Manufacturing and assembly of a shoe or a portion of a shoe is enhanced by automated placement and assembly of shoe parts. For example, a part-recognition system analyzes an image of a shoe part to identify the part and determine a location of the part. Once the part is identified and located, the part can be manipulated by an automated manufacturing tool.

Manufacturing and assembly of a shoe or a portion of a shoe is enhanced by automated placement and assembly of shoe parts. For example, a part-recognition system analyzes an image of a shoe part to identify the part and determine a location of the part. Once the part is identified and located, the part can be manipulated by an automated manufacturing tool.

An apparatus for effecting the positioning of cleats on shoes includes a baseplate to apply the arch of the foot, a gauge provided with a stop that can slide freely on the baseplate to be in contact with the calcaneum of the foot, and a wall for wedging the front part of the foot at the metatarsophalangeal joint of the big toe. The stop is fixed on a plate that slides parallel to the baseplate and a support for a shoe corresponding to the foot is fixed to the sliding plate. The support includes a stop to be placed in contact with the shoe counter. A marker is secured to the apparatus base and designed to indicate, on the shoe sole, the location for placing the cleat. The apparatus enables the distance recorded between the metatarsophalangeal joint of the big toe and calcaneum to be transferred onto the shoe.

An apparatus for effecting the positioning of cleats on shoes includes a baseplate to apply the arch of the foot, a gauge provided with a stop that can slide freely on the baseplate to be in contact with the calcaneum of the foot, and a wall for wedging the front part of the foot at the metatarsophalangeal joint of the big toe. The stop is fixed on a plate that slides parallel to the baseplate and a support for a shoe corresponding to the foot is fixed to the sliding plate. The support includes a stop to be placed in contact with the shoe counter. A marker is secured to the apparatus base and designed to indicate, on the shoe sole, the location for placing the cleat. The apparatus enables the distance recorded between the metatarsophalangeal joint of the big toe and calcaneum to be transferred onto the shoe.

A method for automated manufacturing of shoe soles comprises the steps of: loading a transfer device with at least one outsole element and at least one supporting element, positioning the loaded transfer device adjacent a first part and a second part of a sole mold, transferring the at least one outsole element from the transfer device to the first part and transferring the at least one supporting element from the transfer device to the second part of the sole mold, filling the sole mold with a plurality of individual particles, and applying a medium to bond and/or fuse the particles with each other and with the at least one outsole element.

In a method and device for extracting joint line of shoe, a contact end of a contouring tool is provided to contact a joint contour of a shoe sample, an encoder is provided to generate a plurality of first trajectory coordinate signals of the contact end while the contact end is moved along the joint contour, and a signal processor is provided to receive the first trajectory coordinate signals to create a digital joint line.

A system for producing a textile component of an article includes an additive manufacturing device in selective communication with a processor and memory. The processor and memory are configured to determine a strain value in a region of the textile component of the article based on images of the article from a camera in selective communication with the processor and memory and to generate a strain map based on the strain value. The additive manufacturing device is configured to apply a reinforcement to a textile substrate to variably reinforce the textile substrate according to the strain map and to form the textile component of the article.

Apparatus and systems disclosed herein are designed to be used to study various forces acting on an athletic field or an athletic surface caused by the interaction between a shoe and the turf or athletic surface during a simulated impact. Various surfaces can be tested and analyzed, including assessing deceleration, acceleration and cutting traction potential on the surfaces. The disclosed apparatuses and systems allow for the testing of a wide variety of footwear, at any desired impact angle, and at various simulated forces. Methods, systems, and computer readable media for generating graphical representations associated with surface performance test information are also disclosed herein.

Manufacturing of a shoe is enhanced by creating 3-D models of shoe parts. For example, a laser beam may be projected onto a shoe-part surface, such that a projected laser line appears on the shoe part. An image of the projected laser line may be analyzed to determine coordinate information, which may be converted into geometric coordinate values usable to create a 3-D model of the shoe part. Once a 3-D model is known and is converted to a coordinate system recognized by shoe-manufacturing tools, certain manufacturing steps may be automated.

Manufacturing of a shoe is enhanced by creating 3-D models of shoe parts. For example, a laser beam may be projected onto a shoe-part surface, such that a projected laser line appears on the shoe part. An image of the projected laser line may be analyzed to determine coordinate information, which may be converted into geometric coordinate values usable to create a 3-D model of the shoe part. Once a 3-D model is known and is converted to a coordinate system recognized by shoe-manufacturing tools, certain manufacturing steps may be automated.