A coating composition that is incorporated into a facemask to reduce fogging and glare is provided. For example, in one embodiment, the facemask contains a shield or visor formed from a transparent substrate having at least one surface applied with the coating composition of the present disclosure. The coating composition contains a large amount of nanoparticles, desirably greater than 10 wt %.

A coating composition that is incorporated into a facemask to reduce fogging and glare is provided. For example, in one embodiment, the facemask contains a shield or visor formed from a transparent substrate having at least one surface applied with the coating composition of the present disclosure. The coating composition contains a large amount of nanoparticles, desirably greater than 10 wt %.

The present invention provides a nano phosphatic hybrid geopolymeric corrosion resistant coating material. The tailored precursor of corrosion resistant coating material is obtained by a process involving, together dry grinding of raw materials fly ash, sodium hydroxide, rice husk, tri calcium phosphate and cetyl trimethyl ammonium bromide optionally with sodium silicate, in solid powder form. The developed coating material obtained by adding water to tailored precursor contains nano sized phosphatic compounds of Cancrisilite (sodium aluminium carbonate silicate hydrate), quartz, mullite, heamatite, sodium aluminium silicate, Herschelite (sodium aluminium silicate hydrate), Sucrose, α D-Glucose, Native cellulose, and phenol, responsible for providing improved corrosion resistant properties and adhesion to the mild steel substrates. The geo-polymeric coating material is used as an anti-corrosive, heat resistant coating material on various materials e.g. mild steel substrates.

The present invention provides a nano phosphatic hybrid geopolymeric corrosion resistant coating material. The tailored precursor of corrosion resistant coating material is obtained by a process involving, together dry grinding of raw materials fly ash, sodium hydroxide, rice husk, tri calcium phosphate and cetyl trimethyl ammonium bromide optionally with sodium silicate, in solid powder form. The developed coating material obtained by adding water to tailored precursor contains nano sized phosphatic compounds of Cancrisilite (sodium aluminium carbonate silicate hydrate), quartz, mullite, heamatite, sodium aluminium silicate, Herschelite (sodium aluminium silicate hydrate), Sucrose, α D-Glucose, Native cellulose, and phenol, responsible for providing improved corrosion resistant properties and adhesion to the mild steel substrates. The geo-polymeric coating material is used as an anti-corrosive, heat resistant coating material on various materials e.g. mild steel substrates.

The invention relates to a method for modifying nanofibrillar cellulose composition, comprising—preparing fibrous dispersion of ionically charged nanofibrillar cellulose (NFC), and—applying heat treatment at a temperature of at least 90° C. to the fibrous dispersion until the viscosity of NFC starts to decrease. The viscosity of the heat-treated NFC is reversible by applying shear forces to the NFC.

The invention relates to a method for modifying nanofibrillar cellulose composition, comprising—preparing fibrous dispersion of ionically charged nanofibrillar cellulose (NFC), and—applying heat treatment at a temperature of at least 90° C. to the fibrous dispersion until the viscosity of NFC starts to decrease. The viscosity of the heat-treated NFC is reversible by applying shear forces to the NFC.

The present invention is directed to a process for manufacturing a film or coating comprising high amounts of cellulosic nanomaterial. According to the present invention, a screen printing press, such as a rotary screen press, is used to create a film or coating comprising cellulosic nanomaterial. One benefit of the present process is that the suspension used in the printing process has a high dry content and high viscosity, thereby facilitating the process for manufacturing a film or coating comprising high amounts of cellulosic nanomaterial.

The present invention discloses a composition which uses bio-based, biodegradable film formers to provide a durable strippable coating. The coating includes a film former configured to form a continuous film on the substrate. The coating includes a solvent, wherein the solvent is configured to result an easy application of the substance on the substrate. The coating includes one or more additives. The one or more additives include a plasticizer to improve flexibility of the film. The one or more additives include a release agent configured to reduce adhesion of the coating on the substrate. The one or additives a thickener configured for adjusting a viscosity and of the coating.

The present invention discloses a composition which uses bio-based, biodegradable film formers to provide a durable strippable coating. The coating includes a film former configured to form a continuous film on the substrate. The coating includes a solvent, wherein the solvent is configured to result an easy application of the substance on the substrate. The coating includes one or more additives. The one or more additives include a plasticizer to improve flexibility of the film. The one or more additives include a release agent configured to reduce adhesion of the coating on the substrate. The one or additives a thickener configured for adjusting a viscosity and of the coating.

Suspensions can include a polar solvent, sulfonated polyester material dispersed in the polar solvent, and cellulose nanofibril material dispersed in the polar solvent. Suspensions disclosed and contemplated herein leverage polyester that can be used to independently control film formation and rheology. In some instances, polyesters used in suspensions disclosed herein can perform the role of two additives: aqueous thickener and film reinforcement