WO2010058480A1 - Perforated spinneret and method for producing twist yarn by using perforated spinneret - Google Patents

Abstract

A perforated spinneret (1) characterized in that a plurality of spinning hole groups (31), each including a plurality of odd-shaped spinning holes (2) arranged at intervals along a virtual curve (30) such as an arc extending radially outward from the central part of the discharge front (11) of the spinneret while curving clockwise under a state where the discharge front (11) is viewed from the front, are formed in the discharge front (11), and the plurality of spinning hole groups (31) are arranged while spaced apart from each other in the circumferential direction of the spinneret. When this perforated spinneret is used, soft feeling is attained, and a multi-filament twist yarn having sufficient elasticity and a small variation in quality can be produced.

Description

Porous spinneret and method for producing twisted yarn using the porous spinneret

The present invention relates to a porous spinneret suitable for producing, for example, a multifilament twisted yarn and a method for producing a twisted yarn using the porous spinneret.

Multifilament twisted yarns made of synthetic fibers such as polyester are widely used as materials for fabrics and knitted fabrics, for example. Such a multifilament twisted yarn is obtained by discharging a synthetic resin such as polyester from a spinning hole of a spinneret in which a large number of spinning holes are dispersed on the front surface of the discharge, and performing melt spinning. It is manufactured by twisting a fiber bundle made of fibers.

By the way, as an arrangement mode of the spinning holes on the discharge front surface of the spinneret, a configuration in which the spinning holes are arranged so as to form a plurality of concentric rings centering on the center point of the discharge front surface is known. (See Patent Documents 1 and 2). Also known is a configuration in which spinning holes are arranged in a grid pattern on the discharge front of the spinneret (see Patent Document 2).
JP-A 64-45807 JP-A-7-126910

However, a multifilament twisted yarn manufactured by discharging a synthetic resin such as polyester from the spinning hole of the spinneret having the above-described conventional structure to melt spinning and twisting the obtained fiber bundle is used to knit, fabric When fabrics such as these are produced, there is a problem that the touch feeling is hard and a soft texture cannot be obtained sufficiently, and that stretchability cannot be obtained sufficiently. Furthermore, since the twisted form is difficult to stabilize, there is a problem that variations in quality are likely to occur.

The present invention has been made in view of such a technical background, and is capable of producing a multifilament twisted yarn that can sufficiently produce a soft texture, has sufficient stretchability, and has little variation in quality. It aims at providing the manufacturing method of a spinneret and twisted yarn.

In order to achieve the above object, the present invention provides the following means.

[1] A plurality of irregular shapes along an imaginary curve such as an arc extending in a clockwise direction from the central portion of the discharge front face in a radially outward direction when the discharge front face of the spinneret is viewed from the front A plurality of spinning hole groups in which a plurality of spinning holes are spaced apart from each other are formed on the discharge front surface, and the plurality of spinning hole groups are arranged apart from each other in the circumferential direction of the spinneret. Porous spinneret characterized by

[2] The perforated spinneret according to the preceding item 1, wherein the interval between the spinning holes adjacent to each other in the circumferential direction of the die is gradually increased toward the outer side in the radial direction.

[3] A plurality of irregularities along a virtual curve such as an arc extending in a counterclockwise direction while extending radially outward from the center of the discharge front face when the discharge front face of the spinneret is viewed from the front A plurality of spinning hole groups in which shaped spinning holes are spaced apart from each other are formed on the discharge front surface, and the plurality of spinning hole groups are spaced apart from each other in the circumferential direction of the spinneret. A porous spinneret characterized by that.

[4] The perforated spinneret according to item 3, wherein the interval between the spin holes adjacent to each other in the circumferential direction of the die is gradually increased toward the radially outer side.

