The present disclosure relates to a platform for footwear. The platform includes bevels and an internal channel for assembling an upper with the platform. A first bevel is defined in a first side portion of the platform and is configured to receive a portion of a first upper side. A second bevel is defined in a second side portion of the platform and is configured to receive a portion of a second upper side. An internal channel is positioned within the platform and extends between the first bevel and the second bevel. The internal channel is configured to receive a fastener to assemble the upper with the platform. The platform may also include a slot for receiving an edge portion of a sock liner to assemble the sock liner with the platform.

An insole and/or outsole for a shoe such as an athletic shoe or cleat that includes a multilayer channeled assembly designed at preventing the transfer of heat from extremely hot ground surfaces, most notably synthetic turf, to the foot. In one embodiment, the insole includes a channeled layer of solid material with a very low thermal conductivity, preferably silicon or cork, as the base material beneath a layer of heat resistant felt preferably made of oxidized polyacrylonitrile fibers. The channeling in the base layer allows for air pockets to be created within the insole itself that makes the heat resistant felt more resistant to (i.e., more efficient at preventing) the transfer of heat. In another embodiment, the outsole for a shoe such as an athletic shoe or cleat includes a base layer of channeled solid material with low thermal conductivity, preferably silicon, cork, or polystyrene, below a layer of heat resistant felt preferably made of oxidized polyacrylonitrile fibers. This assembly is encased within a solid plastic mold that extends up to the base of the upper of the shoe or cleat and allows for little or no pressure to be put on the assembly itself. The studs for the cleats are preferably molded out of the plastic encasing itself.

The invention relates to a system of analyzing and quantifying a user's posture and gait, characterized in that it includes a pair 10 of soles 11, 12 each provided with an electronic box 100, 101, 102, each box comprising: an inertial platform, a data processing module 120, 121, 122, a data storage module 130, 131, 132, a means of communication 140, 141, 142, a power source 150.

A method for interlocking a shoe sole can provide the ability for the shoe sole to be attached or removed. For example, a shoe wearer may want the ability to change his or her shoe soles for aesthetic purposes. The shoe sole can also comprise additional functionality for the shoe wearer. For example, a method of also using the shoe sole as storage is discussed herein.

An insole and/or outsole for a shoe such as an athletic shoe or cleat that includes a multilayer channeled assembly designed at preventing the transfer of heat from extremely hot ground surfaces, most notably synthetic turf, to the foot. In one embodiment, the insole includes a channeled layer of solid material with a very low thermal conductivity, preferably silicon or cork, as the base material beneath a layer of heat resistant felt preferably made of oxidized polyacrylonitrile fibers. The channeling in the base layer allows for air pockets to be created within the insole itself that makes the heat resistant felt more resistant to (i.e., efficient at preventing) the transfer of heat. In another embodiment, the outsole for a shoe such as an athletic shoe or cleat includes a base layer of channeled solid material with low thermal conductivity, silicon, cork, or polystyrene, below a layer of heat resistant felt.

An insulating shoe insert including a core layer formed of a cellular material, and a top layer and a bottom layer bonded to opposing sides of the core layer, respectively, the top layer and the bottom layer being configured as thin sheets of aromatic polyamide material such that the top layer and bottom layer cooperate with the core layer to create a heat transfer resistance sufficient to resist transfer of heat through the core layer.

A flexible cellular material is thermoregulated by compressing and expanding gas trapped in its cells A flexible elastomer material of a device that provide thermoregulation includes two layers of different shore hardness and conductivity and is has gas-filled cells. Each cell has a zone to store the gas when compressing the material in the layer C with higher hardness and thermal conductivity and another zone to expand the gas when decompressing the material in the layer D with lower hardness and thermal conductivity. The flexible material can be used as a sole in shoes to maintain a cool temperature. With each step, the cell zones located in the layer C act as adiabatic chambers whose gasses heat with compression. When the foot leaves the ground the zones of cells located in the layer D then act as a reactor nozzle that will expand the air and therefore cool it.

The invention relates to a system of analyzing and quantifying a user's posture and gait, characterized in that it includes a pair 10 of soles 11, 12 each provided with an electronic box 100, 101, 102, each box comprising: an inertial platform, a data processing module 120, 121, 122, a data storage module 130, 131, 132, a means of communication 140, 141, 142, a power source 150.

Provided herein are embodiments of a shoe component. The shoe component may include a toebox, an insole, an adhesive membrane, a thermal-resistant insert, a midsole, and an outsole. The insert may further include a footbed. The footbed may include an upper surface and a bottom surface. The insert may further include an upper laminate on the upper surface of the footbed and a lower laminate on the bottom surface of the footbed.

An insulating shoe insert including a core layer formed of a cellular material, and a top layer and a bottom layer bonded to opposing sides of the core layer, respectively, the top layer and the bottom layer being configured as thin sheets of aromatic polyamide material such that the top layer and bottom layer cooperate with the core layer to create a heat transfer resistance sufficient to resist transfer of heat through the core layer.