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.

An insole for insertion into footwear includes a base, and an arch support located on an underside of the base layer, the arch support including a frame forming at least a portion of a perimeter of the arch support, and multiple ribs extend from a first side of the frame to a second side of the frame, wherein a first set of the ribs is raised relative to a second set of the ribs.

A sole structure for an article of footwear includes a first plate, a fluid-filled bladder supported on the first plate, and a second plate supported on the fluid-filled bladder with the fluid-filled bladder disposed between the first plate and the second plate. The first plate ascends rearward of the fluid-filled bladder and the second plate descends rearward of the fluid-filled bladder with a posterior portion of the first plate above a posterior portion of the second plate rearward of the fluid-filled bladder. A method of manufacturing footwear sole structures includes assembling sole structures for plural ranges of footwear sizes, each of the sole structures including a fluid-filled bladder with a predetermined inflation pressure that is different for at least two of the plural ranges.

A sole structure for an article of footwear includes an outsole and a membrane layer. The outsole has a plurality of protrusions that extend from a base layer. The membrane layer extends between the plurality of protrusions and includes at least a portion that is separated from the base layer by a distance. The membrane layer forms an outer surface of the article of footwear, and is configured to elastically deform toward the base layer in response to an applied force.

An exercise apparatus includes a pair of apparatuses wearable on feet of a user. Each apparatus is configurable between expanded configurations and compressed configurations to simulate a selected motion when the user wearing the pair of apparatuses travels by foot. One of the apparatuses can move towards an expanded configuration while the other apparatus moves towards a compressed configuration.

A sole structure for an article of footwear includes an upper element, a lower element positioned below the upper element and a flexure element. The flexure element may be joined to one of the upper element and the lower element. The flexure element may be configured for slidingly contacting the other of the upper element and the lower element when a vertical compressive load is applied to the upper element. A second flexure element may be provided that extends from the upper element toward the lower element (or vice versa). An article of footwear having the sole structure attached to an upper is also provided.

A support is configured such that a bulge is allowed to deform toward a deformation space due to the deformation space when the deformation space is in an open state, and that the bulge is allowed to deform upward and a buffer member is compressively deformed when the deformation space is in a closed state.

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 shoe sole includes a footbed, a midsole, and an outsole. The footbed includes deformable semi-tubular elements that protrude downward and are received in corresponding trough-shaped cavities of the midsole, which provide cushioning when the semi-tubular elements are compressed under load, and also provide a spring return effect. The semi-tubular elements may have a depth greater than a depth of a corresponding trough shaped cavity whereby the footbed is held in a raised position above the top surface of the midsole. The separation between the footbed and the top surface of the midsole is smaller in forefoot area and greater in the heel area. The separation provides shock absorption and resilience in the shoe because it allows the semi-tubular elements to deform under load and absorb impact shocks.

A sole cushioning module includes a contacting plate, a base plate, a connecting portion and a first spring leaf. The contacting plate abuts against a sole. The base plate and the contacting plate form a space. The connecting portion connects with the contacting plate and the base plate. The first spring leaf is located within the space. The first spring leaf connects with the base plate. The first spring leaf is curved and forms a first outer curved surface. A first region of the first outer curved surface abuts against the contacting plate. When the contacting plate moves towards the base plate, the contacting plate presses on the first outer curved surface. The first spring leaf deforms, and the first outer curved surface slides relative to the contacting plate. The first region shifts towards an end of the first spring leaf connecting with the base plate.