JP4892910B2 - Conductive fiber and fiber product using the same - Google Patents

Description

  The present invention relates to a fiber excellent in conductivity and a fiber product using the same. More specifically, a conductive fiber excellent in both heat resistance and a small change in conductivity at the time of humidity change and a small change in conductivity in the longitudinal direction of the fiber, and a woven fabric using the fiber. Further, the present invention relates to a textile product such as a knitted fabric or a short fiber or a brush roller comprising the same.

  Conventionally and in the future, “conductivity” is one of the important functions in imparting functionality of synthetic fibers. For example, as a clothing fiber for clean rooms or as a fiber for blending carpets, or for applying static electricity in equipment, for clothing, industrial use There is a great demand in a wide range of fields. In recent years, the exposure of electromagnetic waves has increased in daily environments due to the spread of electronic information devices, especially wireless terminals such as mobile phones, and there are concerns about the impact on health. Increasingly, it is used as an electromagnetic shielding material.

  In order to solve the above-mentioned problems, many techniques for providing a conductive performance to the fiber itself by mixing a certain amount of a conductive substance inside the fiber have been proposed. For example, a technique using carbon black as a conductive substance has been proposed. (For example, refer to Patent Document 1). However, in this technology, it is necessary to add a large amount of carbon black in order to ensure sufficient conductivity, and in the case of synthetic fibers, there is always a concern that it will cause deterioration of the yarn-making property, and at the same time, the key to conductivity is Regarding the arrangement of the carbon black to be gripped, increasing the draw ratio in the drawing process after spinning tends to break the electrical connection between the particles and reduce the electrical conductivity. That is, it tends to change greatly due to minor changes in the manufacturing method. Therefore, there is always a potential danger that the conductivity of the manufactured product is not stable.

  In recent years, a technique using a substance generally called “carbon nanotube” having a very small diameter and a high aspect ratio has been proposed as an improvement in the technique of imparting conductivity using the conductive particles. . For example, a resin composition technique using this carbon nanotube (hereinafter sometimes referred to as “CNT”) has been proposed. In the proposal of these technologies, CNT was contained because CNT itself was excellent in conductivity by taking advantage of high mechanical properties such as CNT inherent high strength and high elastic modulus (for example, see Patent Documents 2 and 3). The excellent conductivity of fibers obtained from the conductive polymer composition is foreseen (for example, see Patent Document 4). However, these technical proposals only refer to obtaining fibers having excellent conductivity, and are considered to be impractical if the conductivity of the fibers is not controlled to a certain level, particularly for shielding electromagnetic waves. Design guidelines for conductive fibers for use in electronics applications such as materials, heating elements, and conductive brushes that are applied with high voltage, such as the composition of polymer mixtures, formulation of compositions, or fiber manufacturing methods are proposed. The practicality was limited.

By the way, the present applicants have already proposed the technique about the conductive fiber for the clothing use containing a small amount of CNT until now (for example, refer patent document 5). In this technology, a conductive fiber made by adding at most 3% by weight of CNTs having a structure of 2 to 5 layers with a small diameter has sufficient texture and color tone for clothing while maintaining conductivity. It is possible to achieve the production of fibers having the potential to be used as electronic materials such as conductive brushes. However, due to persistence in clothing applications, when trying to develop as an electronic material, a big problem that could not be detected by the conventional method for evaluating electrical conductivity occurred. That is, a large change in conductivity (spots) was observed in the longitudinal direction of the fiber, and the control of the conductivity could not be achieved to a high degree. In the case of a fiber material, an inappropriate technique has been adopted in which CNT is added during polymerization of a resin that does not improve dispersibility. That is, it turned out that the composition of the fiber and the manufacturing method thereof were heavily applied to clothing applications.
JP-A-50-109351 (Claims) JP-A-8-27279 (Claims) Japanese translation of PCT publication No. 2002-544356 (claims, paragraphs [0002], [0004]) JP-A-9-111135 (Claims, paragraph [0001]) JP-A-2005-54277 (Claims, Examples 4 to 6, Comparative Examples 4 to 6)

  An object of the present invention is to solve the above-mentioned problems of the prior art, have excellent heat resistance, have no conductivity humidity dependency, and have a small change in conductivity in the longitudinal direction of the fiber, and the conductive fiber It is to provide fiber-related products such as woven fabrics, knitted fabrics, nonwoven fabrics, short fibers, clothing, and actuators, and various products using these fiber-related products.

  The present invention has been intensively studied in order to obtain fibers having excellent electrical conductivity, and by using specific materials made of specific materials, the drawbacks of the conventional technology can be solved, and the conventional technology has achieved. It has been found that further merits that could not be obtained can be imparted, and the present invention has been achieved.

  That is, in order to achieve the above-described problems, the present invention employs the following configuration.

(1) The average resistivity having a conductive layer on at least a part of the fiber surface layer is 1.0 × 10 ^{6 to} 1.0 × 10 ¹² [Ω / cm], and the standard deviation of resistivity is 0.2 or less. a conductive fiber, Ri conductive layer Do and a polyester component and a carbon nanotube whose main repeating structural unit at least trimethylene terephthalate, conductive, characterized in der Rukoto made formed by melt composite spinning Sex fibers.

( 2 ) Ratio Y / X of the average resistivity X [Ω / cm] at a temperature of 23 ° C. and a humidity of 55% and the average resistivity Y [Ω / cm] at a temperature of 10 ° C. and a humidity of 15%. but wherein that lies in the range of 1 ≦ Y / X ≦ 5 ( 1) Symbol placement of the conductive fibers.

( 3 ) The conductive fiber as described in (1) or (2) above, wherein the fiber surface layer is a composite fiber covered with a conductive layer.

( 4 ) The conductive fiber according to any one of (1) to ( 3 ), wherein the content of the carbon nanotube in the conductive layer is 0.3 wt% or more and 5 wt% or less.

( 5 ) The conductive fiber according to any one of (1) to ( 4 ), wherein the fiber is a conductive short fiber having a fiber length of 0.05 to 150 mm.

( 6 ) A woven fabric comprising the conductive fiber according to any one of (1) to ( 5 ) at least in part.

( 7 ) The woven fabric according to (6) above, which is a pile weave.

( 8 ) A knitted fabric comprising the conductive fiber according to any one of (1) to ( 5 ) at least partially.

( 9 ) The knitted fabric according to ( 8 ), wherein the knitted fabric is a knitted fabric made of a back-knitted knitted fabric and / or a knitted fabric having pile-like fibers on the surface of the knitted fabric by raising.

( 10 ) A non-woven fabric comprising the conductive fiber according to any one of (1) to ( 5 ) described above at least in part.

( 11 ) A flocked body, wherein the conductive short fibers according to ( 5 ) are used at least in part and are adhered to a base and planted.

( 12 ) At least one kind of fabric selected from the woven fabric, knitted fabric, and nonwoven fabric described in any one of ( 6 ) to ( 10 ) is used as at least a part, and is bonded to a base. Fabric composite.

( 13 ) An actuator comprising at least part of the conductive fiber according to any one of (1) to ( 5 ).

( 14 ) A garment comprising at least part of the conductive fiber according to any one of (1) to ( 5 ).

( 15 ) At least one kind of fabric selected from the woven fabric, knitted fabric and non-woven fabric according to any one of ( 6 ) to ( 10 ) is used at least in part, and is adhered to a rod-like object. Brush roller to do.

( 16 ) A brush roller characterized in that the conductive short fiber according to ( 5 ) is used at least in part and is adhered to a rod-like object and planted.

( 17 ) A cleaning device comprising the brush roller according to any one of ( 15 ) and ( 16 ).

( 18 ) A charging device comprising the brush roller according to any one of ( 15 ) and ( 16 ).

( 19 ) A developing apparatus comprising the brush roller according to any one of ( 15 ) and ( 16 ).

( 20 ) A static eliminator comprising the brush roller according to any one of ( 15 ) and ( 16 ).

( 21 ) Using at least one device selected from the cleaning device described in ( 17 ), the charging device described in ( 18 ), the developing device described in ( 19 ), and the charge eliminating device described in ( 20 ). An electrophotographic apparatus characterized by comprising:

( 22 ) A heating element comprising the conductive fiber according to any one of (1) to ( 5 ) at least in part.

  In the conductive fiber of the present invention, a conductive layer containing carbon nanotubes (Carbon Nano Tube; hereinafter sometimes abbreviated as CNT) for having high conductivity is composed of a polyester component. Since the polyester component has almost no water absorption or hygroscopicity, the humidity dependency of conductivity is very small, and the polyester component has very stable conductivity regardless of humidity change in the use environment. Therefore, in applications that require high conductivity and conductivity stability in environmental changes, such as heating elements that are applied with voltage constantly or frequently as described below, and various brush rollers in electrophotographic apparatuses. It can be suitably employed.

  Moreover, the conductive fiber of this invention can employ | adopt the above-mentioned CNT, and can bear a conductive layer. CNTs are dispersed in the conductive layer and are generally oriented in the longitudinal direction of the fiber. The ratio of diameter to length (aspect ratio) is very large, and the CNTs are very close to or in contact with each other in the conductive layer. It becomes. Therefore, in the conductive layer, the conductive spots in the longitudinal direction of the fiber are always small.

Further, conductive fibers of the present invention, the conductive layer is, by all the fiber surface layer covering cormorants configuration, the magnitude of the standard deviation of resistivity, i.e. can be made very small as the conductive plaques Alternatively, it is possible to make the ratio of the average resistivity under the temperature and humidity conditions of medium temperature and medium humidity of 23 ° C. and 55% humidity and low temperature and low humidity of 10 ° C. and 15% humidity very low. As a result, the stability of the conductivity with respect to environmental changes is further enhanced and improved.

  The fiber in the present invention refers to a thin and long shape, and the length may be a long fiber (filament) generally referred to or a short fiber (staple). In the case of short fibers, the length may be set to a desired length depending on the use, but considering that it is used for spinning or electric flocking as described later, the length is preferably 0.05 to 150 mm. In particular, when used for electric flocking, the length is preferably 0.1 to 10 mm, and more preferably 0.2 to 5 mm.

  Further, the thickness of the conductive fiber of the present invention, that is, the single fiber diameter is not particularly limited, but the single fiber diameter is 1000 μm or less in that it can be used for various applications as described later. It is preferable that it is 0.1 to 100 μm, more preferably 0.5 to 50 μm, and when used in a brush roller described later, the cleaning performance is excellent when incorporated in a cleaning device. It is particularly preferably 0.5 to 25 μm. Here, the single fiber diameter can be measured using transmitted light in the range of about 100 to 1000 times with an optical microscope.

  In addition, the cross-sectional shape of the fiber is not particularly limited, and is preferably a round shape because it has uniform fiber properties, and the fiber is incorporated in the form of a short fiber, a woven fabric, a knitted fabric, or a nonwoven fabric with a brush roller, Depending on the application or purpose of use, for example, when anisotropy is given in the direction of bending of the fiber, or in the electrophotographic apparatus described later, good contact with the toner is obtained to achieve better cleaning performance. A flat type, polygonal shape, multi-leaf type, hollow type, or indefinite type is preferable.