[5] A multifilament twisted yarn by discharging S-twist to a fiber bundle composed of a plurality of discharged synthetic fibers, and a step of discharging the modified cross-section synthetic fiber from the spinning hole of the porous spinneret according to 1 or 2 above A method for producing a twisted yarn comprising the steps of:

[6] A step of discharging the modified cross-section synthetic fiber from the spinning hole of the porous spinneret according to the above item 3 or 4, and a multifilament twisted yarn by Z-twisting the fiber bundle composed of the plurality of discharged synthetic fibers A method for producing a twisted yarn comprising the steps of:

[7] A twisted yarn produced by the production method described in 5 or 6 above.

[8] A fabric manufactured using the twisted yarn described in item 7 above.

In the invention of [1], in a state where the discharge front surface of the spinneret is viewed from the front, along a virtual curve such as an arc extending in a clockwise direction from the central portion of the discharge front surface toward the radially outer side. A plurality of spinning hole groups in which a plurality of spinning holes are spaced apart from each other are formed on the discharge front surface, and the plurality of spinning hole groups are arranged apart from each other in the circumferential direction of the spinneret. If a fiber bundle discharged from the spinning hole of this porous spinneret is subjected to S twist to produce a multifilament twisted yarn, and a fabric such as a knitted fabric or a woven fabric is produced using this twisted yarn, a soft texture and sufficient elasticity In addition, there can be obtained a fabric having a good appearance quality with little variation in quality.

In the invention of [2], since the interval between the spinning holes adjacent in the circumferential direction is configured to gradually increase toward the radially outer side, the twisted form of the twisted yarn can be further stabilized. Thus, it is possible to provide a fabric with less variation in quality and better appearance quality.

In the invention of [3], in a state where the discharge front surface of the spinneret is viewed from the front, along a virtual curve such as an arc extending in a counterclockwise direction while extending radially outward from the central portion of the discharge front surface. A plurality of spinning hole groups each having a plurality of spinning holes arranged at intervals are formed on the discharge front surface, and the plurality of spinning hole groups are arranged apart from each other in the circumferential direction of the spinneret. If the fiber bundle discharged from the spinning hole of the perforated spinneret is Z-twisted to produce a multifilament twisted yarn and a fabric such as a knitted fabric or woven fabric is produced using this twisted yarn, A fabric having a texture and sufficient stretchability, and having a good appearance quality with little variation in quality can be obtained.

In the invention of [4], since the interval between the spinning holes adjacent in the circumferential direction is configured to gradually increase toward the radially outer side, the twisted form of the twisted yarn can be further stabilized. Thus, it is possible to provide a fabric with less variation in quality and better appearance quality.

[5] When the twisted yarn produced by the production method according to the invention of [6] is used, a fabric (knitted fabric, woven fabric, etc.) having a soft texture and sufficient stretchability and having a small quality variation and a good appearance quality Can be provided.

[7] If the twisted yarn of the invention of [7] is used, it becomes possible to provide a fabric (knitted fabric, woven fabric, etc.) having a soft texture and sufficient stretchability, and having little quality variation and good appearance quality.

[8] The fabric (knitted fabric, woven fabric, etc.) according to the invention of [8] has a soft texture and sufficient stretchability, and has little quality variation and good appearance quality.

