Foot support components include plural foot support members (e.g., arched slats or other support members) forming at least a portion of a footbed for a sole structure/article of footwear. Spacings between individual foot support members enable selective activation of one or more individual members, thereby providing support where needed and enhancing overall comfort without overly stiffening the footbed. When made from sufficiently rigid/resilient materials, the foot support components may apply return energy to the wearer's foot. This may occur, for example, by vertically deflecting (e.g., flattening out) one or more foot support members under applied force, and then the deflected foot support member(s) will spring back to and/or toward its/their original shape when the force sufficiently abates/relaxes.

A sole structure for an article of footwear includes a first plate extending from a forefoot region of the sole structure to a heel region of the sole structure. The first plate has a first surface and a second surface formed on an opposite side of the first plate than the first surface. The sole structure further includes a second plate extending from the forefoot region to the heel region. The second plate has a third surface opposing the second surface of the first plate and a fourth surface disposed on an opposite side of the second plate than the third surface. The third surface is spaced apart from the second surface to define a cavity between the first plate and the second plate that extends from a medial side of the sole structure to a lateral side of the sole structure between the forefoot region and the heel region.

A footwear construction includes a sole assembly including a first midsole platform, a second midsole platform below the first midsole platform, a spring plate disposed between the first and second midsole platforms, and an outsole layer disposed below and joined directly with at least one of the plate, the first and the second midsole platforms. The outsole layer can be substantially the only layer below the plate in the forefoot region of the footwear so an underfoot force engaging the outsole layer is transmitted directly to the plate, which also can have an upward curving, multi-radii transition portion extending from a lowermost portion to a forward most portion of the plate so as to roll a wearer's foot forward into a next stride in a gait cycle of the wearer. The plate can define an aperture. A mounting cap can extend through the aperture and can receive a traction spike.

A shoe having a bimodal structure at a sole, the bimodal structure configured to selectively snap to at least one of a second position and a first position. The bimodal structure is a bendable structure that selectively snaps into the first position upon being subjected to a first bending force, and that selectively snaps into the second position upon being subjected to a second bending force, where the first bending force has an opposite direction to the second bending force. A downward force applied to a heel counter of the bimodal shoe while holding portions of the shoe forward from the bimodal structure stationary causes the bimodal structure to snap out of the second position.

A shoe device having bimodal structures, configured to selectively snap the device to at least one of a second position and a first position, which selectively snaps the shoe into a first position upon being subjected to a first bending force, apt for placement or removal of a foot, and selectively snaps the shoe into a second position upon being subjected to a second bending force, apt for securement of a foot or having no foot. A forward leaning, flexible stadium arch structure, assembled to form a heel notch mechanism, connects to a sole. A morphing shoe collar portion connects to a heel. These are combined via vector changing devices for greater functionality.

An article of footwear is provided having an elevated plate structure incorporated in the sole structure and optionally including a fluid-filled chamber. The elevated plate structure can include an upper plate and a plurality of legs extending downward toward the outsole. End portions of the legs can engage an upper region of the outsole. The elevated plate structure can form a cage region that can optionally include a fluid-filled chamber substantially disposed therein. The elevated plate structure can further include a lower plate disposed at an upper region of the outsole, which can form a lower portion of the cage region. Portions of the legs can be integrated with impact-attenuating members in the heel region in various configurations and can provide features for the impact-attenuating members, such as support, impact-attenuation and adjustable impact-attenuation features.

A shoe has a shoe upper configured to receive a foot of a user, a sole coupled the shoe upper and having a cavity, and a sole spring in the cavity. The sole spring has a first leg and an opposite second leg, and the sole spring is removably positioned in the cavity. Accordingly, when the user presses the shoe into contact with a support surface, the first leg and the second leg flex toward each other thereby cushioning the foot of the user, and when the user moves the shoe away from the support surface the first leg and the second flex away from each other thereby propelling the user away from the support surface.

A plurality of orthotic systems are provided. One bi-layer system is constructed from a single sheet of fabric that is molded into two layers. One tri-layer system includes a base layer; a mid-layer; and an upper layer. The upper layer is joined to the mid-layer and the mid-layer is joined to the base layer. The coupling of the base layer, the mid-layer and the upper layer create a rear spring section, a mid-spring section and a front spring section in which the upper layer is suspended over the mid-layer and the heel portion is suspended on the proximal heel end of the base layer.

A footwear having a shock attenuating and cushioning sole is provided, including a base to which first and second wave elements are joined, each element including alternating crests and troughs. The crests are wide and can each form a ground contact surface, whereas the troughs can be narrower than the crests. Crests of one element are disposed adjacent the troughs of another element. The widths of the crests to those of the troughs can be in at least a 2:1 ratio. Forward and rearward ends of the elements are connected to the base, and the troughs intermittently join with the base to secure the elements between the ends and to impair lateral movement. Different groups of wave elements can be grouped together to form a forefoot section, a heel section and/or an arch section, with the sections separated from and compressible independent of the other sections.

A sole structure for an article of footwear is provided. The sole structure includes an outsole having a ground-engaging surface and an upper surface formed on an opposite side of the outsole than the ground-engaging surface. A first cushion is disposed proximate to a medial side of the sole structure and includes a first fluid-filled chamber attached to the upper surface of the outsole and a second fluid-filled chamber attached to the first fluid-filled chamber and disposed between the first fluid-filled chamber and the upper. A second cushion is disposed proximate to a lateral side of the sole structure and includes a third fluid-filled chamber attached to the upper surface of the outsole and a fourth fluid-filled chamber attached to the third fluid-filled chamber and disposed between the third fluid-filled chamber and the upper. The second cushion is fluidly isolated from the first cushion.