Abstract: A spinneret (1) for electrostatic spinning is configured from a structure of an electrically conductive metal material. The structure is provided with a long-axis direction (X), a short-axis direction (Z), and a thickness direction (Y). An inflow port (10) for a spinning starting material fluid is provided to one surface of the structure. A plurality of protrusions (5) are formed on another surface of the structure so as to be aligned along the long-axis direction (X). Each of the plurality of protrusion (5) extends so as to protrude from the structure. The protrusions (5) have, provided to apexes (2) thereof, discharge holes (4) for discharging the starting material fluid. The pitch of the discharge holes (4) exceeds 1 mm.

Abstract: A spinneret (1) for electrostatic spinning is configured from a structure of an electrically conductive metal material. The structure is provided with a long-axis direction (X), a short-axis direction (Z), and a thickness direction (Y). An inflow port (10) for a spinning starting material fluid is provided to one surface of the structure. A plurality of protrusions (5) are formed on another surface of the structure so as to be aligned along the long-axis direction (X). Each of the plurality of protrusion (5) extends so as to protrude from the structure. The protrusions (5) have, provided to apexes (2) thereof, discharge holes (4) for discharging the starting material fluid. The pitch of the discharge holes (4) exceeds 1 mm.

Abstract: A processing apparatus and a processing method capable of producing a point-through-air nonwoven fabric wherein hot air is allowed to penetrate through spots of a web or a sheet-like material and fibers at the penetration site are heat-bonded. The processing apparatus for hot-air treatment nonwoven fabric, includes: a rotating running endless belt with holes, a hot-air blowing apparatus which blows out hot air from an internal side of the endless belt with holes toward an outer side thereof, and an endless belt for fiber conveyance which is arranged on a side opposite to the hot-air blowing side of the hot-air blowing apparatus across the endless belt with holes and the endless belt for fiber conveyance rotates while the hot-air passes therethrough.

Abstract: A composite material as a sheet material is described, being relatively cheap, most useful as a raw material of a sanitary product or the like, such as underwear, dust-proof mask or dispensable paper diaper, etc., and good in processability, stretchability, gas-permeability, softness, and touch. The composite material is formed by laminating a stretchable layer and a conjugate spunbonded nonwoven fabric including conjugate fibers including a low-melting-point component and a high-melting-point component. The conjugate fibers are partially bonded to each other by thermocompression, wherein each bonded portion has fine folded structures including alternate hill and valley regions in the CD, and the distance between neighboring hills is 100-400 ?m in average. The conjugate spunbonded nonwoven fabric exhibits stretchability through the spread of the fine folded structures, and has, at 5% elongation, a CD-strength of 0.1 N/5 cm or less and an MD/CD strength ratio of 200 or more.

Abstract: A composite material as a sheet material is described, being relatively cheap, most useful as a raw material of a sanitary product or the like, such as underwear, dust-proof mask or dispensable paper diaper, etc., and good in processability, stretchability, gas-permeability, softness, and touch. The composite material is formed by laminating a stretchable layer and a conjugate spunbonded nonwoven fabric including conjugate fibers including a low-melting-point component and a high-melting-point component. The conjugate fibers are partially bonded to each other by thermocompression, wherein each bonded portion has fine folded structures including alternate hill and valley regions in the CD, and the distance between neighboring hills is 100-400 ?m in average. The conjugate spunbonded nonwoven fabric exhibits stretchability through the spread of the fine folded structures, and has, at 5% elongation, a CD-strength of 0.1 N/5 cm or less and an MD/CD strength ratio of 200 or more.

Abstract: The present invention provides a processing apparatus and a processing method capable of producing a point-through-air nonwoven fabric wherein hot air is allowed to penetrate through spots of a web or a sheet-like material and fibers at the penetration site are heat-bonded. Specifically, the present invention provides a processing apparatus for hot-air treatment nonwoven fabric, comprising: a rotating running endless belt with holes, a hot-air blowing apparatus which blows out hot air from an internal side of the endless belt with holes toward an outer side thereof, and an endless belt for fiber conveyance which is arranged on a side opposite to the hot-air blowing side of the hot-air blowing apparatus across the endless belt with holes and rotates with passing the hot-air therethrough.