(A) is a front view which shows the discharge front surface of the porous spinneret based on one Embodiment of this invention, (b) is the same front view which added the auxiliary line (imaginary line) for description. FIG. 2 is a cross-sectional view taken along line XX in FIG. Note that the cross-sectional view taken along the line YY in FIG. It is a schematic explanatory drawing of the manufacturing method of the twisted yarn using the porous spinneret of FIG. (A) is a front view which shows the discharge front of the porous spinneret based on other embodiment of this invention, (b) is the same front view which added the auxiliary line (imaginary line) for description. It is a schematic explanatory drawing of the manufacturing method of the twisted yarn using the porous spinneret of FIG. It is a figure which shows an example of the shape of a spinning hole. (A) is a front view showing the discharge front of the porous spinneret used in Comparative Example 1, and (b) is a front view showing the discharge front of the porous spinneret used in Comparative Example 2.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Porous spinneret 2 ... Spinning hole 11 ... Discharge front surface 30 ... Virtual curve 31A ... 1st spinning hole group 31B ... 2nd spinning hole group 31C ... 3rd spinning hole group 31D ... 4th spinning hole group 31E ... 5th spinning Hole group 31F ... Sixth spinning hole group 31G ... Seventh spinning hole group 31H ... Eighth spinning hole group 35 ... Twisted yarn (S twisted)
40 ... Virtual curve 41A ... First spinning hole group 41B ... Second spinning hole group 41C ... Third spinning hole group 41D ... Fourth spinning hole group 41E ... Fifth spinning hole group 41F ... Sixth spinning hole group 41G ... Seventh Spinning hole group 41H ... Eighth spinning hole group 45 ... Twisted yarn (Z twisted)

FIG. 1 shows an embodiment (first embodiment) of a porous spinneret (1) according to the present invention. In this perforated spinneret (1), when the substantially circular discharge front face (11) is viewed from the front, it is bent and extended clockwise from the center of the discharge front face (11) toward the outside in the radial direction. A group of spinning holes (31) in which six spinning holes (2) are arranged at intervals along a substantially semicircular arcuate virtual curve (30) (curved line shown in FIG. 1B). ) Are formed on the discharge front face (11) (eight groups), and the eight spinning hole groups (31A) (31B) (31C) (31D) (31E) (31F) (31G) (31H) ) Are arranged apart from each other in the circumferential direction of the discharge front face (11) of the spinneret. A total of 48 spinning holes (2) are formed in such an arrangement.

Further, as shown in FIG. 1, the innermost side (closest to the center position) of the first spinning hole group (31A) (2) and the innermost side of the second spinning hole group (31B). Spinning hole (2), innermost spinning hole (2) of third spinning hole group (31C), innermost spinning hole (2) of fourth spinning hole group (31D), fifth spinning hole The innermost spinning hole (2) of the group (31E), the innermost spinning hole (2) of the sixth spinning hole group (31F), and the innermost spinning hole (31G) of the seventh spinning hole group (31G). The spinning hole (2) on the innermost side of the spinning hole (2) and the eighth spinning hole group (31H) has a virtual circle (FIG. 1 (FIG. 1 In b), it is arranged so as to be placed on an arc line (virtual line) of a circle indicated by a one-dot chain line on the innermost side.

Similarly, the second spinning hole (2) from the innermost side of each spinning hole group (31A to H) is a virtual circle centering on the center position of the discharge front face (11) that is circular when viewed from the front. It arrange | positions so that it may mount on the circular arc line (virtual line) of (circle shown with the 2nd dashed-dotted line from the innermost side in FIG.1 (b)). Further, the third spinning hole (2) from the innermost side of each spinning hole group (31A to H) is also arranged in the same manner. Hereinafter, the fourth spinning hole (2) from the innermost side of each spinning hole group (31A to H), the fifth spinning hole (2) from the innermost side of each spinning hole group (31A to H), The outermost spinning holes (2) of the spinning hole groups (31A to 31H) are also arranged in the same manner (see FIG. 1 (b)).

In the first embodiment, the spinning hole that does not fall on the virtual curve (30) is not formed, that is, only the spinning hole (2) that falls on the virtual curve (30) is formed. Thus, it is preferable to employ a configuration in which the spinning holes that do not lie on the virtual curve (30) are not formed at all or are substantially not formed.

Further, as apparent from FIG. 1, the interval between the innermost spinning holes (2) adjacent in the circumferential direction <the interval between the second spinning holes (2) from the innermost side adjacent in the circumferential direction < Spacing between the third spinning holes (2) from the innermost side adjacent in the circumferential direction <Spacing between the fourth spinning holes (2) from the innermost side adjacent in the circumferential direction <Fastest adjacent in the circumferential direction They are arranged so that the relationship between the intervals between the fifth spinning holes (2) from the inner side <the interval between the outermost spinning holes (2) adjacent in the circumferential direction is established. In other words, the interval between the spinning holes adjacent to each other in the circumferential direction is configured to gradually increase gradually toward the radially outer side.

