A resilient pad for an article of footwear comprises a plurality of pocketed coil springs each of which is located in discrete pocket formed between two layers of material bonded or otherwise attached together at least at locations between the springs. The springs are preferably coil springs which may be of wire and are preferably of stainless steel or titanium. The springs are preferably wider than they are tall, i.e. they have a diameter which is greater than the height of the spring when the spring is in the pocket. The pad or panel may be substantially co-extensive in plan with a foot of a wearer of the article of footwear.

A shock-absorbing shoe using a spring, comprising: a spring for absorbing shock by providing an elastic force; an outsole which constitutes the bottommost sole of a shoe; an upper sole which is fixed to the top of the outsole, has a gap between the heel part thereof and the heel part of the outsole so as to provide a space in which the spring is provided, and is lowed by the weight of a user or raised by the elastic force of the spring; a lower spring seat which is formed on the upper surface of the outsole and supports the lower end part of the spring; an upper spring seat which is formed below the bottom of the upper sole and supports the upper end part of the spring; and a raising and lowering guide for guiding the lowering and raising of the upper sole straightly.

A shoe includes a first plate, a second plate, a third plate, filler material, springs, an insole, and a midsole. The first plate and the second plate are hingedly connected to each other. The filler material is located between the first plate and the second plate. The springs are located within openings in the filler material. The third plate is affixed to a top surface of the first plate. The insole is located above the third plate. The first plate is made of a thermoplastic elastomer, and the third plate is made of carbon fiber. Another shoe includes a midsole, a plate located above the midsole, springs located at least partially within openings in the midsole, and a spring holding unit located below the midsole for holding the springs. The spring holding unit includes spring holding members and branches connecting corresponding spring holding members.

A modular article of footwear has a shock absorbing insert placed between the insole and the outsole thereof, for example at the heel. The insert includes a spring carrier having upper and lower portions, each having a plurality seats for receiving a respective ends of respective coil springs. Each of the springs extends between said upper and lower portions and is captured therebetween. A pair of opposed permanent magnets generates a separating force which supplements the supporting force of the mechanical springs. The insert may also contain a device for converting mechanical energy to electrical energy.

A sole structure for an article of footwear includes an impact-attenuation support member. The impact-attenuation support member includes a first impact-attenuation element and a second-impact-attenuation element. The first and second impact-attenuation elements include one or more portions that are interlinked and that are movable with respect to one another in at least one direction.

A shock absorbing device having at least one canted spring disposed between two members is described. When the members move toward each other, the one or more canted coil springs are canted and compressed. The shock absorbing device takes advantage of the unique force-displacement curve of canted springs and reduces bounce back.

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.

A shoe midsole having a structure formed by additive manufacturing process, including a bottom pad, an upper pad and a shock-absorbing layer. The bottom pad has foot-shaped profile and includes a plurality of stress zones. The upper pad is arranged opposite to the bottom pad and has foot-shaped profile almost identical to that of the bottom pad. The shock-absorbing layer is arranged between the bottom pad and the upper pad and includes a plurality of pressure-bearing units. The pressure-bearing unit is arranged between the bottom pad and the upper pad in the manner that two ends of each pressure-bearing unit abut against the bottom pad and the upper pad respectively. The pressure-bearing unit has excellent mechanical properties such as higher energy absorption and force bearing capacity for bearing pressures or stress put by the foot, good flexibility and higher deflection capacity that can be elastically deformed in the longitudinal direction.

Provided is a shoe article with an arch spring. A shoe article with an arch spring comprises an arch part 13 contacting a side part of a foot middle part and having a convex curved shape upwardly; and an arch spring 20, 30 formed at the arch part 13, wherein at least one part of the arch spring 20, 30 has an elastic property for moving in an up and down direction and being recovered in an original shape.

Variable stiffness apparatuses using an interconnected dual layer fluid-filled cell array. One example of the present apparatuses comprises: a substrate having a first side and a second side; and a plurality of structures coupled to the substrate, where each structure comprises: a flexible first portion having a first end, a second end, and a sidewall extending between the first end and the second end, the first portion defining a first chamber; and a second portion having a first end, a second end, and a sidewall extending between the first end and the second end, the second portion defining a second chamber in fluid communication with the first chamber; where each of the plurality of structures is coupled to the substrate such that the first portion is disposed on the first side of the substrate, and the second chamber is disposed on the first side or the second side of the substrate.