A decorative member includes: a transparent resin layer provided on a rear surface thereof with a general portion, a stepped portion recessed or protrudingly provided with respect to the general portion, and an inclination portion provided between the stepped portion and the general portion; and a decorative layer provided on the rear surface, wherein: an inclination angle of the inclination portion with respect to a normal line of the general portion is equal to or more than 25° and is equal to or less than 40°; a width of the inclination portion is large beyond 0.38 mm and is equal to or less than 1 mm; and the decorative layer includes: a first layer that covers the stepped portion of the rear surface; and a second layer that covers a part of the rear surface, which is not covered by at least the first layer.

A panel for a flexible package (100), and a method and system for forming the panel is provided. The panel comprises a first laminate having an open-area; a second laminate extending from a top edge to a bottom edge; and a third laminate, the third laminate sealed with the first laminate to cover the open-area, and the top edge and the bottom edge of the second laminate sealed between the first laminate and the third laminate such that area between the top edge and the bottom edge of the second laminate remains free forming a loop with the panel. The panel preferably forms a side-gusset (102) of a flexible packaging pouch, wherein the loop can be used as a handle (110) to carry the flexible package.

A thermal transfer apparatus includes a controller to control a transfer tool and a pressing body conveyor. The controller controls the pressing body conveyor to press a predetermined region of a transfer object, and controls the transfer tool and the pressing body conveyor to press at least a portion of thermal transfer foil placed on the predetermined region pressed by the transfer tool and a light absorption film having a light absorption property and placed on the thermal transfer foil and to apply light to the light absorption film.

A method of manufacturing a display device includes attaching a protective film onto a display panel that includes a display area and a pad area, where the protective film includes an adhesive layer and a protective layer disposed on the adhesive layer, half-cutting the protective film along a cutting line between the display area and the pad area such that a total thickness of the protective layer and a partial thickness of the adhesive layer are cut, irradiating a partially cut portion of the adhesive layer with a laser beam along at least a portion of the cutting line, and detaching a portion of the protective film that corresponds to the pad area along the cutting line.

An adhesive composition for use in debonding with light irradiation, which composition can achieve debonding through irradiation with light, wherein the adhesive composition contains an adhesive component and carbon black, and the adhesive component contains a component (A) which is cured through hydrosilylation.

A method for producing a laminated core is provided in which a plurality of lamination sheets is partially or completely separated from a strip made of a soft magnetic alloy by laser sublimation cutting, the lamination sheets each having a main surface and a thickness d. The main surface of a first of the lamination sheets is stacked on the main surface of a second of the lamination sheets in a direction of stacking and the main surfaces of the first and the second lamination sheets are substance-to-substance joined at a plurality of points by laser welding, a plurality of filler-free joints being formed between the between the first and the second lamination sheets and being entirely surrounded by the main surfaces of the first and the second lamination sheets.

Method for producing a packaging film strip for providing a number of individual packaging film parts for packing food or beverages, wherein the packaging film contains for each designated individual packaging film part an area having a printed two-dimensional code as unique packaging or product identifier. The process comprises the steps of providing at least one first substrate film strip (10, 25), applying on one side of said at least one first substrate film strip (10, 25) an artwork printing (20) for each individual packaging film part, depositing a DFC ink area (28) for each individual packaging film part onto the surface of the substrate film strip (10, 12) lying opposite to the artwork printing (20), slitting the packaging film to provide a series of individual packaging film parts running along the longside of the packaging film, ablating the individual DFC ink areas (28) by a computer-controlled laser beam (8) for providing a predetermined and individual code (2, 3, 30) as unique packaging or product identifier, cleaning the surface of the film strip comprising the individual codes (2, 3, 30), and checking the quality of the codes (2, 3, 30).

A composite workpiece having at least one metallic cover layer and a non-metallic core layer is disclosed. The metallic cover layer and the non-metallic core layer are connected to one another, with one lying on top of the other. The metallic cover layer, in a marking region on a side facing toward the non-metallic core layer, includes a profile, in particular a surface profile, for marking the composite workpiece.

An electrical connection between the backplane and the light-transmissive front electrode of an electrowetting device is provided by forming an aperture through the top front electrode coupled and a substrate coupled thereto and subsequently introducing a flowable, electrically-conductive material into the aperture. The flowable, electrically-conductive material provides an electrical contact between the light-transmissive electrically-conductive layer and the backplane.

An object of the present invention is to provide a thin volume hologram sheet to be embedded sufficiently resistant to a mechanical stress such as a stress including a tensile stress, a shear stress and a compression stress at the time of processing even under a heating condition, a forgery prevention paper and a card using the same. The object is achieved by providing a volume hologram sheet to be embedded comprising a volume hologram layer, and a substrate disposed only on one side surface of the volume hologram layer using an adhesion means, wherein a peeling strength of the volume hologram layer and the substrate is 25 gf/25 mm or more.