TW202104699A - Knitted fabric and garment - Google Patents

Abstract

Provided is a single knitted fabric that takes print well regardless of right or wrong side thereof, and that is highly resistant to peeling of a pressure adhesive tape. The present invention relates to a knitted fabric and a garment comprising the knitted fabric. The knitted fabric comprises a single knitted fabric with a jersey structure composed of a non-elastic fiber and an elastic fiber, and is characterized in that: a dynamic friction coefficient of a sinker loop side of the knitted fabric when rubbed from a cast-on direction to a cast-off direction is no greater than 0.500; regarding both a needle loop side and the sinker loop side of the knitted fabric, a difference between a dynamic friction coefficient when rubbed from the cast-on direction to the cast-off direction and a dynamic friction coefficient when rubbed from the cast-off direction to the cast-on direction is no greater than 0.13; and a ratio of the dynamic friction coefficient of the needle loop side to the dynamic friction coefficient of the sinker loop side when rubbed from the cast-on direction to the cast-off direction is 0.70-1.00.

Description

Knitting and clothing

The present invention relates to a knitted fabric and clothes.

Previously, as a method of imparting design to clothing, there was a method of imparting design patterns to knitted fabrics by printing. In addition, in order to reduce the seams when sewing knitted fabrics into clothing, there is also a method of bonding the knitted fabric and the knitted fabric by crimping tape. However, regarding the previous single-knot knitted fabric, although it is easy to obtain a lightweight and thin knitted fabric with high versatility, it is only suitable for printing on the front side (knitting needle yarn loop surface) of the knitted fabric in one direction. The crimping tape attaches the front and back sides (knitting needle yarn loop surface and sinker yarn loop surface) of the knitted fabric, but the crimping tape on the sinker yarn loop surface is slightly less resistant to peeling. In addition, the design imparted by printing is mainly performed on the outside air side of the clothing. Because printing is performed on the relatively smooth needle loop surface of the knitted fabric, it is necessary to make the sinker yarn loop whose smoothness is worse than that of the needle yarn loop surface. The surface is placed on the skin side of the clothes, and sometimes the skin will feel irritation. In order to reduce the irritation to the skin, a method of arranging the knitting needle yarn loop surface of the knitted fabric on the skin side of the clothing (refer to Patent Document 1 below) or having the knitting needle yarn loop surface of the knitted fabric arranged on the clothing skin has also been proposed. It is a knitted fabric with a layer structure (refer to Patent Document 2 below) by arranging cellulose fibers with good skin touch on the surface of the knitting needle yarn loop (see Patent Document 2 below), but both are the outside air side of the clothing, which is sinker yarn On the ring surface, the printing load becomes worse, and the design pattern of good quality cannot be obtained, and the peeling resistance of the crimping tape will not be improved. In addition, in the following patent document 3, in order to make a knit fabric with good skin touch that reduces the discomfort caused by bad touch such as unevenness, it is disclosed that there is a positional relationship between the yarn loops exposed on the back of the knit fabric Knitted fabric for control. However, Patent Document 3 does not show a solution to the ease of printing and bearing on the front and back sides and the peeling resistance of the crimping tape. As such, there has not yet been provided a knitted fabric suitable for clothing materials that can express design patterns by printing regardless of the front and back sides of the single-knot knitted fabric, and have good peeling resistance of the crimping tape. [Prior Technical Literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open No. 2013-213300 [Patent Document 2] International Publication No. 2018/180801 [Patent Document 3] Japanese Patent Laid-Open No. 2015/218407

[The problem to be solved by the invention]

In view of the above-mentioned prior art, the problem to be solved by the present invention is to provide a single-comb knitted fabric that can easily carry printing regardless of the front and back sides of the knitted fabric and has good peel resistance of the crimping tape. [Technical means to solve the problem]

In order to solve the above-mentioned problems, the inventor of the present invention conducted intensive research and repeated experiments. As a result, he unexpectedly discovered that a single-knot knitted fabric with a small difference in friction characteristics between the front and back sides can be manufactured, and thus completed the present invention. That is, the present invention is as follows. [1] A knitted fabric characterized in that it is a single-comb knitted fabric with a plain stitch structure including inelastic fibers and elastic fibers, and when the sinker loop surface of the knitted fabric rubs from the direction of the start of knitting to the direction of the end of knitting The dynamic friction coefficient is 0.500 or less. The dynamic friction coefficient of the knitting needle yarn loop surface and the sinker yarn loop surface of the knitted fabric when rubbing from the knitting start direction to the knitting end direction and the dynamic friction coefficient from the knitting end direction to the knitting start direction The difference between is 0.13 or less, and the ratio of the dynamic friction coefficient of the knitting needle yarn loop surface to the dynamic friction coefficient of the sinker yarn loop surface when rubbing from the knitting start direction to the knitting end direction is 0.70-1.00. [2] The knitted fabric described in [1] above, wherein the standard deviation of the friction coefficient of the sinker yarn loop surface from the knitting start direction to the knitting end direction is less than 0.500, and the sinker yarn loop surface from the knitting start The difference between the standard deviation of the friction coefficient when rubbing in the direction of the end of knitting and the standard deviation of the coefficient of friction when rubbing in the direction of the beginning of knitting from the end of knitting is 0.200 or less. [3] The knitted fabric as described in [1] or [2] above, wherein the standard deviation of the friction coefficient when the knitting needle yarn loop surface rubs from the knitting start direction toward the knitting end direction and the standard deviation from the knitting end direction toward the knitting start direction The difference in the standard deviation of the friction coefficient during friction is 0.025 or less. [4] The knitted fabric as described in any one of the above [1] to [3], wherein the ratio of the water diffusion area of the needle yarn loop surface to the sinker yarn loop surface of the above knitted fabric is 1.00 ~ 1.10. [5] The knitted fabric as described in any one of [1] to [4] above, wherein the ratio of the cold contact value of the needle loop surface of the knitted fabric to the cold contact value of the sinker loop surface It is 1.00～1.30. [6] The knitted fabric as described in any one of [1] to [5] above, wherein the number of weft turns is 70-150/inch and the number of warp turns is 50-80/inch, and the density index It is 4000～12000. [7] The knitted fabric as described in any one of [1] to [6] above, wherein the longest inelastic fiber among the inelastic fibers contained in the knitted fabric has a yarn length of 160-240 mm/100 w. [8] A garment comprising the knitted fabric described in any one of [1] to [7] above. [9] The garment as described in [8] above, wherein the needle loop surface of the knitted fabric is arranged on the skin side. [10] A method for manufacturing a knitted fabric, which is the method for manufacturing a knitted fabric as described in any one of [1] to [7] above, wherein the non-elastic fiber includes a cellulose-based filament yarn Yarns and yarns containing synthetic fibers, the two types of yarns are alternately arranged in the warp direction so that the yarn length of the synthetic fiber-containing yarns in the fabric is longer than the yarn length of the cellulose-based filament yarns The length is 5 mm～20 mm. [Effects of Invention]