The shape (front view shape) of the spinning hole (2) on the discharge front surface (11) is a substantially cross-shaped irregular shape as shown in FIG. That is, the deformed shape of the discharge front surface (11) of the spinning hole (2) includes a substantially cross-shaped main hole portion (2a) and enormous hole portions formed at the tip portions of the main hole portion (2a) ( 2b) (2b) (2b) (2b) (see FIG. 6).

Further, in the state where the discharge front face (11) of the spinneret (1) is viewed from the front, the cross axis direction of the main hole portion (2a) of the spinning hole (2) is arranged to face at least two different directions. Has been. That is, as shown in FIG. 1, in this first embodiment, the cross axis direction of the main hole portion (2a) of the spinning hole (2) constituting the first spinning hole group (31A) and the second spinning hole The axial direction of the cross of the main hole portion (2a) of the spinning hole (2) constituting the group (31B) is different. The main hole portion (2) of the spinning holes (2) constituting the first spinning hole group (31A), the third spinning hole group (31C), the fifth spinning hole group (31E), and the seventh spinning hole group (31G) ( The cross axis directions of 2a) are all the same. The main hole portion (2) of the spinning holes (2) constituting the second spinning hole group (31B), the fourth spinning hole group (31D), the sixth spinning hole group (31F), and the eighth spinning hole group (31H) ( The cross axis directions of 2a) are all the same.

Further, as shown in FIG. 2, the spinning hole (2) formed in the perforated spinneret (1) is located from the discharge rear surface side to the discharge front surface side in the region on the discharge front surface (11) side of the base (1). The diameter is reduced.

Next, a method for producing a twisted yarn using the above-structured porous spinneret (1) will be described. As shown in FIG. 3, the synthetic resin is supplied to the porous spinneret (1) to discharge the modified cross-section synthetic fiber from the spinning hole (2) of the porous spinneret (1). A multifilament twisted yarn (35) is obtained by applying S twist while bundling synthetic fibers.

The discharged synthetic fibers are arranged in the same manner as the arrangement of the spinning holes (2) in the porous spinneret (1), and are obtained by applying S twist to the fiber bundle in such an arrangement. When a fabric such as a knitted fabric or a woven fabric is manufactured using the multifilament twisted yarn (35), a soft texture and sufficient stretchability can be obtained, and a fabric with little variation in quality and good appearance quality can be obtained.

Further, as is apparent from FIG. 1, for example, a cooling air flow is blown from the lower side to the upper side of the fiber discharged from the spinning hole (2) of the porous spinneret (1). Assuming that most of the spinning holes (2) do not overlap (over) in the vertical direction, the cooling air can be irradiated to almost all the spinning fibers in an equal amount. A twisted yarn with little variation is obtained.

Further, in the state where the discharge front face (11) of the spinneret (1) is viewed from the front, the cross axis direction of the main hole portion (2a) of the spinning hole (2) is arranged to face at least two different directions. Therefore, the twisted form of the twisted yarn can be further stabilized, and a twisted yarn with less quality variation can be obtained.

FIG. 4 shows a second embodiment of the porous spinneret (1) according to the present invention. In this perforated spinneret (1), in a state where the substantially circular discharge front face (11) is viewed from the front, the pipe spinneret (1) is bent in the counterclockwise direction while extending radially outward from the central portion of the discharge front face (11). A group of spinning holes in which six spinning holes (2) are arranged at intervals along a substantially semicircular arc-shaped virtual curve (40) (curved line shown in FIG. 4B). 41) are formed on the discharge front surface (11) (eight groups), and these eight spinning hole groups (41A) (41B) (41C) (41D) (41E) (41F) (41G) ( 41H) are arranged apart from each other in the circumferential direction of the discharge front face (11) of the spinneret. A total of 48 spinning holes (2) are formed in such an arrangement.