  The conductive fiber of the present invention has a conductive layer composed of a polyester component and carbon nanotubes on at least a part of the fiber surface layer. Since the conductive layer is provided on at least a part of the fiber surface layer, the conductivity of the fiber itself can be controlled by the properties of the conductive layer, and a desired conductive performance can be imparted.

In order to have at least a portion to the conductive layer of the fibers surface layer, the conductive layer is extruded from the conductive layer other than the component and melting the polymer with different flow paths as the conductive layer are arranged in the fiber surface within the same die Can be formed by composite spinning. Conductive fibers of the present invention, in that capable of expressing stable conductivity is a composite fiber formed by composite spinning. Here, the proportion of the conductive layer in the composite fiber is preferably 5% by volume or more, more preferably 10% by volume or more, and 20% by volume or more in order to develop high conductivity. It is particularly preferred that The volume% is also applied to fibers in which the fiber surface layer described later is entirely covered with a conductive layer.

And since the electroconductivity of the electroconductive fiber of this invention is excellent in electroconductive stability, so that the area of the electroconductive layer in the fiber surface is large, it is preferable that the fiber surface layer is a fiber completely covered with the electroconductive layer. The fiber surface is covered with all conductive layers, when the inner layer portion is formed of components other than the conductive layer in the present invention, i.e., when a composite fiber comprising a composite component of the conductive layer and the inner layer portion For example, the inner layer portion may be disposed as a component responsible for the fiber physical properties of the conductive fiber of the present invention, for example, strength and elongation, by not containing a conductive agent, or within the scope not detracting from the spirit of the present invention. May be a layer having a different function containing a conductive agent other than carbon nanotubes, or a layer containing a functional component.

It is important that the conductive layer of the conductive fiber of the present invention is a polyester component having trimethylene terephthalate as a main repeating structural unit as one component. Since it is a polyester having trimethylene terephthalate as the main repeating structural unit , as described above, there is almost no water absorption or hygroscopicity. Therefore, when used for conductive fibers as one component of the conductive layer, the conductive humidity The dependence is very small, and it is highly preferable because it has a very stable conductivity without being influenced by the humidity change of the use environment.

Further, the polyester having trimethylene terephthalate as the main repeating structural unit used in the present invention may be copolymerized with other components within a range not detracting from the gist of the present invention, for example, a dicarboxylic acid compound is copolymerized. be able to. Examples of the dicarboxylic acid compound include terephthalic acid, isophthalic acid, naphthalenedicarboxylic acid, diphenyldicarboxylic acid, anthracene dicarboxylic acid, phenanthrene dicarboxylic acid, diphenyl ether dicarboxylic acid, diphenoxyethanedicarboxylic acid, diphenylethanedicarboxylic acid, adipic acid, sebacic acid, 1,4-cyclohexanedicarboxylic acid, 5-sodium sulfoisophthalic acid, 5-tetrabutylphosphonium isophthalic acid, azelaic acid, dodecanedioic acid, hexahydroterephthalic acid, aromatic, aliphatic and alicyclic dicarboxylic acids and their Derivatives, adducts, structural isomers and optical isomers such as alkyl, alkoxy, allyl, aryl, amino, imino, halide, etc. It one of the may be used alone or in a range that does not impair the gist of the invention may be used in combination of two or more.

  As the copolymer component, a diol compound can be copolymerized. Examples of the diol compound include ethylene glycol, propylene glycol, butylene glycol, pentanediol, hexanediol, 1,4-cyclohexanedimethanol, neopentyl glycol, Aromatic, aliphatic, alicyclic such as hydroquinone, resorcin, dihydroxybiphenyl, naphthalenediol, anthracenediol, phenanthrenediol, 2,2-bis (4-hydroxyphenyl) propane, 4,4'-dihydroxydiphenyl ether, bisphenol S List diol compounds and their alkyl, alkoxy, allyl, aryl, amino, imino, halide and other derivatives, adducts, structural isomers and optical isomers It can, may be used one kind of these diol compounds alone or in a range that does not impair the gist of the invention may be used in combination of two or more.

  Examples of the copolymer component include a compound having a hydroxyl group and a carboxylic acid in one compound, that is, a hydroxycarboxylic acid. Examples of the hydroxycarboxylic acid include lactic acid, 3-hydroxypropionate, 3-hydroxy Aromatic, aliphatic, and alicyclic diol compounds such as butyrate, 3-hydroxybutyrate valerate, hydroxybenzoic acid, hydroxynaphthoic acid, hydroxyanthracenecarboxylic acid, hydroxyphenanthrenecarboxylic acid, (hydroxyphenyl) vinylcarboxylic acid, and the like And derivatives such as alkyls, alkoxys, allyls, aryls, aminos, iminos, halides, adducts, structural isomers and optical isomers. One of these hydroxycarboxylic acids may be used alone. And again In a range that does not impair the gist of the invention may be used in combination of two or more.

In the present invention, among polyesters, the dispersibility of carbon nanotubes is more excellent, and as a polyester component, a polyester in which the main repeating structural unit is composed of trimethylene terephthalate (hereinafter, abbreviated as “PTT polyester” may be used). ) Is used . The PTT polyester is a polymer formed by an esterification reaction of terephthalic acid as a carboxylic acid and trimethylene glycol as an alcohol. The PTT polyester component does not greatly change the melt viscosity even when a large amount of carbon nanotubes are contained, and only a normal PTT polyester is used in a process for forming fibers, for example, melt spinning. Melt spinning can be achieved in the same way as melt spinning.

In the conductive layer of the present invention, one type of polyester having trimethylene terephthalate as the main repeating structural unit may be used alone, or a plurality of types of polymers may be used in combination as long as the gist of the invention is not impaired.

The conductive fiber of the present invention may be incorporated in an apparatus and used at a high temperature as described later as one of its uses. Therefore, since it is preferable that the shape change at high temperature is small, that is, excellent in heat resistance, the polyester component used in the conductive layer of the present invention preferably has a melting point of 150 ° C. or higher, and a melting point of 200 ° C. or higher. Is more preferable. However, if the melting point is too high, may promote decomposition of the polyester used in the present invention, because there are cases where deteriorate in melt spinning to be described later, the polyester in the present invention, especially the P TT polyester In this case, the melting point is particularly preferably 300 ° C. or lower. Here, the melting point is the H.V. The peak temperature measured by the method described in the item.

Moreover, in the conductive fiber of this invention, it is preferable that layers other than a conductive layer consist of a polymer which has a fiber formation ability as a main component. Examples of the polymer having fiber-forming ability include, for example, polyester polymers, polyamide polymers, polyimide polymers, polyolefin polymers, vinyl polymers such as polyacrylonitrile polymers synthesized by addition polymerization of vinyl groups, and fluorine. And polymers, cellulose polymers, silicone polymers, aromatic or aliphatic ketone polymers, elastomers such as natural rubber and synthetic rubber, and various other engineering plastics.

  More specifically, examples of the polymer having fiber-forming ability include various polyesters that can be used in the conductive layer.

  Specific examples of the polymer having the fiber-forming ability include, for example, a polyolefin polymer synthesized by a mechanism in which a monomer having a vinyl group is formed by an addition polymerization reaction such as radical polymerization, anionic polymerization, or cationic polymerization. And other vinyl polymers include polyethylene, polypropylene, polybutylene, polymethylpentene, polystyrene, polyacrylic acid, polymethacrylic acid, polymethyl methacrylate, polyacrylonitrile, polytetrafluoroethylene, polyvinylidene fluoride, polyvinylidene chloride, Polycyanide vinylidene, etc. are mentioned, but these may be a polymer by homopolymerization, such as polyethylene alone or polypropylene alone, or by conducting a polymerization reaction in the presence of a plurality of monomers. For example, when polymerizing in the presence of styrene and methyl methacrylate, a copolymerized polymer called poly (styrene-methacrylate) is produced, but in the range not impairing the gist of the invention, A polymer which is such a copolymer may be used.

  Or as a specific example of the polymer which has this fiber formation ability, the polyamide type polymer formed by reaction of carboxylic acid or carboxylic acid chloride, and an amine can be mentioned, for example, Specifically, nylon 6, nylon 7, Nylon 9, Nylon 11, Nylon 12, Nylon 6,6, Nylon 4,6, Nylon 6,9, Nylon 6,12, Nylon 5,7, Nylon 5,6, etc. are mentioned, and the gist of the present invention is impaired. As long as there is no other aromatic, aliphatic or alicyclic dicarboxylic acid and aromatic, aliphatic or alicyclic diamine component, or one compound such as aromatic, aliphatic or alicyclic is carboxylic acid and amino An aminocarboxylic acid compound having both groups may be used alone, or a polyamide-based polymer in which the third and fourth copolymerization components are copolymerized It may be.

  Other polymers having fiber-forming ability include polycarbonate polymers formed by transesterification of alcohol and carbonic acid derivatives, polyimide polymers formed by cyclization polycondensation of carboxylic acid anhydrides and diamines, and dicarboxylic acid esters. Polybenzimidazole polymers formed by the reaction of diamines with diamines, polysulfone polymers, polyether polymers, polyphenylene sulfide polymers, polyether ether ketone polymers, polyether ketone ketone polymers, aliphatic polyketones, etc. In addition to these polymers, polymers derived from natural polymers such as cellulosic polymers, chitin, chitosan and derivatives thereof are also included.

  As the polymer having fiber forming ability, polyester is preferable in that the interfacial adhesion to the conductive layer is good and peeling does not easily occur. For example, polyethylene terephthalate, polytrimethylene terephthalate, polybutylene terephthalate, polyethylene naphthalate and polycyclohexane. Examples thereof include dimethanol terephthalate and polylactic acid. A more preferable example is to use the same polyester as the conductive layer.

  In the layers other than the conductive layer of the conductive fiber of the present invention, a single polymer selected from the above-mentioned various polymers may be used alone, and a plurality of types of polymers may be used as long as the gist of the invention is not impaired. May be used in combination.

The carbon nanotube (CNT) contained in the conductive layer in the present invention is not particularly limited as long as it has conductivity, but as a preferable one, for example, the conductivity of the CNT is 5000 [ [Ω · cm] or less is preferable, and 1000 [Ω · cm] or less is more preferable. In addition, although the conductivity of the CNT is preferably low as a specific resistance value, a conductivity of 1.0 × 10 ⁻⁸ [Ω · cm] or more is preferably used as the conductivity characteristics of the CNT. Here, the specific resistance value is the value of Example E. below. It can be measured by the method of item.

