Provided is a non-skid shoe capable of absorbing shock including: an outsole; a plurality of accommodation grooves formed on the outsole, the accommodation groove including a groove portion, and a penetrated portion extending from the groove portion and penetrating the outsole; a support member which is accommodated in the respective accommodation grooves, and includes a support portion disposed in the groove portion, a first guide portion formed at a center of the support portion, and a second guide portion extending from the first guide portion and penetrating a bottom surface of the support portion; a movable member which is disposed in the respective support members, and includes a latch portion and a protruding portion; a pressing member engaged to an upper portion of the first guide portion; a resilient member disposed in the first guide portion; and a midsole engaged to the top surface of the outsole.

Ski boot sole (10), characterized in that it comprises: a plate (11) made of a composite material comprising reinforcing ribs (20); rear (30) and front (40) components extending under the plate (11) and forming gripping tread patterns (35, 45).

An article of footwear includes a midsole, a cleat plate including a bottom surface that faces toward a ground surface when the article of footwear is worn by a user, and a traction element connected with the cleat plate. The traction element includes a base member that is embedded within the cleat plate and a ground engaging member that extends from the base member and is exposed and extends transversely from the bottom surface of the cleat plate, where the ground engaging member has a length that is greater than a lengthwise dimension of the base member.

An article of footwear with an arrangement of cleats is disclosed. The arrangement of cleats may enhance traction during the first step of sprinting, quick directional changes, and backward movement. The arrangement of cleats may be disposed on a base plate and may include a first angled cleat aligned with the hallux of a user and a second angled cleat disposed proximate a rearward edge of the base plate. The first angled cleat and two flat cleats may be aligned with the perimeter of a circle on the forefoot region of the base plate.

A cleat assembly for a shoe comprising an anchor for anchoring to the shoe, a cleat, a first biasing member circumscribing the anchor and engaged with the cleat, and a second biasing member biasing the first biasing member. The second biasing member can directly engage the first biasing member or a bushing that circumscribes the anchor. So constructed, the cleat assembly provides multiple degrees of freedom. That is, the cleat assembly provides effective axial shock absorbance coupled with 360° tilting of the cleat for enhancing a user's ability to suddenly change direction when wearing a shoe equipped with the cleat assembly, thereby minimizing stress and impact on muscles, joints and ligaments and enhancing the performance of athletes wearing such shoes.

Presented are S-shaped cleats for footwear, methods for making/using S-shaped cleats, and footwear fabricated with S-shaped cleats. A cleat structure for an article of footwear includes a mounting base, such as a pair of coplanar mounting plates, that attaches to the footwear's sole structure. A center wall projects downwardly from the mounting base and has opposing lateral sides with a distal end extending therebetween. A pair of sidewalls each projects downwardly from the base and adjoins a respective lateral side of the center wall. Each sidewall has a respective angled edge that projects at an oblique angle from the distal end of the center wall. The two sidewalls are located on opposing sides of the center wall; the sidewalls may be parallel to and extend in opposite directions of each other. The center wall and sidewalls may be substantially flat panels with multiple polygonal faces or may have arcuate sides.

A traction cleat assembly for a golf shoe includes a hub and removable cover affixed to the hub body in a fixed position with mated sealing engagement between the hub and removable cover defining a, the hub body including a minor driven fitting comprising one of a female fitting and male fitting defined in the hub bottom surface, and the cover top surface including a minor driving fitting for mating engagement with the minor driven fitting to define mated engagement therebetween.

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 stud for an outsole includes: an outer tubular portion located on an outsole body and having a tubular shape; and a core portion located inside the outer tubular portion. The outer tubular portion is integral with the outsole body with no seam between the outer tubular portion and the outsole body. An inner wall surface of the outer tubular portion surrounds, and is in contact with, a side surface of the core portion. This configuration reduces separation of the stud from the outsole and firmly holds the stud on the outsole.

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.