Also, as shown in FIG. 4, the innermost (closest to the center position) spinning hole (2) of the first spinning hole group (41A) and the innermost side of the second spinning hole group (41B). Spinning hole (2), innermost spinning hole (2) of third spinning hole group (41C), innermost spinning hole (2) of fourth spinning hole group (41D), fifth spinning hole The innermost spinning hole (2) of the group (41E), the innermost spinning hole (2) of the sixth spinning hole group (41F), and the innermost spinning hole (41G) of the sixth spinning hole group (41G). The spinning hole (2) on the innermost side of the spinning hole (2) and the eighth spinning hole group (41H) is a virtual circle centered on the center position of the discharge front surface (11) that is circular in front view (FIG. 4 ( In b), it is arranged so as to be placed on an arc line (virtual line) of a circle indicated by a one-dot chain line on the innermost side.

Similarly, the second spinning hole (2) from the innermost side of each spinning hole group (41A to H) is a virtual circle centered on the center position of the discharge front face (11) that is circular when viewed from the front. It arrange | positions so that it may mount on the circular arc line (virtual line) of (circle shown with the 2nd dashed-dotted line from the innermost side in FIG.4 (b)). Further, the third spinning hole (2) from the innermost side of each spinning hole group (41A to H) is also arranged in the same manner. Hereinafter, the fourth spinning hole (2) from the innermost side of each spinning hole group (41A to H), the fifth spinning hole (2) from the innermost side of each spinning hole group (41A to H), The outermost spinning holes (2) of the spinning hole groups (41A to 41H) are also arranged in the same manner (see FIG. 4 (b)).

In the second embodiment, the spinning hole that does not fall on the virtual curve (40) is not formed, that is, only the spinning hole (2) that falls on the virtual curve (40) is formed. Thus, it is preferable to employ a configuration in which the spinning holes that do not fall on the virtual curve (40) are not formed at all or are substantially not formed.

Further, as apparent from FIG. 4, the interval between the innermost spinning holes (2) adjacent in the circumferential direction <the interval between the second spinning holes (2) from the innermost side adjacent in the circumferential direction < Spacing between the third spinning holes (2) from the innermost side adjacent in the circumferential direction <Spacing between the fourth spinning holes (2) from the innermost side adjacent in the circumferential direction <Fastest adjacent in the circumferential direction They are arranged so that the relationship between the intervals between the fifth spinning holes (2) from the inner side <the interval between the outermost spinning holes (2) adjacent in the circumferential direction is established. In other words, the interval between the spinning holes adjacent to each other in the circumferential direction is configured to gradually increase gradually toward the radially outer side.

The shape (front view shape) of the spinning hole (2) on the discharge front surface (11) is a substantially cross-shaped irregular shape as shown in FIG. That is, the deformed shape of the discharge front surface (11) of the spinning hole (2) includes a substantially cross-shaped main hole portion (2a) and enormous hole portions formed at the tip portions of the main hole portion (2a) ( 2b) (2b) (2b) (2b) (see FIG. 6).

Further, in the state where the discharge front face (11) of the spinneret (1) is viewed from the front, the cross axis direction of the main hole portion (2a) of the spinning hole (2) is arranged to face at least two different directions. Has been. That is, as shown in FIG. 4, in this second embodiment, the cross axis direction of the main hole portion (2a) of the spinning hole (2) constituting the first spinning hole group (41A) and the second spinning hole The axial direction of the cross of the main hole portion (2a) of the spinning hole (2) constituting the group (41B) is different. The main hole portion (2) of the spinning holes (2) constituting the first spinning hole group (41A), the third spinning hole group (41C), the fifth spinning hole group (41E), and the seventh spinning hole group (41G) ( The cross axis directions of 2a) are all the same. The main hole portion (2) of the spinning holes (2) constituting the second spinning hole group (41B), the fourth spinning hole group (41D), the sixth spinning hole group (41F), and the eighth spinning hole group (41H) ( The cross axis directions of 2a) are all the same.

