A coating composition is provided comprising a hydrophilic characteristic-effecting material compound. The production of the hydrophilic characteristic-effecting material compound is effected by admixing of operative starting materials. The operative starting materials include a superwetter material and an adhesion promoting agent material. The hydrophilic characteristic-effecting material compound includes a superwetter material-derived coating composition material fraction and an adhesion promoting agent material-derived material fraction. The adhesion promoting agent material-derived coating composition material fraction is configured for interacting with a substrate such that, in response to, at least, contacting between the coating composition and the substrate, adhesion of an operative surface material to the substrate is effected.

A nano-composite material for coating glass, as well as methods of its manufacture and use, are disclosed. The composite may be composed of a first metal oxide bridging a silicone oil moiety and an anionic surfactant moiety, and a second metal oxide bound to the silicone oil moiety. The composite may be fabricated by heating a first metal oxide and a second metal oxide with silicone oil, followed by the addition of a mixture of the surfactant and an oxidizing solution. The composite may be mixed with a suitable solvent and applied to a hot glass sheet. A glass coated with such a composite may transmit visible light, absorb some ultraviolet light, and reflect some near infrared light. The optical characteristics of the coated glass may be used to reduce heat in a glass-enclosed area by reducing the amount of infrared and ultraviolet light transmitted through the glass.

A nano-composite material for coating glass, as well as methods of its manufacture and use, are disclosed. The composite may be composed of a first metal oxide bridging a silicone oil moiety and an anionic surfactant moiety, and a second metal oxide bound to the silicone oil moiety. The composite may be fabricated by heating a first metal oxide and a second metal oxide with silicone oil, followed by the addition of a mixture of the surfactant and an oxidizing solution. The composite may be mixed with a suitable solvent and applied to a hot glass sheet. A glass coated with such a composite may transmit visible light, absorb some ultraviolet light, and reflect some near infrared light. The optical characteristics of the coated glass may be used to reduce heat in a glass-enclosed area by reducing the amount of infrared and ultraviolet light transmitted through the glass.

A method includes applying a monolithic transparent substrate for separating a chamber cooled to a temperature of 0 to 4° C. from an ambient atmosphere, wherein a face of the monolithic transparent substrate in contact with the cooled air is provided with a low-emissivity layer, and another face of the monolithic transparent substrate in contact with the ambient atmosphere is provided with an anti-condensation layer

A method includes applying a monolithic transparent substrate for separating a chamber cooled to a temperature of 0 to 4° C. from an ambient atmosphere, wherein a face of the monolithic transparent substrate in contact with the cooled air is provided with a low-emissivity layer, and another face of the monolithic transparent substrate in contact with the ambient atmosphere is provided with an anti-condensation layer

The present invention provides compound of formulae (A1), (A2), (B1), (B2), (C1) and (C2) which can form a layer having water-repellency, oil-repellency and antifouling property as well as high friction durability:

##STR00001##

wherein each symbols are as defined in the specification.

The present invention provides compound of formulae (A1), (A2), (B1), (B2), (C1) and (C2) which can form a layer having water-repellency, oil-repellency and antifouling property as well as high friction durability:

##STR00001##

wherein each symbols are as defined in the specification.

Disclosed herein are a color coating composition for an LED lamp diffuser and a color-coated glass article using the same. The color coating composition is capable of increasing durability and a life of an LED lamp, satisfactorily maintaining an external appearance and a lighting quality thereof for a long time, and realizing various colors, by manufacturing a glass-made diffuser as a means for diffusing light of the LED lamp in a manner of coating the diffuser on various sheets of transparent or translucent glass such as tubes and bulbs so that the diffuser is not deformed and discolored due to light and heat, and has high strength and translucency.

Disclosed herein are a color coating composition for an LED lamp diffuser and a color-coated glass article using the same. The color coating composition is capable of increasing durability and a life of an LED lamp, satisfactorily maintaining an external appearance and a lighting quality thereof for a long time, and realizing various colors, by manufacturing a glass-made diffuser as a means for diffusing light of the LED lamp in a manner of coating the diffuser on various sheets of transparent or translucent glass such as tubes and bulbs so that the diffuser is not deformed and discolored due to light and heat, and has high strength and translucency.

Disclosed herein are delamination resistant glass pharmaceutical containers which may include an aluminosilicate glass having a Class HGA 1 hydrolytic resistance when tested according to ISO 720-1985 testing standard. The glass containers may also have a compressive stress layer with a depth of layer of greater than 25 μm. A surface compressive stress of the glass containers may be greater than or equal to 350 MPa. The delamination resistant glass pharmaceutical containers may be ion exchange strengthened and the ion exchange strengthening may include treating the delamination resistant glass pharmaceutical container in a molten salt bath for a time less than or equal to 5 hours at a temperature less than or equal to 450° C.