JP2023133778A - knitted fabric - Google Patents

Abstract

To provide a knitted fabric excellent in stretchability, designability and antielectricity.SOLUTION: A knitted fabric is formed by using at least a first knitting yarn in which a non-conductive fiber is covered with a conductive fiber and a second knitting yarn formed only of the non-conductive fiber. In an area ratio, 15% or more of a surface of the first knitting yarn is covered with the conductive fiber having electric resistance value of 109 Ω/cm or less. When mass of the knitted fabric is 100 mass%, the content of the conductive fibers in the knitted fabric is 0.5 to 10 mass%, and the knitted fabric has a portion at which the first knitting yarn forms a stitch with the other first knitting yarn by skipping the second knitting yarn.SELECTED DRAWING: Figure 1

Description

The present invention relates to knitted fabrics, and particularly to flat knitted fabrics or circular knitted fabrics.

Synthetic fibers made from synthetic resins such as polyamide, polyester, and polyolefin can be obtained at low prices as raw materials, and have excellent mechanical properties and ease of handling, making them highly suitable for use in clothing such as uniforms. There is.

On the other hand, these fibers tend to be more statically charged due to friction than natural fibers, and can be used not only in areas where static charging is a problem, such as work clothes in clean rooms, but also in areas where you can feel it clinging to your body or attract dust. There are inherent problems caused by electrostatic charge, such as increased electrification.

For this reason, conductive fibers are known in which conductive particles such as metal particles and carbon black are kneaded into a synthetic resin and spun (Patent Document 1).

By the way, woven fabrics and knitted fabrics are broadly known as fabrics, and they are used depending on the usage situation. Knitted fabrics have excellent elasticity because the stitches tend to deform due to bending and stretching forces. Therefore, even when used as a uniform material, it expands and contracts according to the movements of the worker's body, making it possible to work comfortably. Additionally, there is a high degree of freedom in controlling air permeability.

Japanese Patent Application Publication No. 2004-44071

In conductive fibers containing conductive particles that are used as a countermeasure to the above-mentioned problems caused by charging of fibers, the conductive particles are generally colored, for example, carbon black is colored black. Fibers containing conductive particles can be colored, which can limit the design of clothing. Further, since it is necessary to use a certain amount of conductive particles to ensure a conductive path, synthetic fibers tend to become brittle due to the inclusion of conductive particles.

Therefore, in the technique described in Patent Document 1, an improvement is made by creating a composite fiber made of a resin containing conductive particles and a resin not containing conductive particles. However, the problem of coloring due to the use of conductive particles has not been resolved.

Therefore, an attempt may be made to reduce the impact on the design by replacing some of the non-conductive fibers with conductive fibers.

When this is applied to knitted fabrics, the conductivity differs depending on the direction in which the knitting yarn travels and the direction perpendicular to this, since stitches are formed by conductive fibers and stitches are formed by non-conductive fibers. It becomes.

Additionally, it is possible that anisotropy could be improved by manipulating the knitting structure to create loops where conductive fibers contact each other, but the stitches become deformed due to expansion and contraction of the knitted fabric caused by the wearer's movements. As a result, the contact between the conductive fibers frequently breaks down, so the improvement in anisotropy was not sufficient in the end.

There is room to improve this problem by using smaller, tighter stitches, but in that case, the elasticity of the knitted fabric would be sacrificed.

Therefore, an object of the present invention is to provide a knitted fabric that is excellent in stretchability, and also excellent in design and antistatic properties.

In order to solve the above problems, the present invention has a first knitted yarn in which conductive fibers are covered with non-conductive fibers, and a second knitted yarn made only of non-conductive fibers. A knitted fabric knitted using at least the above-mentioned first knitting yarn, in which 15% or more of the surface thereof is covered in terms of area ratio with conductive fibers having an electrical resistance value of 10 ⁹ Ω/cm or less. In the knitted fabric, the content of the conductive fiber is 0.5 to 10% by mass when the mass of the knitted fabric is 100% by mass, and the first knitted yarn has a content of 0.5 to 10% by mass. This is a knitted fabric in which at least a portion of the second knitting yarn is made non-knit and has stitches between it and the other first knitting yarn.

