An automated system and method wrap the fastening ties around the body of a continuous stream of facemasks in a facemask production line. The facemasks are oriented such that each facemask has a leading pair of ties and a trailing pair of ties extending from a body in a conveying direction of the production line. At a wrapping station in the production line, the body is subsequently clamped with a clamping device of an automated robotic arm. The robotic arm is driven in the conveying direction while rotating the clamping device and body relative to a rotation axis through the body to cause the leading and trailing pairs of ties to wrap around the body. The robotic arm then deposits the facemask with wrapped ties onto the conveyor.

A ghillie suit manufacturing apparatus includes: a camouflage yarn feeding unit adapted to continuously feed camouflage yarns having different colors required for camouflage by a given distance from the left side to the right side and from the right side to the left side; a knotting unit adapted to tie the camouflage yarns fed from the camouflage yarn feeding unit on both side end portions of the camouflage yarns to form knots on both left and right sides of the camouflage yarns, while having given distances between the knots; and a cutting unit adapted to cut given portions of the camouflage yarns located between the knots formed on both left and right sides of the camouflage yarns by means of the knotting unit.

A ghillie suit manufacturing apparatus includes: a camouflage yarn feeding unit adapted to continuously feed camouflage yarns having different colors required for camouflage by a given distance from the left side to the right side and from the right side to the left side; a knotting unit adapted to tie the camouflage yarns fed from the camouflage yarn feeding unit on both side end portions of the camouflage yarns to form knots on both left and right sides of the camouflage yarns, while having given distances between the knots; and a cutting unit adapted to cut given portions of the camouflage yarns located between the knots formed on both left and right sides of the camouflage yarns by means of the knotting unit.

A system allows a user to select designs for apparel and preview these designs before manufacture. The previews provide photorealistic visualizations in two or three dimensions, and can be presented on a computer display, projected on a screen, or presented in virtual reality (e.g., via headset), or augmented reality. The system can also include a projection system that projects the new designs onto garments on mannequins in a showroom. The garments and the new designs projected onto the garments have a three-dimensional appearance as if the garments having the new designs are worn by people. Software and lasers are used in finishing the garments to produce garments with the new designs and the finished garments have an appearance of the three-dimensional appearance of the garments and new designs on the mannequins with the new designs projected onto the garments by the projection system.

A system allows a user to select designs for apparel and preview these designs before manufacture. The previews provide photorealistic visualizations in two or three dimensions, and can be presented on a computer display, projected on a screen, or presented in virtual reality (e.g., via headset), or augmented reality. The system can also include a projection system that projects the new designs onto garments on mannequins in a showroom. The garments and the new designs projected onto the garments have a three-dimensional appearance as if the garments having the new designs are worn by people. Software and lasers are used in finishing the garments to produce garments with the new designs and the finished garments have an appearance of the three-dimensional appearance of the garments and new designs on the mannequins with the new designs projected onto the garments by the projection system.

A labor protection glove includes a glove body including a glove liner and a back rubber protection layer disposed on a surface of a back of the glove liner. The glove liner includes a skin contact layer, a moisture absorption layer disposed outside the skin contact layer and a wear-resistant layer disposed outside the moisture absorption layer. The back rubber protection layer includes a finger rubber layer disposed at a back of a finger of the glove, a palm-back rubber layer disposed at a back of a palm of the glove body, and a root knuckle rubber layer disposed between the finger rubber layer and the palm-back rubber layer for protecting a knuckle. The finger rubber layer and the root knuckle rubber layer are independently formed by injection molding.

A labor protection glove includes a glove body including a glove liner and a back rubber protection layer disposed on a surface of a back of the glove liner. The glove liner includes a skin contact layer, a moisture absorption layer disposed outside the skin contact layer and a wear-resistant layer disposed outside the moisture absorption layer. The back rubber protection layer includes a finger rubber layer disposed at a back of a finger of the glove, a palm-back rubber layer disposed at a back of a palm of the glove body, and a root knuckle rubber layer disposed between the finger rubber layer and the palm-back rubber layer for protecting a knuckle. The finger rubber layer and the root knuckle rubber layer are independently formed by injection molding.

Due to rapid advancement in computing technology of both hardware and software, the labor intensive sewing process has been transformed into a technology-intensive automated process. During an automated process, product materials may become wrinkled or folded, which can slow down the automated process or result in human intervention. Various examples are provided related to the automation of sewing robots, and removal of wrinkles from products. Images of material on a work table can be captured and analyzed to determine if there are wrinkles or folds in the product. The robot can remove the wrinkle or fold by manipulating the material through the use of end effectors such as, e.g., budgers.

Laser finishing of apparel products allows an operating model that reduces finishing cost, lowers carrying costs, increases productivity, shortens time to market, be more reactive to trends, reduce product constraints, reduces lost sales and dilution, and more. Improved aspects include design, development, planning, merchandising, selling, making, and delivering. The model uses fabric templates, each of which can be used to produce a multitude of laser finishes. Operational efficiency is improved.