A sole structure is configured such that in a state where a ground surface of an outsole is in contact with the ground surface, when a planta support surface of a deformable part receives a load of a human body, the deformable part is flexurally deformed downward while being supported on a fixed end functioning as a supporting point, thereby allowing the planta support surface to be inclined downward such that a free end of the deformable part moves downward.

A sole structure for an article of footwear is provided and includes a first sole plate formed at least in part from a first material having a first stiffness and including a first ground-engaging portion and a second ground-engaging portion, the first ground-engaging portion defining a first aperture extending around the second ground-engaging portion. The sole structure further including a membrane coupled to the first ground-engaging portion and the second ground-engaging portion and at least partially exposed by the first aperture, the membrane formed at least in part from a second material having a second stiffness that is less than the first stiffness.

A sole structure includes a thin plate made of an elastic material having a higher elastic modulus than that of a midsole and stacked on a lower side of the midsole and a shock-absorbing body made of a soft-elastic material and abutting on a lower surface of the plate at least in a hindfoot area. The plate extends from a position corresponding to calcaneus of the foot of a shoe wearer at least to a position corresponding to first interphalangeal joint of the foot in a longitudinal direction, is interposed between the midsole and the shock-absorbing body in the hindfoot area, is interposed between the midsole and an outsole in a forefoot area, and is formed such that at least a portion of the plate serves as an exposed portion in which a lower surface is exposed above a grounding surface in a midfoot area.

A force absorbing device for a footwear appliance includes a shoe upper and a shoe sole having a planar sole surface, such that forces between the shoe upper and planar sole surface in ground contact are absorbed by force mitigation assemblies disposed in the shoe sole. A force mitigation assembly adapted for an athletic shoe includes a linkage to a wearer interface responsive to movement based on activity of the wearer. An attachment to a sole surface receives ground forces transmitted from frictional contact between the sole surface and a surface against which the sole is disposed, such as for running, turning, etc. A force mitigation assembly absorbs these forces received from the sole surface for directing the received force in a controlled manner. An elastic field in the force mitigation assembly is defined by a resilient material adapted to deform in response to the received force.

A force absorbing device for a footwear appliance includes a shoe upper and a shoe sole having a planar sole surface, such that forces between the shoe upper and planar sole surface in ground contact are absorbed by force mitigation structures disposed in the shoe sole. A footwear article includes a split-sole system that redefines a shoe sole as coplanar surfaces having a force mitigating interface for receiving sudden forces and effectively mitigating these forces by storing kinetic energy and releasing it over time. An elastic field in the force mitigation structure is defined by a resilient material adapted to deform in response to the received force. Frictional engagement between the upper and lower sole may also be augmented by surface characteristics such as dimples, voids and lubricants, in addition to interference engagement with an elastic field.

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 plantar shaped shoe sole constituted by layers includes a mid-sole constituted by a body and elastically compressible protrusions protruding downward from a body lower surface, each having an axial cavity and first holes. An upper surface of the body has holes associated with first holes of each protrusion. First protrusions are arranged at a central area of the heel and forefoot of the body and have a greater protruding height than second protrusions. First and second protrusions have first and second apices, respectively, forming anatomically-contoured curved surfaces, formed at protrusion free ends, opposite the body lower surface. Each axial cavity extends from the upper surface to their respective apex. There are more forefoot region first holes of first protrusions than second protrusions. The sole includes a tread and an elastic plantar supporting structure, at least one seat on the upper surface wherein the apices are positioned on the seat.

A sole structure for an article of footwear includes a first cushioning element, a second cushioning element, and a panel disposed within a joint formed between the first cushioning element and the second cushioning element. The first cushioning element includes a first surface and a second surface formed on an opposite side from the first surface. The second cushioning element includes a third surface and a fourth surface formed on an opposite side from the third surface. The third surface of the second cushioning element is joined to the second surface of the first cushioning element to form a joint between the first cushioning element and the second cushioning element, where the fabric panel is interposed between the first cushioning element and the second cushioning element within the joint. The panel may be a fabric panel, and more particularly, may include a mesh textile material.

The present invention provides a method for manufacturing shoes having springs embedded therein, the method in which comfort and body weight distribution effect can be enhanced by means of the shock-absorbing force of resilient members being more effectively transmitted to the soles of a wearer.

Foot support members, e.g., sole structures for articles of footwear, include dynamically transformable portions, e.g., to change a dimension and/or apply a tensile or compressive force to some portion of an article of footwear or other foot-receiving device. Such foot support members may include a flexible support member having a wave shaped portion that flexes under an applied force. Flexing of this wave shaped portion under weight of a wearer produces: (a) a change in at least one of a longitudinal or transverse dimension of the foot support member, (b) application of a compressive or tensile force to the plantar support component and/or another part of the foot support member, article of footwear, or other foot-receiving device, (c) flattening of the wave shaped portion, and/or (d) compressing the wave shaped portion together (e.g., to fold up, decrease in overall height, etc.).