A comfort system for Cowboy and work boots, including an insole chassis, an insole chassis backing board, and cushioning pads for absorbing and attenuating shocks encountered by a wearer of the boots. Cushioning pads are secured to a surface of the insole chassis backing board, and apertures in the insole chassis allow the cushions to pass through. Additional cushioning pads are retained in recesses in the midsole. Pads on insole chassis backing board and midsole are vertically aligned. A steel toe inset is utilized in conjunction with the comfort system for work boots. A rim may depend below the midsole to receive a foamed plastic pad.

A variable friction shoe includes a midsole and an outsole. The outsole includes at least a first high-friction surface and at least a first low-friction surface, wherein the first low-friction surface remains prominent if vertical ground reaction forces (GRFs) are low and wherein the high-friction surface is prominent in response to increasing GRFs.

An anti-fatigue shoe apparatus is presented that is designed to reduce foot fatigue and discomfort. The anti-fatigue shoe apparatus makes use of novel combinations of insole, midsole, outsole, and comfort material configurations and designs to provide comfort, support, and flexibility within work footwear. The anti-fatigue shoe apparatus includes a raised arch support piece that cradles the foot's natural arch, reducing torque and improving stability. Toe and heel comfort zones made of cushioning materials provide targeted support and pressure relief. In some embodiments an injection system for providing a liquid comfort material injected into the toe and heel zones through canals in the outsole are presented for customized cushioning. The invention comes in various material combinations.

A plurality of fluid-filled chambers may be incorporated into sole structures of articles of footwear. The chambers may be configured to be substantially diamond-shaped. The chambers may lie within cavities formed by a lower surface of the midsole and may extend into apertures in the outsole. The apertures in the outsole may be aligned with the cavities of the midsole. The chambers may be bounded by bounding regions between and at the perimeter of the chambers. The bounding regions may be formed of a polymer foam material of the midsole. The chambers may additionally be connected.

A shoe is configured such that front and back clearances, which are respectively provided between a front wall surface of a second receiving portion and a front end of a second buffering member received in the second receiving portion and between a back wall surface of the second receiving portion and a back end of the second buffering member received in the second receiving portion, permit the second buffering member made of an elastic material to move in a longitudinal direction in the second receiving portion when a ground surface of an outsole contacts the ground and the weight of a human body is put on a heel support surface.

An article of footwear may include a sole structure fixedly attached to an upper defining an internal cavity configured to receive a foot of a wearer. The sole structure may include an exposed outer member configured to contact the ground, the exposed outer member including a first aperture, and a sensory feedback member disposed at least partially within the first aperture in the outer member, the sensory feedback member including a first end and a second end. The first end of the sensory feedback member may include a projection extending through the first aperture and configured to contact the ground. In addition, the second end of the sensory feedback member may include a plurality of flexible bristles extending through a portion of the sole structure and exposed to the internal cavity.

An article of footwear may have an upper and a sole structure secured to the upper. The sole structure has a plurality of support elements, and each of the support elements include a shell and a core. The shell defines an interior void and is formed from a polymer material that extends around substantially all of the void. The core has a shape of the void and is located within the void, with at least a portion of the core being a polymer foam material. The polymer foam material of at least two of the support elements may have different densities.

An orthotic device for insertion into footwear for correcting over pronation or supination of a foot is disclosed herein. The orthotic device may include an insole comprising an upper surface and a lower surface. The upper surface of the insole may receive and support at least a portion of the foot. The orthotic device also may include a removable angle insert attachable to the lower surface of the insole. The removable angle insert may increase an angle about a side of the insole to correct over pronation or supination of the foot.

An insole having a top sheet, a base layer, a forefoot pad, a heel cushion, and stability cradle. The forefoot pad can be made a blown EVA or other material, and the heel cushion can be made of a clear TPR, soft polyurethane or blown EVA. A heel cup surrounds the exterior back by a heel cup, and a heel pod opening and midfoot pod opening is located in the stability cradle for allowing placement of heel pads and midfoot pads in a replacement manner. There is also a soft metatarsal raised dome on the top (foot contact) surface of the insole which would be directly above the metatarsal midfoot area.

A sole for a shoe or other footwear. The sole includes at least two structures, each structure being configurable, and wherein at least a part of each of said at least two structures is located in a single frontal plane cross-section of the sole when the sole is upright and in an unloaded condition. The sole also includes at least one electronic control system that controls a configuration of each said at least two structures. Optionally, the at least two structures and/or the at least one electronic control system are located in a midsole section of said sole.