The invention relates to a metering device (100) for metering, in a manually-controlled manner, a light-curing material present in said metering device (100), the device comprising at least one reservoir (1) which can be deformed at least in some sections thereof and in which said light-curing material is contained, as well as a metering arrangement (3) for applying the light-curing material. The invention also relates to a kit and a method.

A method for cutting or otherwise removing material from an inorganic substrate (e.g., a substrate formed from a cementitious material, such as concrete, or stone, etc.) includes applying an aqueous solution that includes a hardener/densifier to the inorganic substrate and/or to a removal element (e.g., a saw blade, an abrasive wheel, a grinding disk, etc.), the inorganic substrate or material removed from the inorganic substrate as the removal element removes material from the inorganic substrate. A system for removing material from an inorganic substrate includes a removal element and an aqueous solution that includes a hardener/densifier.

A method for cutting or otherwise removing material from an inorganic substrate (e.g., a substrate formed from a cementitious material, such as concrete, or stone, etc.) includes applying an aqueous solution that includes a hardener/densifier to the inorganic substrate and/or to a removal element (e.g., a saw blade, an abrasive wheel, a grinding disk, etc.), the inorganic substrate or material removed from the inorganic substrate as the removal element removes material from the inorganic substrate. A system for removing material from an inorganic substrate includes a removal element and an aqueous solution that includes a hardener/densifier.

The present disclosure relates to a method of manufacturing an elastic laminate for an disposable absorbent hygiene product, said elastic laminate comprises at least a first continuous sheet and at least one elastic strand. Furthermore, it is disclosed an apparatus and a disposable absorbent hygiene product comprising an elastic laminate manufactured according to the method.

A device (4) for applying a viscous liquid, in particular an MFC dispersion, onto a moving substrate (52) comprises an inlet (72, 73a-73f) for the viscous liquid, a casting chamber (61a, 61b), a lower portion of which being open to the substrate (52), and a metering portion (69, 661), for limiting a thickness of a wet film that is formed on the substrate downstream of the device. The device further comprises a shear section (42) arranged inside the casting chamber (61a, 61b). The shear section (42) comprises a fluidization rod (68), arranged in the casting chamber (61a, 61b), for providing shearing of the viscous liquid inside the casting chamber (61a, 61b).

A device (4) for applying a viscous liquid, in particular an MFC dispersion, onto a moving substrate (52) comprises an inlet (72, 73a-73f) for the viscous liquid, a casting chamber (61a, 61b), a lower portion of which being open to the substrate (52), and a metering portion (69, 661), for limiting a thickness of a wet film that is formed on the substrate downstream of the device. The device further comprises a shear section (42) arranged inside the casting chamber (61a, 61b). The shear section (42) comprises a fluidization rod (68), arranged in the casting chamber (61a, 61b), for providing shearing of the viscous liquid inside the casting chamber (61a, 61b).

An object surface treatment system facilitates the treatment of articles of manufacture before they are printed. The system includes a chamber having walls and a lid configured to close the chamber, a flexible member mounted to the lid of the chamber, a vacuum source operatively connected to an interior volume of the chamber, and a plurality of actuators. A controller is configured to operate the actuators and vacuum source to move the applicator to apply a chemical to the flexible member, move the lid to close the chamber, produce a vacuum within the chamber and move a portion of the surface of the flexible member into engagement with a surface of an object within the chamber, cease operation of the vacuum source to enable the flexible member to return to a position adjacent the lid, and remove the lid from the chamber for removal of the object from the chamber.

An object surface treatment system facilitates the treatment of articles of manufacture before they are printed. The system includes a chamber having walls and a lid configured to close the chamber, a flexible member mounted to the lid of the chamber, a vacuum source operatively connected to an interior volume of the chamber, and a plurality of actuators. A controller is configured to operate the actuators and vacuum source to move the applicator to apply a chemical to the flexible member, move the lid to close the chamber, produce a vacuum within the chamber and move a portion of the surface of the flexible member into engagement with a surface of an object within the chamber, cease operation of the vacuum source to enable the flexible member to return to a position adjacent the lid, and remove the lid from the chamber for removal of the object from the chamber.

A thermoplastic prepreg includes a web or mesh of fibers in which the web or mesh of fibers includes chopped fibers. The thermoplastic prepreg also includes a thermoplastic material that fully impregnates the web or mesh of fibers so that the thermoplastic prepreg has a void content of less than 5%. The thermoplastic material is polymers that are formed by in-situ polymerization of monomers or oligomers in which greater than 90% of the monomers or oligomers react to form the thermoplastic material. The thermoplastic prepreg includes between 5 and 95 weight percent of the thermoplastic material and the chopped fibers that form the web or mesh of fibers are un-bonded.

A thermoplastic prepreg includes a web or mesh of fibers in which the web or mesh of fibers includes chopped fibers. The thermoplastic prepreg also includes a thermoplastic material that fully impregnates the web or mesh of fibers so that the thermoplastic prepreg has a void content of less than 5%. The thermoplastic material is polymers that are formed by in-situ polymerization of monomers or oligomers in which greater than 90% of the monomers or oligomers react to form the thermoplastic material. The thermoplastic prepreg includes between 5 and 95 weight percent of the thermoplastic material and the chopped fibers that form the web or mesh of fibers are un-bonded.