Abstract: A composite spunbond nonwoven and a laminate using the same are provided. The composite spunbond nonwoven is formed of a composite fiber including a low melting point component and a high melting point component. The composite fiber is partially thermal compression bonded to each other, and thermal compression bonded portions have fine folded structures formed by repeating convex portions and concave portions in a CD (cross direction in nonwoven manufacturing). An average of distances between adjacent convex portions of the folded structures is in a range of 100 ?m-400 ?m. The composite spunbond nonwoven exhibits an elongation property by unfolding the fine folded structures. When the composite spunbond nonwoven is elongated by 5%, a CD strength is less than or equal to 0.1 N/5 cm width, and a MD/CD strength ratio is greater than or equal to 200. MD is longitudinal direction in nonwoven manufacturing.

Abstract: A continuous fiber nonwoven comprising composite continuous fibers having the spiral crimps obtained by compositely spinning two thermoplastic resins having the difference in the melting points of 15° C. or more is provided, and it is characterized in that the contact points of the fibers are adhered one another by fusing of the thermoplastic resin having a low melting point and located on the outside of the spiral crimps.

Abstract: A continuous fiber nonwoven comprising composite continuous fibers having the spiral crimps obtained by compositely spinning two thermoplastic resins having the difference in the melting points of 15° C. or more is provided, and it is characterized in that the contact points of the fibers are adhered one another by fusing of the thermoplastic resin having a low melting point and located on the outside of the spiral crimps.

Abstract: A compact in-line high-speed apparatus and method for producing thermoplastic synthetic fibers includes a melt spinning device with a spinning block and a tow drawer; wherein the spinning block has at least one extruder, at least one spinneret block, and heating devices, and the tow drawer draws fibers spun from the spinning block as a bundled tow. Also provided is a drawn tow accumulating device equipped with at least two tow feeding rolls and a tow accumulating conveyer, wherein the tow feeding rolls feed the tow obtained from the tow drawer onto the tow accumulating conveyer, and the tow accumulating conveyer accumulates the tow fed from the tow feeding rolls. A high-speed tow stretching device is used for stretching tie tow supplied from the drawn tow accumulating device at high stretching speed.

Abstract: A non-woven fabric composed of thermoplastic fiber comprising at least two resin components A and B and having a cross section where the component A forms a branching fiber in which a plurality of strands extend radially from the center to the outside and the component B forms a fine fiber which connects to and protrudes from the branching fiber; split branch fibers of the conjugated fiber; and split fibers of the fine fibers, and an absorbent article using the non-woven fabric. The non-woven fabric of the present invention has an excellent hand feeling and sufficient bulkiness, and it is suitable for absorbent articles such as disposable diapers, sanitary napkins, and pads for incontinence or the like.

Abstract: A laminated nonwoven fabric having a good texture, providing no rough touch, and having a high strength and a large delamination strength are provided. A nonwoven fabric of a multi-layer structure comprises (a) a composite spun bonded nonwoven fabric composed of a low melting point resin component and a high melting point resin component and (b) a composite melt blown extra-fine-fiber nonwoven fabric having a fiber diameter of 10 &mgr;m or less and being composed of a low melting point resin and a high melting point resin; both of the nonwoven fabrics are laminated, and the fibers in each of the nonwoven fabrics and both of the nonwoven fabrics are thermally fused. A method of manufacturing a nonwoven fabric having a multi-layer structure comprises laminating each of the nonwoven fabrics in a multi-layer structure and heating the laminate at a temperature higher than the thermal fusion temperature to cause thermal fusion of the both layers.

Abstract: A filament non-woven fabric comprising thermoplastic conjugated filaments comprising at least one low melting point resin or low softening point resin selected from the group consisting of olefin binary copolymer or olefin terpolymer as the first component and crystalline thermoplastic resin as the second component. The thermoplastic conjugated filament contains inorganic powder in at least the first component, wherein the content of the inorganic powder is 500 to 50000 weight ppm with respect to the fibers. The present invention can provide a filament non-woven fabric that is excellent in the high adhesive property, low temperature adhesive property, hand feeling such as softness or touch etc., and uniformity. Furthermore, operating efficiency such as the spinning property is good. Absorbent articles can be produced using the above mentioned filament non-woven fabrics.

Abstract: A bulky and highly strong filament nonwoven fabric and method of manufacturing the filament nonwoven fabric which is made of conjugated filaments, whose intersections are melted and adhered, and which has a 15-35 cc/g specific volume and satisfies the following Formula (1) between strength and specific volume;Y.gtoreq.-1.25X+125 (1)wherein Y is a geometrical mean of vertical and horizontal strength per 5 cm wide and 1 g/cm.sup.2 nonwoven fabric ?unit: g/(g/m.sup.2 .multidot.5 cm!; Y=(MD.times.CD).sup.1/2 where MD is vertical strength ?unit: g/(g/m.sup.2 .multidot.5 cm! and CD is horizontal strength ?unit: g/(g/m.sup.2 .multidot.5 cm!; and X=specific volume of a nonwoven fabric ?unit: cc/g!; and wherein the conjugated filament is made of a low melting point polymer and a high melting point polymer with a difference in melting points of at least 15.degree. C., and has the low melting point polymer on at least one section of a filament surface and has crimps.