The single-knot knitted fabric of the present invention improves the smoothness of the sinker yarn loop surface and the difference in the dynamic friction coefficient between the sinker yarn loop surface and the knitting needle yarn loop surface is small, so regardless of the front and back sides of the knitted fabric It is easy to carry and print, thereby improving the convenience of the braid, and also improving the peel resistance of the crimping tape.

Hereinafter, embodiments of the present invention will be described in detail. The characteristic of the knitted fabric of this embodiment is that it is a single-comb knitted fabric with a plain stitch structure including inelastic fibers and elastic fibers. The sinker loop surface of the knitted fabric is rubbed from the knitting start direction to the knitting end direction. The dynamic friction coefficient is 0.500 or less. The knitting needle yarn loop surface and sinker yarn loop surface of the knitted fabric are the difference between the dynamic friction coefficient when the knitting start direction and the knitting end direction are rubbed from the knitting end direction to the knitting start direction. The difference is 0.13 or less, and the ratio of the dynamic friction coefficient of the knitting needle yarn loop surface to the dynamic friction coefficient of the sinker yarn loop surface when rubbing from the knitting start direction to the knitting end direction is 0.70-1.00.

First, the woven fabric of this embodiment is characterized in that it contains elastic fibers and inelastic fibers. The non-elastic fiber used can be either filament yarn or spun yarn. Specifically, as the filament yarn, synthetic fibers such as polyamide-based fibers, polyester-based fibers, acrylic fibers, polypropylene-based fibers, and vinyl chloride-based fibers, semi-synthetic fibers such as acetate, and fibers are preferred. Those containing chemical fibers such as regenerated fibers such as plain fibers. The form of the filament yarn may be any of raw yarn (unprocessed yarn), false twisted processed yarn, colored yarn, etc., and may also be a composite yarn of the same. Furthermore, the cross-sectional shape of the filament yarn is 〇, △, cross, W type, M type, C type, I type, dog bone type, hollow fiber, etc., and is not particularly limited. As the spun yarn, it can be natural fibers such as cotton, wool, and hemp, or synthetic fibers such as polyamide-based fibers, polyester-based fibers, acrylic fibers, polypropylene-based fibers, vinyl chloride-based fibers, etc., and semi-natural fibers such as acetate. Synthetic fibers and regenerated fibers such as cellulose fibers and the like include chemical fibers, and these may be either singly or blended. In other words, it is sufficient to appropriately select suitable materials according to the purpose. For example, when it is necessary to use materials such as reducing the sultry heat in clothes to make clothes, cellulose fibers are better, and in order to impart cold contact or quick-drying properties, it is preferable to use filament yarns containing cellulose fibers. (Hereinafter, also referred to as "cellulose-based filament yarn") and polyester-based filaments, or cellulose-based filament yarns and polyamide-based filaments are used as composite false twisted processed yarns. In addition, two of the above-mentioned fibers (for example, yarns containing cellulose-based filament yarns and yarns containing synthetic fibers) may be alternated in the warp direction at 1:1, 1:2, 2:2, etc. Ground configuration, and yarns can also be combined to make a knitted fabric with a layered structure.

As the above-mentioned inelastic fibers, there are two types of yarns including cellulose filament yarns and yarns including synthetic fibers. When the two types of yarns are alternately arranged in the warp direction, it is preferable to include synthetic fibers. The yarn length of the yarn is set to be 5 mm to 20 mm longer than the yarn length of the yarn containing the cellulose-based filament yarn to manufacture a green fabric. Since the heat shrinkage or crimping performance of cellulose filaments is small, the heat shrinking or crimping performance of yarns containing only cellulose filaments or composite yarns, such as cellulose filaments, also becomes smaller. On the other hand, yarns containing synthetic fibers have greater heat shrinkage than yarns containing cellulose-based filaments, and have greater crimping performance when being made into false-twisted processed yarns. Therefore, in the manufacture of a knitted fabric in which yarns containing cellulose-based filament yarns and yarns containing synthetic fibers are alternately arranged in the warp direction, it is better to reduce the unevenness of the finished fabric and improve the smoothness. In order to set the yarn length of the synthetic fiber-containing yarn to be longer in the stage of fabric production. If the yarn length of synthetic fiber is 5 mm or more and 20 mm or less with respect to the yarn containing cellulose filament yarn, the surface of the fabric after processing is not easy to produce unevenness, and it is particularly easy to reduce the standard deviation of the friction coefficient, so it is preferable.

As the elastic fiber used, it can be polyurethane elastic yarn, polyether-ester elastic yarn, polyamide elastic yarn, polyolefin elastic yarn, or those that are coated with non-elastic fibers and placed in a covered state. . Furthermore, a so-called rubber yarn in the form of a yarn containing natural rubber, synthetic rubber, and semi-synthetic rubber can also be used, but it is preferably a polyurethane elastic yarn which has excellent stretchability and is generally widely used. Among them, polyurethane elastic yarns are preferred, and ethylenediamine is more preferably used as a chain extender to prepolymerize polytetramethylene glycol and diphenylmethane-4,4-diisocyanate. Polyurethane elastic yarn containing polyurethane produced by chain extension reaction.

