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.

The present invention relates to shoe, in particular a sports shoe. The shoe includes a sole plate having in a forefoot area a plurality of leaf spring elements, wherein the sole plate and the plurality of leaf spring elements are manufactured as a single piece. Each of the plurality of leaf spring elements has one free end not connected with the sole plate.

The present invention relates to shoe, in particular a sports shoe. The shoe includes a sole plate having in a forefoot area a plurality of leaf spring elements, wherein the sole plate and the plurality of leaf spring elements are manufactured as a single piece. Each of the plurality of leaf spring elements has one free end not connected with the sole plate.

A shoe with a spring heel is provided. The shoe includes a shoe top portion, a sole and a spring. The shoe top portion is operable to retain a user foot within. The sole is secured to the bottom of the shoe top portion. The sole includes a front toe portion and a rear heel portion. The rear heel portion includes an upper inner surface and lower inner surface formed by a cutout portion. The spring is disposed within the cutout portion. The spring includes an upper plate and a lower plate joined by a U-shaped bend. The upper plate is secured to the upper inner surface and the lower plate is secured to the lower inner surface of the rear heel portion.

An article of footwear that offers different levels of cushioning and support depending on the direction of force applied to the midsole. An outer edge of the midsole includes an inwardly-extending elongate groove with a V-shaped cross-sectional configuration. An elongate insert having a V-shaped cross-sectional configuration is secured to the elongate groove. The insert forms a spring that dynamically alters the character of the support provided by the footwear to a foot of a wearer during banking or side-to-side movement.

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.

The improved footwear system of the present application uses composite materials in the design of an advanced modular in-shoe foot orthosis and a new container assembly which includes a high performance energy storage and return element orthosis. The footwear system uses a method of manufacture incorporating a new last model. The advantages of the footwear system over standard issue combat boots include lower weight, improved treatment of lower extremity overuse injuries and reduction of the occurrence of such overuse injuries by protecting at-risk feet with advanced footwear which can be customized to meet the biomechanical needs as well as the specific activities of the wearer.

A sole structure for an article of footwear having an upper includes an outsole having a ground engaging surface and a midsole member disposed between the outsole and the upper. The midsole member has a pocket extending from a heel region to a forefoot region and a sole plate disposed within the pocket. The sole plate extends from the heel region into the forefoot region. In the heel region, the sole structure is shaped to define an entry region that is configured to increase contact at the ground engaging surface during a heel strike. The entry region defines an angled portion that is angled at an entry angle relative to a flat ground surface. The midsole member is a supercritical foam.

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 separated prosthetic foot with a transverse arch belongs to the technical field of manufacturing of artificial limbs. The characteristics of the transverse arch of the human foot are combined into the previous transverse-straight carbon fiber foot design to improve the stiffness of the prosthetic foot and reduce the weight of the prosthetic foot. A forefoot part employs a separated curved plate design, and two simple curved plates with different curvatures are used for simulating a complex curved surface of the transverse arch of the human, such that the manufacturing cost is reduced, and the various parts of the sole are non-uniform in stiffness distribution: the outer side of the foot is a single-layer forefoot plate with a smaller curvature and minor stiffness; and the inner side of the foot is a double-layer stacked forefoot plate, and the lower layer plate has a large radius in curvature and stiffness.