Further, as shown in FIG. 2, the spinning hole (2) formed in the perforated spinneret (1) is located from the discharge rear surface side to the discharge front surface side in the region on the discharge front surface (11) side of the base (1). The diameter is reduced.

Next, a method for producing a twisted yarn using the above-structured porous spinneret (1) will be described. As shown in FIG. 5, the synthetic resin is supplied to the porous spinneret (1) to discharge the modified cross-section synthetic fiber from the spinning hole (2) of the porous spinneret (1). A multifilament twisted yarn (45) is obtained by Z-twisting the synthetic fiber while being bundled.

Since the discharged synthetic fibers are arranged in the same manner as the arrangement mode of the spinning holes (2) in the porous spinneret (1), the multi-fiber obtained by Z-twisting the fiber bundles in the arrangement mode is arranged. When a fabric such as a knitted fabric or a woven fabric is manufactured using the filament twisted yarn (45), a soft texture and sufficient stretchability can be obtained, and a fabric with less quality variation and good appearance quality can be obtained.

As is clear from FIG. 4, for example, an air flow for cooling is blown from the lower side to the upper side of the fiber discharged from the spinning hole (2) of the porous spinneret (1). Assuming that most of the spinning holes (2) do not overlap (over) in the vertical direction, the cooling air can be irradiated to almost all the spinning fibers in an equal amount. A twisted yarn with little variation is obtained.

Further, in the state where the discharge front face (11) of the spinneret (1) is viewed from the front, the cross axis direction of the main hole portion (2a) of the spinning hole (2) is arranged to face at least two different directions. Therefore, the twisted form of the twisted yarn can be further stabilized, and a twisted yarn with less quality variation can be obtained.

に お い て In the method for producing a twisted yarn, the synthetic resin (that is, the raw material of the synthetic fiber) supplied to the porous spinneret (1) is not particularly limited, and examples thereof include a polyester resin.

In the above embodiment, the shape of the spinning hole (2) on the discharge front surface (11) is a substantially cross-shaped irregular shape as shown in FIG. 6, but is not particularly limited to such a configuration. Alternatively, any shape may be used as long as it is an irregular shape (non-circular shape). For example, a polygonal shape such as a triangular shape or a quadrangular shape may be employed.

Moreover, in the said 1st Embodiment, although the said virtual curve (30) is formed in the substantially semicircular arc shape, it is not specifically limited to such a structure, From the center part of the said discharge front surface (11). Any curve may be used as long as the curve extends in the clockwise direction while facing outward in the radial direction. For example, the curve curves in the clockwise direction while going outward in the radial direction from the central portion of the discharge front surface (11). It may be a parabola extended.

Moreover, in the said 2nd Embodiment, although the said virtual curve (40) is formed in the substantially semicircular arc shape, it is not specifically limited to such a structure, From the center part of the said discharge front surface (11). Any curve may be used as long as it is curved outwardly extending in the counterclockwise direction while facing outward in the radial direction. For example, the counterclockwise direction is directed radially outward from the center of the discharge front surface (11). It may be a parabola or the like that is bent and bent.

Moreover, in the said embodiment, although one spinning hole group (31) (41) is comprised from six spinning holes (2), it is not specifically limited to such a structure, Two or more Any configuration having a plurality of spinning holes may be used. Among them, one spinning hole group (31) (41) is preferably composed of three or more spinning holes (2), particularly preferably composed of 4 to 20 spinning holes (2). It is. The number of spinning holes (2) in each spinning hole group (31) (41) may be the same number (for example, six) as in the above embodiment, or may be a different number. .

