A cushioning article comprises a first and a second polymeric sheet bonded to one another and enclosing an interior cavity. The polymeric sheets retain a gas in the interior cavity. A tensile component disposed in the interior cavity includes a first tensile layer, a second tensile layer, and a plurality of tethers spanning the interior cavity and connecting the first tensile layer to the second tensile layer. An inwardly-protruding bond joins the first polymeric sheet to the first tensile layer, protrudes inward from the first polymeric sheet toward the second polymeric sheet, and partially traverses the plurality of tethers. The first polymeric sheet is displaced from the first tensile layer adjacent to the inwardly-protruding bond by the gas. A method of manufacturing a cushioning article is disclosed.

The invention generally relates to removable outsole cushion attachments and shoe covers that are cushioned and disposable. The removable outsole cushion attachments and shoe covers can be used by healthcare professionals and others to achieve comfort and eliminate or at least reduce the fatigue associated with standing for long periods of time.

Described herein is a shock absorbing apparatus configured for use in a sole or insole for footwear. The device is generally provided in a raised structure equipped with air flow holes, a gripped bottom, and a smooth top.

The invention provides a textile comprising a supporting mechanism disposed on a surface of a fabric, having a printed layer and a layered elastic support; the elastic support is made of thermoplastic elastomer, and is connected with the printed layer; and a plurality of air-permeable elements disposed in the supporting mechanism. The textile of the invention can be made into wearables for a human body, and the supporting mechanism is capable of supporting human motor organs. The invention also provides a supportive thermoprinting material, a printed layer and a thermoplastic elastomer material layer are disposed on a surface of a substrate, and the printed layer and the thermoplastic elastomer material layer of the thermoprinting material are combined on a fabric to form the textile of the invention.

A cycling shoe cover is disclosed for protection of a cycling shoe when a cyclist dismounts and desires to walk in the cycling shoe. The cycling shoe cover includes a pair of side panels. A toe is coupled to one end of each of the pair of side panels forming a front pocket mateable with the toe of a cycling shoe. A heel is coupled to the opposite end of each of the pair of side panels forming a back pocket mateable with the heel of a cycling shoe. A sole member has a bottom surface and is joined to the pair of side panels. The bottom surface of the sole member is interposed between the cycling shoe and a ground surface when the cycling shoe cover is worn over the cycling shoe.

Provided in the present disclosure is an outsole including a sheet body which includes a substrate sheet and an injection molded article fixed to the substrate sheet, and a shoe that has the injection molded article having a certain melt viscosity and thereby being excellent in grip performance and long-term durability.

A shoe includes a sole having a midsole formed by a plurality of layer members laminated together, and an upper portion joined to the sole, The plurality of layer members of the midsole includes a cut having a linear shape, and a depth from a first height position to a second height position in a thickness direction.

A midsole for an article of footwear including a three dimensional mesh including interconnected unit cells and methods of making the same. The interconnected unit cells each include a plurality of struts defining a three dimensional shape. The interconnected unit cells are connected at nodes having a valence number defined by the number of struts connected at that node. The valence number of the nodes may vary to provide customized characteristics to zones or portions of the midsole. The plurality of interconnected unit cells may be organized in a warped cubic lattice structure. The warped cubic lattice structure and the size/shape of interconnected unit cells may vary to provide customized characteristics to zones or portions of the midsole. The three dimensional mesh may be customized based on a biometric data profile for an individual, or group of individuals. The midsole may be manufactured using an additive manufacturing process.

An article of footwear including a sole, and an upper having a lateral side and a medial side, each including a first lace opening. A lateral lace support and a medial lace support are attached to the sole and positioned adjacent to inner surfaces of the lateral and medial sides of the upper. The lateral lace support has a first length and the medial support has a second length, where the second length is greater than the first length, and each include a second lace opening. A lace is threaded through the first lace openings of the upper and the second lace openings of the lateral lace support and the medial lace support, where an axis extending between the lateral lace support and the medial lace support, after the lace is secured to the upper, is offset from an axis extending from a center of gravity of a user's foot.

A method of forming a structural honeycomb includes cutting and folding a substrate sheet according to predetermined cutting and folding patterns and fold angles that cause the sheet to form a honeycomb having cells that each have at least one face abutting, or nearly abutting, the face of another cell. The honeycomb is then stabilized by joining abutting, or nearly abutting, faces to hold the honeycomb together. The honeycomb may have a prespecified three-dimensional shape. The folding pattern may include corrugation, canted corrugation, or zig-zag folds. Joining may employ fixed and/or reversible joinery, including slotted cross section, tabbed strip, angled strip, integral skin, sewn, or laced. At least some folds may be partially-closed to create bends and twists in the honeycomb structure. Some surfaces of the honeycomb may be covered with a skin or face sheet. The substrate sheet may have flexible electronic traces.