A sole structure for an article of footwear comprises a midsole system with a plurality of cushioning units, each having multiple cushioning layers configured to work together as a system to absorb a compressive load, such as a dynamic compressive load due to impact with the ground, in stages of progressive cushioning according to the relative stiffness values of the layers. Various midsole systems disclosed include isolated cushioning units, linked cushioning units, sole layers having stanchions interfacing with the midsole system, midsole systems with sole layers having keyed and unkeyed portions overlying a bladder, and midsole systems with vertically-stacked cushioning units disposed in inverted relationship to one another.

A sole structure for an article of footwear comprises a midsole having four stacked polymeric sheets bonded to one another to define a first cushioning layer, a second cushioning layer, and a third cushioning layer. Each cushioning layer comprises a sealed chamber retaining gas in isolation from each other sealed chamber. Bonds between adjacent ones of the sheets are arranged such that the third cushioning layer is stacked directly above the first cushioning layer with the second cushioning layer bordering both the first cushioning layer and the third cushioning layer, and the sealed chamber of the second cushioning layer includes a plurality of elongated segments each extending lengthwise across a longitudinal midline of the midsole at a respective acute angle to the longitudinal midline.

A shoe midsole is strategically integrated or scored to produce various straight and arcuate lines. Straight lines are integrated widthwise between edges on an arch side on an outer side. Arcuate lines are integrated into various places at the top of a toe portion, with at least one extending down through a midpoint in a heel portion. The latter arcuate line maintains curvatures that parallel curvatures on the outer side at some places and the arch side at other places. Also crossing at the midpoint in the heel portion are intersecting lines.

Improved soles and insoles for shoes, in particular sports shoes, are described. In an aspect, a sole for a shoe, in particular a sports shoe, with at least a first and a second surface region is provided. The first surface region comprises expanded thermoplastic polyurethane (“TPU”). The second surface region is free from expanded TPU.

An article with a sole structure including a first layer and a second layer are disclosed. The first layer includes a set of apertures arranged in an auxetic configuration that permit the first layer to exhibit a first auxetic behavior. The second layer includes a set of projections arranged in an auxetic configuration that permit the second layer to exhibit a second auxetic behavior. The first layer and the second layer may be joined together in a manner that allows the first auxetic behavior to occur independently of the second auxetic behavior.

A cushion device is provided comprising a plurality of cells arranged in an array. Each one of the plurality of cells may comprise a plurality of vertical walls interconnected to form a vertical structure. Each vertical wall of each cell may be connected to an adjacent vertical wall of an adjacent cell such that each cell is connected to a plurality of adjacent cells. Each of the plurality of vertical walls may comprise a port where the port of each vertical wall of each cell may be in fluid communication with an adjacent port of the adjacent vertical wall of the adjacent cell via a fluid aperture.

A sole for article of footwear includes a midsole component having an inner surface and an outer surface opposite the inner surface. A plurality of blind holes each extends from the outer surface toward the inner surface. The plurality of blind holes are arranged in an auxetic configuration in the outer surface. Each hole in the plurality of holes extends towards the inner surface. The plurality of blind holes is arranged in a pattern that provides a tunable performance characteristic. The patterns of blind holes vary between different regions of the midsole component to provide different types of responses in the different regions.

A variety of devices for protecting a user's foot from injury are disclosed. In one instance, the device is an external metatarsal protection device for a shoe or boot, having a sole with a first surface for supporting a wearer's foot and a second surface for contacting a ground area, an upper affixed to the sole, and an integral toe cap. An interior surface of the upper and the first surface of the sole define a receptacle for receiving the wearer's foot. The external protection device is incorporated along an exterior surface of the upper and is positioned to protect at least a metatarsal region of the wearer's foot. In an instance, the external protection device has injection-molded first and second layers of material, with the cushioning elements formed on a surface of the first layer and a plurality of grooves defined on a surface of the second layer.

A sole for article of footwear includes a midsole component having an inner surface and an outer surface opposite the inner surface. A plurality of blind holes each extends from the outer surface toward the inner surface. The plurality of blind holes are arranged in an auxetic configuration in the outer surface. Each hole in the plurality of holes extends towards the inner surface. The plurality of blind holes is arranged in a pattern that provides a tunable performance characteristic. The patterns of blind holes vary between different regions of the midsole component to provide different types of responses in the different regions.

A sole structure includes a sole component, which has an inner surface and an outer surface opposite the inner surface. The sole component has a length and a thickness. The sole component includes a sole material, and the sole material has a density. At least one of the thickness or the density varies along the length of the sole component. The sole component defines a plurality of holes extending from at least one of the inner surface and the outer surface and arranged to form an auxetic structure. The auxetic structure is configured such that, when the sole component is tensioned in a first direction, the sole component expands in both the first direction and in a second direction orthogonal to the first direction. A property of the auxetic structure varies as a function of the density or the thickness of the sole component.