The knitted fabric of the present embodiment is characterized in that it is a single-knot knitted fabric including a plain stitch. The single-comb knitted fabric containing the plain stitch is the simplest knitting structure, and the production efficiency is higher, which can make the thickness thinner and lighter, so it is suitable for making clothes. The single-knot knitted fabrics that are not plain stitches have the following situations: the shape of the knitting needle loop surface and the sinker loop surface are quite different, and it is difficult to align their shapes and make the smoothness the same. As single knot knitted fabrics that are not plain stitches, there are lay-up weaves and pile weaves. Regarding double-knot knitted fabrics or tricot knits that are not single-knot knitted fabrics, there are cases where the production efficiency is lower than that of single-knot knitted fabrics, and it is difficult to make the thickness thinner and lighter. In the plain stitch structure, in order to further add the performance of the knitted fabric, it can also be made into a so-called 3-layer plain knitted fabric containing two types of inelastic fibers and one type of elastic fiber. By forming a three-layer jersey knit fabric, one more inelastic fiber can be used than a normal jersey knit fabric, so the additional inelastic fiber characteristics can be imparted to the knitted fabric. In this case, the non-elastic fiber may be any fiber having the characteristics to be imparted. For example, if it is desired to impart moisture absorption and moisture release properties to a knitted fabric, cellulose fibers may be used.

Regarding the knitted fabric of the present embodiment, the dynamic friction coefficient of the sinker loop surface of the knitted fabric when rubbed from the knitting start direction to the knitting end direction is 0.500 or less, preferably 0.400 or less, and more preferably 0.300 or less. If the dynamic friction coefficient of the sinker yarn loop surface of the knitted fabric when rubbing from the knitting start direction to the knitting end direction exceeds 0.500, the following situation exists: the smoothness of the knitted fabric surface is poor, so that the sinker yarn loop surface of the knitted fabric is printed The load-bearing capacity deteriorates, or the peel resistance of the crimping tape decreases. Furthermore, in the knitted fabric of this embodiment, the direction in which the inelastic fibers in the knitted fabric can be easily extracted is the end of knitting, and the opposite direction is the start of knitting. In addition, "rubbing from the knitting start direction to the knitting end direction" refers to rubbing in the warp direction (warp direction) from the knitting start direction to the knitting end direction.

Regarding the knitted fabric of this embodiment, the knitting needle yarn loop surface and sinker loop surface of the knitted fabric are the dynamic friction coefficient when the knitting start direction is rubbed toward the knitting end direction and the dynamic friction coefficient when the knitting end direction is rubbed toward the knitting start direction. The difference between is 0.13 or less, preferably 0.12 or less, and more preferably 0.11 or less. If the difference between the knitting needle yarn loop surface and the sinker yarn loop surface of the knitted fabric when the friction coefficient from the knitting start direction to the knitting end direction and the dynamic friction coefficient from the knitting end direction to the knitting start direction is greater than 0.13, there is The situation is as follows: In particular, the smoothness of the sinker yarn loop surface is poor, so that the printing load on the sinker yarn loop surface is poor, and the peel resistance of the crimping tape is also reduced.

Regarding the knitted fabric of this embodiment, the ratio of the dynamic friction coefficient of the needle loop surface of the knitted fabric to the dynamic friction coefficient of the sinker loop surface of the knitted fabric when the knitted fabric rubs from the knitting start direction to the knitting end direction (knitting needles The dynamic friction coefficient of the yarn loop surface/the dynamic friction coefficient of the sinker yarn loop surface) is 0.70 to 1.00, preferably 0.80 to 1.00, more preferably 0.90 to 1.00. If the ratio of the dynamic friction coefficient of the knitting needle loop surface of the knitted fabric to the dynamic friction coefficient of the sinker loop surface of the knitted fabric when the knitted fabric rubs from the knitting start direction to the knitting end direction does not reach 0.70, the following situation exists: The smoothness of the loop surface of the sinker yarn of the knitted fabric is poor, so the printing load of the loop surface of the sinker yarn of the knitted fabric is poor, and the peel resistance of the crimping tape is also reduced. Regarding the structure of the yarn loops, the friction of the sinker loops of the knitted fabric when the knitting starts from the knitting direction to the knitting end direction will not be more frictional than the knitted fabric when the knitting starts from the knitting direction to the knitting end direction The friction of the loop surface of the knitting needle is better, so the dynamic friction coefficient of the loop surface of the knitting needle and the dynamic friction coefficient of the loop surface of the knitting fabric when the knitting is rubbed from the knitting start direction to the knitting end direction The ratio will hardly exceed 1.00.

From the standpoint of the printing load and the peel resistance of the crimping tape, the standard deviation of the friction coefficient when rubbing from the knitting start direction to the knitting end direction of the sinker yarn loop surface of the knitted fabric of this embodiment is preferably 0.500 or less , More preferably 0.400 or less, still more preferably 0.300 or less, particularly preferably 0.200 or less.

Regarding the knitted fabric of this embodiment, in the sinker loop surface of the knitted fabric, from the viewpoint of the printing load and the peel resistance of the crimping tape, the standard of the friction coefficient when rubbing from the knitting start direction to the knitting end direction The difference between the deviation and the standard deviation of the friction coefficient when rubbing from the knitting end direction to the knitting start direction is preferably 0.20 or less, more preferably 0.18 or less, and still more preferably 0.15 or less.

Regarding the knitted fabric of this embodiment, in the knitting needle yarn loop surface of the knitted fabric, from the viewpoint of the printing load and the peel resistance of the crimping tape, the standard of the friction coefficient when rubbing from the knitting start direction to the knitting end direction The difference between the deviation and the standard deviation of the friction coefficient when rubbing from the knitting end direction to the knitting start direction is preferably 0.025 or less, more preferably 0.020 or less, and still more preferably 0.017 or less.

Generally speaking, a single knot knitted fabric including a plain stitch has a different structure on the front and back of the knitted fabric, and has a knitting needle yarn loop surface and a sinker yarn loop surface. As shown in Figure 1, the loop surface of the knitting needle is arranged with V-shaped continuous loops, so there is less friction in the longitudinal and horizontal directions of the knitted fabric. In contrast, the loop surface of the sinker is arranged with semicircular loops. , So especially the longitudinal friction of the braid is higher. Furthermore, in the knitting needle yarn loop surface and the sinker yarn loop surface, the friction from the knitting start direction to the knitting end direction of the knitted fabric is greater than the friction from the knitting end direction to the knitting start direction of the knitted fabric, and it has directionality. The smoothness is uneven, especially the friction of the sinker yarn loop surface, which varies greatly depending on the direction. The reason is that the overlap of the yarns is directional due to weaving. Therefore, making the friction of the sinker yarn loop surface uniform will greatly affect the ease of printing and the peeling resistance of the crimping tape.