The knitted fabric of the present invention is preferably any knitted fabric selected from the group consisting of weft knitted fabrics and circular knitted fabrics, and can be a multiple knitted fabric with other knitted fabrics.

According to the present invention, it is possible to provide a knitted fabric that is excellent in stretchability, and also excellent in design and antistatic properties.

2 is a schematic diagram of the knitting structure employed in Example 1. FIG. 2 is a schematic diagram of a knitting structure adopted in Comparative Example 1. FIG.

The knitted fabric of the present invention is knitted using at least a first knitting yarn in which conductive fibers are covered with non-conductive fibers, and a second knitting yarn consisting only of non-conductive fibers. . The conductive fibers and non-conductive fibers that constitute the first knitted yarn and the non-conductive fibers that constitute the second knitted yarn are preferably multifilament yarns.

(first knitting yarn)
In the first knitted yarn, conductive fibers are covered with non-conductive fibers.

Because conductive fibers and non-conductive fibers can be processed by melt spinning or solution spinning, it is preferable to use synthetic resin as a component, and there are no particular restrictions on the synthetic resin that can be used, as long as it can be spun. However, synthetic resins such as polyolefins, polyamides, and polyesters can be mentioned. Among them, nylon 6, nylon 66, nylon 12, polyethylene terephthalate, polyethylene naphthalate, polytrimethylene terephthalate, polybutylene terephthalate, polyethylene, and polypropylene can be suitably used. These synthetic resins may be copolymers with other copolymerizable components, or may be mixtures of multiple types.

Further, the synthetic resins used for the conductive fibers and the non-conductive fibers may be the same type of resin or different types of resins. For example, when the same type of resin is used, it has excellent productivity and recyclability, and also has a good texture. In an embodiment in which polyester is used as the material, antistatic properties are enhanced by utilizing the hygroscopicity of polyamide, and a knitted fabric with excellent mechanical properties can be obtained by utilizing the high toughness of polyester.

Further, the conductive fiber used in the present invention has an electrical resistance value of 10 ⁹ Ω/cm or less (in this specification, 10 ^m means 1 × 10 ^m unless otherwise specified. , m is an integer), there are no restrictions on the method of imparting conductivity, but typically methods include imparting conductivity by incorporating conductive particles into a synthetic resin, Examples include a method of coating the surface of the fiber with a conductive component, but from the viewpoint of washing durability, it is preferable to use a method of imparting conductivity by incorporating conductive particles into the synthetic resin.

In the present invention, the electrical resistance value of the non-conductive fiber is the electrical resistance value when the synthetic resin used is made into fiber as it is, but generally, the electrical resistance value is 10 ¹² Ω/cm or more. be.

Further, the conductive fiber used in the present invention is preferably a composite fiber of a non-conductive resin and a resin containing conductive particles. Sea-island type, concentric circle type or core-sheath type composite fibers in which the contained resin part is covered with a non-conductive resin part, or a resin part containing conductive particles and a non-conductive resin part. Examples include multi-petaled or bimetallic composite fibers exposed on the surface. From the viewpoint of design, it is preferable to use an island-in-the-sea type, concentric type, or core-sheath type conjugate fiber. On the other hand, multi-petaloid or bimetallic composite fibers are advantageous in terms of antistatic properties, since fibers with low electrical resistance can be easily obtained.

In the conductive fiber used in the present invention, examples of the conductive particles include metal particles, crystalline or amorphous inorganic carbonaceous particles, and conductive particles coated on the surface of the synthetic resin fiber. Metals can be mentioned as the chemical components. When using metal, sputtering, vapor deposition, or plating can be used. Inorganic carbonaceous particles such as carbon black are preferably employed because they have good compatibility with synthetic resins, can provide sufficient electrical conductivity, and have little influence on spinnability.