  Further, since it is preferable not to impair the physical properties of the fiber when it is contained in the conductive layer of the conductive fiber of the present invention, and it is preferable not to aggregate, the diameter of the CNT is in the range of 0.1 to 100 nm on average. The thing of the range of 0.5-50 nm is more preferable. In addition, the ratio of CNT diameter D to length L (aspect ratio) L / D has an appropriate size so that the CNTs do not aggregate in the conductive layer or conductive fibers are formed. Has a preferable characteristic that the conductivity in the longitudinal direction of the fiber is substantially oriented and the electrical conductivity in the longitudinal direction of the fiber is uniform, so that L / D is preferably 10 to 10,000, and more preferably 15 to 5000. It is preferably 20 to 3000, particularly preferably. Here, the L / D is the value of Example J. below. It is measured by the method.

  The content of the CNT in the conductive layer is 0.3 wt% or more and 5 wt% because the fibers have high conductivity and the properties such as strength and elongation of the conductive fibers are stable. The content is preferably 0.5% by weight or more and particularly preferably 3% by weight or less.

  In the present invention, as a method of adding carbon nanotubes to the conductive layer, that is, a method of adding CNT to the polyester, specifically, a polyester is melted in an inert gas atmosphere, CNT is added, an extruder or a static Examples thereof include a melt kneading method using a kneader such as a mixer or a kneading element under normal pressure or reduced pressure. In this method, it is preferable to mix polyester and CNT at a desired ratio in advance at any stage before melting the polyester (sometimes referred to as “dry blend”). Since it is obtained by a body, it is more preferable to mix polyester as powder. In addition, when adding CNTs after melting the polyester, the CNTs may be transported to a side feeder provided in the extruder and mixed in the extruder.

In particular, for the extruder, a multi-axis extruder having one axis or two or more axes can be suitably used, but a multi-axis extruder having two or more axes in that CNT is kneaded uniformly in polyester without aggregation as much as possible. Is preferably adopted. At this time, with respect to the ratio l / w of the length (l) of the extruder involved in kneading the screw and the thickness (w) of the screw, it is preferable that l / w is 20 or more in terms of improving kneadability, It is more preferably 30 or more, and particularly preferably 40 or more. At this time, if the shear rate for melt kneading in the extruder is too small, CNT may not be uniformly dispersed in the polyester, and if it is too large, the shear heat generation of the polyester during melt kneading may occur. since there are cases where the polyester is degraded, it is better that appropriately determined, is preferably 150-6000 ^{[sec -1],} and more preferably from 300 to 5000 ^{[sec -1]} Accordingly, 500 to 4000 [ sec ⁻¹ ] is particularly preferable. Here, regarding the shear rate, the thickness of the extruder shaft (w [mm]), the gap between the extruder screw and the barrel portion in which the screw is housed (generally called “clearance”) (h [mm ]), And the number of revolutions per minute of the screw (n [number of revolutions / min]) is calculated as (shear rate [sec ⁻¹ ]) = 2πwn / 60 h.

  In particular, with regard to the static mixer described above, for example, an operation of dividing a flow path through which a mixture of melted polyester and CNT is divided into two or more and reunifying (one operation from this division to unification is performed once. The static mixer is preferably 5 or more, and more preferably 10 or more, from the standpoint of excellent kneadability. . Further, although it depends on the required length of the flow path, it is preferably 50 or less.

  As the polyester of the conductive layer which is preferable in the conductive fiber of the present invention or the polymer having the fiber forming ability of the layers other than the conductive layer described above, a polymer having a viscosity usually used for a synthetic fiber can be used. For example, if the polyester is polyethylene terephthalate, the intrinsic viscosity (IV) is preferably 0.4 to 1.5, and more preferably 0.5 to 1.3. Moreover, if it is polytrimethylene terephthalate, it is preferable that it is IV0.7-2.0, and it is more preferable that it is 0.8-1.8. Or if it is polybutylene terephthalate, it is preferable that it is IV0.6-1.5, and it is more preferable that it is 0.7-1.4. For example, if the polyamide polymer is nylon 6, the intrinsic viscosity [η] is preferably 1.9 to 3.0, and more preferably 2.1 to 2.8.

Further, the melt viscosity of the polyester component having trimethylene terephthalate as the main repeating structural unit used in the conductive layer of the present invention may be appropriately set depending on the amount of CNT added and the fiber configuration, and is determined by the melt spinning temperature of the polymer used. A polymer having a shear rate of 10 [sec ⁻¹ ] and a shear viscosity of 10 to 10,000 [Pa · sec] is usually used, and preferably 50 to 5,000 [Pa · sec]. Here, the melt viscosity is the same as in Example F. below. Use the value measured by the method in the section.

  The single yarn fineness of the conductive fiber of the present invention may be determined as appropriate according to the intended use, but as described later, for example, when used for clothing lining or other various clothing A fineness in the range of 0.01 to 5.0 dtex is preferable, and a fineness in the range of 0.1 to 3.0 dtex is more preferable considering that a homogeneous yarn can be obtained. For example, when used for a fiber brush incorporated in an electrophotographic apparatus as described later, a fineness in the range of 0.2 to 25.0 dtex is preferable, and a fineness in the range of 0.5 to 7.0 dtex is more preferable. . In particular, in color electrophotographic apparatuses that have been increasing in recent years, it may be preferable that the single yarn fineness is small in order to adapt to the colorant used (sometimes referred to as toner). The fineness is particularly preferably in the range of 0.5 to 2.5 dtex. Here, the single yarn fineness is determined by the following Example A.1. Use the value measured by the method in the section.

  Since the conductive fiber of the present invention may be exposed to high temperature depending on the environment at the time of use, the shrinkage rate when held in the atmosphere at 160 ° C. for 15 minutes is 20% or less in terms of excellent heat resistance. It is preferable that it is 10% or less. The lower the value, the more preferably up to 0%. Here, the shrinkage ratio is shown in Example G. below. Use the value measured by the method in the section.

  The conductive fiber of the present invention preferably has a residual elongation of 5 to 100%, and 5 to 50% in terms of small deformation during use in various applications such as apparel and for brush rollers described later. It is particularly preferred that Here, the residual elongation is measured according to Example B. below. Use the value measured by the method in the section.

  The conductive fiber of the present invention can resist instantaneous large stress in various applications, or has good scraping property when scraping a colorant for a brush roller incorporated in an electrophotographic apparatus described later. Therefore, the initial tensile elastic modulus is preferably 10 cN / dtex or more, particularly preferably 15 cN / dtex or more. The higher the value, the more preferably CNT is contained in the conductive layer, so that a maximum of 1000 cN / dtex or less is suitably produced. Here, the initial tensile elastic modulus is the value of Example B. below. Use the value measured by the method in the section.

  The conductive fiber of the present invention preferably has a breaking strength of 1.0 cN / dtex or more in order to stably satisfy the shape or characteristics for various uses such as apparel and for brush rollers described later. More preferably, it is 5 cN / dtex or more, and even more preferably 2.0 cN / dtex or more. Normally, polyesters containing carbon black at a high concentration to produce highly conductive fibers have very low breaking strength (less than 1.0 cN / dtex) when the fibers are formed. However, it was difficult to increase the breaking strength even when using the above. However, even if the present inventors have a high concentration of carbon nanotubes in the polyester, the CNTs are uniformly dispersed in the conductive layer, and when the fibers are formed, they are generally oriented in the longitudinal direction of the fibers. Rather, it has been found that the breaking strength can be specifically increased. The higher the breaking strength is, the better. However, in consideration of productivity, a product having 15.0 cN / dtex or less is preferably produced. Here, the breaking strength was measured according to Example B. below. Use the value measured by the method in the section.

It is important that the conductive fibers of the present invention have an average resistivity of 1.0 × 10 ^{6 to} 1.0 × 10 ¹² [Ω / cm]. The range of the average resistivity is a desired conductivity required for various applications as described later, such as clothing, actuators, brush rollers, heating elements, or various products incorporating them. Very preferably employed. The smaller the average resistivity, the higher the conductivity, that is, the easier it is to conduct electricity, so depending on the application, it is necessary to have a low average resistivity, but the amount of CNT that can be contained in the conductive layer to the maximum The lower limit of the average resistivity is 1.0 × 10 ⁶ [Ω / cm] in view of the use in which the obtained conductive fiber is used. In particular, when the conductive fiber of the present invention is used for a brush roller incorporated in an electrophotographic apparatus as will be described later, the average resistivity is in the range of 1.0 × 10 ^{8 to} 1.0 × 10 ¹² [Ω / cm]. It is preferable that conductive fibers having an average resistivity in a range as described later are employed according to the characteristics of the member and apparatus used for the brush roller. Also, the heating element has a desired size after becoming a woven or knitted fabric, but may be appropriately set according to the target heating value, but 1.0 × 10 ^{6 to} 1.0 × 10 ⁸ [Ω / Cm] is preferable. Here, the average resistivity is shown in Example C.1 below. Use the value measured by the method in the section.

Moreover, since the conductive fiber of this invention should ensure the stable electroconductivity by various uses which are mentioned later, the magnitude | size of the standard deviation of a resistivity is 0.2 or less. The smaller the value, the more stable conductivity is ensured, and it is particularly preferable that the value is 0.1 or less. Most preferably, the standard deviation is not 0 but is close to 0 as much as possible. Conventionally, when the average resistivity of the conductive fiber is in the range of 1.0 × 10 ^{9 to} 1.0 × 10 ¹² [Ω / cm], the standard deviation of the resistivity is 0.2 or less. It has been very difficult to use conventional conductive carbon black or other conductive agents. However, the present inventors have found for the first time that this can be achieved with a polyester prepared under a certain prescription and in which CNTs are uniformly dispersed. Here, the standard deviation of the resistivity is the following example C.I. Use the value measured by the method in the section.

Furthermore, the conductive fiber of the present invention is a conductive fiber even in a temperature and humidity change, specifically in a wet climate such as in the rainy season, or in a dry climate such as in winter. It is preferable that the performance of the above does not change at all. Therefore, the average resistivity X (= Ω _X / cm) at medium temperature and medium humidity (temperature 23 ° C. humidity 55%) and the average resistivity Y at low temperature and low humidity (temperature 10 ° C. humidity 15%). The ratio Y / X to (= Ω _Y / cm) is preferably in the range of 1 ≦ Y / X ≦ 5, more preferably in the range of 1 ≦ Y / X ≦ 4, and 1 ≦ Y / A range of X ≦ 2 is particularly preferable. Here, the ratio of the average resistivity is shown in Example D. below. Use the value measured by the method in the section.

The conductive fiber of the present invention has a specific resistance value of 10 ⁶ to 10 ⁹ [Ω · cm] as a short fiber, in that the conductive fiber can be processed more efficiently particularly when it is converted into a short fiber and subjected to electric flocking. It is preferable that it is 10 ⁷ to 10 ⁸ [Ω · cm]. And it is preferable to treat with a conductive preparation agent or the like in order to make these short fibers having a preferable specific resistance value. Examples of the conductive preparation agent include an aqueous solvent or an organic solvent mixed with silica-based particles, and the particle size of the silica-based particles at that time is usually 1 nm to 200 μm. A particle size of 3 nm to 100 μm is preferred. Here, the specific resistance value is the value of Example E. below. Use the value measured by the method in the section.

