A formulation for forming an ink-receptive coating on a substrate includes more than 1 percent by weight (wt. %) of dry matter of a mesoporous material including particles of precipitated silica, wherein the mesoporous material is incorporated in the formulation in the form of a paste having a water content within a range of 60-95 wt. %, wherein the paste has been obtained by washing and dewatering of a slurry formed by mixing alkali silicate with a salt solution so that coagulation occurs.

Provided is a toilet paper roll of a longer product, having a pattern with excellent design visually observable, and little creases and crumples. The toilet paper roll is a roll of two-ply toilet paper with a roll diameter of 110 to 115 mm, the toilet paper having a paper thickness of 60 to 90 m per ply, wherein the toilet paper has a pattern printed by halftone printing and solid printing on one of its surfaces, the total area of the pattern accounts for 10 to 20%, the total area of halftone printed areas accounts for 7.5% or more, and the total area of solid printed areas accounts for 4.0% or less, of a surface of the toilet paper, and 65 to 90 m of the toilet paper has been rolled around a paper tube at a roll density of 0.83 to 2.05, with the one of its surfaces bearing the pattern positioned externally.

Provided is a toilet paper roll of a longer product, having a pattern with excellent design visually observable, and little creases and crumples. The toilet paper roll is a roll of two-ply toilet paper with a roll diameter of 110 to 115 mm, the toilet paper having a paper thickness of 60 to 90 m per ply, wherein the toilet paper has a pattern printed by halftone printing and solid printing on one of its surfaces, the total area of the pattern accounts for 10 to 20%, the total area of halftone printed areas accounts for 7.5% or more, and the total area of solid printed areas accounts for 4.0% or less, of a surface of the toilet paper, and 65 to 90 m of the toilet paper has been rolled around a paper tube at a roll density of 0.83 to 2.05, with the one of its surfaces bearing the pattern positioned externally.

The present invention relates to a cigarette butt wrapping paper which comprises: a body having a planar shape approximately similar to the shape of a cigarette pack; a flame-retardant coated surface which is formed on the inside of the body, has a transverse length approximately similar to the circumferential length of a cigarette butt, and is coated with a material having a heat resisting function; an adhesive applied surface onto which an adhesive has been applied, wherein the adhesive applied surface is an area surrounding the outer circumferential surface of the flame-retardant coated surface; and opening forming parts which are formed in such a manner that the opposite side ends of the lower end of the body are inwardly recessed and form an entrance, through which the cigarette butt can be input, when the opposite side ends are matched and boned to each other.

The present invention relates to a cigarette butt wrapping paper which comprises: a body having a planar shape approximately similar to the shape of a cigarette pack; a flame-retardant coated surface which is formed on the inside of the body, has a transverse length approximately similar to the circumferential length of a cigarette butt, and is coated with a material having a heat resisting function; an adhesive applied surface onto which an adhesive has been applied, wherein the adhesive applied surface is an area surrounding the outer circumferential surface of the flame-retardant coated surface; and opening forming parts which are formed in such a manner that the opposite side ends of the lower end of the body are inwardly recessed and form an entrance, through which the cigarette butt can be input, when the opposite side ends are matched and boned to each other.

The disclosure relates to a method for producing a decorative paper by a digital printing machine, wherein the method comprises the following steps: a. providing at least one base stock; b. printing a surface of the base stock with a primer, so as to result in a printed base stock; c. printing the surface of the printed base stock with at least one printing ink by means of the digital printing machine, wherein, at at least one location, the surface of the base stock is not printed with the primer or with the printing ink.

The disclosure relates to a method for producing a decorative paper by a digital printing machine, wherein the method comprises the following steps: a. providing at least one base stock; b. printing a surface of the base stock with a primer, so as to result in a printed base stock; c. printing the surface of the printed base stock with at least one printing ink by means of the digital printing machine, wherein, at at least one location, the surface of the base stock is not printed with the primer or with the printing ink.

A sensor, comprising including a composite substrate including a template material, where the template material includes a plurality of insulating fibers, and a plurality of carbon nanotubes bonded to the insulating fibers forming a nanotube coating on the insulating fibers, and where the composite substrate exhibits a tensional fracture induced by a unidirectional tensile force to the composite substrate, wherein the plurality of insulating fibers align along the tensile force and expand in an out-of-plane direction at the site of the fracture, a first electrode coupled to the nanotube coating on one side of the fracture, and a second electrode coupled to the nanotube coating on the opposite side of the fracture, such that an electrical signal applied between the first electrode and the second electrode passes through the plurality of junctions at the site of the fracture.

A sensor, comprising including a composite substrate including a template material, where the template material includes a plurality of insulating fibers, and a plurality of carbon nanotubes bonded to the insulating fibers forming a nanotube coating on the insulating fibers, and where the composite substrate exhibits a tensional fracture induced by a unidirectional tensile force to the composite substrate, wherein the plurality of insulating fibers align along the tensile force and expand in an out-of-plane direction at the site of the fracture, a first electrode coupled to the nanotube coating on one side of the fracture, and a second electrode coupled to the nanotube coating on the opposite side of the fracture, such that an electrical signal applied between the first electrode and the second electrode passes through the plurality of junctions at the site of the fracture.

There is provided a decorative sheet having high ink adhesion without using an oil-based ink having a high environmental load. The decorative sheet includes: a base paper; a thermoplastic resin layer provided on one surface side of the base paper; an ink layer provided on the thermoplastic resin layer of opposite to the base paper side and containing a water-based ink and at least one of a xylene diamine-based curing agent, a polycarbodiimide-based curing agent, and an aziridine-based curing agent as a curing agent; and a surface protective layer provided on the opposite surface side to the thermoplastic resin layer of the ink layer. The addition amount of the curing agent in the ink layer is preferably 1 part by mass or more and 30 parts by mass or less based on 100 parts by mass of the water-based ink.