The fineness of the conductive fiber used in the present invention is preferably 10 dtex to 90 dtex, and the single yarn fineness of the conductive fiber is preferably 1 dtex to 25 dtex. By using yarn with such a fineness or single yarn fineness, it is possible to ensure passability during yarn processing such as twisting with non-conductive fibers and covering, and to stretch the yarn by non-knitting over several courses. The loop can be knitted without yarn breakage, and antistatic properties and process passability can be maintained.

The fineness of the non-conductive fiber used in the first knitting yarn of the present invention is preferably 20 dtex to 180 dtex, and the single yarn fineness of the non-conductive fiber is preferably 0.3 dtex to 10 dtex. preferable. By using yarn with such fineness or single yarn fineness, the durability of the first knitting yarn composed of conductive fibers during wearing and washing can be maintained, and the initial deterioration of antistatic properties can be prevented. It becomes possible to prevent it.

In the first knitted yarn used in the present invention, the conductive fibers are covered with the non-conductive fibers, and the conductive fibers cover 15% of the surface area of the non-conductive fibers. The above is covered. By setting the coverage to 15% or more, good conductivity with small anisotropy can be maintained even if the stitches are deformed due to expansion and contraction caused by the operator's actions. The coverage is preferably 18% or more, more preferably 20% or more. Although there is no particular upper limit, it is preferably 40% or less in consideration of the balance between improvement in antistatic properties and design. There are no particular restrictions on the covering method, but at a higher level, it is possible to maintain good electrical conductivity with small anisotropy even if the stitches are deformed due to expansion and contraction due to the operator's movements. It is preferable that non-conductive fibers be double-covered with conductive fibers. Note that the coverage can be determined by the method described in the Examples section.

(Second knitting yarn)
The second knitting yarn consists only of non-conductive fibers. However, it is not excluded that a small amount of conductive fibers may be included as long as the object of the present invention is not impaired.

The description of the non-conductive fibers used in the second knitting yarn refers to the description of the non-conductive fibers used in the first knitting yarn, except for the following points.

The fineness of the non-conductive fiber used in the second knitting yarn of the present invention is preferably 50 dtex to 200 dtex, and the single yarn fineness of the non-conductive fiber is preferably 0.3 dtex to 10 dtex. preferable. By using yarns having such a fineness or single yarn fineness, it is possible to obtain a fabric with appropriate breathability, and a garment that is excellent in comfort when worn.

In addition, by using fibers with antibacterial and deodorizing functions as the second knitting yarn, it is possible to obtain fabrics that have functions tailored to the application in addition to being conductive, allowing you to create clothing tailored to your needs. can be provided.

(knitted fabric)
The knitted fabric of the present invention is a knitted fabric in which the first knitting yarn and the second knitting yarn are used. Although other knitting yarns may be used as long as they do not impede the purpose of the present invention, in order to simplify the explanation below, a knitted fabric using the first knitting yarn and the second knitting yarn will be taken as an example. I will explain.

The method for obtaining the knitted fabric is not particularly limited. A known method can be used for this purpose. The first knitting yarn may be introduced locally into the knitted fabric, but in order to maintain good antistatic properties of the knitted fabric as a whole, it is necessary to introduce it periodically, that is, n yarns to the knitting machine. It is preferable to introduce one first knitting yarn for every second knitting yarn (where n is a positive integer). This cycle may be changed as appropriate depending on the site where it is planned to be used.

In the knitted fabric of the present invention, at least a portion of the first knitting yarn is knitted so that the second knitting yarn is non-knitted and has stitches between it and other first knitting yarns. This will be explained using FIG. 1. That is, in the knitting shown in FIG. 1, the first knitting yarn skips the stitches of the five second knitting yarns and knits the stitches between adjacent first knitting yarns. By ensuring a physical connection between the adjacent first knitting yarns in this way, good conductivity with small anisotropy is maintained even if the stitches are deformed due to expansion and contraction caused by the operator's movements. be able to. As described above, this effect is even more remarkable when the first knitting yarn is made of non-conductive fibers double-covered with conductive fibers.