  The conductive fiber of the present invention is a matting agent, a flame retardant, a lubricant, an antioxidant, an ultraviolet absorber, an infrared absorber, a crystal nucleating agent, a fluorescent whitening agent, and a terminal group blocking as long as the gist of the invention is not impaired. A small amount of an additive such as an agent may be retained. Moreover, when the conductive fiber of this invention turns into a composite fiber as above-mentioned, these additives may be hold | maintained in any layer other than a conductive layer and / or a conductive layer. Furthermore, in this invention, you may contain another electrically conductive agent in the range which does not impair the meaning and other required fiber physical properties of this invention. Here, other conductive materials include metals having a specific resistance value of 10,000 Ω · cm or less and 0.01 nΩ · cm or more, conductive carbon black (conductive ketjen black, furnace black, acetylene black, etc.) or metal oxides. Particles can be employed.

  Hereinafter, the preferable manufacturing method of the electroconductive fiber of this invention is illustrated.

Conductive fibers of the present invention are possible and easily allowed to contain in a state where the carbon nanotubes are arranged in fiber維中conductive layer is a high concentration and uniformly dispersed, also precisely controllable fiber shape Therefore, it is preferably produced by melt spinning. And obtain fibers in the composite spinning to Turkey to have a conductive layer on at least a portion of the fiber維表layer.

  The melt-discharged fiber is cooled to a glass transition temperature (Tg) or lower and is not processed or after a treatment agent is attached, and then at a take-up speed of 100 to 10,000 m / min, preferably 4000 m / min or less, more preferably 3000 m. / Min or less, even more preferably 2500 m / min or less, particularly preferably 2000 m / min or less. Taking productivity into consideration, the take-up is performed at a take-up speed of 100 m / min or more, preferably 500 m / min or more. Here, the number of bundles of fibers ejected from the cap hole (the number of fibers in the yarn) may be appropriately selected according to the intended use or application, and 3000 even in the state of one monofilament. Although multifilaments composed of the following plural yarns may be used, 4 to 500 are preferable, and 10 to 150 are particularly preferable in that a fiber having stable physical properties can be obtained and suitably used for various applications. Further, the treatment agent to be adhered can be appropriately used according to the use of the fiber, and although a water-containing or non-water-containing treatment agent can be adopted here, the photosensitive agent of the electrophotographic apparatus using the conductive fiber of the present invention. In order to prevent the body from being deteriorated, it is preferable that no compound which causes deterioration of the photoreceptor is contained.

  After taking-up, without winding or once winding, the polymer constituting the fiber is heated to a glass transition temperature (Tg) + 100 ° C. or lower, more preferably glass transition temperature Tg−20 ° C. to Tg + 80 ° C. To a temperature at which the residual elongation of the drawn yarn becomes 5 to 60%, and preferably at a magnification at which the residual elongation of the drawn yarn becomes 5 to 50%. Here, after stretching once (that is, after finishing the first stage stretching), the second stage stretching may be performed at a magnification of 1 to 2 times.

  After stretching, the fiber is preferably heat-treated at a temperature not lower than the final stretching temperature and not higher than the melting point (Tm). By performing a heat treatment at a high temperature after stretching, the fiber can be made more excellent in heat resistance. Here, the Tg and Tm are the same as those in Example H. below. Use the value measured by the method in the section. Moreover, it is preferable that the fiber is subjected to a relaxation treatment of 15% or less during the process from the heat treatment to the winding up as a product. By performing the relaxation treatment, the conductivity of the obtained fiber in the fiber longitudinal direction can be further improved.

  The stretching method or the heat treatment method after stretching is not particularly limited, and a contact-type bath using a heated heater such as a heated pin-like object, a roller-like object, or a plate-like object, or a heated liquid, or Although it is possible to employ non-contact heating media using heated gas, heated steam, electromagnetic waves, etc., contact type heaters such as heated pin-like objects, roller-like objects, plate-like objects, and heated liquids A contact type bath using a metal is preferable because the apparatus is simple and heating efficiency is high, and a heated roller is particularly preferable.

  The conductive fibers of the present invention may be subjected to false twisting when used for woven fabrics or knitted fabrics, and for various apparel applications. In the false twisting process, the fiber is heated without heating the drawn yarn or undrawn yarn or with a heated pin-like product, roller-like product, plate-like product, non-contact type heater, etc. It is false twisted with a belt-like material. The drawn false twisted fiber is preferably wound as it is or after being heat set, although not particularly limited. Further, the conductive fiber of the present invention may be subjected to twist processing instead of the false twist processing.

  The conductive fiber of the present invention can be made into a woven fabric that is used at least in part or in whole in accordance with the use or shape that can be used. Here, for example, single woven fabrics such as broad, voile, lone, gingham, tropical, taffeta, shantung, desin and other plain weaves, denim, surge, gabardine and other twill weaves, satin, doskin and other satin weaves, baskets, panama, mats and hops Nanako weaves such as sac and oxford, woven fabrics such as grosgrain, ottoman, and hair cord, steep slashes such as French twill, herringbone, broken twill, gradual syllabary, Yamagata syllabary, tearing syllabary, flying syllabary, curving swash Sentences, ornamental text, irregular vermillion, stacked vermillion, expanded vermillion, day-night vermillion, honeycombs, hacks, pear fabrics, Niagara, etc., and two woven fabrics combined into one woven fabric. Double woven fabrics such as piques and blister weaves, weft double weaves such as Bedford cords, weft double weaves such as air-woven fabrics and bag weaves In addition, examples of pile fabrics include weft pile weaves such as benji and corten, warp pile weaves such as towels, velvet and velvet, etc. Examples include fabrics such as woven fabrics. Pile fabrics are particularly preferable for use in brush roller fabrics described later. The conductive fiber of the present invention used for producing the woven fabric is not particularly limited with respect to the form of fibers such as raw yarn, twisted yarn, false twisted yarn, long fiber (filament), or short fiber (staple). There is no.

  In addition, the conductive fiber of the present invention can be made into a knitted fabric that is used at least in part or in whole according to the use or shape that can be used. Here, flat knitting such as tengu and single, rib knitting such as rubber knitting and milling, pearl knitting such as links, kanoko, pear fabric, accordion knitting, small pattern, lace knitting, fleece knitting, single knitting knitting , Weft knitting such as ripple, Milan rib, double picket, etc. or warp knitting such as tricot, russell, miranese, etc. Alternatively, a knitted fabric that has been subjected to raising treatment for protruding pile-like fibers on the surface of the knitted fabric is preferable. The conductive fibers of the present invention used for producing the knitted fabric are not particularly limited with respect to the form of fibers such as raw yarn, twisted yarn, false twisted yarn, long fiber (filament), or short fiber (staple). Absent.

  In addition, the conductive fiber of the present invention can be made into a non-woven fabric that is used at least in part or in whole in accordance with the use or shape that can be used. Here, examples of the nonwoven fabric include those formed by bonding or adhesion methods such as a chemical bond method, a thermal bond method, a needle punch method, a water jet punch (spun lace) method, a stitch bond method, and a felt method. The conductive fiber of the present invention used for preparing the fiber is not particularly limited with respect to the form of fibers such as raw yarn, twisted yarn, false twisted yarn, long fiber (filament) or short fiber (staple).

  The above-mentioned woven fabric or knitted fabric in which the conductive fiber of the present invention is used at least in part may be subjected to processing such as conventional scouring, dyeing, heat setting, etc. Physical processing such as pressing, embossing press, compact processing, flexible processing, heat setting, bonding processing, laminating processing, coating processing, antifouling processing, water repellent processing, antistatic processing, flameproofing processing, insect control processing, hygiene Chemical processing such as processing, foam resin processing, and other application processing such as microwave application, ultrasonic application, far-infrared application, ultraviolet application, and low-temperature plasma application may be performed.

  The above-mentioned woven fabric, knitted fabric, or non-woven fabric in which the conductive fiber of the present invention is used at least in part includes the conductive fiber of the present invention and synthetic fibers, semi-synthetic fibers, natural fibers, etc. that are different from the present invention. For example, at least one kind of fiber selected from cellulose fiber, wool, silk, stretch fiber, and acetate fiber may be used. Specifically, examples of the cellulose fiber include natural fibers such as cotton and hemp, or copper ammonia rayon, rayon, polynosic and the like, and the content of the conductive fiber of the present invention mixed with these cellulose fibers. Although there is no restriction | limiting in particular, 0.1-50 weight% is preferable in order to make use of the texture of a cellulose fiber, moisture absorption, water absorption, antistatic property, etc., and to make use of the electroconductivity of the fiber of this invention. In addition, the wool and silk used for the mixture can be used as they are, and the content of the conductive fiber of the present invention mixed with the wool or silk is about the texture of the wool, warmth, bulkiness, In order to make use of silk texture and squeak noise and to make use of the conductivity of the fiber of the present invention, 0.1 to 50% by weight is preferable. The stretch fibers used for mixing are not particularly limited, and polyester-based elastic yarns typified by dry-spun or melt-spun polyurethane fibers, polybutylene terephthalate fibers, and polytetramethylene glycol copolymerized polybutylene terephthalate fibers. In a mixed fabric using stretch fibers, the conductive fiber content of the present invention is preferably about 0.1 to 50% by weight. The acetate fiber used for mixing is not particularly limited, and may be diacetate fiber or triacetate fiber. The content of the conductive fiber of the present invention to be mixed with these acetate fibers is the texture of the acetate fiber and the sharpness. In order to make use of gloss and make use of the conductivity of the fiber of the present invention, 0.1 to 50% by weight is preferable.

  About these various mixed woven fabrics, knitted fabrics, or nonwoven fabrics, the form of the conductive fibers of the present invention and the mixing method are not particularly limited, and known methods can be used. For example, mixed methods include woven fabrics such as union woven fabrics and reversible fabrics used for warp or weft yarns, knitted fabrics such as tricot and russell, and other knitting, doubling, and entanglement may be performed.

  The woven fabric, knitted fabric or non-woven fabric using the conductive fiber of the present invention at least partly or entirely may be dyed, including the above-mentioned mixed ones. For example, in the case of knitting, post-weaving or non-woven fabric, the web It is preferable to take the steps of scouring, pre-setting, dyeing, and final setting by a conventional method after forming the film by the above-described joining or bonding method. Further, when the conductive fiber of the present invention is not only a conductive layer but also a component other than the conductive layer is a polyester polymer and forms a part of the fiber surface layer, it is usually used after scouring and before dyeing. Alkali weight loss treatment may be performed by the method. The scouring is preferably performed in a temperature range of 40 to 98 ° C. In particular, in the case of mixed use with stretch fibers, it is more preferable to scour the fabric while relaxing because it improves elasticity. One or both of the heat sets before and after dyeing can be omitted, but it is preferable to carry out both in order to improve the form stability and dyeability of the woven fabric, knitted fabric or nonwoven fabric. The heat setting temperature is 120 to 190 ° C., preferably 140 to 180 ° C., and the heat setting time is 10 seconds to 5 minutes, preferably 20 seconds to 3 minutes.