The friction characteristics of the knitted fabric of the present embodiment indicating smoothness were measured using a static-dynamic friction measuring machine Tribomaster Type: TL201Ts manufactured by Trinity-Lab. The conditions of the measurement are friction element: unpatterned type/contact surface 11 mm×15 mm, measurement load: 3.75 g, friction speed 30 mm/sec, friction distance 100 mm, reciprocating 3 times under the above conditions. The rubbing starts from the knitting start direction to the knitting end direction. After rubbing 100 mm, the rubbing direction is reversed, and the knitting starts from the knitting end direction to the knitting start direction. Repeat this action 3 times to calculate the standard deviation of the dynamic friction coefficient and the friction coefficient from the knitting start direction to the knitting end direction, and the dynamic friction coefficient and the standard deviation of the friction coefficient from the knitting end direction to the knitting start direction. Use calculation 3 The second is the average value obtained.

Regarding the knitted fabric of this embodiment, the ratio of the water diffusion area of the needle yarn loop surface of the knitted fabric to the water diffusion area of the sinker yarn loop surface is preferably 1.00 to 1.10, more preferably 1.00 to 1.08, and still more preferably 1.00 ~1.06, more preferably 1.00 to 1.04. If the surface of the woven fabric is smooth, the moisture absorbed on the surface of the woven fabric is easily diffused on the surface of the woven fabric. Therefore, it can be considered that the water diffusion area represents one of the functions of smoothness. The ratio of the water diffusion area of the knitting needle yarn loop surface of the knitted fabric to the water diffusion area of the sinker yarn loop surface of the knitted fabric (knitting needle yarn loop surface/sinking yarn loop surface) exceeds 1.10 refers to the sinker of the knitted fabric The water diffusibility of the yarn loop surface is worse than that of the knitting needle yarn loop surface of the knitted fabric, and thus the smoothness is poor. Therefore, the printing load of the sinker yarn loop surface is poor, and the peel resistance of the crimping tape is also reduced. As far as the structure of the yarn loop is concerned, the smoothness of the loop surface of the sinker yarn of the knitted fabric is no better than the smoothness of the loop surface of the knitting needle of the knitted fabric, so the water diffusibility of the sinker yarn loop surface of the knitted fabric is no better than The water diffusivity of the knitting needle yarn loop surface of the knitted fabric is better, and there is almost no water diffusion area of the knitting needle yarn loop surface of the knitted fabric and the water diffusion area of the sinker yarn loop surface of the knitted fabric is less than 1.00 situation.

Regarding the knitted fabric of this embodiment, the comparison between the cold contact value of the needle yarn loop surface of the knitted fabric and the cold contact value of the sinker yarn loop surface of the knitted fabric is preferably 1.00 to 1.30, more preferably 1.00 to 1.25, More preferably, it is 1.00 to 1.20. If the surface of the knitted fabric is smooth, the contact area increases and the cold contact sensitivity becomes higher. Therefore, it can be considered that the cold contact value represents one of the functions of smoothness. Regarding the smoothness of the knitted fabric, if the ratio of the cold contact value of the knitting needle yarn loop surface of the knitted fabric to the cold contact value of the sinker yarn loop surface of the knitted fabric exceeds 1.30, the sinker yarn loop surface of the knitted fabric The smoothness becomes worse, so the printing load on the loop surface of the sinker of the knitted fabric is poor, and the peeling resistance of the crimping tape is also reduced. As far as the structure of the yarn loop is concerned, the smoothness of the loop surface of the sinker yarn of the knitted fabric is no better than that of the needle yarn loop surface of the knitted fabric, so the contact cold sensitivity value of the sinker yarn loop surface of the knitted fabric does not It is better than the cold value of the knitting needle yarn loop surface of the knitted fabric, and there is almost no ratio of the cold touch value of the knitting needle yarn loop surface of the knitted fabric to the cold contact value of the sinker yarn loop surface of the knitted fabric Circumstances below 1.00.

Regarding the knitted fabric of this embodiment, it is preferable that the number of weft turns is 70-150/inch (2.54 cm), the number of warp turns is 50-80/inch, and the density index is 4000-12000. The number of weft turns of the braid is more preferably 80-130/inch, and more preferably 90-110/inch. The number of warp turns of the braid is more preferably 55-70/inch, and more preferably 55-65/inch. The density index is more preferably 4200 to 10,000, still more preferably 4400 to 8000, and particularly preferably 4600 to 6000. The density index is given by the following formula (1): Density index = the number of weft turns of the braid (pieces/inch) × the number of warp turns of the braid (pieces/inch) (1) And it is calculated, and it is the value that becomes the standard of density. If the density index is higher, the denseness is higher. If the number of weft turns of the knitted fabric is more than 70/inch, the number of warp turns is more than 50/inch, and the density index is more than 4000, the density required for smoothness is excellent, the printing load is good, and the crimping The peel resistance of the tape is also easy to improve. If the number of weft turns of the knitted fabric is less than 150/inch, the number of warp turns is less than 80/inch, and the density index is less than 12000, there is no need to use a knitting machine with high gauge needles or fine-grain yarns. The woven fabric is not too thin, and the burst strength is high enough, so the durability of the clothes will not be a problem.

The fineness of the non-elastic fiber used in the knitted fabric of this embodiment is preferably in the range of 15 to 200 detx, more preferably 20 to 170 dtex, still more preferably 30 to 120 dtex, particularly preferably 40 to 100 dtex. If the fineness of the inelastic fiber is less than 15 dtex, the breaking strength when used as a knitted fabric may become too low, and durability as a clothing may become a problem. On the other hand, if the fineness of the inelastic fiber exceeds 200 dtex, a knitting machine with low gauge needles must be used, and a better density index cannot be obtained, and the desired effect cannot be obtained.

The fineness of the elastic fiber used in the knitted fabric of this embodiment is preferably in the range of 15 to 80 dtex, more preferably 20 to 60 dtex, and still more preferably 30 to 50 dtex. If the denier of the elastic fiber is less than 15 detx, it may not be able to obtain the required extensibility and recovery. On the other hand, if the fineness of the elastic fiber exceeds 80 dtex, the weight per unit area may increase, and it may become too heavy as clothing.

