Devices with internal flexibility sipes, such as slits, provide improved flexibility, improved cushioning to absorb shock and/or shear forces, and improved stability of support. Siped devices can be used in any existing product that provides or utilizes cushioning and stability. These products include human and other footwear, both soles and uppers, as well as orthotics; athletic, occupational and medical equipment and apparel; padding or cushioning, such as for equipment or tool handles, as well as furniture; balls; tires; and any other structural or support elements in a mechanical, architectural, or any other product.

A sole structure for an article of footwear includes a cushioning element having a top surface, a bottom surface formed on an opposite side of the cushioning element from the top surface, a ramp surface spaced apart from the bottom surface in a heel region of the cushioning element, a heel pocket extending through the cushioning element from the top surface to the ramp surface, and a plurality of pillars extending from the ramp surface and surrounding the pocket. The sole structure additionally includes a plurality of cushioning particles disposed within the pocket, an outsole attached to the cushioning element and enclosing a first end of the pocket, and an upper barrier layer attached to the top surface of the cushioning element and covering a second end of the pocket.

A sole structure for an article of footwear includes a cushioning element having a top surface, a bottom surface formed on an opposite side of the cushioning element from the top surface, a ramp surface spaced apart from the bottom surface in a heel region of the cushioning element, a heel pocket extending through the cushioning element from the top surface to the ramp surface, and a plurality of pillars extending from the ramp surface and surrounding the pocket. The sole structure additionally includes a plurality of cushioning particles disposed within the pocket, an outsole attached to the cushioning element and enclosing a first end of the pocket, and an upper barrier layer attached to the top surface of the cushioning element and covering a second end of the pocket.

Various articles, such as footwear, apparel, athletic equipment, watchbands, and the like, and methods of forming those articles are presented. The articles are generally formed, in whole or in part, using rapid manufacturing techniques, such as laser sintering, stereolithography, solid deposition modeling, and the like. The use of rapid manufacturing allows for relatively economical and time efficient manufacture of customized articles. The articles may include one or more reinforcements configured to provide added durability to various regions of the articles. In addition, the articles may be formed from two or more materials in a single rapid manufacturing process. The rapid manufacturing additive fabrication technique may also include using of varying intensities of the laser to fuse material to form the articles.

Presented are footwear sole structures with pressure-mapped midsole topographies and inlaid wear-mitigating outsoles, methods for making/using such sole structures, and footwear fabricated with such sole structures. An article of footwear includes an upper for receiving and attaching to a foot of a user, and a sole structure attached to the upper for supporting thereon the user's foot. The sole structure includes a midsole that is formed with a first material having a first hardness, and an outsole that is mounted to the midsole and formed with a second material that is harder than the first material. The midsole has a ground-facing surface with multiple cavities, multiple channels interspersed with the cavities, and ground-contacting land segments that separate the cavities from the channels. The outsole is disposed in the channels and positioned between the cavities such that a ground-contacting outsole surface is substantially flush with the midsole's ground-contacting land segments.

Provided is a non-skid shoe capable of absorbing shock including: an outsole; a plurality of accommodation grooves formed on the outsole, the accommodation groove including a groove portion, and a penetrated portion extending from the groove portion and penetrating the outsole; a support member which is accommodated in the respective accommodation grooves, and includes a support portion disposed in the groove portion, a first guide portion formed at a center of the support portion, and a second guide portion extending from the first guide portion and penetrating a bottom surface of the support portion; a movable member which is disposed in the respective support members, and includes a latch portion and a protruding portion; a pressing member engaged to an upper portion of the first guide portion; a resilient member disposed in the first guide portion; and a midsole engaged to the top surface of the outsole.

Provided is a non-skid shoe capable of absorbing shock including: an outsole; a plurality of accommodation grooves formed on the outsole, the accommodation groove including a groove portion, and a penetrated portion extending from the groove portion and penetrating the outsole; a support member which is accommodated in the respective accommodation grooves, and includes a support portion disposed in the groove portion, a first guide portion formed at a center of the support portion, and a second guide portion extending from the first guide portion and penetrating a bottom surface of the support portion; a movable member which is disposed in the respective support members, and includes a latch portion and a protruding portion; a pressing member engaged to an upper portion of the first guide portion; a resilient member disposed in the first guide portion; and a midsole engaged to the top surface of the outsole.

Presented are footwear sole structures with pressure-mapped midsole topographies and inlaid wear-mitigating outsoles, methods for making/using such sole structures, and footwear fabricated with such sole structures. An article of footwear includes an upper for receiving and attaching to a foot of a user, and a sole structure attached to the upper for supporting thereon the user's foot. The sole structure includes a midsole that is formed with a first material having a first hardness, and an outsole that is mounted to the midsole and formed with a second material that is harder than the first material. The midsole has a ground-facing surface with multiple cavities, multiple channels interspersed with the cavities, and ground-contacting land segments that separate the cavities from the channels. The outsole is disposed in the channels and positioned between the cavities such that a ground-contacting outsole surface is substantially flush with the midsole's ground-contacting land segments.

Presented are footwear sole structures with pressure-mapped midsole topographies and inlaid wear-mitigating outsoles, methods for making/using such sole structures, and footwear fabricated with such sole structures. An article of footwear includes an upper for receiving and attaching to a foot of a user, and a sole structure attached to the upper for supporting thereon the user's foot. The sole structure includes a midsole that is formed with a first material having a first hardness, and an outsole that is mounted to the midsole and formed with a second material that is harder than the first material. The midsole has a ground-facing surface with multiple cavities, multiple channels interspersed with the cavities, and ground-contacting land segments that separate the cavities from the channels. The outsole is disposed in the channels and positioned between the cavities such that a ground-contacting outsole surface is substantially flush with the midsole's ground-contacting land segments.

An outsole for a shoe includes i) a main tread to be secured to a shoe, the main tread having a sole portion and a heel portion, ii) at least one non-slip element integrated to the main tread and being positioned within one of the sole and heel portions; and iii) a retractable crampon, including at least one spike, that is mounted to the other one of the sole and heel portions of the main tread. The retractable crampon is movable between a deployed position, wherein the at least one spike extends from the main tread, and a retracted position, wherein the at least one spike is prevented from contacting the ground by the main tread.