A conveying device includes a conveyor and a carrying member. The conveyor is movable along a transporting path that sequentially defines an upstream segment and a downstream segment, and an outer surface of the conveyor includes a detecting region. The carrying member is mounted on the outer surface of the conveyor. A height of the carrying member with respect to the outer surface is larger than or equal to 3 mm.

A conveying device includes a conveyor and a carrying member. The conveyor is movable along a transporting path that sequentially defines an upstream segment and a downstream segment, and an outer surface of the conveyor includes a detecting region. The carrying member is mounted on the outer surface of the conveyor. A height of the carrying member with respect to the outer surface is larger than or equal to 3 mm.

The present disclosure relates to a shoemaking method and a shoemaking system, wherein the shoe design data is obtained from a user through the Internet or Internet of Things, and the purchase data is provided to the user according to the shoe design data. When an order data is obtained from the user, at least one pair of designed shoes is produced according to the shoe design data. The present method provides a tracking tag for the designed shoes. The tracking tag corresponds to tracking information. When the tracking tag is scanned by the scanning device connected to the Internet or Internet of Things, the scanning device uploads the tracking information through the Internet or Internet of Things.

The present disclosure relates to a shoemaking system, including a processing unit, a first conveying device, a first pickup device, a scanning device, a first coating device and a first applying device. The first conveying device comprises at least one support; the first pickup device picks up an upper and the upper is disposed on the first support of the first conveying device. The scanning device is connected to the processing unit and can scan a scanning area; the first conveying device moves the upper on the first support to the scanning area. The scanning device scans the upper in the scanning area and outputs three-dimensional structure data; the processing unit obtains the three-dimensional structure data from the scanning device and decides a first coating path and a first applying path. The first coating device is configured to spray a first treating agent to the upper according to the first coating path; the first applying device is configured to apply a first adhesive to the upper according to the first applying path.

An automatic shoe-lacing machine for securing a shoelace onto a shoe upper includes a jig unit, a robotic arm unit and a control unit. The jig unit permits the shoe upper to be disposed thereon. The robotic arm unit is disposed at the proximity of the jig unit. The robotic arm unit simultaneously holds and moves two tipping members of the shoelace for sequentially passing the tipping members through eyelets formed in the shoe upper. The control unit controls the movement of the robotic arm unit.

The invention relates to measurement technology and is intended for measuring the shape, the internal dimensions and the flexibility of shoes. The proposed measurement method consists in using probes with indicators, which create tension on the measured surface. A camera and a flat marking band are used for tracing the shape of the internal surface of a shoe. On the basis of the sum of the images, a three-dimensional model of the internal surface of the tested shoe is made, and the flexibility properties are determined by scanning the object with different forces. A device comprises a body, a camera mounted therein, two or more probes with indicators, and a flat marking band. The invention makes it possible to increase accuracy and to reduce the labor intensiveness and time of measurements.

A needle assembly for a stitching machine comprises a stitching jig comprising a needle holder, a needle clamp hoop and a fixing jig. The needle holder has needle sockets to hold a plurality of needles. The needle clamp hoop is connected to the needle holder to retain needles in the sockets. The fixing jig is connected to the needle clamp hoop to couple with a reciprocating bar of the stitching machine. A method for manufacturing an article of footwear upper comprises laying out a first sheet of material; positioning a second sheet of material to overlap with the first sheet of material at an overlap; positioning a felt material adjacent the overlap so that the second sheet of material is between the first sheet of material and the felt material; and felting the felt material to draw fibers of the felt material through the first and second sheets of material.

Systems and methods are provided for collecting three-dimensional surface data of a lasted shoe upper that is mated with a sole that is configured for the lasted upper. The mated three-dimensional data is used with three-dimensional data of the lasted shoe upper in an unmated configuration with the sole to determine a location of an edge defined by the intersection of the lasted upper and the sole when mated. The bite line identifies an edge where the upper and a sole assembly will intersect on a finished shoe, which may represent a bounding line for application of adhesive to the lasted upper for boding the sole thereto.

A shoe upper pad printing and moulding system includes a pad printing machine, an imprint device and a turntable. The turntable is provided with a plurality of positioning portions. With the pad printing machine arranged beside the turntable, and the turntable serving to carry the object, it only needs to micro-adjust the processing positions of the pad printing machine and the imprint device before processing to align the pad printing position and the imprint position with the same parts of the positioning portions, the pad printing position and the imprint position can accurately fall in the same parts of the object during processing, so that the yield of finished products can be improved and labor and time costs can be reduced.

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.