In the knitted fabric of the present invention, when the mass of the knitted fabric is 100% by mass, the content of the conductive fibers is 0.5% by mass to 10% by mass. When the amount is less than 0.5% by mass, sufficient antistatic properties cannot be obtained, and it is difficult to maintain conductive anisotropy when the stitches are deformed due to expansion and contraction due to operator's actions. From the viewpoint of eliminating the effects of operator movements at a high level, the lower limit of the content of the conductive fibers is preferably 1.0% by mass or more, and more preferably 1.5% by mass or more. Moreover, from the viewpoint of a balance between improvement in antistatic properties and designability, the upper limit of the content of the conductive fibers is preferably 4.0% by mass or less, and more preferably 3.0% by mass or less.

In the knitted fabric of the present invention, the first knitting yarn is knitted by repeating one or more types of patterns, and the area of the knitted fabric surrounded by the first knitting yarn per unit of the pattern is 72 mm ² or less. It is preferable that it is organized as follows. By knitting in this way, it is possible to obtain a knitted fabric which is good in terms of design and has higher antistatic properties.

The knitted fabric of the present invention is preferably one selected from the group consisting of weft knitted fabrics and circular knitted fabrics. Weft-knitted fabrics and circular-knitted fabrics have superior elasticity and drapability compared to woven fabrics and warp-knitted fabrics, and are comfortable to wear when made into clothing, and also have excellent workability. can.

In addition, when using one of the knitted fabrics selected from the group consisting of weft knitted fabrics and circular knitted fabrics, it is preferable to knit with a yarn length of 150 to 350 mm per 100 wales. , it is possible to create a knitted fabric with better elasticity and appropriate breathability, resulting in a garment with excellent ease of movement and comfort when worn.

The knitted fabric of the present invention can be a multiple knitted fabric of the knitted fabrics of the present invention, or a multiple knitted fabric of the knitted fabric of the present invention and another knitted fabric. In this case, the knitted fabric of the present invention constitutes at least one of the layers of the multiple knitted fabric. Of course, all the layers may be the knitted fabric of the present invention. A typical example of multiple knitted fabrics is double knitted fabrics. By using a multiple knitted fabric, even if the stitches are deformed due to expansion and contraction due to the movement of the worker, the movement of the position of the first knitting yarn is suppressed, and the conductive anisotropy can be maintained at a higher level. It is possible. Furthermore, it is possible to increase the degree of freedom in designing the texture, feel, and appearance, and the degree of freedom in terms of design can be increased. In the case of a multilayer knitted fabric, it is preferable that the layer made of the knitted fabric of the present invention be provided at a position that forms the outer surface when viewed from the wearer. This is because the high antistatic effect of the knitted fabric of the present invention can be fully utilized.

The knitted fabric of the present invention preferably has an elongation rate of 15% or more in the warp direction and 50% or more in the weft direction. By using such a knitted fabric, it is possible to improve comfort in clean rooms due to its antistatic properties and stretchability, and to increase the degree of freedom in uniform design, such as using parts of stretchable parts. In addition, in the case of a multiple knitted fabric, it is preferable that the elongation rate is that of a multiple knitted fabric.

The knitted fabric of the present invention preferably has air permeability of 100 cm ³ /(cm ² ·sec) or more. By using such a knitted fabric as work clothes, it becomes possible to work comfortably in a clean room where the temperature varies widely depending on the work area. In addition, in the case of a multiple knitted fabric, it is preferable that the fabric has air permeability as a multiple knitted fabric.

Moreover, the knitted fabric of the present invention can be preferably subjected to treatments such as dyeing that are applied to ordinary knitted fabrics, both as a knitted fabric and as work clothes.

