A spinning nozzle which has a perforated part in which ejection holes have been arranged in a density as high as 600-1,200 holes/mm.sup.2. This process for producing a fibrous bundle comprises ejecting a spinning dope having a viscosity as measured at 50° C. of 30-200 P from the ejection holes of the spinning nozzle to produce a fibrous bundle. This fibrous bundle has a single-fiber fineness of 0.005-0.01 dtex. By the wet-process direct spinning, a mass of nanofibers which are stably uniform and continuous can be produced at a high efficiency.

A spinning nozzle which has a perforated part in which ejection holes have been arranged in a density as high as 600-1,200 holes/mm.sup.2. This process for producing a fibrous bundle comprises ejecting a spinning dope having a viscosity as measured at 50° C. of 30-200 P from the ejection holes of the spinning nozzle to produce a fibrous bundle. This fibrous bundle has a single-fiber fineness of 0.005-0.01 dtex. By the wet-process direct spinning, a mass of nanofibers which are stably uniform and continuous can be produced at a high efficiency.

A thermally conductive, electrical insulating paper having a thermal conductivity greater than 0.4 W/m-K is described. The thermally conductive, electrical insulating paper is a nonwoven paper that comprises aramid fibers, an aramid pulp, a binder material; and a synergistic blend of thermally conductive fillers, wherein the synergistic blend comprises a primary thermally conductive filler; and a secondary thermally conductive filler.

A thermally conductive, electrical insulating paper having a thermal conductivity greater than 0.4 W/m-K is described. The thermally conductive, electrical insulating paper is a nonwoven paper that comprises aramid fibers, an aramid pulp, a binder material; and a synergistic blend of thermally conductive fillers, wherein the synergistic blend comprises a primary thermally conductive filler; and a secondary thermally conductive filler.

A spinning nozzle which has a perforated part in which ejection holes have been arranged in a density as high as 600-1,200 holes/mm.sup.2. This process for producing a fibrous bundle comprises ejecting a spinning dope having a viscosity as measured at 50 C. of 30-200 P from the ejection holes of the spinning nozzle to produce a fibrous bundle. This fibrous bundle has a single-fiber fineness of 0.005-0.01 dtex. By the wet-process direct spinning, a mass of nanofibers which are stably uniform and continuous can be produced at a high efficiency.

A spinning nozzle which has a perforated part in which ejection holes have been arranged in a density as high as 600-1,200 holes/mm.sup.2. This process for producing a fibrous bundle comprises ejecting a spinning dope having a viscosity as measured at 50 C. of 30-200 P from the ejection holes of the spinning nozzle to produce a fibrous bundle. This fibrous bundle has a single-fiber fineness of 0.005-0.01 dtex. By the wet-process direct spinning, a mass of nanofibers which are stably uniform and continuous can be produced at a high efficiency.

The present invention provides conductive paper with excellent electrical conductivity, strength, and heat resistance, and a method for producing the same, the conductive paper including: a paper substrate containing at least a carbon fiber and a fibrillated fiber, and in which an amount of the fibrillated fiber is from 10 to 120% by mass with respect to the carbon fiber; and a cured product of a thermosetting resin at least partially impregnated into the paper substrate; and the method for producing conductive paper, the method including the steps of: preparing a slurry containing at least a carbon fiber and a fibrillated fiber, and in which an amount of the fibrillated fiber is from 10 to 120% by mass with respect to the carbon fiber; obtaining a paper substrate by subjecting the slurry to a papermaking process; impregnating the paper substrate with a thermosetting resin; and heating the paper substrate impregnated with the thermosetting resin to cure the thermosetting resin.

The present invention provides conductive paper with excellent electrical conductivity, strength, and heat resistance, and a method for producing the same, the conductive paper including: a paper substrate containing at least a carbon fiber and a fibrillated fiber, and in which an amount of the fibrillated fiber is from 10 to 120% by mass with respect to the carbon fiber; and a cured product of a thermosetting resin at least partially impregnated into the paper substrate; and the method for producing conductive paper, the method including the steps of: preparing a slurry containing at least a carbon fiber and a fibrillated fiber, and in which an amount of the fibrillated fiber is from 10 to 120% by mass with respect to the carbon fiber; obtaining a paper substrate by subjecting the slurry to a papermaking process; impregnating the paper substrate with a thermosetting resin; and heating the paper substrate impregnated with the thermosetting resin to cure the thermosetting resin.