Regarding the knitted fabric of this embodiment, the weight per unit area is preferably in the range of 50 to 300 g/m ² , more preferably 80 to 200 g/m ² , and still more preferably 100 to 170 g/m ² . If the weight per unit area is less than 50 g/m ² , the sense of perspective or breaking strength may deteriorate. On the other hand, if the weight per unit area exceeds 300 g/m ² , it may be too heavy when worn as clothing, which may hinder movement.

Regarding the knitted fabric of this embodiment, the longest yarn length in the inelastic fiber used is preferably 160～240 mm/100 W (warp loop), more preferably 170～220 mm/100 W, and more preferably 190 ～210 mm/100 W. Furthermore, the yarn length per 100 W is calculated as follows. Mark the two ends of 100 continuous knitting loops in the transverse direction (weft direction) of the braid, extract the marked part of the yarn from the braid, apply a load of size × 0.1 g, and measure the length. If the longest yarn length of the non-elastic fiber used is 160 mm/100 W or more, the braid will have sufficient stretchability and soft texture, which can easily meet the requirements of clothing. On the other hand, if the longest yarn length of the non-elastic fibers used is 240 mm/100 W or less, the non-elastic fibers will not appear on the surface of the knitted fabric and will easily become one with excellent smoothness. Furthermore, in order to make the knitted fabric dense and the yarn length within the above range, it is necessary to significantly shrink it in post-processing such as dyeing processing to adjust the density and yarn length.

In order to make clothes with soft texture without hindering the stretchability of elastic fibers, the single yarn fineness of the non-elastic fibers is preferably 0.3-3.0 dtex, more preferably 0.5-25 dtex, and even more preferably 0.8-2.3 dtex.

The stretch ratio of the elastic fiber of the knitted fabric of this embodiment is not particularly limited as long as the knitted fabric has moderate stretchability and does not break when knitted. For example, the range of 2.5 to 3.5 times is often used.

The knitted fabric of the present embodiment can be knitted by a flat knitting machine or a single-bar circular knitting machine, and it is not particularly limited as long as a weight per unit area or texture suitable for the purpose can be obtained. In addition, although there are no particular restrictions on the gauge needles of the knitting machine, it is preferably a knitting machine with 18-50 gauge needles arbitrarily selected according to the application or the thickness of the fiber used, and more preferably 24-40 gauge needles , And more preferably 28-36 gauge needles.

The knitted fabric of this embodiment can also be thrown into the dyeing steps such as pre-sizing, dyeing, and finalizing after knitting. The processing method only needs to be carried out according to the usual processing method of elastic fiber mixed braid. In order to achieve the required smoothness, it is better to adjust the temperature, the spreading rate and the indentation rate in the warp direction at the time of pre-sizing. As an incidental process in the dyeing stage, anti-fouling processing, antibacterial processing, deodorizing processing, deodorizing processing, water absorption processing, moisture absorption processing, ultraviolet absorption processing, weight reduction processing, etc. can be appropriately given according to the final required characteristics, and then as post processing. According to the final required characteristics, it can be appropriately given calendering processing, embossing processing, wrinkling processing, raising processing, fiber-drawing transparent printing processing, soft processing using silicone softeners, etc. Especially the water absorption process is effective for reducing stickiness when worn as clothing.

In the printing and processing of the knitted fabric of this embodiment, the method or method is not limited, and hand printing, roller printing, screen printing, gravure printing, transfer printing, and inkjet printing can be used. Either way, it is also preferable to select an appropriate method according to the target pattern or the material to be printed. In addition, as coloring components, organic or inorganic pigments (including metal powders) can be used, and printing materials can also be used together with disperse dyes, acid dyes, cationic dyes, reactive dyes, and direct dyes. , Fluorescent dyes, etc.

When the knitted fabric of the present embodiment is made into clothing, it is not necessary to sew, but to bond the knitted fabric and the knitted fabric by pressure bonding tape. There are no special restrictions on the crimping tape used, and crimping tape that meets the purpose of use can be used appropriately.

The knitted fabric of the present embodiment can be used for, for example, underwear, sportswear, outerwear, swimwear, etc. that fit the body.

For the knitted fabric of this embodiment, for example, when the sinker loop surface of the knitted fabric is used on the outside air side of the garment, the needle yarn loop surface becomes the skin side, and the sinker loop surface of the knitted fabric is usually used for Compared with the clothes on the skin side, the friction coefficient is lower and the cold touch value is higher, so it is easy to feel smoothness or coldness. [Example]

Hereinafter, the present invention will be specifically explained using examples and comparative examples. Each evaluation system in Examples and Comparative Examples was performed as follows. (1) Dynamic friction coefficient and standard deviation of friction coefficient Tribomaster Type: TL201Ts, a static-dynamic friction measuring machine manufactured by Trinity-Lab, was used for the measurement. The conditions of the measurement are friction element: unpatterned type/contact surface 11 mm×15 mm, measurement load: 3.75 g, friction speed 30 mm/sec, friction distance 100 mm, reciprocating 3 times under the above conditions. Start rubbing from the knitting start direction to the knitting end direction. After rubbing 100 mm, reverse the rubbing direction and rubbing from the knitting end direction to the knitting start direction. Repeat this action 3 times to calculate the standard deviation of the dynamic friction coefficient and the friction coefficient from the knitting start direction to the knitting end direction, and the dynamic friction coefficient and the standard deviation of the friction coefficient from the knitting end direction to the knitting start direction. Use calculation 3 The second is the average value obtained.

(2) Water diffusion area Use a micropipette at 20°C and 65%RH to load water or the reactive dye "Sumifix Brilliant Blue" manufactured by Sumitomo Scientific Corporation into 100 g of water and dissolve 0.05 g of the dye solution into 0.1 cc of water droplets. On acrylic board. In addition, a 10 cm×10 cm sample taken from a cloth that has been conditioned for 24 hours in the same environment is gently placed on the dye solution with the measuring side facing down, and the area where the dye solution spreads after 5 minutes is measured. Assuming that the diffusion area is elliptical diffusion, the diffusion length in the longitudinal direction and the diffusion length in the transverse direction are calculated in the form of (π/4)×(lengthwise×lengthwise).

