Metalized materials are provided, in which the metalized materials include (i) a substrate comprising a nonwoven, a film, or a combination thereof; (ii) a metal coating layer (MCL); and (iii) a transparent coating layer (TCL); wherein the MCL is located directly or indirectly between the substrate and the TCL. Peelable metalized materials are also provided, in which the peelable metalized materials include a metalized material and a removable carrier layer located directly adjacent to the TCL. Methods for making peelable metalized materials and metalized materials are also provided.

A method for producing a cellulose product from a multi-layer cellulose blank structure, wherein the method comprises the steps; forming the multi-layer cellulose blank structure from at least a first layer of dry-formed cellulose fibres and a second layer of a cellulose fibre web structure, through arranging the at least first layer and second layer in a superimposed relationship to each other and in the superimposed relationship arranging the at least first layer and second layer in contact with each other; arranging the multi-layer cellulose blank structure in a forming mould; heating the multi-layer cellulose blank structure to a forming temperature in the range of 100 C. to 300 C., and forming the cellulose product from the multi-layer cellulose blank structure in the forming mould, by pressing the heated multi-layer cellulose blank structure with an isostatic forming pressure of at least 1 MPa, preferably 4-20 MPa, wherein the multi-layer cellulose blank structure is shaped into a two-dimensional or three-dimensional fibre composite structure having a single-layer configuration.

An optical-film wound body of a long-length optical film, formed by winding a substrate film/masking film stacked body with a length of 1,000 m or more, the substrate film/masking film stacked body being formed by stacking a substrate film and a masking film, wherein the masking film is formed of a material having a melting peak of 25 C. or higher and 70 C. or lower, and a peel strength of the substrate film with a polarizing plate at an inner wound portion and that at an outer wound portion satisfy a specific relationship; a method for storing the wound body; and a method for producing a substrate film/polarizing plate stacked body.

A plural preform assembly having nested preforms with an inner preform and an outer preform. The preforms are sealably joined together, defining a volume between the preforms. Propellant is disposed in the volume between the preforms. The preforms are later blow molded to provide a bag in bottle, bottle in bottle or similar container. The propellant charge is already present when blow molded, preventing the need for a later propellant filling step.

A plural preform assembly having nested preforms. The preforms are held together by an interference fit. The interference fit is provided by the friction between the preforms which occurs when the inner preform is inserted into the outer preform. At least one preform may have ribs extending radially towards the other preform. The ribs provided concentricity and interference to hold the preforms together during subsequent operations. The preforms may later be blow molded to provide a bag in bottle or similar container.

The present invention aims to provide an interlayer film for a laminated glass which is easily peelable without autohesion even after storage in a stacked state, and a laminated glass prepared using the interlayer film for a laminated glass. The present invention relates to an interlayer film for a laminated glass, having a large number of protrusions on at least one surface, the surface having an arrangement density of the protrusions of 3 protrusions/mm.sup.2 or more, and the protrusions having an area ratio of 15 to 75% to the surface.

Systems and methods for using a non-stick conductive material to automate tool touch-off in an additive manufacturing process are provided. A substrate comprises a first conductive layer, an intermediate binder layer, and a second non-stick conductive layer. The non-stick conductive layer may comprise perfluoroalkoxy alkanes and carbon nanotubes. An electrical connection may be made between the first conductive layer and the second non-stick conductive layer. When used with an additive manufacturing device, when the nozzle of the device contacts the substrate, a circuit may close resulting in a detectable voltage drop. When the voltage drop is detected, a reference point for the additive manufacturing device may be set.

A method for creating a transition from an edge of an add-on part mounted on the outer surface of a rotor blade, including the steps: delimiting an application area on the rotor blade surface and the add-on part to be covered by a sealant compound with a thin and smooth masking tape; dispensing of the sealant on the application area; distribution of the sealant; removing the masking tape; and smoothening of a sealant transition step with a flexible tool, is provided. A wind turbine rotor blade is also provided.

In one aspect, the present disclosure provides a polymer film with a low glass transition temperature. In an embodiment, when in contact with a metal substrate, the polymer film adheres to the metal substrate under heating and/or mechanical pressure. In an embodiment, the polymer film comprises a butadiene copolymer and a butylene polymer. In another aspect, the present disclosure further provides a method of masking a metal substrate using the polymer film. In yet another aspect, the present disclosure provides a method of chemically or electrochemically processing a metal substrate that is masked with the polymer film.

A method for repairing a leak caused by a hole (3) at the bottom of a container (I) with liquid contents (2), comprising a reversible sealing of the leak in which: a sealing mixture (5) is poured into the liquid contents in the vicinity of the hole, the sealing mixture (5) comprising a sealing product (7) and solid fillers (8) mixed into the sealing product (7), the sealing product (7) having a density greater than those of the liquid contents and the fillers, and the capability to solidify within the liquid contents (2), the sealing mixture (5) spreads over the bottom (4) of the container (I) and reaches the hole (3), fillers (8) filling the hole (3) and enabling the sealing product (7) to solidify over the hole, forming a peelable sealing layer that can then be removed after the container is emptied, before the leak is ultimately repaired.