second outsole includes a first series of lugs disposed along a lateral edge of the second outsole and extending through the first outsole in the forefoot region, and a second series of lugs disposed along a medial edge of the second outsole and extending through the first outsole in the hindfoot region.

The present invention is directed toward an article of footwear that effectively reduces rotation the article of footwear during a golf swing. The article of footwear includes an upper and a sole structure, where the sole structure is comprised of a midsole, a first outsole, and a second outsole. The article of footwear includes a forefoot region, a midfoot region, and a hindfoot region. The first outsole is coupled to both the midsole and the second outsole, while the second outsole is disposed between the midsole and the first outsole. The second outsole includes a first series of lugs disposed along a lateral edge of the second outsole and extending through the first outsole in the forefoot region, and a second series of lugs disposed along a medial edge of the second outsole and extending through the first outsole in the hindfoot region.

A composite cleat includes a first component and a second component. The first component is made of a first material and is formed a first connecting portion extended along a longitudinal axis and a ground contact surface disposed at one end thereof. The second component is made of a second material different from the first material and is formed a second connecting portion fixedly connected with the first connecting portion and a threaded stud disposed at one end thereof.

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.

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.