A method of forming a fiber reinforced plate for an article of footwear is described. The method includes embroidering a reinforcing strand to a substrate layer with a thread according to a strand configuration. One or more substrate layers with strand configurations are arranged relative to a base plate. The one or more substrate layers are bonded to the base plate to form the fiber reinforced plate. The reinforcing strands may be formed of a heat fusible material so that adjacent segments of the strands bond to one another and/or the substrate layer. Various strand configurations of reinforcing strands embroidered to substrate layers are described. Multiple substrate layers with different strand configurations can be bonded together with a base plate to form a fiber reinforced plate with reinforcement at selected locations based on the strand configurations.

A method of forming a fiber reinforced plate for an article of footwear is described. The method includes embroidering a reinforcing strand to a substrate layer with a thread according to a strand configuration. One or more substrate layers with strand configurations are arranged relative to a base plate. The one or more substrate layers are bonded to the base plate to form the fiber reinforced plate. The reinforcing strands may be formed of a heat fusible material so that adjacent segments of the strands bond to one another and/or the substrate layer. Various strand configurations of reinforcing strands embroidered to substrate layers are described. Multiple substrate layers with different strand configurations can be bonded together with a base plate to form a fiber reinforced plate with reinforcement at selected locations based on the strand configurations.

A method of forming a fiber reinforced plate for an article of footwear is described. The method includes embroidering a reinforcing strand to a substrate layer with a thread according to a strand configuration. One or more substrate layers with strand configurations are arranged relative to a base plate. The one or more substrate layers are bonded to the base plate to form the fiber reinforced plate. The reinforcing strands may be formed of a heat fusible material so that adjacent segments of the strands bond to one another and/or the substrate layer. Various strand configurations of reinforcing strands embroidered to substrate layers are described. Multiple substrate layers with different strand configurations can be bonded together with a base plate to form a fiber reinforced plate with reinforcement at selected locations based on the strand configurations.

This invention is directed to an improved contact surface for manipulating articles wherein the microstructure included on the contact surface having a plurality of pillars spaced apart in the range of 200 m and 600 m, having a height in the range of 50 m and 1200 m, a width of in the range of 70 m and 300 m, a wall draft angle between 0 and 15, a density of in the range of 5,000 to 20,000 pillars per square inch, and a friction rating greater than 7. The contact surface can be included on a sewing machine feed dog, a glove, sporting equipment, firearm grip, hand rail, tool grip, tool handle, and a strap such as for a satchel or backpack.

A method of forming a fiber reinforced plate for an article of footwear is described. The method includes embroidering a reinforcing strand to a substrate layer with a thread according to a strand configuration. One or more substrate layers with strand configurations are arranged relative to a base plate. The one or more substrate layers are bonded to the base plate to form the fiber reinforced plate. The reinforcing strands may be formed of a heat fusible material so that adjacent segments of the strands bond to one another and/or the substrate layer. Various strand configurations of reinforcing strands embroidered to substrate layers are described. Multiple substrate layers with different strand configurations can be bonded together with a base plate to form a fiber reinforced plate with reinforcement at selected locations based on the strand configurations.

This invention is directed to an improved contact surface for manipulating articles wherein the microstructure included on the contact surface having a plurality of pillars spaced apart in the range of 200 m and 600 m, having a height in the range of 50 m and 1200 m, a width of in the range of 70 m and 300 m, a wall draft angle between 0 and 15, a density of in the range of 5,000 to 20,000 pillars per square inch, and a friction rating greater than 7. The contact surface can be included on a sewing machine feed dog, a glove, sporting equipment, firearm grip, hand rail, tool grip, tool handle, and a strap such as for a satchel or backpack.