A web substrate having at least one embossed ply having a surface thereof is disclosed. The surface has surface area comprising at least about 0.2 percent line embossments and a ratio of line embossment area to dot embossment area greater than 1.5.

A web substrate having at least one embossed ply having a surface thereof is disclosed. The surface has surface area comprising at least about 0.2 percent line embossments and a ratio of line embossment area to dot embossment area greater than 1.5.

A web substrate having at least one embossed ply having a surface thereof is disclosed. The surface has surface area comprising at least about 0.2 percent line embossments and a ratio of line embossment area to dot embossment area greater than 1.5.

Provided is a build mat to which a 3D print sticks well and from which the 3D print is easily separated. The build mat provided by this invention comprises a substrate and a surface layer provided to the first face of the substrate. The build mat has a peel strength of 1.5 N/18 mm or greater and 10 N/18 mm or less, determined by peeling the mat from polylactic acid (PLA) placed on the surface layer; and it is constituted so that the surface layer remains on the PLA in the peel strength measurement.

Surface elements comprising a decorative upper layer and a supporting core are disclosed. In such surface elements the decorative upper layer can comprise a digitally applied wood grain pattern made up of at least four colors, said pattern being applied to an underlying white ground coating provided on said supporting core, said pattern comprising at least one of visually simulated knots, cracks, flaws and grain. In such surface elements the decorative upper layer can further comprise an at least partly translucent wear layer arranged over said pattern, said wear layer consisting of a cured substance comprising silicon oxide. In such surface elements the decorative upper layer can further be provided with a surface structure increasing the realism of said wood grain pattern, being directed in accordance with the direction of said pattern and being in the form of narrow elongated recesses simulating the pores of wood.

The embossing unit includes at least one embossing roller with a rotation axis and a substantially cylindrical surface with a plurality of embossing protuberances with linear extension; a pressure roller with a yielding surface; an embossing nip defined between the pressure roller and the embossing roller; a feed path of a web material extending through the embossing nip. Along the linear extension thereof the embossing protuberances have a variable inclination with respect to the rotation axis of the embossing roller and a variable cross section along the longitudinal extension of the embossing protuberances.

Low slough, high basis weight tissue webs and products are provided. The tissue webs generally have basis weights greater than about 16 grams per square meter (gsm), while maintaining less than about 4 mg of slough. All while yielding tissue products that are both thick and soft.

Processes for manufacturing surface elements are disclosed. The surface elements can comprise a decorative upper layer and a supporting core. Processes for manufacturing such surface elements can comprise obtaining a decor at least by digitization of a number of archetypes selected from woods and minerals by making a high resolution digital picture of said archetypes, storing said decor digitally, manufacturing a plurality of supporting cores, each being of rectangular shape and each having a size essentially equaling only one desired end user format and provided with an upper side and a lower side, editing said decor to fit said shape and size of each one of said plurality of supporting cores, and digitally applying different patterns on each of said plurality of supporting cores, wherein said patterns are selected and parted from said decor and said decor is used to control said digitally applying the different patterns.

Processes for manufacturing surface elements are provided. The surface elements can include a decorative upper layer and a supporting core. Processes for manufacturing such surface elements can comprise manufacturing a supporting core having a format essentially equaling the desired end user format and provided with an upper side and a lower side, providing a ground coating on the supporting core, and applying a digitally printed dcor comprising inks of at least four colors directly on top of the ground coating by means of an ink-jet type printer, said four colors comprising one or more colors different from cyan, magenta, yellow and black; said digitally printed dcor being one of wood or mineral, and providing and curing an at least partly translucent wear layer on the upper side of the supporting core.

Processes for manufacturing surface elements are provided. The surface elements can comprise a decorative upper layer and a supporting core. Processes for manufacturing such surface elements can comprise manufacturing a supporting core having an upper side, treating said upper side of said supporting core, including at least one of the steps of ground coating with a primer, sanding and providing said upper side with a surface structure, applying a digitally printed dcor comprising inks of at least four colors directly on top of the ground coating by an ink-jet type printer, said digitally printed decor being one of wood or mineral, and providing and curing a protecting and at least partly translucent wear layer on the upper side of the supporting core.