A system and method for production of a customizable food and beverage cooler are disclosed. In one embodiment of the system, a mold includes two primary halves configured to produce an injection molded part that is a component of the food and beverage cooler. An aperture intersects one of the primary halves of the mold to accommodate an insertion block that includes a reverse image thereon such that molten plastic flow around the reverse image produces an integrally molded image on the component of the food and beverage cooler. Further, the aperture accommodates a combination insertion block and insertion plate having the reverse image thereon. One of the insertion block or combination insertion block and insertion plate is selected for disposing in the aperture based on the desired production run of the injection molded part.

A one-piece component comprising a tetrahedral-octahedral honeycomb lattice is disclosed herein, along with a mold, a system and methods of making the component. A one-piece component comprising a truncated tetrahedral-octahedral honeycomb lattice also is disclosed, along with corresponding molds, systems and methods.

Method for producing a plastic molded part (1), wherein, in the method, a mold insert (3) with a diffractive surface relief (32) is provided, the mold insert (3) is inserted into one mold half of an injection mold (5) which, together with at least one further mold half, forms a cavity for producing the plastic molded part (1), wherein the mold insert (3) is inserted into the injection mold (5) such that the diffractive surface relief (32) forms a partial area of the surface of the cavity formed by the mold half (5), and the plastic molded part (1) is molded by injection molding by means of the injection mold (5). The invention furthermore relates to a mold insert as well as an injection mold for such a method, as well as a plastic molded part produced in this way.

The invention relates to a method for coding a dimensionally stable packaging container or an associated component made of a plastics-based and/or paper-based material composition, the packaging container being suitable for storing consumer goods such as food, washing agents, etc., wherein, during a shape-forming process for forming the three-dimensional packaging container or the associated component by means of a shaping tool mold, at least one outer and/or inner side undergoes, in at least one position, a shape-changing treatment acting on its first surface in order to produce at least one three-dimensional code.

In one or more embodiments, micro light guides are constructed that include a wall and one or more features extending from or protruding into one or more surfaces of the wall. The microstructure light guide is defined by a mold and formed as a single article with uniform internal stresses. In at least some embodiments, the mold that defines the microstructure light guide employs pixelated mold portions that enable selective temperature adjustment of discrete regions of the mold portions to form the microstructure light guide.

An optically readable code support to be associated with or be part of a capsule intended for delivering a beverage in a beverage producing device, the support including at least one sequence of symbols represented on the support so that each symbol is sequentially readable by a reading arrangement of an external reading device while the capsule is driven in rotation along an axis of rotation. The symbols are essentially formed of a succession of light reflective surface portions and light absorbing surface portions. The light absorbing surface portions provide a lower light-reflective intensity than the light-reflective surface portions, and the code support includes at least one base layer extending continuously at least along the sequence of symbols. The light-absorbing surface portions are roughened surface portions having a higher rugosity (Rz) than the light-reflective surface portions.

An embodiment relates to a vehicular lamp and a vehicle comprising the same, the vehicular lamp comprising: a lens portion; and a light source portion for emitting light toward the lens portion, wherein the lens portion comprises a body having least one curved surface and a film portion arranged on one side of the body so as to generate a 3D stereoscopic image using the light, and the lens portion is injected in an in-mold labelling (IML) type using a mold. Accordingly, the design-related degree of freedom can be improved, thereby providing an enhanced aesthetic appearance, and the manufacturing process can be simplified, thereby improving the productivity.

A purpose is to provide a resin encoder scale a cost of which can be reduced by making processing easy by producing the encoder scale as a resin molded piece including a scale pattern. A resin encoder scale is used in a reflection-type optical encoder and a scale pattern for position measurement is provided thereto. In the scale pattern, a low reflection part a surface of which is molded as a rough surface during resin molding and which has low reflectivity of light and a high reflection part a surface of which is molded as a mirror surface during the resin molding and which has higher reflectivity of light than the low reflection part are arranged alternately.

An uncoated lens with anti-reflective, non-fouling, and water-repelling characteristics comprises a lens body and nanosized structures. The lens body comprises a front surface and a rear surface. The front surface and the rear surface are opposite to each other. The nanosized structures are positioned on the front surface. The nanosized structures and the lens body are integrally formed by a molding process. The nanosized structures comprise a plurality of protrusions. A size of each protrusion is smaller than a wavelength of visible light.

A manufacturing method for a plastic-molded automotive interior trim component produces a curvilinear finished surface with a relatively flat portion and a relatively curved portion. A decorative film subcomponent is molded with a substantially smooth outer surface that is pigmented with a desired color of the finished surface. The decorative film subcomponent is placed into a mold having a film-receiving surface with a three-dimensional texture at both the relatively flat portion and the relatively curved portion. A structural backing member is in-mold laminated with the decorative film subcomponent by injecting molten plastic material against the inner surface of the decorative film subcomponent in the mold, wherein pressure of the molten plastic material expands the decorative film subcomponent to form an embossed pattern which is substantially uniform and undistorted covering at least part of the relatively flat portion and at least part of the relatively curved portion.