The present invention is an electroconductive laminate characterized in that the hard coat layer is formed from a hard coating composition which contains (A) a phenolic novolac acrylate having two or more acrylate groups, (B) a bisphenol structure-containing diacrylate having 2 to 4 moles of alkylene oxide structure with two or three carbon atoms in each molecule, (C) a polyfunctional acrylate having three or more acrylate groups, and (D) a polyfunctional urethane acrylate having three or more acrylate groups and an ester structure.

A highly heat-resistance and flame-retardant polymer composite composition for cable covering includes a polyolefin-based resin composition, a calcium-based flame retardant, 1% to 10% by weight of a non-halogen-based flame retardant, and a crosslinking agent. The composition exhibits excellent flame retardancy and heat resistance, has excellent flexibility, oil resistance, and processability due to low hardness, and has particularly improved mechanical properties through a special combination of various organic and inorganic materials.

A highly heat-resistance and flame-retardant polymer composite composition for cable covering includes a polyolefin-based resin composition, a calcium-based flame retardant, 1% to 10% by weight of a non-halogen-based flame retardant, and a crosslinking agent. The composition exhibits excellent flame retardancy and heat resistance, has excellent flexibility, oil resistance, and processability due to low hardness, and has particularly improved mechanical properties through a special combination of various organic and inorganic materials.

The method according to the invention consists in that the carrier is covered with at least two varnished layers, the two layers being made of electron curable varnishes, which may contain an additive increasing adhesion between the layers, and if the layer which is applied first, counting from the side of the carrier, containing an interlayer adhesion increasing additive, is irradiated with an excimer lamp and then pre-polymerized by electron radiation or UV light, then after applying the second layer also containing an interlayer adhesion increasing additive, the combined layers are cured by electron radiation or UV light. On the other hand, if the layer applied first, counting from the carrier side, is only pre-polymerized by electron radiation or UV light, then after applying the second layer, which then contains an additive increasing adhesion between the layers, it is subjected to irradiation by an excimer lamp and then the combined layers are cured by electron radiation or UV light. As a result, it is possible to obtain a product whose layer refined with excimer lamp and the layer only cured with electron radiation or UV light, are bound together regardless of the order of their occurrence.

The method according to the invention consists in that the carrier is covered with at least two varnished layers, the two layers being made of electron curable varnishes, which may contain an additive increasing adhesion between the layers, and if the layer which is applied first, counting from the side of the carrier, containing an interlayer adhesion increasing additive, is irradiated with an excimer lamp and then pre-polymerized by electron radiation or UV light, then after applying the second layer also containing an interlayer adhesion increasing additive, the combined layers are cured by electron radiation or UV light. On the other hand, if the layer applied first, counting from the carrier side, is only pre-polymerized by electron radiation or UV light, then after applying the second layer, which then contains an additive increasing adhesion between the layers, it is subjected to irradiation by an excimer lamp and then the combined layers are cured by electron radiation or UV light. As a result, it is possible to obtain a product whose layer refined with excimer lamp and the layer only cured with electron radiation or UV light, are bound together regardless of the order of their occurrence.

A roll is made of a porous film in a belt-like shape, the porous film having a width of not smaller than 20 mm. In a case where a roughness along a width direction of an outermost surface of the roll is measured at 1 mm intervals across an entire width of the outermost surface, a difference between a maximum roughness value and a minimum roughness value in a distance of 20 mm in the width direction of the outermost surface is less than 25 m.

The present invention is directed at coatings for oven bake clay that when applied make the surface of the resulting object food safe. Among the many different possibilities contemplated, the coating may contain one or more food safe plastics that may be in particle form and may form suspensions or colloids when mixed with water, food safe oil or other food safe liquids to ease application. Among the many potential additional ingredients contemplated, the coating may contain one or more surfactants to improve the formation of a suspension or colloid or one or more food safe dyes so that the oven bake clay can be painted. Among the many methods of making the coating contemplated, the components may be mixed to form a suspension or colloid through one or more of agitation, stirring or sonication. It is further contemplated that the coating may be applied to an unbaked oven bake clay object and then baked or alternatively applied to a baked oven bake clay object and then re-baked.

The present invention is directed at coatings for oven bake clay that when applied make the surface of the resulting object food safe. Among the many different possibilities contemplated, the coating may contain one or more food safe plastics that may be in particle form and may form suspensions or colloids when mixed with water, food safe oil or other food safe liquids to ease application. Among the many potential additional ingredients contemplated, the coating may contain one or more surfactants to improve the formation of a suspension or colloid or one or more food safe dyes so that the oven bake clay can be painted. Among the many methods of making the coating contemplated, the components may be mixed to form a suspension or colloid through one or more of agitation, stirring or sonication. It is further contemplated that the coating may be applied to an unbaked oven bake clay object and then baked or alternatively applied to a baked oven bake clay object and then re-baked.

A composition for treating textile materials includes water, polyethylene, surfactant, preservative, and a mixture comprising sugar alcohol, hydrolyzed animal protein, and sarcosine compound. The composition can further include a fragrance. A textile material treated with the compositions described above can be a material selected from leather, nylon, or a mixture thereof. A method of preparing a composition for treating a textile material is also disclosed.

A composition for treating textile materials includes water, polyethylene, surfactant, preservative, and a mixture comprising sugar alcohol, hydrolyzed animal protein, and sarcosine compound. The composition can further include a fragrance. A textile material treated with the compositions described above can be a material selected from leather, nylon, or a mixture thereof. A method of preparing a composition for treating a textile material is also disclosed.