An automated in-mold label handling and product unloading device for use with a plastic material injection molding machine includes a label handling arm provided with a label holder at an outer end thereof, and a product unloading arm provided with a product gripper at an outer end thereof. The device has a stationary frame and a first linear guide device that supports the label handling arm so as to reciprocate along a y-axis direction. The device has a second linear guide device that supports the product unloading arm so as to reciprocate along a y-axis direction. The first and second linear guide devices are guided relative to the frame to be movable parallel to the x-axis. A label handling arm x-axis drive mechanism has a first drive motor mounted on the frame and a first transmission coupled to said first drive motor and to the first linear guide device.

A method of fabricating a decorated molding article includes forming an all-in-one coating on a substrate and performing a curing step, thereby forming a composite layer structure with a protective effect, a color effect, and a bonding effect. The composite layer structure may form a molded film with better physical properties (e.g., higher hardness, better protection effect, and the like) after the blister molding process. Therefore, the molded film of the embodiments may be applied to a laser engraving process to form a variety of light-transmitting decorated molding articles.

A method and a device (20) for decorating an injection-molded part (40), and an injection-molded part (40). The method for decorating an injection-molded part (40) includes the following steps, which are in particular carried out in the following order: a) providing a transfer film in the form of a roll (10) b) cutting the transfer film to size to form at least one label (30, 11) c) laying the at least one label (30) in an injection-molding apparatus (21) by means of a robot arm (24, 12) d) closing the injection-molding apparatus (21, 13) e) back-injection molding the at least one label (30) by means of an injection-molding compound (14) f) opening the injection-molding apparatus (21) and removing the injection-molded part (40, 15).

A method of making an iridescent badge that includes: embossing a diffraction grating into a polymeric film to form a diffraction film; positioning the diffraction film in a mold; and injecting a translucent polymeric material into the mold over the diffraction film to form a vehicular badge. Further, the diffraction grating has a thickness from 250 nm to 1000 nm and a period from 50 nm to 5 microns. Another method of making an iridescent badge includes: heating a diffraction film positioned in a mold; applying a vacuum to form the film against a mold surface; and injecting a translucent polymeric material over the mold surface to form a vehicular badge. Further, the diffraction film comprises a polymeric material and a diffraction grating having a thickness from 250 nm to 1000 nm and a period from 50 nm to 5 microns.

The present invention provides a multilayer label having good gas barrier properties and is capable of maintaining the gas barrier properties at a high level even when exposed to physical stresses such as deformation and impart. The present invention relates to a multilayer label for in-mold labeling. This multilayer label includes a base (X), a layer (Z) containing an aluminum atom, and a layer (Y) containing a polymer (A) having a functional group containing a phosphorus atom.

A functional component having a button function includes a support component, a film, and an electrical switching element. The support component has a recess. The film covers the recess. The electrical switching element is situated below the recess and is actuatable by pressure being exerted on the film in the area above the recess. A ring-shaped or hollow cylindrical body is situated along an inner edge surface of the recess and is in contact with the film.

Methods for producing a dispenser for dispensable products are disclosed. The method includes attaching a label to the front plate of the dispenser by an in-mold process. The label has a label height (H2) that is less than the front plate height (H1) and label width (W2) that is less than the front plate width (W1) such that a border is formed around at least a portion of the label in the front plate. The front plate can be formed from a transparent material while the label is formed from an opaque material.

A functional component having a button function includes a support component, a film, and an electrical switching element. The support component has a recess. The film covers the recess. The electrical switching element is situated below the recess and is actuatable by pressure being exerted on the film in the area above the recess. A ring-shaped or hollow cylindrical body is situated along an inner edge surface of the recess and is in contact with the film.

A molded article comprising a container top is disclosed. The molded article includes a threadless frame defining an opening, a flip cap located substantially coplanar with, and integrally formed with, the frame, a compound hinge between the frame and the flip cap, the hinge allowing the flip cap to rotate about the hinge to rest on top of the frame, an in-mold lidding film having a perimeter molded to the frame such that the in-mold lidding film covers the opening defined by the frame, wherein the in-mold lidding film is removable from the frame, and a pull tab, formed from the in-mold lidding film, that extends past the opening defined by the frame.

The present invention achieves cost reduction by simplifying the manufacturing process for a film-formed molded product provided with a metal coating film capable of transmitting electromagnetic waves therethrough. This method for manufacturing a film-formed molded product which includes a molded product and a metal coating film covering the molded product comprises: forming the molded product between a movable mold and a fixed mold; and then forming the metal coating film which covers the molded product by a film-forming part of a second mold without taking the molded product out from between the movable mold and the fixed mold. The metal coating film is capable of transmitting electromagnetic waves therethrough as a result of generation of cracks after being formed.