  The conductive fiber of the present invention is very useful as a fiber itself because it is excellent in conductivity, and the fiber can be used as it is. However, as described above, the length of the fiber is 0.05 to 150 mm as one form of the fiber. Used as a short fiber. The short fiber is formed by cutting the filament into a single yarn or a tow in which a plurality of yarns are bundled. Particularly, the short fiber having a length of 0.1 to 10 mm is, for example, By a variety of methods such as electric flocking and spraying, it is possible to obtain a flocked body that is bonded to the base and planted.

  More than 50% of the fibers planted by the electric flocking process are bonded in a generally upright state from 10 degrees to the base (that is, 90 degrees). Here, within the range which does not impair the meaning of invention, in addition to the short fiber which consists of the conductive fiber of this invention, the short fiber used when making this flocked body from other fibers which are not the conductive fiber of this invention These short fibers may be mixed and planted. The flocked body is formed by adhering a short fiber to a base and planting, and when adhering, for example, an acrylic, urethane, or ester adhesive may be used for adhesion. preferable. Here, the thickness of the adhesive layer is preferably 1 to 500 μm, and a single layer or, if necessary, a plurality of types of adhesives may be mixed or divided into a plurality of layers. Further, the base to be planted is not particularly limited, and may be appropriately selected according to the device for incorporating the flocked body and the adhesive used, but synthetic resin, natural resin, synthetic fiber, natural fiber, wood, Films, sheets, paper, plates, fabrics, etc. made of minerals or metals can be suitably used, or even if directly implanted on the base of a metal processed body, synthetic or natural resin processed body or molded body which is a member for various applications itself good. In particular, in order to increase the affinity with the adhesive, a sheet made of a synthetic or natural resin or metal subjected to a hydrophilic treatment is preferable. And if this base | substrate is the raw material which forms the front and back, such as the said film, sheet | seat, paper, board, cloth, according to a use or the objective, it can plant on both surfaces of the surface and a back surface. The flocked body can be used as a conductive brush roller because of its conductivity, for example, as its usage or application.

  The above-mentioned woven fabric, knitted fabric or non-woven fabric using the conductive fiber of the present invention as at least a part thereof can be a fabric composite bonded to a base. In this case, if the fabric is pile weave or yarn ends on the surface of the fabric by pile weaving or treatment, and if the knitted fabric is pile-like fiber raising or raising the pile or yarn ends are on the knitted surface In the brush roller mentioned later, a function may be improved more and a thing is preferable. When adhering, it is preferable to adhere using, for example, an acrylic, urethane, or ester adhesive. Here, the thickness of the adhesive layer is preferably 1 to 500 μm, and a single layer or, if necessary, a plurality of types of adhesives may be mixed or divided into a plurality of layers. Further, the substrate to be bonded is not particularly limited, and may be appropriately selected according to the apparatus incorporating the fabric composite and the adhesive used, but synthetic resin, natural resin, synthetic fiber, natural fiber, wood, Films, sheets, paper, boards, fabrics, etc. made of minerals or metals can be suitably used, or they can be directly bonded to the base of a metal processed body, synthetic or natural resin processed body or molded body, which is a member for various applications. good. In particular, in order to increase the affinity with the adhesive, a sheet made of a synthetic or natural resin or metal subjected to a hydrophilic treatment is preferable. If the substrate is a material forming the front and back surfaces, such as the film, sheet, paper, board, or fabric, the fabric is formed by adhering the woven fabric, knitted fabric, or nonwoven fabric to both the front and back surfaces according to the purpose or purpose. Can be a composite. The fabric composite can be used as a conductive brush roller because of its electrical conductivity, for example, because of its electrical conductivity.

  Since the conductive fiber of the present invention has a stable conductivity and can be controlled to a desired resistivity, a weak current can flow when a certain voltage is applied. By utilizing this, it is possible to form an actuator that is controlled and driven by a signal sent with a weak current. Specifically, the actuator can transmit a weak electric current as a signal, for example, as a human muscle, so that it can be used in an actuator circuit.

  The conductive fiber of the present invention can be used as a garment by using at least a part or all of the conductive fiber. For example, when it is made into clothing, it is more comfortable to wear, such as being able to suppress the generation of static electricity in winter or when dry due to its excellent conductivity, or it is difficult to get dust close to it, so when manufacturing surgical clothing or semiconductors It can form dust-proof clothing such as work clothes. In that case, it is preferable to use the conductive fiber of the present invention as warp and / or weft every few. Also, as a secondary effect, the conductive layer contains carbon nanotubes to improve the thermal conductivity of the fiber, and it is a contact-cooling material that instantly takes heat away during clothing or enters the warm room from the cold outside in winter. It can be used as a warming material that warms your body immediately.

  At least one kind of fabric selected from the woven fabric, knitted fabric and non-woven fabric of the present invention can be used for at least a part or all of the fabric to adhere to a rod-like object to form a brush roller.

At least one type of fabric selected from woven fabrics, knitted fabrics, and nonwoven fabrics used here is cut by the length (that is, the winding width) that is functionally required for the rod-shaped object when bonded to the rod-shaped object. May be wound around and glued in one round, or it may be wound in a spiral shape around a rod-like object that is cut into a width that is a fraction of one-tenth of the length of the rod-like object. May be. The adhesive used here may be appropriately employed depending on the intended use or purpose, and various types such as acrylic, ester, or urethane can be employed, and conductive carbon black, metal, etc., if necessary. Or a magnetic control agent such as a metal such as iron, nickel, cobalt, molybdenum, an oxide of these metals, or a mixture thereof. Here, the thickness of the adhesive layer is preferably 1 to 500 μm, and a single layer or, if necessary, a plurality of types of adhesives may be mixed or divided into a plurality of layers. Furthermore, the conductive treatment agent or conductive sheet having a specific resistance of 10 ² to 10 ¹⁰ [Ω · cm] on the bonding surface before the at least one kind of fabric selected from the woven fabric, the knitted fabric, and the nonwoven fabric is bonded. A material such as a conductive film may be laminated.

The short fibers according to the present invention can be used for at least a part or all of them to be adhered to a rod-like object and planted to form a brush roller. The short fiber used here may be sprayed with a short fiber by electric gas or may be subjected to electric flocking when it is planted by adhering to a rod-like object, but it is generally upright on the surface of the rod-like object. Is preferably obtained by electric flocking. At this time, 50% or more of the short fibers are bonded in a generally upright state from 10 degrees to the vertical (that is, 90 degrees) on the surface of the rod-like object. Here, as long as the spirit of the invention is not impaired, the short fibers used are mixed with the short fibers made of the conductive fibers of the present invention and the short fibers made of other fibers that are not the conductive fibers of the present invention. May be installed. In addition, the adhesive for planting by adhesion is not particularly limited, and for example, an acrylic, urethane, or ester adhesive is selected and used depending on the application or purpose. The thickness of the agent layer is preferably 1 to 500 μm, and a single layer or, if necessary, a plurality of types of adhesives may be mixed or divided into a plurality of layers. In addition, the specific resistance value of the brush roller itself of the brush roller formed by using the short fiber of the present invention for at least a part and adhering to a rod-like object is 10 ² to 10 ¹¹ [Ω · cm]. preferable.

  The main material used for the core of the rod-shaped object described above may be any material suitable for the intended use or purpose, and may be selected from metals, synthetic resins, natural resins, wood, minerals, etc., alone or in combination. However, when used as a member to be incorporated in an electrophotographic apparatus described later, it is preferably made mainly of metal. Further, when the rod-like object is a metal, an intermediate layer covers at least a part of the metal or a necessary part of the metal, and at least one kind of fabric selected from the woven fabric, the knitted fabric, and the nonwoven fabric is formed thereon. It is preferable that the fibers are bonded or the short fibers are bonded and planted. The material used as the intermediate layer mainly provides cushioning properties to the rod-like object, or bears auxiliary elasticity / rigidity when it cannot be achieved only by the elasticity / rigidity of the brush-like fibers, which will be described later. For example, the toner removal performance in the cleaning device or the toner application performance in the developing device is significantly improved. Although not particularly limited, for example, a urethane material, an elastomer material, a rubber material, or an ethylene-vinyl alcohol material is preferably used for the intermediate layer. And it is preferable that the thickness of this intermediate | middle layer is 0.05-10 mm, Furthermore, the above-mentioned electroconductivity control agent or magnetic control agent may be added as needed.

At least a part of at least one kind of fabric selected from the woven fabric, knitted fabric and non-woven fabric of the present invention is used, and a brush roller formed by adhering to a rod-like object or at least a part of the short fiber is used to adhere to a rod-like object. The brush roller thus implanted is preferably used as a member of a cleaning device incorporated in an electrophotographic apparatus, for example, due to the conductivity of the fiber of the present invention used. Here, the average resistivity of the conductive fibers of the brush roller used in the cleaning device is preferably in the range of 1.0 × 10 ¹⁰ [Ω / cm] to 1.0 × 10 ¹² [Ω / cm]. And depending on the mechanism of the cleaning device. While the brush roller is rotating in the cleaning device, electricity is applied if necessary, while unnecessary materials (for example, residual colorant that has not been transferred in the electrophotographic device or fibers detached from the paper) However, when the conductive fiber of the present invention is used, it is a fiber having stable conductive performance even when there is a change in temperature and humidity as described above. The performance is remarkably excellent. In addition, as described above, the brush roller is used in a cleaning device, as described above, in addition to the brush roller being in direct contact with the photosensitive member for cleaning, the member for cleaning the photosensitive member (as described above, also in the case of a brush roller). As a brush roller for cleaning the cleaning device itself, or as a brush roller for transferring the collected unnecessary toner to another place. Used. In the cleaning device of the present invention, one brush roller may be used or a plurality of two or more brush rollers may be used depending on the purpose and the cleaning mechanism.

At least a part of at least one kind of fabric selected from the woven fabric, knitted fabric and non-woven fabric of the present invention is used, and a brush roller formed by adhering to a rod-like object or at least a part of the short fiber is used to adhere to a rod-like object. The brush roller thus implanted is derived from the conductivity of the fiber of the present invention used, and is preferably incorporated and used in a charging device that can be used in an electrophotographic apparatus described later. The average resistivity of the conductive fibers of the brush roller incorporated in the charging device is preferably 1.0 × 10 ⁸ [Ω / cm] or more and 1.0 × 10 ¹⁰ [Ω / cm] or less. It is done. The performance of the charging device using the brush roller depends on the conductive performance of the brush roller, i.e., the performance of the conductive fiber, but the environment within the electrophotographic apparatus as well as being able to uniformly charge the photosensitive body, which is the original purpose. It is required that the conductivity of the brush roller does not change at all with respect to changes, that is, changes in temperature and humidity that gradually change during operation of the electrophotographic apparatus, or changes in temperature and humidity due to the season. On the other hand, the conductive fiber of the present invention does not change the conductivity at all with respect to the above-mentioned environmental change, so that the photosensitive member is less likely to be charged unevenness and becomes a very excellent charging device. In addition, even when there is residual toner on the surface of the photoreceptor of the electrophotographic apparatus due to insufficient cleaning, the brush roller is brush-like and can also serve as a cleaning roller. In the case of downsizing the electrophotographic apparatus, it is possible to save space as a cleaning device and a charging device without separately installing the cleaning device and the charging device. It is also possible to do so, and that is also much better. In the charging device of the present invention, one or a plurality of brush rollers may be used depending on the purpose and mechanism.

