The present disclosure illustrates a manufacturing method of a vamp with an embossed pattern comprising: (1) providing a plain cloth. (2) heating the plain cloth by an oven to soften the plain cloth. (3) cooling the plain cloth and forming an embossed pattern on the plain cloth by a cold pressing roller, and the cold pressing roller provided with a predetermined pattern. (4) forming an embossed layer with the embossed pattern on the plain cloth. Because of the cold pressing roller, a depth of the cooled embossed layer is the same as a depth of the predetermined pattern. Hence, the embossed pattern can maintain its appearance.

A weighted and holographic plastic spinner blade comprises a plastic elliptical-shaped spinner blade having a body formed in plastic injection molding and, integral to the body, a printed label on a first side of body and a weight at an aft end of body. An ink or foil is hot stamped at a second side of the body to create a holographic image that is visible through the body and printed label, forming visual fish attractant properties. Method of manufacture includes: providing an elliptical-shaped mold; positioning a partially transparent printed label on a first side of mold; positioning a weight member in an aft end of the mold; injecting a polymer composition into the mold to form body; hot stamping foil on second side of the body, the ink or foil forming a holographic image; the holographic image visible through the at least partially transparent printed label and body.

A method for printing on a multi-dimensional object may include creating a customized object holder for the multi-dimensional object by heating a thermoforming sheet to a thermoforming temperature, molding the heated thermoforming sheet around at least a portion of a multi-dimensional object to form a holding portion for the multi-dimensional object, creating one or more printable areas on the molded thermoforming sheet, and applying one or more datum points on the molded thermoformed sheet. The one or more datum points may be configured to provide information relating to position of the one or more printable areas to a print system.

A process is disclosed to encapsulate the exterior surface of a metal drinking cup or other similar heat resistant container with plastic material such as polybutylene terephthalate in an injection molding process. A fixture holds a metal container in place and is inserted within a mold. Plastic material is then injected into the mold and surrounds the exterior surface of the container and allowed to cool. The container includes various physical features on its exterior to prevent the slipping of the plastic material off of the cup after cooling. Using an injection molding process to surround and encapsulate the exterior surface of a metal container with plastic results in a thicker surface over the container, and creates an ideal platform for receiving high resolution images and designs for impregnation using a further dye sublimation process.

Techniques for integrating a machine-readable matrix with a component of a mechanical structure using three-dimensional (3-D) printing are disclosed. Such techniques include generating at least one data model representing the component, and projecting a matrix pattern identifying one or more features of the component onto a selected surface portion of the component to produce a modified data model for use as an input to a 3-D printer.

Plastic flooring having registration system contains: an electronic control unit electrically connected with roller equipment and the registration system, the roller equipment is configured to deliver a substrate, a printing layer, and an abrasion resistance layer toward a rolling device. The rolling device includes a fourth roller set having pressing patterns identical to surface patterns of the printing layer, and the registration system has a first sensor, a tension regulator, and a second sensor. The first sensor is disposed on a delivery path of the printing layer which corresponds to the first sensor and has multiple positioning points. A length between a first positioning point and a second positioning point depends on a perimeter of the fourth roller set so as to form a print unit, and the first sensor is configured to sense the multiple positioning points and to transmit sensed signals to the electronic control unit.

A method for printing on a multi-dimensional object may include creating a customized object holder for the multi-dimensional object via thermoforming. The customized object holder includes at least one datum point for providing registration information corresponding to one or more printable areas of the multi-dimensional object. The method may then include mounting the multi-dimensional object on the customized object holder, attaching the customized object holder to a moving sled of a print system, and controlling the movement of the moving sled relative to a plurality of print heads, and operating the plurality of print heads to eject marking material onto the multi-dimensional object. The movement of the moving sled may be controlled by determining a position of at least one printable area on the multi-dimensional object, and using the determined position to control the movement of the moving sled relative to the plurality of print heads.

The present disclosure is directed to a system for vacuum forming a component. The system includes a base and a plurality of mold segments positioned on the base. The plurality of mold segments are removably coupled together to define a mold cavity configured for forming the component. The base and one or more of the plurality of the mold segments collectively define a corresponding vacuum chamber of a plurality of vacuum chambers of the system. At least one of vacuum chambers is fluidly isolated from the other vacuum chambers. One or more of the plurality of the mold segments further define a plurality of vacuum passages fluidly coupling the mold cavity and the corresponding vacuum chamber.

A multi-component synthetic closure and/or a rod-shaped intermediate product which incorporate printed indicia comprising ink that is invisible under normal lighting and/or temperature conditions and a continuous, in-line manufacturing process therefor are described. In the preferred embodiment of the present disclosure, the core member of the synthetic closure and/or the rod-shaped intermediate product can be formed by a continuous extrusion process which enables the core to be manufactured as an elongated, continuous length of material. As the continuous elongated length of extruded material forming the central core is advanced from the extruder towards an outer skin forming station, the central core passes through a printing station for forming any desired indicia among which can be a registration mark that can be invisible under normal lighting and/or temperature conditions on the outer surface of the central core prior to the application of the outer skin layer.

A weighted and holographic plastic spinner blade comprises a plastic elliptical-shaped spinner blade having a body formed in plastic injection molding and, integral to the body, a printed label on a first side of body and a weight at an aft end of body. An ink or foil is hot stamped at a second side of the body to create a holographic image that is visible through the body and printed label, forming visual fish attractant properties. Method of manufacture includes: providing an elliptical-shaped mold; positioning a partially transparent printed label on a first side of mold; positioning a weight member in an aft end of the mold; injecting a polymer composition into the mold to form body; hot stamping foil on second side of the body, the ink or foil forming a holographic image; the holographic image visible through the at least partially transparent printed label and body.