(3) Contact coldness value For a knitted fabric cut into 8 cm×8 cm under humidity control under 20℃×65% environment, the cooling base is set as KES-F7-II manufactured by Jiaduo Technology Co., Ltd. In the range of 20℃±0.5℃, place the knitted fabric on the cooling base with the skin side of the knitted fabric facing up. ^{After that, the maximum heat transfer (W/cm 2} ) when the hot plate of the device heated to the temperature of the cooling base +10°C is placed on the skin surface of the knitted fabric is measured.

(4) Printing bearing situation For the printing of the bearing dot pattern on the sinker yarn loop surface of the knitted fabric, the state of the printed pattern after 100 washing treatments according to the JIS-L-1096-G method is judged visually based on the following evaluation criteria . If the following benchmark is 3 or more, there is no practical problem: 5: No printing cracks or peeling occurred at all. 4: Printing cracks or peeling occurred in more than 0% and less than 20% of the total. 3: Printing cracks or peeling occurred in more than 20% and less than 40% of the total. 2: Printing cracks or peeling occurred in more than 40% of the total and less than 60%. 1: Print cracks or peeling occurred in more than 60% of the total.

(5) Peel resistance of crimping tape Take two specimens with a width of 50 mm × a length of 150 mm from the knitted fabric, and place them on the side of the sinker loop of one specimen and the end of the needle loop of the other specimen. Lay the crimping tape with a width of 10 mm at the 10 mm position. The sample was washed 100 times in accordance with the JIS-L-1096-G method. The sample was set in a tensile testing machine so that the entire width of the sample was grasped, a load of 14.7 N was applied, and the measurement was held for 1 minute. The amount of peeling. If the following benchmark is 3 or more, there is no practical problem: 5: The amount of peeling is 0 mm. 4: The amount of peeling exceeds 0 and is 2 mm or less. 3: The amount of peeling exceeds 2 and is 4 mm or less. 2: The amount of peeling exceeds 4 and is 6 mm or less. 1: The peeling amount exceeds 6 mm.

[Example 1] A single-comb circular knitting machine with 36 gauge needles was used, and the elastic fiber was made of polyurethane elastic fiber 22 dtex (A ), non-elastic fiber uses nylon filament 22 dtex 20 f and cupra filament 56 dtex 45 f composite false twisted mixed fiber yarn (B) of 80 dtex 65 f and nylon filament false twisted processed yarn 78 dtex 68 f(C), a knitted loop composed of the above elastic fiber (A) and the above inelastic fiber (B) and the above elastic fiber (A) and the above inelastic fiber (C) The knitting loops formed by the yarn are arranged alternately in the warp direction of the knitted fabric at a ratio of 1:1, so as to obtain a smooth surface with a length of 10 mm of the false twisted yarn (C) relative to the mixed fiber yarn (B) The fabric of plain knitting. Carry out the predetermined type condition or dyeing condition, finishing condition when the cloth is dyed and finished, and the finishing condition is the same as that of the usual processing polyurethane elastic fiber mixed woven fabric, so as to obtain a unit area weight of 130 g/ m ² , a braid with a thickness of 0.43 mm, 81 weft loops/inch, and 56 warp loops/inch. The results are shown in Table 1 below. The obtained woven fabric is a woven fabric with good printing load and good peel resistance of the crimping tape.

[Example 2] In addition to changing the yarn length of the inelastic fiber of Example 1, the same circular knitting machine, elastic fiber and inelastic fiber as in Example 1 were used to obtain elastic fiber and inelastic fiber configuration. Set as the original fabric of the same smooth jersey knitted fabric. In the same dyeing step as in Example 1, the fabric was fabricated so that the weight per unit area became 128 g/m ² , the thickness became 0.41 mm, the weft loops became 90 pieces/inch, and the warp loops became 54 pieces/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained woven fabric is a woven fabric with good printing load and good peel resistance of the crimping tape.

[Example 3] The fabric made of the false twisted processed yarn (C) has the same yarn length as the non-elastic fiber blended yarn (B) of Example 1, except that the same circular knitting as in Example 1 was used. The machine, elastic fiber, inelastic fiber, the configuration of obtaining elastic fiber and inelastic fiber are also the same as the original cloth of smooth jersey knitted fabric. In the same dyeing step as in Example 1, the fabric was made such that the weight per unit area was 132 g/m ² , the thickness was 0.46 mm, the weft loops were 75/inch, and the warp loops were 55/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained woven fabric is a woven fabric with good printing load and good peel resistance of the crimping tape.

[Example 4] In addition to changing the yarn length of the inelastic fibers of Example 1, the same circular knitting machine, elastic fibers and inelastic fibers as in Example 1 were used to obtain elastic fibers and inelastic fibers. Set as the original fabric of the same smooth jersey knitted fabric. In the same dyeing step as in Example 1, the fabric was made such that the weight per unit area became 165 g/m ² , the thickness became 0.53 mm, the weft loops became 96 per inch, and the warp loops became 56 per inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained woven fabric is a woven fabric with good printing load and good peel resistance of the crimping tape.

[Example 5] The non-elastic fiber of Example 1 uses a blended yarn (B) of 67 dtex 65 f obtained by compounding false-twisted nylon filament 22 dtex 20 f and cupra filament 44 dtex 45 f And nylon filament false-twisted processed yarn 56 dtex 48 f(C), except that the yarn length of each was changed, and the same circular knitting machine and elastic fiber as in Example 1 were used to obtain a combination of elastic fiber and non-elastic fiber. The configuration is also the same as the original fabric of the smooth jersey knitted fabric. In the same dyeing step as in Example 1, the fabric was made such that the weight per unit area became 105 g/m ² , the thickness became 0.48 mm, the weft loops were 85 pieces/inch, and the warp loops were 50 pieces/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained woven fabric is a woven fabric with good printing load and good peel resistance of the crimping tape.