Abstract: A cylindrically shaped product having superior filtrability, water-permability, etc., a process for producing the same in a good efficiency, and a filter and a draining material using the same are provided, the cylindrically shaped product obtained by winding multi-component, conjugate spun-bonded long fibers, consisting of at least two components of a lower melting resin component and a higher melting resin component, the melting temperature difference therebetween being 10.degree. C. or higher, and cylindrically shaped product having been hot-melt-adhered by the lower melting resin component.

Abstract: Disclosed is a laminated non-woven fabric of a multi-layer structure comprising a layer of a composite, spun bond non-woven fabric composed of long fibers containing a low melting point resin component and a high melting point resin component, and a layer of a non-woven fabric of melt-blow ultrafine mixed fibers comprising low melting point ultrafine fibers and high melting point ultrafine fibers both of the fibers have an average fiber diameter of 10 .mu.m or less, both of the layers are laminated, and fibers in each of the non-woven fabrics and both of the layers are heat-melt adhered with each other. The laminated non-woven fabric has a good hand feeling and a high peeling strength of adjacent layers, but has no rough feeling.

Abstract: A combined filament type, melt-blow spinneret device can correspond to various kinds of microfine, combined filaments, and includes a spinning-resin-feeding plate 2 having respective resin-introducing grooves 7a, 7b for introducing two kinds of spinning resins A and B; a distributing plate 3 having distributing grooves 9a, 9b for respectively distributing the spinning resins A, B fed from the resin-introducing grooves of the resin-feeding plate 2; a nozzle plate 5 having a cavity 22 for receiving a separating plate 4 therein and a plurality of holes formed in a bottom interior surface of a downwardly-extending portion of the nozzle plate 5; a separating plate 4 received in the cavity 22 and attached to the second major surface of the distributing plate 3, the separating plate 4 including separation grooves 17a, 17b engraved from a side portion to a bottom portion thereof facing a plurality of holes 14 of the nozzle plate 5, for introducing the different spinning resins into the plurality of holes; and a clear

Abstract: A spinneret device for side-by-side, conjugate melt-blow spinning can correspond to combinations of various heterogeneous polymers for conjugate spinning and is uniform in the conjugate state such as conjugate ratio between single fibers, the proportion of the peripheral percentage of both the components in the fiber cross-section, etc. and has fineness, a large nozzle plate width and a superior productivity. The device is composed mainly of a spinning resin-feeding plate; a distributing plate; a separating plate provided with confluent grooves of conjugate components engraved at the bottom part of the plate, corresponding in number to the spinning nozzles; a nozzle plate; and a plate for controlling the clearance for a gas. Even when the viscosity unevenness, spinning temperature unevenness, etc.

Abstract: A fiber bundle comprising a plurality of composite fibers spun out of a spinneret is blown against a working net conveyor by a drawing force of a high-speed air stream while the air stream is sucked and removed from below the net conveyor to deposit the fiber bundle on the net conveyor to form a web, and the web is then heat-treated to develop crimps and the fibers thermally adhere together at their points of contact, thereby obtaining a nonwoven fabric, wherein the air stream is blown against the web from below the net conveyor for a time before the heat-treatment, with an intensity sufficient to make the web to float in such a manner that the bottom face of the web rise above the net conveyor by 0.2 to 30 mm.

Abstract: A spinneret device for conjugate fibers of eccentric sheath-and-core type, capable of universally corresponding to various polymer-spinning conditions; affording a uniform eccentric extent of the core component; reducing the quality variation of single fibers and also that of fibers with lapse of time; being manufactured by easy works and economically are provided, which device includes cap 1; inlets of stocks 2, 2A; reservoirs 3, 3A; partitioner 4 separating 3 and 3A; filter 6; first distributing plate 7 provided with introducing holoes 8A, 8 for alternately distributing the stocks into front and rear distributing grooves 10A, 10; second distributing plate 9 on the back surface of which the grooves 10A, 10 being parallel, equally spaced and linear are engraved and on the ventral surface of which pressure-controlling holes 11A, 11 are bored; eccentricity-controlling plate 14 on the back surface of which grooves for eccentricity, 15 are engraved and the ventral surface (flat) of which introducing holes 16 for