(Work clothes)
The knitted fabric of the present invention is suitable for use in workwear such as uniforms. There are no particular restrictions on the method of processing knitted fabric into workwear. A known method can be used for this.

The workwear of the present invention has a surface resistance value of 10 ⁵ to 10 ⁹ measured in accordance with IEC61340-5-1 on the surface where the knitted fabric of the present invention is exposed. Such a surface resistance value provides sufficient antistatic properties for workwear, and can be applied to a variety of uses.

Hereinafter, the present invention will be explained in more detail by giving specific examples. However, the present invention should not be construed as being limited to such examples.

In this Example section, various physical properties and characteristics were measured or evaluated by the following methods. Note that the various physical properties and characteristics described in this specification can be measured or evaluated by these methods.

(Electrical resistance value of thread)
A thread was attached so that the length between the terminals of the voltmeter was 10 cm, a constant voltage was applied to both ends, and the resistance value (Ω/cm) was calculated by measuring the current. The measurement was performed three times and the arithmetic mean value was obtained.

(Fabric surface resistance value)
The surface resistance value was measured by the method described in IEC (International Electrotechnical Commission) 61340-5-1.

Note that clothing (blouson, polo shirt) sewn using the fabric was measured at an applied voltage of 100 V after being temperature-controlled and humidity-controlled for 24 hours in a temperature-controlled environment with a room temperature of 23° C. and a relative humidity of 25%.

(Elongation)
The elongation rate of the knitted fabric was measured by the D method of elongation rate (constant load method for knitted fabrics) of JIS L 1096 (2010.8.16.1). The measurement was performed three times and the arithmetic mean value was obtained.

The elongation rate of the woven fabric was measured according to JIS L 1096 (2010.8.16.1) elongation rate B method (constant load method for woven fabrics). The measurement was performed three times and the arithmetic mean value was obtained.

(Breathability)
Using knitted fabric or woven fabric, JIS L 1096 (2010.8.26) Breathability 8.26.1. Air permeability (cm ³ /(cm ² ·sec)) was measured by A (Frazier method). The measurement was performed five times, and the arithmetic mean value was obtained.

(coverage rate)
The coverage of the first knitted yarn was calculated from the fineness, specific gravity, yarn length, and number of yarn bundles of the conductive fibers and non-conductive fibers for the sampled first knitted yarn according to the formula below.

Coverage rate C (%)

here,
W ₁ : Yarn width in the cross-sectional direction of the conductive fiber knitting yarn (μm)

W ₂ : Circumference in the cross-sectional direction of the knitted yarn of non-conductive fibers (μm)

_De : Fineness of conductive fiber (dtex)
D _ne : Fineness of non-conductive fiber (dtex)
ρ _e : Specific gravity of conductive fiber (g/cm ² )
ρ _ne : Specific gravity of non-conductive fiber (g/cm ² )
L ₁ : Length of conductive fiber (μm)
L ₂ : Length of non-conductive fiber (μm)
N ₁ : Number of conductive fibers wound around the first knitting yarn The fineness of each fiber was calculated according to JIS L 1013 8.3.1A, and the specific gravity ρ was calculated according to JIS L 1013 8.17.

The length L ₁ of the conductive fibers and the length L ₂ of the non-conductive fibers of the first knitted yarn were measured five times and determined as the arithmetic average value.

(Example 1)
As the first knitting yarn, a composite yarn (covered with conductive fibers) is made by double covering a polyester multifilament yarn (84 dtex, 36 filaments) with a carbon-containing polyester multifilament yarn (22 dtex, 4 filaments, electrical resistance value 10 ⁹ Ω/cm). 34.6%), a polyester multifilament false twisted yarn (111 dtex, 36 filaments) was used as the second knitting yarn, and a 22 gauge circular knitting machine (manufactured by Fukuhara Seiki Seisakusho, M-LPJ4B) was used as the knitting machine. A circular knitted fabric was knitted using a total of 36 yarns. The supply ratio of each knitting yarn is 8.9% by mass of the first knitting yarn and 91.1% by mass of the second knitting yarn, and the content of the carbon-containing polyester multifilament yarn is 2.9% by mass in the main knitted fabric. It became. As shown in FIG. 1, the knitted fabric was knitted so that the first knitting yarn had stitches with other first knitting yarns on the surface.