[Example 6] Using only the mixed fiber yarn (B) and elastic fiber (A) of the inelastic fiber used in Example 5, the above elastic fiber (A) and the mixed fiber yarn (B) were combined and knitted The original fabric of the plain knitted fabric. In the same dyeing process as in Example 1, the fabric was made such that the weight per unit area became 120 g/m ² , the thickness became 0.42 mm, the weft loops became 92 pieces/inch, and the warp loops became 57 pieces/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained woven fabric is a woven fabric with good printing load and good peel resistance of the crimping tape.

[Comparative Example 1] The circular knitting machine and the yarn length of the inelastic fiber used in Example 1 were changed, except that the same elastic fiber and inelastic fiber as in Example 1 were used to obtain elastic fiber and inelastic fiber The configuration is also the same as the original fabric of the smooth jersey knitted fabric. In the same dyeing step as in Example 1, the fabric was made such that the weight per unit area became 134 g/m ² , the thickness became 0.49 mm, the weft loops became 91 pieces/inch, and the warp loops became 45 pieces/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained knitted fabric is a knitted fabric in which the smoothness of the sinker yarn loop surface is insufficient, and the peeling resistance of the printing bearing and the crimping tape becomes a problem in the practical range.

[Comparative Example 2] A single-comb circular knitting machine with 32 gauge needles was used. The elastic fiber was made of polyurethane elastic fiber 22 dtex( A), the non-elastic fiber uses cupra filament yarn (B) and polyester filament false-twisted yarn 56 dtex 72 f(C), and the above-mentioned non-elastic fiber (C ), on the sinker surface of the knitted fabric, the above-mentioned inelastic fibers (B) and the above-mentioned inelastic fibers (C) are alternately arranged in the warp direction of the knitted fabric at a ratio of 1:1, in the middle of the knitted fabric The layer is configured with elastic fibers (A) to obtain the plain fabric of the smooth jersey knitted fabric with the above three-layer structure. In the same dyeing step as in Example 1, the fabric was made such that the weight per unit area became 135 g/m ² , the thickness became 0.46 mm, the weft loops became 77 pieces/inch, and the warp loops became 50 pieces/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained knitted fabric is a knitted fabric in which the smoothness of the sinker yarn loop surface is insufficient, and the peeling resistance of the printing bearing and the crimping tape becomes a problem in the practical range.

[Comparative Example 3] The circular knitting machine and the yarn length of the inelastic fiber used in Example 1 were changed, except that the same elastic fiber and inelastic fiber as in Example 1 were used to obtain elastic fiber and inelastic fiber The configuration is also the same as the original fabric of the smooth jersey knitted fabric. In the same dyeing step as in Example 1, the fabric was made such that the weight per unit area became 118 g/m ² , the thickness became 0.43 mm, the weft loops became 87 pieces/inch, and the warp loops became 40 pieces/inch. Make adjustments to obtain a braid. The results are shown in Table 1 below. The obtained knitted fabric is a knitted fabric in which the smoothness of the sinker yarn loop surface is insufficient, and the peeling resistance of the printing bearing and the crimping tape becomes a problem in the practical range.

[Table 1] Example 1 Example 2 Example 3 Example 4 Example 5 Example 6 Weaving organization Flat needle ← ← ← ← ← Needle 36 GG ← ← ← ← ← Non-elastic yarn B Yarn type Nylon/Copper ammonia fiber composite yarn ← ← ← ← ← Denier/Number of filaments 80 T/65 F ← ← ← 67 T/65 F ← Yarn length mm/100 w 209 196 209 211 215 184 Inelastic yarn C Yarn type Nylon processing yarn ← ← ← ← - Denier/Number of filaments 78 T/68 F ← ← ← 56 T/48 F - Yarn length mm/100 w 214 202 200 218 214 - Alternate knitting rate of non-elastic yarn 1:01 ← ← ← ← - The set yarn length difference of the non-elastic yarn in the fabric (CB)mm 10 10 0 10 10 - Elastic yarn A Yarn type Polyurethane ← ← ← ← ← Fineness 22 T ← ← ← ← ← Unit area weight g/m ² 130 128 132 165 105 120 Thickness mm 0.43 0.41 0.46 0.53 0.48 0.42 Density/inch c81w56 c90w54 c75w55 c96w56 c85w50 c92w57 Density index 4536 4860 4125 5376 4250 5244 Dynamic friction coefficient Knitting needle yarn loop surface Knitting start → knitting end direction 0.195 0.217 0.334 0.228 0.293 0.268 Knitting end → Knitting start direction 0.121 0.114 0.215 0.11 0.175 0.161 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.074 0.103 0.119 0.118 0.118 0.107 Sinking yarn loop surface Knitting start → knitting end direction 0.206 0.225 0.405 0.261 0.337 0.353 Knitting end → Knitting start direction 0.115 0.116 0.278 0.139 0.229 0.257 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.091 0.109 0.127 0.122 0.108 0.096 The ratio of the knitting needle yarn loop surface to the sinker yarn loop surface in the direction from the beginning of knitting to the end of knitting 0.95 0.96 0.82 0.87 0.87 0.76 Standard deviation of friction coefficient Knitting needle yarn loop surface Knitting start → knitting end direction 0.185 0.188 0.205 0.178 0.255 0.283 Knitting end → Knitting start direction 0.173 0.174 0.189 0.163 0.242 0.268 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.012 0.014 0.016 0.015 0.013 0.015 Sinking yarn loop surface Knitting start → knitting end direction 0.285 0.208 0.413 0.191 0.373 0.397 Knitting end → Knitting start direction 0.18 0.172 0.334 0.172 0.245 0.271 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.105 0.036 0.079 0.019 0.128 0.126 Water diffusion area Knitting needle yarn loop surface 11.6 11.5 11.2 9.9 10.6 11.1 Sinking yarn loop surface 11.2 11.1 10.3 9.9 10.2 10.8 Ratio of knitting needle yarn loop surface to sinker yarn loop surface 1.04 1.04 1.09 1 1.04 1.03 Cold contact value Knitting needle yarn loop surface 0.177 0.18 0.168 0.18 0.148 0.195 Sinking yarn loop surface 0.166 0.155 0.129 0.147 0.124 0.154 Ratio of knitting needle yarn loop surface to sinker yarn loop surface 1.07 1.16 1.3 1.22 1.19 1.27 Printability of sinker yarn loop surface 5 5 3 3 4 3 Peelability of crimping tape 5 5 3 4 3 4

