A system for stitching two parts of a shoe together includes a stitching machine with a head and a cylinder bed. The head has a needle base disposed on a lower end adjacent the cylinder bed such that the two shoe parts can be stitched together therebetween. A positioning mechanism has a curved drive frame and is capable of moving the curved drive frame in a rotating motion along the circumference of the curved drive frame and in a linear direction generally along an axis of the curved drive frame. A jig positions the two shoe parts with respect to one another and is coupled to the curved drive frame. The jig includes a curved support surface for supporting the two shoe parts.

Manufacturing of a shoe or a portion of a shoe is enhanced by executing various shoe-manufacturing processes in an automated manner. For example, shoe parts may be retrieved and temporarily assembled according to preset relative positions to form part stacks. The part stacks may be retrieved with the relative positioning of the shoe parts being maintained and placed at a stitching machine for more permanent attachment via stitching of the parts to form a shoe assembly. Movement during stitching of a conveyance mechanism that transfers the part stack from the stacking surface to the stitching machine and movement of a needle associated with the stitching machine may be controlled by a shared control mechanism such that the movements are synchronized with respect to one another. Vision systems may be leveraged to achieve movement and position information between and at machines and locations.

Manufacturing of a shoe or a portion of a shoe is enhanced by executing various shoe-manufacturing processes in an automated manner. For example, shoe parts may be retrieved and temporarily assembled according to preset relative positions to form part stacks. The part stacks may be retrieved with the relative positioning of the shoe parts being maintained and placed at a stitching machine for more permanent attachment via stitching of the parts to form a shoe assembly. Movement during stitching of a conveyance mechanism that transfers the part stack from the stacking surface to the stitching machine and movement of a needle associated with the stitching machine may be controlled by a shared control mechanism such that the movements are synchronized with respect to one another. Vision systems may be leveraged to achieve movement and position information between and at machines and locations.

A sewing machine and a method of operating a sewing machine able to gather one or more materials through a variable speed transfer disc or transfer cup. The gathering operation can assist in joining materials of different lengths without causing a warp or other unintended variation in the sewn article. The gathering operation may be used in connection with sewing of an article of footwear upper with an insole portion to form a foot-receiving cavity. During a sewing operation, a tension on the thread may be adjusted and confirmed with a display output. Similarly, an indication of pressure applied to decrease a rotational speed of the transfer disc or the transfer cup may be presented on a display output to achieve repeatability across operators and articles.

A sewing machine and a method of operating a sewing machine able to gather one or more materials through a variable speed transfer disc or transfer cup. The gathering operation can assist in joining materials of different lengths without causing a warp or other unintended variation in the sewn article. The gathering operation may be used in connection with sewing of an article of footwear upper with an insole portion to form a foot-receiving cavity. During a sewing operation, a tension on the thread may be adjusted and confirmed with a display output. Similarly, an indication of pressure applied to decrease a rotational speed of the transfer disc or the transfer cup may be presented on a display output to achieve repeatability across operators and articles.

A stitching system includes a jig capable of joining two shoe parts and capable of being used in an automated stitching machine. The jig includes a lower member capable of being operably coupled to the automated stitching machine and an upper member also capable of being operably coupled to the automated stitching machine. The two shoe parts are held in place between the lower member and the upper member. The lower member, the upper member and the two shoe parts therebetween are moved by the automated stitching machine in accordance with a pattern stored in the automated stitching machine.

A stitching system includes a jig capable of joining two shoe parts and capable of being used in an automated stitching machine. The jig includes a lower member capable of being operably coupled to the automated stitching machine and an upper member also capable of being operably coupled to the automated stitching machine. The two shoe parts are held in place between the lower member and the upper member. The lower member, the upper member and the two shoe parts therebetween are moved by the automated stitching machine in accordance with a pattern stored in the automated stitching machine.

A system for stitching two parts of a shoe together includes a stitching machine with a head and a cylinder bed. The head has a needle base disposed on a lower end adjacent the cylinder bed such that the two shoe parts can be stitched together therebetween. A positioning mechanism has a curved drive frame and is capable of moving the curved drive frame in a rotating motion along the circumference of the curved drive frame and in a linear direction generally along an axis of the curved drive frame. A jig positions the two shoe parts with respect to one another and is coupled to the curved drive frame. The jig includes a curved support surface for supporting the two shoe parts.

An embroidered vamp process includes the following steps: (1) designing a vamp manufacture drawing by a computer; (2) according to the design drawing of step (1), cutting different pieces of cloth into base fabric of the vamp and a splice component of the vamp respectively by a laser; (3) typesetting the splice component cut in step (2) on the base fabric, then embroidering the splice component on the base fabric according to an embroidery thread pattern of the drawing by an embroidery machine; (4) cutting out the redundant base fabric of the vamp along the edge the splice component by, once again, the laser, forming the vamp of the finished product shoe model. An embroidered vamp comprises a vamp body, said vamp body comprising the base fabric and the splice component, said splice component being embroidered on the surface of base fabric by embroidery thread.

An embroidered vamp process includes the following steps: (1) designing a vamp manufacture drawing by a computer; (2) according to the design drawing of step (1), cutting different pieces of cloth into base fabric of the vamp and a splice component of the vamp respectively by a laser; (3) typesetting the splice component cut in step (2) on the base fabric, then embroidering the splice component on the base fabric according to an embroidery thread pattern of the drawing by an embroidery machine; (4) cutting out the redundant base fabric of the vamp along the edge the splice component by, once again, the laser, forming the vamp of the finished product shoe model. An embroidered vamp comprises a vamp body, said vamp body comprising the base fabric and the splice component, said splice component being embroidered on the surface of base fabric by embroidery thread.