(Example 2)
As the first knitting yarn, a composite yarn (coated with conductive fibers) is made by double covering a polyester multifilament yarn (167 dtex, 48 filaments) with a carbon-containing polyester multifilament yarn (22 dtex, 4 filaments, electrical resistance value 10 ⁹ Ω/cm). 24.4%), a polyester multifilament false twisted yarn (167 dtex, 48 filaments) was used as the second knitting yarn, and a 22 gauge circular knitting machine (manufactured by Fukuhara Seiki Seisakusho, M-LPJ4B) was used as the knitting machine. A circular knitted fabric was knitted using a total of 36 yarns. The supply ratio of each knitting yarn is 10.0% by mass of the first knitting yarn and 90.0% by mass of the second knitting yarn, and the content of the carbon-containing polyester multifilament yarn is 1.9% by mass in the main knitted fabric. It became. As in Example 1, the knitted fabric was knitted so that the first knitting yarn had stitches with other first knitting yarns on the surface, as shown in FIG.

(Comparative example 1)
Knitting was performed using the same first knitting yarn, second knitting yarn, knitting machine, total yarn supply number, supply ratio of each knitting yarn, and content of carbon-containing polyester multifilament yarn as in Example 1, as shown in FIG. Next, the first knitting yarn was knitted with other first knitting yarns in a border shape with no stitches.

(Comparative example 2)
The carbon-containing polyester multifilament yarn in Example 1 was replaced with a nylon multifilament yarn (22 dtex, 20 filaments, electrical resistance value 10 ¹⁶ Ω/cm), and the other items were as shown in FIG. 1 in the same manner as in Example 1. Organized.

(Comparative example 3)
As the first knitting yarn, a composite yarn (covered with conductive fibers) is made by single covering polyester multifilament yarn (84 dtex, 36 filaments) with carbon-containing polyester multifilament yarn (22 dtex, 4 filaments, electrical resistance value 10 ⁹ Ω/cm). A circular knitted fabric was knitted in the same manner as in Example 1 using the second knitting yarn, the knitting machine, and the total number of yarns fed. The supply ratio of each knitting yarn is 7.4% by mass of the first knitting yarn and 92.6% by mass of the second knitting yarn, and the content of the carbon-containing polyester multifilament yarn is 1.5% by mass in the main knitted fabric. It became. The knitted fabric was knitted as shown in FIG. 1 as in Example 1.

(Comparative example 4)
Polyethylene terephthalate multifilament yarn (167 dtex, 48 filaments) for the first warp, polyester filament yarn (167 dtex, 48 filaments) for the second warp, and carbon-containing polyester multifilament yarn (22 dtex, 4 filaments, electrical resistance value 10 ⁹ Ω) /cm) double-covered yarns (conductive fiber coverage 24.4%) are arranged alternately at a ratio of 21 to 1, and the first weft is made of the same polyethylene terephthalate multifilament as the first warp. The yarn and the second weft are made by alternately arranging the same polyester filament yarn as the second warp and a carbon-containing polyester multifilament yarn at a ratio of 17 to 1. A gray fabric with a twill structure was woven using a twill fabric (ZAX 9200, manufactured by J.D. Co., Ltd.). The ratio of each of the yarns is 93.3% by mass of polyethylene terephthalate multifilament (warp 1, weft 1) and 6.7% by mass of the same double covering yarn (warp 2, weft 2), and the carbon-containing polyester multifilament yarn The content was 1.4% by mass in the main knitted fabric.