[Table 2] Comparative example 1 Comparative example 2 Comparative example 3 Weaving organization ← ← ← Needle 28 GG 32 GG 28 GG Non-elastic yarn B Yarn type Nylon/Copper ammonia fiber composite yarn Cupra Nylon/Copper ammonia fiber composite yarn Denier/Number of filaments 80 T/65 F 33 T/24 F 80 T/65 F Yarn length mm/100 w 228 245 193 Inelastic yarn C Yarn type Nylon processing yarn Polyester processing yarn Nylon processing yarn Denier/Number of filaments 78 T/68 F 56 T/72 F 78 T/68 F Yarn length mm/100 w 235 220 204 Alternate knitting rate of non-elastic yarn 1:01 Add yarn 1:01 Setting yarn length difference of non-elastic yarn (CB)mm 10 10 10 Elastic yarn A Yarn type ← ← ← Fineness ← ← ← Unit area weight g/m ² 134 135 118 Thickness mm 0.49 0.46 0.43 Density/inch c91w45 c77w50 c87w40 Density index 4095 3850 3480 Dynamic friction coefficient Knitting needle yarn loop surface Knitting start → knitting end direction 0.264 0.384 0.352 Knitting end → Knitting start direction 0.114 0.243 0.213 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.15 0.141 0.139 Sinking yarn loop surface Knitting start → knitting end direction 0.508 0.768 0.475 Knitting end → Knitting start direction 0.327 0.465 0.33 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.181 0.303 0.145 The ratio of the knitting needle yarn loop surface to the sinker yarn loop surface in the direction from the beginning of knitting to the end of knitting 0.52 0.5 0.74 Standard deviation of friction coefficient Knitting needle yarn loop surface Knitting start → knitting end direction 0.742 0.717 0.514 Knitting end → Knitting start direction 0.705 0.666 0.471 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.037 0.051 0.043 Sinking yarn loop surface Knitting start → knitting end direction 1.091 1.512 0.716 Knitting end → Knitting start direction 0.774 1.006 0.483 (From the beginning of knitting to the end of knitting)-(from the end of knitting to the beginning of knitting) 0.317 0.506 0.233 Water diffusion area Knitting needle yarn loop surface 10.7 11.2 11.2 Sinking yarn loop surface 9.9 9.5 10.7 Ratio of knitting needle yarn loop surface to sinker yarn loop surface 1.08 1.18 1.05 Cold contact value Knitting needle yarn loop surface 0.165 0.149 0.17 Sinking yarn loop surface 0.126 0.122 0.138 Ratio of knitting needle yarn loop surface to sinker yarn loop surface 1.31 1.22 1.23 Printability of sinker yarn loop surface 1 1 2 Peelability of crimping tape 2 1 1 [Industrial availability]

The single-knot knitted fabric of the present invention improves the smoothness of the sinker yarn loop surface and the difference in the dynamic friction coefficient between the sinker yarn loop surface and the knitting needle yarn loop surface is small, so regardless of the front and back sides of the knitted fabric It is easy to carry and print, thereby improving the convenience of the braid, and also improving the peel resistance of the crimping tape. Therefore, the single-knot knitted fabric of the present invention can be preferably used for sportswear, casual wear, tights and other clothing materials with improved design.

Figure 1 is a schematic diagram of the knitting needle yarn loop surface and sinker yarn loop surface of the plain stitch.

Claims (10)

A knitted fabric characterized in that it is a single-comb knitted fabric with a plain stitch structure comprising inelastic fibers and elastic fibers, and the coefficient of dynamic friction when the sinker yarn loop surface of the knitted fabric rubs from the knitting start direction to the knitting end direction Below 0.500, the difference between the dynamic friction coefficient of the knitting needle yarn loop surface and the sinker yarn loop surface when rubbing from the knitting start direction to the knitting end direction and the dynamic friction coefficient when rubbing from the knitting end direction to the knitting start direction is both It is 0.13 or less, and the ratio of the dynamic friction coefficient of the knitting needle yarn loop surface to the dynamic friction coefficient of the sinker yarn loop surface when rubbing from the knitting start direction to the knitting end direction is 0.70-1.00. Such as the knitted fabric of claim 1, in which the standard deviation of the friction coefficient when the sinker yarn loop surface rubs from the knitting start direction to the knitting end direction is less than 0.500, and the sinker yarn loop surface rubs from the knitting start direction to the knitting end direction The difference between the standard deviation of the friction coefficient at the time and the standard deviation of the friction coefficient when rubbing from the knitting end direction to the knitting start direction is 0.200 or less. Such as the knitted fabric of claim 1 or 2, in which the standard deviation of the friction coefficient when the knitting needle yarn loop surface rubs from the knitting start direction to the knitting end direction and the standard deviation of the friction coefficient when rubbing from the knitting end direction to the knitting start direction The difference is 0.025 or less. The knitted fabric according to any one of claims 1 to 3, wherein the ratio of the water diffusion area of the needle loop surface of the above-mentioned knitted fabric to the water diffusion area of the sinker loop surface is 1.00 to 1.10. The knitted fabric of any one of claims 1 to 4, wherein the ratio of the cold contact value of the needle loop surface of the knitted fabric to the cold contact value of the sinker loop surface is 1.00 to 1.30. For example, the knitted fabric of any one of claims 1 to 5, wherein the number of weft turns is 70-150/inch, the number of warp turns is 50-80/inch, and the density index is 4000-12000. Such as the knitted fabric of any one of claims 1 to 6, wherein the longest inelastic fiber among the inelastic fibers contained in the knitted fabric has a yarn length of 160-240 mm/100 w. A garment comprising the knitted fabric according to any one of claims 1 to 7. Such as the garment of claim 8, wherein the knitting needle yarn loop surface of the above-mentioned knitted fabric is arranged on the skin side. A method for manufacturing a knitted fabric, which is the method for manufacturing a knitted fabric according to any one of claims 1 to 7, wherein the non-elastic fibers include yarns containing cellulose-based filament yarns and yarns containing synthetic fibers The two types of yarns are alternately arranged in the warp direction so that the yarn length of the synthetic fiber-containing yarn in the green fabric is 5 mm-20 mm longer than the yarn length of the cellulose-based filament yarn.

Images