Moreover, in the said embodiment, although the number of installation of the spinning hole group (31) (41) is 8 (8 groups), it is not limited to such an installation number in particular, 2 or more ( (Multiple groups). Among these, the number of the spinning hole groups (31) and (41) is preferably 4 to 16 (groups) from the viewpoint of sufficiently obtaining the above-described effects.

The method for producing the porous spinneret (1) and the twisted yarn according to the present invention is not particularly limited to that of the above-described embodiment, and any design can be used as long as it does not depart from the spirit of the claims. Changes are also allowed.

Next, specific examples of the present invention will be described, but the present invention is not particularly limited to these examples.

<Example 1>
By supplying the polyester resin to the porous spinneret (1) of FIG. 1 described in the previous section, the irregular cross-section fibers are discharged from the spinning hole (2), and DTY processing is performed on the discharged 48 irregular cross-section fibers ( By applying (S twist), a 55 dtex (50 denier) multifilament twisted yarn (35) was produced (see FIG. 3). A knitted fabric was obtained by mesh knitting using this twisted yarn (35).

Note that the thickness (L) of the porous spinneret (1) was set to 23 mm, and the diameter (D) of the discharge front surface (11) was set to 83 mm (see FIG. 2). Moreover, the size of the spinning hole (2) was set to M = 0.3 mm, N = 0.08 mm, S = 0.08 mm, and T = 0.8 mm in FIG. Further, the diameter of the innermost virtual circle is 32.12 mm, the diameter of the second virtual circle from the innermost side is 48.85 mm, the diameter of the third virtual circle from the innermost side is 60.29 mm, The diameter of the fourth virtual circle from the innermost side is 68.88 mm, the diameter of the fifth virtual circle from the innermost side is 74.20 mm, and the outermost virtual circle (that is, the sixth virtual circle from the innermost side) The diameter of the (imaginary circle) was 76.00 mm (see FIG. 1B). Further, the radius of the substantially semicircular arc-shaped virtual curve (30) was set to 19.00 mm (see FIG. 1B).

<Example 2>
Example 1 except that the thickness of the twisted yarn (35) is adjusted to 82.5 dtex (75 denier) by adjusting the discharge pressure when discharging the irregular cross-section fiber from the spinning hole (2). I got a knitted fabric.

<Example 3>
A knitted fabric was obtained in the same manner as in Example 2 except that the shape of the discharge front surface (11) of the spinning hole (2) was all designed to be an equilateral triangle. The arrangement mode of the spinning holes (2) was also the same as in Example 2.

<Example 4>
The discharge front surface (11) of the spinning holes (2) constituting the second spinning hole group (31B), the fourth spinning hole group (31D), the sixth spinning hole group (31F), and the eighth spinning hole group (31H). A knitted fabric was obtained in the same manner as in Example 2 except that the shape was changed to a substantially triangular shape and a regular triangle was designed. The arrangement mode of the spinning holes (2) was also the same as in Example 2.

<Comparative Example 1>
A knitted fabric was obtained in the same manner as in Example 2 except that the arrangement of the spinning holes in the porous spinneret (91) was set to be concentric (the number of spinning holes: 48) shown in FIG. The size and shape of the spinning hole (92) were the same as in Example 2.

<Comparative example 2>
A knitted fabric was obtained in the same manner as in Example 2 except that the arrangement of the spinning holes in the porous spinneret (91) was set to the lattice shape (number of spinning holes: 48) shown in FIG. The size and shape of the spinning hole (92) were the same as in Example 2.

Each knitted fabric obtained as described above was evaluated by the following evaluation method.

<Texture evaluation method>
The knitted fabric was touched by hand to check its tactile sensation and evaluated based on the following criteria.
“◎”: Tactile feeling is very soft and has a very soft texture “O”: Tactile feeling is soft and the texture is good “×”: Tactile feeling is felt and the texture is not good.