  At least a part of at least one kind of fabric selected from the woven fabric, knitted fabric and non-woven fabric of the present invention is used, and a brush roller formed by adhering to a rod-like object or at least a part of the short fiber is used to adhere to a rod-like object. The brush roller thus implanted is derived from the conductivity of the fiber of the present invention used, and is preferably incorporated and used in a developing device. In the later-described electrophotographic apparatus, the developing apparatus visualizes a latent image drawn by a laser on the surface of the photosensitive member uniformly charged by the charging apparatus. Since there is no change in the resistivity of the brush roller even with respect to environmental changes, the toner for visualization is uniformly supplied to the photoreceptor and visualized, and the resulting developed product or printed product is contaminated or has print spots. Because it is very beautiful with little or no, it is much better.

Using at least a part of at least one kind of fabric selected from the woven fabric, knitted fabric and nonwoven fabric of the present invention, and using at least a part of a brush roller bonded to a rod-like object or the short fiber, and adhering to the rod-like object. The brush roller thus implanted is derived from the conductivity of the fiber of the present invention used, and is preferably incorporated and used in a static eliminator that can be used in an electrophotographic apparatus described later. The average resistivity of the conductive fibers of the brush roller comprising the conductive fibers of the present invention incorporated in the static eliminator is 1.0 × 10 ⁶ [Ω / cm] or more and 1.0 × 10 ⁸ [Ω / cm] or less. Those in the range are preferably used. In particular, when used in an electrophotographic apparatus described later, the conductive fibers of the brush roller exhibit a stable and free surface neutralizing effect, and the cleaning effect of the cleaning device usually disposed after the static eliminating device is more effective. In addition to being able to be increased, when the electrophotographic apparatus is downsized, it can be incorporated as a static eliminator and a cleaning apparatus by using the brush roller, which is remarkably excellent.

  An electrophotographic apparatus using at least one device selected from the cleaning device, charging device, developing device, and static eliminator of the present invention, specifically a laser beam monochrome printer, a laser beam color printer, a monochrome copying machine, Examples include color copiers, monochrome or color facsimiles, multifunctional multifunction machines, word processors, etc., but development or printing is performed by a mechanism that draws a latent image with a laser on a charged photoreceptor and visualizes it with toner. Since the apparatus uses the conductive fiber of the present invention as described above, it has stable cleaning, charging, developing, and static elimination performance regardless of environmental changes in the electrophotographic apparatus, particularly temperature and humidity. The printed or developed product is not only monochrome but also a color that uses multiple types of toner and uses a large amount of toner. It if is especially very beautiful, more increase the driving speed of the electrophotographic apparatus, i.e. it is possible to increase the printing or developing speed per unit time (number of sheets). Further, as described above, the electrophotographic apparatus of the present invention using the conductive fiber of the present invention is very preferable because it can achieve further miniaturization, space saving, and power saving.

  As described above, the woven fabric using the conductive fiber of the present invention at least in part uses a fiber having very excellent conductivity, so that not only when the fiber is used for the entire woven fabric, but also a part of the woven fabric. Even if this fiber is used for the fabric, it becomes a fabric having excellent conductive performance or ability to release electricity (in other words, electrostatic performance), so that it can be used for various materials such as curtains, curtains, and human body static electricity. It can be used for automobile seats such as automobiles, railways, and aircraft, wall materials and rugs, futons, blankets, and bedclothes.

  The knitted fabric using at least a part of the conductive fiber of the present invention becomes a knitted fabric having conductive performance or electrostatic performance in the same manner as the above-mentioned woven fabric, so that it is used for various materials, for example, rugs such as building wall materials and carpets, It can be used for vehicle seats such as automobiles and railroad aircraft, wall materials, rug vehicle seats or bedding such as futons, blankets and mattresses.

  Since the nonwoven fabric using the conductive fiber of the present invention for at least a part becomes a nonwoven fabric having electrical conductivity or electrostatic performance similar to the above-described woven fabric or knitted fabric, the same material as that for the above-mentioned woven fabric or knitted fabric is used. In addition to being usable, it can be widely used as a material requiring a thickness, for example, a partition material, a package, a cushion or the like, which is not suitable for the generation of static electricity, and a room peripheral member.

  Further, as yet another use of the short fibers made of the conductive fibers of the present invention, woven fabrics, in particular pile woven fabrics, knitted fabrics or non-woven fabrics, these can be used to be planted on a base to form a flocked body or a fabric composite. Can do. Since these flocks or fabric composites are excellent in electrical conductivity or antistatic properties, they can be used as various interior materials with excellent touch.

  Since the conductive fiber of the present invention or the short fiber made of the conductive fiber is excellent in conductivity, it can be used as a part of an actuator circuit such as an artificial muscle that reacts with weak electricity that performs various operations. Is possible. In addition to having high conductivity, the conductive fibers of the present invention have very small conductive spots in the longitudinal direction of the fiber, so that when used as part of these circuits, the conductive fibers have extremely excellent performance. .

  The apparel using at least a part of the conductive fiber of the present invention uses a fiber having excellent conductivity, and therefore can suppress the generation of static electricity during clothing and escape from the body. It is useful when used as a dust proof clothing because it does not attract dust because it is hard to generate static electricity because it is hard to generate static electricity, and it dissipates heat outside the body because carbon nanotubes have excellent thermal conductivity. For example, sports clothing (golf wear, gateball, baseball, etc.) that requires these functions, such as touch-sensitive clothing that can take heat from outside the body immediately into a cold body Tennis, soccer table tennis, volleyball, basketball, rugby, American football, hockey, athletics, triathlon, speed Skating, ice uniforms, such as hockey) and infants, women, the elderly of clothing, Other than outdoor clothing (shoes, bags, supporters, socks, climbing clothes) can be suitably used for such.

  The heating element comprising the conductive fibers of the present invention uses conductive fibers having excellent conductivity and very small conductive spots. A good heating element is obtained and excellent. In addition, the heating element will be used at low temperature and low humidity mainly in winter, but the fiber of the present invention does not depend on temperature or humidity or is very small, so it exhibits stable conductive performance even in winter. And a very excellent heating element.

  The brush roller formed by adhering at least a part of at least one kind of fabric selected from the woven fabric, the knitted fabric, and the nonwoven fabric of the present invention uses an electrically conductive fiber at least in part, and thus has an electrical effect. It is excellent because it has a function of efficiently removing unnecessary substances or imparting necessary substances by using them.

  Since the brush roller using the short fiber of the present invention uses at least a part of the conductive fiber, it is necessary to efficiently remove or require unnecessary materials by using the electrical action as described above. In addition to having a function of imparting a substance to be added, it is excellent because the fiber planting density of the brush roller or the removal performance or imparting performance of the brush roller can be easily controlled according to the purpose by controlling the fiber length of the short fiber. ing. In particular, when the rod-shaped object to be implanted is mainly made of metal, the conductivity (specific resistance value) of the brush roller itself can be controlled by controlling the conductivity of the conductive fiber of the present invention. If the object consists of a metal and an intermediate layer covering at least a part of the metal, cushioning can be imparted by controlling the material and thickness of the intermediate layer, so the removal performance or imparting performance of the brush roller itself Can be remarkably improved.

  The cleaning device using the brush roller of the present invention is very excellent in removal performance when the brush roller itself rotates to remove unnecessary substances and clean them. For example, in the electrophotographic apparatus to be described later, when the toner can be electrically removed, the conductive performance of the brush roller does not fluctuate even when there is an environmental change in the electrophotographic apparatus, particularly a humidity change. It has excellent removal performance at all times. In addition, the brush roller of the present invention is a member that performs a cleaning activity in addition to directly cleaning a target substance in the cleaning device, for example, an electrophotographic device described later in contact with a photosensitive member. It is also useful as a member for removing unnecessary materials and cleaning the cleaning device itself, resulting in a high-performance cleaning device.

  The charging device using the brush roller of the present invention is used by controlling the conductivity (specific resistance value) of the brush roller itself. For example, the photoconductor is uniformly charged by an electrophotographic apparatus described later. In addition to being able to charge the photoreceptor uniformly when used as a brush roller, the specific resistance value of the brush roller itself changes even when the environment in the electrophotographic apparatus changes, for example, when the electrophotographic apparatus is operating or when the humidity changes due to seasonal changes. No change or very small change, so that charging spots on the photoconductor hardly appear, which is very good. In addition, even when there is residual toner due to insufficient cleaning on the photoreceptor of the electrophotographic apparatus, the brush roller can also function as a cleaning roller, so that contamination during development or printing can be avoided. In addition to being excellent with little or no, when the electrophotographic apparatus is downsized, the cleaning device and the charging device can be applied only by the brush roller as a combined use, that is, as a cleaning device and a charging device without separately installing the cleaning device and the charging device. Because it is very good.

  The developing device using the brush roller of the present invention is used by making full use of the conductivity of the brush roller itself in the same way as the effect of the charging device described above. When the toner is attached to the drawn electrostatic latent image, the toner is uniformly distributed because there is little or almost no unevenness of the specific resistance value of the brush roller itself when the environment changes such as humidity as described above. The developed or printed product obtained by being supplied to the surface and visualized is very beautiful with little or no contamination.

  The static eliminator using the brush roller according to the present invention controls the content of carbon nanotubes contained in the fiber to reduce the conductivity (specific resistance value) of the brush roller, thereby providing a very excellent static eliminator. It is useful because it becomes a brush roller having performance. In particular, when used in an electrophotographic apparatus described later, since the brush roller made of countless hairs (fibers) has a stable and uniform neutralizing effect, the cleaning apparatus disposed after the neutralizing apparatus In addition to being able to enhance the cleaning effect, when the electrophotographic apparatus is downsized, it can be incorporated as a static eliminator and cleaning apparatus by using the brush roller.

  An electrophotographic apparatus using at least one device selected from the cleaning device, the charging device, the developing device, and the static eliminator of the present invention, specifically, a laser beam printer, a copying machine, a facsimile, and a multifunctional multifunction device. In addition, as described above, a device that develops or prints a latent image with a laser on a charged photoconductor such as a word processor and visualizes it with toner is a stable cleaning and printing system regardless of environmental changes in the electrophotographic apparatus. Since it has charging / developing / static charge performance, the obtained print or developed product is very beautiful. In addition, by optimizing the fiber length of the brush roller or the content of carbon nanotubes contained, it has more stable cleaning / electricity resistance / development / static elimination performance, so that the driving speed of the electrophotographic apparatus is further increased, that is, the unit It is possible to increase the printing or developing speed (number of sheets) per hour, which is very preferable.