(Comparative example 5)
Single covering polyester filament yarn (167 dtex, 48 filaments) with carbon-containing polyester multifilament yarn (22 dtex, 4 filaments, electrical resistance value 10 ⁶ Ω/cm) in the same first warp and second warp as in Comparative Example 4. The yarns (coverage rate of conductive fibers: 12.0%) were arranged alternately at a ratio of 19 to 1, respectively, and the same first weft and second weft as in Comparative Example 4 had a second warp and a second warp. The same polyester filament yarn is single-covered with carbon-containing polyester multifilament yarn, which are alternately arranged at a ratio of 17 to 1, and a twill structure fabric is created using an air jet loom (ZAX9200, manufactured by Tsudakoma Industries). Weaved gray fabric. The ratio of each of the yarns is 94.0% by mass of polyethylene terephthalate multifilament (warp 1, weft 1) and 6.0% by mass of the same single covering yarn (warp 2, weft 2), and the carbon-containing polyester multifilament yarn The content was 0.7% by mass in the main knitted fabric.

A summary of Examples and Comparative Examples is shown in Table 1.

Furthermore, it was confirmed that the knitted fabric of the example maintains its surface resistance value even when stretched, exhibits no anisotropy even when the stitches are deformed due to stretching, and exhibits high conductivity.

1 First knitting yarn 2 Second knitting yarn

Claims (12)

A knitted fabric knitted using at least a first knitted yarn in which conductive fibers are covered with non-conductive fibers and a second knitted yarn consisting only of non-conductive fibers, the fabric comprising: The first knitted yarn has 15% or more of its surface area covered with conductive fibers having an electrical resistance value of 10 ⁹ Ω/cm or less, and the knitted fabric has a mass of 100 Ω/cm. %, the content of the conductive fiber is 0.5 to 10% by mass, and at least a part of the first knitted yarn is made of a non-knitted second knitted yarn. A knitted fabric having a stitch between a first knitting yarn and a first knitting yarn. The knitted fabric according to claim 1, wherein the first knitting yarn is a non-conductive fiber double-covered with a conductive fiber. The knitted fabric according to claim 1 or 2, wherein the conductive fiber is a multifilament yarn containing inorganic carbonaceous particles. The first knitting yarn is knitted by repeating one or more types of patterns, and the area of the knitted fabric surrounded by the first knitting yarn per unit of the pattern is 72 mm ² or less. The knitted fabric according to any one of claims 1 to 3. The knitted fabric according to any one of claims 1 to 4, wherein the conductive fibers have a total fineness of 10 dtex to 90 dtex, and a single yarn fineness of the conductive fibers 1 dtex to 25 dtex. The knitted fabric according to any one of claims 1 to 5, wherein the knitted fabric is any one selected from the group consisting of a weft knitted fabric and a circular knitted fabric. The knitted fabric according to any one of claims 1 to 6, wherein the conductive fibers are knitted with a yarn length of 150 to 350 mm per 100 wales. A multiple knitted fabric, wherein at least one layer of the layers of the multiple knitted fabric is the knitted fabric according to any one of claims 1 to 7. 9. The multiple knitted fabric according to claim 8, wherein the knitted fabric according to any one of claims 1 to 7 is positioned on the outside as viewed from the wearer. The knitted fabric according to any one of claims 1 to 7 or the multilayer fabric according to any one of claims 8 and 9, characterized in that the elongation rate is 15% or more in the warp direction and 50% or more in the weft direction. knitted fabric. The knitted fabric according to any one of claims 1 to 7 or the multiple knitted fabric according to any one of claims 8 and 9, which has an air permeability of 100 cm ³ /(cm ² ·sec) or more. Workwear using the knitted fabric according to any one of claims 1 to 7 or the multiple knitted fabric according to any one of claims 8 and 9, wherein the surface of the workwear where the knitted fabric is exposed , work clothes characterized by having a surface resistance value of 10 ⁵ to 10 ⁹ Ω as measured in accordance with IEC61340-5-1.

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