<Elasticity evaluation method>
The stretch rate of each knitted fabric was measured based on the following stretch rate measurement method of the knitted fabric, and the stretchability was evaluated based on the following criteria.
(Measurement method of stretch rate of knitted fabric)
Based on the constant load method of JIS L1018 (load 490.4 cN), the stretch rate in the weft direction (course direction) of the knitted fabric was measured.
"◎" ... Elongation rate of the knitted fabric is 40% or more "O" ... Elongation rate of the knitted fabric is 30% or more and less than 40% "X" ... Elongation rate of the knitted fabric is less than 30% thing.

<Appearance quality evaluation method>
The knitted fabric was visually inspected for the presence of horizontal steps (surface streaks that were visually recognized as thin streaks due to irregular reflection due to variations in the cross-sectional shape of the yarn, etc.) and evaluated based on the following criteria.
“◯”: No row is recognized and the surface appearance of the knitted fabric is very good “Δ”: A little row is recognized “×”: A row is remarkably recognized.

As is apparent from Table 1, the knitted fabrics of Examples 1 to 4 of the present invention had a soft texture, excellent stretchability, and very good appearance quality.

On the other hand, the knitted fabric of Comparative Example 1 was insufficient in stretchability and in appearance quality.

The terms and explanations used here are used to describe the embodiments according to the present invention, and the present invention is not limited to these. The present invention allows any design changes within the scope of the claims without departing from the spirit thereof.

Claims (10)

1. A plurality of irregularly shaped spinning holes along an imaginary curve such as an arc extending in a clockwise direction from the center of the discharge front face toward the radially outer side when the discharge front face of the spinneret is viewed from the front A plurality of spinning hole groups formed by being spaced apart from each other are formed on the discharge front surface, and the plurality of spinning hole groups are arranged apart from each other in the circumferential direction of the spinneret. Porous spinneret.
2. The perforated spinneret according to claim 1, wherein the interval between the spinning holes adjacent in the circumferential direction of the spinneret is configured to gradually increase toward the radially outer side.
3. Spinning with a plurality of irregular shapes along a virtual curve such as an arc extending in a counterclockwise direction while extending radially outward from the center of the discharge front face when the discharge front face of the spinneret is viewed from the front A plurality of spinning hole groups in which holes are spaced apart from each other are formed on the discharge front surface, and the plurality of spinning hole groups are spaced apart from each other in the circumferential direction of the spinneret. Porous spinneret.
4. The perforated spinneret according to claim 3, wherein the interval between the spinnerets adjacent to each other in the circumferential direction of the spinneret is configured to gradually increase toward the radially outer side.
5. Discharging the modified cross-section synthetic fiber from the spinning hole of the porous spinneret according to claim 1;
   A step of obtaining a multifilament twisted yarn by applying S twist to the discharged fiber bundle composed of a plurality of synthetic fibers;
   The manufacturing method of the twisted yarn characterized by including.
6. Discharging the modified cross-section synthetic fiber from the spinning hole of the porous spinneret according to claim 2;
   A step of obtaining a multifilament twisted yarn by applying S twist to the discharged fiber bundle composed of a plurality of synthetic fibers;
   The manufacturing method of the twisted yarn characterized by including.
7. Discharging the modified cross-section synthetic fiber from the spinning hole of the porous spinneret according to claim 3;
   A step of obtaining a multifilament twisted yarn by applying Z twist to a fiber bundle composed of a plurality of discharged synthetic fibers;
   The manufacturing method of the twisted yarn characterized by including.
8. Discharging the modified cross-section synthetic fiber from the spinning hole of the porous spinneret according to claim 4,
   A step of obtaining a multifilament twisted yarn by applying Z twist to a fiber bundle composed of a plurality of discharged synthetic fibers;
   The manufacturing method of the twisted yarn characterized by including.
9. A twisted yarn produced by the production method according to any one of claims 5 to 8.
10. A fabric manufactured using the twisted yarn according to claim 9.

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