  EXAMPLES Hereinafter, the present invention will be described specifically and in detail with reference to examples, but the present invention is not limited only to these examples. In addition, the physical-property value in an Example was measured with the following method.

A. Measurement of Fineness [dtex] and Single Yarn Fineness [dtex] The fiber (multifilament) is crushed by 100 m in length, and the weight (g) of the crushed fiber is measured and multiplied by 100. The average value of three measurements obtained in the same manner was defined as the fineness of the fiber. Regarding the single yarn fineness, a value obtained by dividing the fineness by the number of single fibers constituting the filament was defined as a single yarn fineness [dtex].

B. Measurement of initial tensile elastic modulus, residual elongation, and breaking strength of fiber Tensilon tensile tester (TENSIRON UCT-100) manufactured by Orientec Co., Ltd., if it is an undrawn yarn, the initial sample length is 50 mm, and the tensile speed is 400 mm / min. In the case of a drawn yarn, the strength and the residual elongation were measured at an initial sample length of 200 mm and a tensile speed of 200 mm / min, respectively, and the average value measured five times was used as each measured value.

C. Calculation of Average Resistivity [Ω / cm] and Standard Deviation of Resistivity A sample to be measured at medium temperature and medium humidity (temperature 23 ° C. and humidity 55%) was measured after being kept in the atmosphere for at least 1 hour. When running a yarn with a pair of mirror rollers consisting of a yarn feeding roller and a take-up roller, the running yarn comes into contact with a probe comprising two rod terminals connected to an insulation resistance meter SM8220 made by Toa DKK between the rollers. In this equipment, the thickness of the rod is 5mm, the distance of the yarn contacted between the rod terminals is 2.0cm, the applied voltage is 100V, the yarn feeding speed is 100cm / min, the yarn tension between the rollers is 0.5g / dtex, the insulation resistance system The resistance value was measured for a length of 200 cm at a sampling rate of 0.2 seconds, and the value obtained by dividing the average resistance value [Ω] of the obtained value by the distance (2 cm) of the thread contacting between the rod terminals The average resistivity was [Ω / cm]. A value obtained by dividing the value of the standard deviation calculated at the same time by the average resistivity was defined as the standard deviation in the present invention.

D. Ratio of average resistivity between medium temperature and medium humidity and low temperature and low humidity (temperature 10 ° C, humidity 15%) The measurement method of the item is adopted, and C.I. The average resistivity was obtained by measurement in the same manner as for the term, and the ratio (Y / X) of the obtained average resistivity X and Y was obtained.

E. Measuring method of specific resistance value The measurement was carried out after holding the sample to be measured at the medium temperature and humidity for at least 1 hour in the atmosphere. When the object to be measured was a fiber having a length of 100 mm or more, the fiber bundle was made into a bundle of 1000 dtex, cut to a length of 50 mm, and an electrode was attached to the end face for measurement. When the object to be measured is a fibrous or powdery material having a length of less than 100 mm, 50 kg is applied to an insulator box-shaped container having electrodes 10 cm long, 2 cm wide and 1 cm deep and having electrodes on both end faces. It was measured after being filled and sealed at a pressure of / cm ² and converted into a specific resistance value [Ω · cm] per unit volume. For the gut-shaped one, two terminals of the tester are arbitrarily selected using a tester for a gut having a diameter D (with a diameter in the range of 0.2 to 0.3 cm) and a length of 12 cm in one measurement. The resistance value R [Ω] was measured at an interval of 10 cm, and the resistance value R [Ω] was measured, and the specific resistance value of the gut was obtained from the formula of (specific resistance value) = R × (D / 2) ² × π / 10. . The specific resistance value was measured once for each of five different guts, and the average value of the five times was taken as the specific resistance value of the gut.

F. Measurement of Melt Viscosity Using a Capillograph 1B manufactured by Toyo Seiki Co., Ltd., under a nitrogen atmosphere, the barrel diameter was 9.55 mm, the nozzle length was 10 mm, the nozzle inner diameter was 1 mm, and the shear rate was 10 sec ⁻¹ . The measurement temperature was measured at the melt spinning temperature of each polymer (unless otherwise specified, 290 ° C for PET and 260 ° C for PTT). And the average value of the value measured 5 times was made into the measured value of melt viscosity. Regarding measurement time, 5 measurements were completed within 30 minutes in order to prevent deterioration of the sample. For the high shear rate, the aforementioned shear rate was measured as 1000 sec- ¹ .

G. Calculation of shrinkage rate (dry heat shrinkage) for 15 minutes in the atmosphere at 160 ° C. One clip is attached to a bundle obtained by scooping five rings of 1 m drawn yarn, and the length L1 of the bundle is measured (at this time, about 500 mm). Length). Next, it is slowly lowered into the atmosphere at 160 ° C. and left to stand for 15 minutes. After 15 minutes, it is taken out and air-dried for 1 hour or more. After air drying, the length L2 of the bundle is measured again. The shrinkage rate (%) is calculated by the following formula.

Shrinkage rate (%) = (L1−L2) ÷ L1 × 100
H. Measurement of glass transition point (Tg) and melting point (Tm) Using a differential scanning calorimeter (DSC-2) manufactured by PerkinElmer Co., Ltd., the sample was measured at a heating rate of 16 ° C./min. The definitions of Tm and Tg are as follows. After observing the endothermic peak temperature (Tm ₁ ) observed once measured at a heating rate of 16 ° C./min, the temperature is kept at a temperature of about (Tm ₁ +20) ° C. for 5 minutes. Rapidly cool to room temperature (hold for 5 minutes by combining the quenching time and room temperature holding time) and measure the endothermic peak temperature as Tg as a stepwise baseline deviation when measured again at 16 ° C / min. The endothermic peak temperature observed as the melting temperature of the crystal was defined as Tm.

I. Measurement of fiber length of short fibers Short fibers having a length of 20 mm or more are subjected to a load of 0.1 g / dtex using a vernier caliper, and short fibers having a length of less than 20 mm are measured using NIPPON KOGAKU K. The length of 50 short fibers was measured 20 times using K SHADOW GRAPH Model 6 and the average value was defined as the fiber length.

J. et al. Measurement of diameter D of carbon nanotube and ratio of L to D (aspect ratio) L / D A block in which CNT is embedded in fiber epoxy resin as it is (hereinafter referred to as CNT block), or CNT present in the fiber If there is, a block (hereinafter referred to as a fiber block) in which the fiber is embedded in an epoxy resin is dyed with a ruthenium oxide solution, and if it is a CNT block, an arbitrary place is cut as it is with a CNT block. Ultra-thin sections are cut near the fiber center in the direction parallel to the fiber axis direction in the case of fiber blocks, and ultra-thin sections of single fiber longitudinal sections are produced, respectively, and a transmission electron microscope (TEM) observation device (Hitachi, Ltd.) (Manufactured by H-7100FA type) at an acceleration voltage of 75 kV and observation at an arbitrary magnification of 100,000 to 500,000 times. Obtained as a digitized photograph in the observation, select 100 arbitrary CNTs on the photograph, measure the diameter D and length L of the CNTs by analyzing the image in WinROOF made by Mitani Corporation, D and L / D were calculated to determine the average value of 100, and the average value was used as the average diameter D and aspect ratio L / D of the CNT.

Reference Example 1 (Synthesis of polyethylene terephthalate and preparation of pellets)
To a low polymer obtained by ordinary esterification reaction from 166 parts by weight of terephthalic acid and 75 parts by weight of ethylene glycol, 0.03 part by weight of 85% phosphoric acid aqueous solution as a coloring inhibitor and antimony trioxide as a polycondensation catalyst 0.06 parts by weight, 0.06 parts by weight of cobalt acetate tetrahydrate as a toning agent was added to carry out a polycondensation reaction, and the normally used IV 0.66, melt viscosity 131 [Pa · sec] (measuring temperature 290 ° C. 10 sec ⁻¹ ) polyethylene terephthalate (hereinafter referred to as PET) pellets were obtained.

Reference Example 2 (Polytrimethylene terephthalate synthesis and pellet preparation)
Dimethyl terephthalate 130 parts (6.7 mole parts), 1,3-propanediol 114 parts (15 mole parts), calcium acetate monohydrate 0.24 parts (0.014 mole parts), lithium acetate dihydrate To a low polymer obtained by transesterifying 0.1 parts (0.01 mole parts) of salt and distilling off methanol, 0.065 parts of trimethyl phosphate and 0.134 parts of titanium tetrabutoxide were added. The polycondensation reaction was performed while distilling off 1,3-propanediol, and a chip-shaped prepolymer was obtained. The obtained prepolymer was further subjected to solid phase polymerization at 220 ° C. under a nitrogen stream, and polytrimethylene terephthalate (hereinafter referred to as IV 1.15, melt viscosity 393 [Pa · second] (measurement temperature 260 ° C., 10 sec ⁻¹ )) PTT) pellets were obtained.

Reference Example 3 (Preparation of conductive layer component added with carbon nanotube (CNT), manufacture of conductive fiber)
The PET pellets obtained in Reference Example 1 were once dried as a powdery material of about 1 mm in vacuum at 150 ° C. for 10 hours, and kneading of carbon nanotubes synthesized by a vapor phase growth method with an average diameter of 20 nm and L / D = 131 was completed. The resin composition of PET and CNT obtained later is dry blended so that the CNT is 2% by weight, and a biaxial extruder (screw diameter 37 mm, screw L / D = 45, screw rotation speed 300 rpm, clearance 0.5 mm) ) And melt-kneaded at 280 ° C. to obtain a PET-CNT resin composition (PET-CNT).
Using this PET-CNT, an extruder type melt spinning machine equipped with a biaxial extruder (screw diameter 20 mm, screw L / D = 50, screw rotation speed 150 rpm, clearance 0.5 mm), with a spinning temperature of 290 ° C. and a pore size of 0 .3 mm, round hole-shaped mouthpiece with 24 holes and a filter with a fine 20 μm filter layer are melt-spun and water-based so that the effective amount is 1 wt%. After the treatment agent (active ingredient concentration of 20% by weight) was adhered, an undrawn yarn having a total fineness of 350 dtex and a filament number of 24 was obtained without any problem at a take-up speed of 1000 m / min. There was no problem in spinnability, and no breakage was observed even during continuous spinning for 5 hours.
When the obtained multifilament is stretched, the yarn feeding speed of the yarn feeding roller is 100 m / min, the first roller is 85 ° C. and the yarn feeding speed is 100 m / min, and the second roller is 140 ° C. and the yarn feeding speed is 250 m / min. The third roller was subjected to drawing and heat treatment at room temperature at a yarn feeding speed of 245 m / min, and then the yarn was wound after being cooled to Tg or less of the polyester with a cold roller. There was no problem such as winding of a single yarn around the roller during drawing, and the drawability was excellent. Table 1 shows the yarn physical properties.

