A healthcare footwear article includes an upper shoe body and a sole member provided underneath the upper shoe body and is connected with the upper shoe body to form an integral body. The upper shoe body and the sole member is configured from a material consisting of approximately 70% to approximately 80% of silicon rubber by weight, approximately 5% to approximately 20% of negative ion powder by weight, approximately 2% to approximately 7% of antiwear agent by weight, approximately 5% to approximately 20% of titanium powder by weight, approximately 0.1% to approximately 1.5% of vulcanizing agent by weight, approximately 5% to approximately 10% of infrared ray powder by weight, and approximately 0.1% to approximately 8% of dye by weight.

A healthcare footwear article includes an upper shoe body and a sole member provided underneath the upper shoe body and is connected with the upper shoe body to form an integral body. The upper shoe body and the sole member is configured from a material consisting of approximately 70% to approximately 80% of silicon rubber by weight, approximately 5% to approximately 20% of negative ion powder by weight, approximately 2% to approximately 7% of antiwear agent by weight, approximately 5% to approximately 20% of titanium powder by weight, approximately 0.1% to approximately 1.5% of vulcanizing agent by weight, approximately 5% to approximately 10% of infrared ray powder by weight, and approximately 0.1% to approximately 8% of dye by weight.

A method of making a moisture-permeable and waterproof shoe includes: forming a vamp and a bottom liner from a fabric laminate and connecting the vamp and the bottom liner to form a semi-finished shoe with seams; disposing a shoe last in a foot-receiving space provided in the semi-finished shoe; coating an outer surface of the semi-finished shoe with a resin material and curing the resin material to form a moisture-permeable and waterproof resin layer on the outer surface of the semi-finished shoe and to cover the seams; attaching a shoe sole to the bottom liner; and removing the shoe last from the receiving space.

The disclosure relates to articles of footwear (100) and components thereof, including outsoles (112), which can be used in conditions normally conducive to the accumulation of soil on the outsoles (112). In particular, the disclosure relates to articles of footwear (100) and components thereof including an outsole (112) with a material (116) including a polymeric network formed of a plurality of polymer chains, where the material (116) defines external ground-facing surface or side of the outsole (112). The outsoles (112) can prevent or reduce the accumulation of soil on the footwear (100) during wear on unpaved surfaces such as sporting fields.

The disclosure relates to articles of footwear (100) and components thereof, including outsoles (112), which can be used in conditions normally conducive to the accumulation of soil on the outsoles (112). In particular, the disclosure relates to articles of footwear (100) and components thereof including an outsole (112) with a material (116) including a polymeric network formed of a plurality of polymer chains, where the material (116) defines external ground-facing surface or side of the outsole (112). The outsoles (112) can prevent or reduce the accumulation of soil on the footwear (100) during wear on unpaved surfaces such as sporting fields.

Upper components for footwear include: (a) a first upper component that includes a first layer having a first material as a first filament including first plural, non-intersecting, spaced apart path segments (wherein the first filament has a width dimension of less than 3 mm wide (and in some examples, less than 2 mm wide, less than 1.5 mm wide, less than 1 mm wide, or even less than 0.75 mm wide)); and (b) a second upper component including a fabric element formed at least in part of a fusible material, wherein the fusible material of the second upper component is fused to the first material of the first upper component (e.g., in an adhesive-free manner). Additional layers of material, including additional layers including filament and/or fabric elements, e.g., of the types described above, may be included in the upper.

Upper components for footwear include: (a) a first upper component that includes a first layer having a first material as a first filament including first plural, non-intersecting, spaced apart path segments (wherein the first filament has a width dimension of less than 3 mm wide (and in some examples, less than 2 mm wide, less than 1.5 mm wide, less than 1 mm wide, or even less than 0.75 mm wide)); and (b) a second upper component including a fabric element formed at least in part of a fusible material, wherein the fusible material of the second upper component is fused to the first material of the first upper component (e.g., in an adhesive-free manner). Additional layers of material, including additional layers including filament and/or fabric elements, e.g., of the types described above, may be included in the upper.

An outsole for an athletic shoe that includes a heel section and a forefoot section. The heel and forefoot sections are on the outer surface of the outsole. The forefoot section includes a tread pattern that provides first and second ground friction forces. The first ground friction force promotes rotation in a first rotational direction about a rotation point of the forefoot section. The second ground friction force restricts rotation in a second rotational direction about the rotation point. The second rotational direction is opposite of the first rotational direction and the second ground friction force is greater than the first ground friction force.

The soft boot and liner include a moisture transfer system that includes an inner fabric layer carefully selected from technically advanced fabrics. A series of layers are provided outside the inner liner including foam material layers, spacer fabrics and breathable membranes, in various orders. Encapsulation technology and waterproofing are used as well. The outer fabric layer is also capable of working with the other layers to promote the transfer of moisture. Frothed foams and flocking with fibers are further characteristics of the present invention. The moisture transfer system is incorporated into a soft boot or skate or as a removable liner for a shell boot. Numerous other modifications and applications are disclosed.

The present invention relates to a system integrated or retrofitted to a shoe for preventing a wearer of the shoe from becoming stuck in mud, sand, water, or any other soft terrain while walking. The system includes a pair of tubes positioned on opposing sides of the shoe/boot and a rigid attachment overlapping a portion of the sole of the shoe. A valve having a lengthwise opening can be placed between the rigid attachment and the sole such that each tube of the pair of tubes is attached to opposing ends of the valve using a pair of elbow tubes. Each elbow tube passes through a hole in the rigid attachment to connect to the valve. The valve creates a vacuum when the shoe to which the system is attached is stepped onto the terrain and when the shoe is lifted, the vacuum is released.