Comparative Example 1 (Production of conductive fiber using carbon black)
In Reference Example 3 , instead of CNTs, dry blending is performed so that the conductive furnace carbon black (hereinafter referred to as FCB) having an average diameter of 25 nm is 15% by weight in the resin composition of PET and FCB obtained after completion of kneading. A resin composition of PET and FCB (PET-FCB) was obtained in the same manner as in Example 1 except that it was prepared.
When melt spinning was carried out using this PET-FCB by the same method as in Reference Example 3 , it was difficult to melt and spin for 5 minutes or more continuously due to frequent yarn breakage. And when the undrawn yarn obtained somehow was drawn by the same drawing method as in Example 1, the single yarn was frequently wound around the roller. When the conductivity of the drawn yarn obtained was measured, the conductivity (standard deviation) in the longitudinal direction of the fiber was 1.15, which was very large.

Reference Examples 4 to 7 and Comparative Examples 2 and 3
In Reference Example 3 , the same discharge rate (same volume per unit time) in the spinning process under the same spinning conditions as in Reference Example 3 , except that the carbon nanotube content in the conductive layer was changed as shown in Table 1. The conductive fiber was obtained in the same manner as in Example 1 except for the other spinning conditions. When the carbon nanotube content was 0.1% by weight (Comparative Example 2), the required conductivity (resistivity) was high, and the conductive spots (standard deviation) were large. Further, as the content increases, the physical properties of the resulting fiber are improved in electrical conductivity, but other physical properties tend to decrease. In an excessively high concentration (7% by weight, Comparative Example 3), melt spinning is performed. I can't pick up. Table 1 shows the yarn physical properties.

Reference Example 8
The PTT pellet obtained in Reference Example 2 is once dried in a powder form of about 1 mm, vacuum dried at 150 ° C. for 10 hours, and then the same CNT as in Reference Example 3 is obtained in the resin composition of PTT and CNT obtained after completion of kneading. Using the same biaxial extruder as in Reference Example 3 , the mixture was melt blended at 255 ° C. to obtain a PTT / CNT resin composition (PTT-CNT).
In this using a PTT-CNT Reference Example 3 and the same extruder type melt spinning machine, the same spinneret as in Reference Example 3 at a spinning temperature of 260 ° C., performs filtering, the melt-spun using a treating agent, of 1000 m / min take-up speed Thus, an undrawn yarn having a total fineness of 295 dtex and 24 filaments was obtained without any problem. There was no problem in spinnability, and no breakage was observed even during continuous spinning for 5 hours.
When the obtained multifilament is stretched, the yarn feeding speed of the yarn feeding roller is 100 m / min, the first roller is 70 ° C. and the yarn feeding speed is 100 m / min, and the second roller is 120 ° C. and the yarn feeding speed is 250 m / min. The third roller was subjected to drawing and heat treatment at room temperature at a yarn feeding speed of 245 m / min, and then the yarn was wound after being cooled to Tg or less of the polyester with a cold roller. There was no problem such as winding of a single yarn around the roller during drawing, and the drawability was excellent. Table 1 shows the yarn physical properties.

Examples 1-3
Extruder type compound melt spinning machine equipped with two twin-screw extruders (screw diameter 20 mm, screw L / D = 50, screw rotation speed 150 rpm, clearance 0.5 mm), sheath component is conductive layer, core component is normal PTT Polyester composition for polymerizing PTT and forming a conductive layer in the same manner as in Reference Example 2 and Reference Example 8 except that the composite spinning for obtaining the core-sheath type composite fiber is melt-spun at a spinning temperature of 260 ° C. The product was melt-kneaded and the yarn was made to obtain conductive fibers shown in Table 2. Table 2 shows the results of the yarn physical properties. As in Reference Example 8 , a conductive fiber excellent in conductivity and yarn physical properties was obtained.

Comparative Example 4
When performing composite spinning similar to Example 1 , in Comparative Example 4, the conductive layer in Example 2 was used as the core component, and the layers other than the conductive layer were sheath components, and the ratio of the components other than the conductive layer and the conductive layer The yarn was produced without changing to obtain a drawn yarn. Although the yarn forming property was good, the conductive layer was not in the fiber surface layer, so the conductivity was inferior.

Example 4
When performing the same composite spinning as in Example 1, the same melt spinning as in Example 1 except for performing conjugate spinning to arrange to have four positions of the conductive layer shown in FIG. 1 in the fiber surface, the table Conductive fibers having the physical properties described in 2 were obtained. Although the conductive spots (standard deviation) of the obtained fibers were slightly larger than those in Example 1 , good conductive fibers were obtained.

Example 5
When composite spinning similar to Example 1 was performed, the same spinning as in Example 1 was performed except that PET obtained in Reference Example 1 was disposed as the core component and melt spinning was performed at a spinning temperature of 275 ° C. Conductive fibers having the physical properties described in 2 were obtained. The obtained fiber had good electrical conductivity.

Example 6
Using the fibers obtained in Reference Example 3, Reference Example 8 and Example 1 , after cutting into short fibers of 0.5, 1.0, 2.0 and 4.0 mm respectively, Nissan Chemical Industries After treatment with colloidal silica "Snowtex OS (registered trademark)" manufactured by Co., Ltd., polyester film "Lumirror (registered trademark) QT33 (thickness 100 μm)" manufactured by Toray Industries, Inc., acrylic ester manufactured by Dainippon Ink & Chemicals, Inc. A thickness of about 100 μm of a system adhesive DICNAL K-1500 (2% by weight of DICNAL VS-20 is used as a thickener with respect to 100% by weight of K-1500; hereinafter referred to as “adhesive A”) Then, it was applied to one side of the film, and electric flocking was applied to one side of the film to which the adhesive was applied to create a flocked body (A1 to A12; Table 3).

About flocking property (degree of success of flocking), it is almost upright (double circle), some sleeping fibers are seen (○), about half of the fibers are sleeping (△), upright As a result of visually judging that there were few things (x) and evaluating them, both were excellent as double circles.
Further, a pile woven fabric and a single tricot knitted fabric were prepared using the fibers obtained in Reference Example 3, Reference Example 8 and Example 1 , respectively, and then a brushed one was prepared, and the adhesive A was used as described above. The fabric composites B1 to B3 and C1 to C3 were produced by bonding to the polyester film. As described above, all of B1 to B3 and C1 to C3 had good brushing properties (see Table 4).

Example 7
The length of the fabric with a weaving density of 150 yarns / inch using the conductive fibers produced in Reference Example 7 and Example 3 as the warp and weft, and electrodes provided at both ends so that the length is 20 cm and the width is 5 cm. When a voltage of 100 V was applied to both electrodes of a 20 cm fabric object, a heating element whose temperature rose at a rate of temperature rise of 5 ° C./min was obtained.

Example 8
Using 12 kinds of short fibers derived from Reference Example 3, Reference Example 8 and Example 1 obtained in Example 12 (fiber lengths of 0.5, 1.0, 2.0, and 4.0 mm, respectively) Using the adhesive A of Example 6 , a rod-like object M (only metal rod) and a rod-like object N (metal bar with a urethane intermediate layer (thickness 1.5 mm) obtained by adding 5% of conductive carbon black to the metal rod) (Embodiment covered with 2cm end) is subjected to electric flocking (only the intermediate layer portion is applied to the rod-like object N), and after removing unbonded short fibers from the rod-like object, a brush roller is obtained. (Brush rollers M1 to M12 (see Table 5) for the rod-like object M, and N1 to N12 for the rod-like object N (see Table 6)). Further, the pile fabric of Example 12 was bonded to and planted on the rod-like object M to obtain brush rollers MM1 to MM3 (see Table 7). The specific resistance values of the brush roller M2 and the brush roller N2 under normal conditions were 10 ^9.3 Ω · cm and 10 ^8.6 Ω · cm, respectively. And when the specific-resistance value change in the humidity change of the brush roller N2 was measured, it was ^108.5 ohm * cm (normal conditions) ^-108.7 ohm * cm (low temperature low humidity). That is, the brush roller using the conductive fiber of the present invention was excellent because the conductive spots were small even in the humidity change. When the change in specific resistance value of the brush roller MM2 was measured in the same manner, it was 10 ^7.5 Ω · cm (normal conditions) −10 ^7.7 Ω · cm (low temperature and low humidity), and the same conductivity as the brush roller M2. The spots were small and excellent even in humidity changes.

Example 9
A monochrome laser printer in which the brush rollers M1 to M12, N1 to N12, and MM1 to MM3 obtained in Example 8 are incorporated in a cleaning device is continuously printed for a long time (10 sheets are printed and discharged per minute). When the printability was confirmed together with the humidity change in the printer, the humidity in the printer decreased from the initial 65% to 31% at about 1000 sheets starting printing, and further decreased to 25% when about 10,000 sheets were printed. Even when the number of printed sheets exceeded 20000, the sharpness of printing and the toner cleaning performance were excellent.

Example 10
Using each conductive fiber obtained in Reference Examples 3, 7, 8 and Examples 1 , 3 , one uses normal PTT fiber for warp and only uses the conductive fiber for weft. A Y-shirt was created from the plain weave (clothes P1-P5 were obtained). The other produced Y-shirts using the fibers obtained in Reference Examples 3, 7, 8 and Examples 1 and 3 for all warps and wefts (clothing Q1 to Q5). When 10 men selected at random were subjected to a monitor clothing test, all responded that they felt “I feel cold when I wear them (there is a cold feeling of contact)” for all clothing P1 to P5 and Q1 to Q5 (see Table 8).

6 is a cross-sectional view of a composite fiber used in Example 4. FIG.

Claims (8)

Conductive fiber having an average resistivity of 1.0 × 10 ^{6 to} 1.0 × 10 ¹² [Ω / cm] having a conductive layer in at least a portion of the fiber surface layer, and a standard deviation of resistivity of 0.2 or less a and, Ri conductive layer Do and a polyester component and a carbon nanotube whose main repeating structural unit at least trimethylene terephthalate, conductive fibers, characterized in der Rukoto made formed by melt composite spinning at. The ratio Y / X between the average resistivity X [Ω / cm] at a temperature of 23 ° C. and a humidity of 55% and the average resistivity Y [Ω / cm] at a temperature of 10 ° C. and a humidity of 15% is 1 claim 1 Symbol placement of conductive fibers, characterized in that in the range of ≦ Y / X ≦ 5. Conductive fibers according to claim 1 or 2, wherein the fiber surface layer is a composite fiber is covered in all conductive layers. The conductive fiber according to any one of claims 1 to 3 , wherein the content of carbon nanotubes in the conductive layer is 0.3 wt% or more and 5 wt% or less. The conductive fiber according to any one of claims 1 to 4 , wherein the conductive fiber is a conductive short fiber having a fiber length of 0.05 to 150 mm. A woven fabric comprising the conductive fiber according to any one of claims 1 to 5 at least in part. The woven fabric according to claim 6, which is a pile weave. A fabric composite comprising a fabric comprising the woven fabric according to claim 6 or 7 as at least a part thereof and adhered to a substrate.

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